Multiple-Component Remediation for Developmental Reading Disabilities: IQ, Socioeconomic Status, and...

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http://ldx.sagepub.com/ Journal of Learning Disabilities http://ldx.sagepub.com/content/early/2010/04/07/0022219409355472 The online version of this article can be found at: DOI: 10.1177/0022219409355472 published online 5 May 2010 J Learn Disabil Shapiro Robin D. Morris, Maureen W. Lovett, Maryanne Wolf, Rose A. Sevcik, Karen A. Steinbach, Jan C. Frijters and Marla B. Race as Factors in Remedial Outcome Multiple-Component Remediation for Developmental Reading Disabilities: IQ, Socioeconomic Status, and Published by: Hammill Institute on Disabilities and http://www.sagepublications.com can be found at: Journal of Learning Disabilities Additional services and information for http://ldx.sagepub.com/cgi/alerts Email Alerts: http://ldx.sagepub.com/subscriptions Subscriptions: http://www.sagepub.com/journalsReprints.nav Reprints: http://www.sagepub.com/journalsPermissions.nav Permissions: by guest on May 23, 2011 ldx.sagepub.com Downloaded from

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http://ldx.sagepub.com/content/early/2010/04/07/0022219409355472The online version of this article can be found at:

 DOI: 10.1177/0022219409355472

published online 5 May 2010J Learn DisabilShapiro

Robin D. Morris, Maureen W. Lovett, Maryanne Wolf, Rose A. Sevcik, Karen A. Steinbach, Jan C. Frijters and Marla B.Race as Factors in Remedial Outcome

Multiple-Component Remediation for Developmental Reading Disabilities: IQ, Socioeconomic Status, and  

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Journal of Learning DisabilitiesXX(X) 1 –29© 2010 Hammill Institute on DisabilitiesReprints and permission: sagepub.com/journalsPermissions.navDOI: 10.1177/0022219409355472http://journaloflearningdisabilities.sagepub.com

Multiple-Component Remediation for Developmental Reading Disabilities: IQ, Socioeconomic Status, and Raceas Factors in Remedial Outcome

Robin D. Morris1, Maureen W. Lovett2, Maryanne Wolf 3, Rose A. Sevcik1, Karen A. Steinbach2, Jan C. Frijters4, and Marla B. Shapiro1

Abstract

Results from a controlled evaluation of remedial reading interventions are reported: 279 young disabled readers were randomly assigned to a program according to a 2 × 2 × 2 factorial design (IQ, socioeconomic status [SES], and race). The effectiveness of two multiple-component intervention programs for children with reading disabilities (PHAB + RAVE-O; PHAB + WIST) was evaluated against alternate (CSS, MATH) and phonological control programs. Interventions were taught an hour daily for 70 days on a 1:4 ratio at three different sites. Multiple-component programs showed significant improve-ments relative to control programs on all basic reading skills after 70 hours and at 1-year follow-up. Equivalent gains were observed for different racial, SES, and IQ groups. These factors did not systematically interact with program. Differential outcomes for word identification, fluency, comprehension, and vocabulary were found between the multidimensional pro-grams, although equivalent long-term outcomes and equal continued growth confirmed that different pathways exist to effective reading remediation.

Keywords

treatment, dyslexia, response to intervention, intervention, reading

The prevalence of reading acquisition failure in the U.S. school‑age population continues to be a major social and political concern. Although improvements have been observed since the nation’s original 1992 report card, the National Assessment of Educational Progress (NAEP) in 2007 esti‑mated that 34% of fourth‑grade children are significantly below average in reading skills (U.S. Department of Educa‑tion: National Center for Education Statistics, 2007). When these figures are examined according to socioeconomic sta‑tus (SES) and ethnic group, the results are even more trou‑bling: 50% of children from low‑income families read below a basic level, as opposed to 21% of higher income children. By ethnic group, 54% of children who are African American, 51% of children who are Hispanic, and 23% of children who are European American read below the basic level on the NAEP.

If unresolved, the problem of reading acquisition fail‑ure will limit the future potential of more than 10 million American youth (National Reading Panel [NRP]—Report of the Subgroups, 2000; Snow, 2002). If the above trends continue, there will be an ever‑expanding academic gap

according to SES and ethnic grouping. In this article, we evaluate the efficacy of three reading intervention pro‑grams with a particular interest in assessing response to intervention by young impaired readers who differ in race, IQ, and SES.

Developmental reading disability (RD) is a term applied to those children who unexpectedly fail to learn to read, whether defined on the basis of significant reading under‑achievement or relative to expectations based on IQ, age, or grade level (Fletcher, Morris, & Lyon, 2003). Recently, there has been an increasing number of well‑controlled research reports that have focused on critical components

1Georgia State University, Atlanta, USA2The Hospital for Sick Children, University of Toronto, Ontario, Canada3Tufts University, Medford, MA, USA4Brock University, St. Catharines, Ontario, Canada

Corresponding Author:Maureen W. Lovett, The Hospital for Sick Children, University of Toronto, 555 University Avenue, Toronto M5G 1X8, CanadaEmail: [email protected]

J Learn Disabil OnlineFirst, published on May 5, 2010 as doi:10.1177/0022219409355472

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2 Journal of Learning Disabilities XX(X)

for the effective remediation of children with RD and of those at risk for not acquiring fluent reading skills and good reading comprehension. Progress has been achieved in identi‑fying the critical components of effective early reading instruc‑tion (Rayner, Foorman, Perfetti, Pesetsky, & Seidenberg, 2001), particularly for teaching basic literacy skills. Although much remains to be investigated with regard to the instruc‑tion and measurement of higher order reading fluency and comprehension skills (Biancorosa & Snow, 2006; NRP, 2000), considerable recent progress has been made in this area as well, particularly for children within the range of normal reading development (Guthrie et al., 2004, 2007; Wigfield et al., 2008; Williams, 2005; Williams et al., 2005, 2007). Issues related to teaching higher order reading skills to children with RD have been discussed in recent years (Gersten, Fuchs, Williams, & Baker, 2001; Johnston, Barnes, & Desrochers, 2008).

Much of the early intervention work on reading disabili‑ties investigated disabled readers of average IQ and SES. Decades of reliance on IQ‑achievement discrepancies in identifying children with RD resulted in the relative exclu‑sion of children with lower IQs and significant reading underachievement from research. Despite increasing recog‑nition that IQ and the IQ‑achievement discrepancy do not reliably discriminate children who will respond well to reading intervention (Shaywitz, Morris, & Shaywitz, 2008; Stage, Abbott, Jenkins, & Berninger, 2003; Vellutino, Scanlon, & Lyon, 2000), an implicit assumption persists that children without the advantages of an average to above‑average IQ and access to an enriched environment will not respond to the verbally mediated interventions that are effective with struggling readers of average IQ and SES.

Post hoc analyses of early intervention outcomes for 128 at‑risk first graders revealed that Verbal IQ was a minor con‑tributor to word identification skills relative to specific reading‑related language predictors like phonological processing, rapid naming, and orthographic skills (Stage et al., 2003). Indeed, ratings for attention provided greater prediction power than Verbal IQ in this analysis. This study identified three language‑related processing deficits that characterized at‑risk children in different combinations: deficits in phono‑logical processing skills, slow rapid naming, and deficient orthographic processing skills. Those at‑risk children with two or three of these language‑processing deficits did not grow as quickly in varied reading skills as at‑risk children with relatively intact language skills. Any of these process‑ing deficits was sufficient to slow the growth of word iden‑tification skills in intervention, regardless of the child’s IQ at entry (Stage et al., 2003).

Other studies confirm that first graders with and without reading achievement/IQ discrepancies do not show a dif‑ferential response to early intervention (Vellutino et al., 1996). Similarly, longitudinal data from Francis, Shaywitz, Stuebing, Shaywitz, and Fletcher (1996) revealed no real

differences in rate of reading growth among first‑ through ninth‑grade students, whose reading achievement was and was not discrepant from IQ. To date, however, the relative contributions of IQ and demographic variables like SES and race have never been studied prospectively in a bal‑anced factorial design to determine their relevance in pre‑dicting reading intervention outcomes.

Results from three decades of research describe a small set of core deficits in language development and in more global processing abilities that appear consistently associ‑ated with reading disabilities, particularly the most severe cases. A majority of children with developmental RD are characterized by deficits in phonological processing that are demonstrated at both sublexical and lexical levels of pro‑cessing. Such children exhibit a range of defining deficits in their explicit awareness of, and ability to manipulate, the sound structure of spoken words (Snowling & Hulme, 1993, 2005). Phonological difficulties are known to persist into adulthood for individuals with histories of RD (Shaywitz et al., 1999) and have led both to concerns about their ame‑nability to remediati on (e.g., Wagner, Torgesen, & Rashotte, 1994) and to incentives to conduct rigorous research on intervention and prevention for phonologically based read‑ing disabilities (Lyon & Moats, 1997).

A failure to acquire rapid, context‑free, word identifica‑tion skills appears to be a highly reliable indicator of most cases of severe RD (Fletcher, Lyon, Fuchs, & Barnes, 2007). Results from some intervention studies suggest that a failure to parse a syllable into sub‑syllabic units may underlie the difficulties in acquiring an alphabetic decoding strategy and in developing stable word identification and attack skills (Lovett, Warren‑Chaplin, Ransby, & Borden, 1990). Because these children do not spontaneously segment spoken sylla‑bles into smaller units, they have no basis for (a) segmenting orthographic (spelling) patterns corresponding to these units; (b) extracting rules for their synthesis; or (c) using them to decode a new word by analogy to a known word (Gaskins, Downer, & Gaskins, 1986; Lovett et al., 1994). Such deficits in word recognition processes are also thought to contribute to many forms of poor comprehension (Fletcher et al., 2007; Perfetti, 1992).

Many impaired readers are also characterized by deficits in naming speed and a profile of reading comprehension and fluency problems (Wolf, 2007). Extensive evidence from different paradigms and a growing number of languages now suggests that naming‑speed deficits (NSD) may repre‑sent a second core deficit in reading disability. Some researchers have described naming speed problems as largely independent of phonological skills (Clarke, Hulme, & Snowling, 2005; McBride‑Chang & Manis, 1996; Wolf & Bowers, 1999) and more predictive of RD than phoneme awareness in transparent and logosyllabic orthographies (L. H. Tan, Spinks, Eden, Perfetti, & Siok, 2005). Other researchers have contended that naming‑speed deficits are

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Morris et al. 3

related to central phonological processing deficits (Compton, DeFries, & Olson, 2001; Schatschneider, Carlson, Francis, Foorman, & Fletcher, 2002; Vukovic & Siegel, 2006; Wagner et al., 1997).

Regardless of their independence, naming‑speed deficits may be related to problems of dysfluency at several possible levels of print‑to‑speech mapping. Wolf and Bowers (1999, 2000) describe three potentially interrelated ways in which deficits in the processes underlying letter‑naming speed may contribute to word‑reading speed problems and to reading acquisition failure: (a) by slowing and/or preventing the development and amalgamation of rapid connections between and among orthographic, phonological, and semantic pro‑cesses at sublexical and word levels (Ehri, 1997); (b) by lim‑iting the quality of representation of common orthographic patterns in memory (Bowers, Golden, Kennedy, & Young, 1994); and (c) by increasing the amount of repeated practice needed to form all types of high‑quality representations involved in reading (Collins & Levy, 2008; Levy, 2001; Levy, Abello, & Lysynchuk, 1997). Wolf and Katzir‑Cohen (2001) discuss reading fluency as a developing process that is shaped by contributions from phonological, orthographic, semantic, syntactic, and morphological processes. Recent work has high‑lighted the interdependence of fluency and comprehension growth in the development of reading skill (Collins & Levy, 2008; Klauda & Guthrie, 2008).

Another learning deficit, in strategy learning and execu‑tive functioning, is considered an important part of reading acquisition failure. Research with children with RD has pro‑duced several reports demonstrating particular difficulties in executive processing and the acquisition of self‑regulatory strategies, and these problems appear to exist independent of their phonological processing difficulties (Swanson & Saez, 2003; Swanson & Siegel, 2001). These aspects of metacog‑nitive function are important in the context of understanding children’s lack of transfer and generalization failures (Harris, Graham, & Pressley, 1992) during reading acquisition and reading remediation. It has been suggested that even when children with RD have received strategy instruction, they may remain novices because they fail to transform simple strategies into more efficient forms (Swanson, Hoskyn, & Lee, 1999). Strategy acquisition, application, and self‑monitori ng are critical to acquisition of effective word identification and reading comprehension strategies. Strategy use and evaluation are components of reading development that become increasingly significant as the child acquires greater reading skill.

Remediating core deficits. A number of well‑controlled research studies have been reported focusing on the reme‑diation of reading problems in the early elementary grades (Foorman, Francis, Fletcher, Schatschneider, & Mehta, 1998; Scanlon & Vellutino, 1997; Torgesen, Wagner, & Rashotte, 1997a; Torgesen, Wagner, Rashotte, Lindamood, et al., 1999; Vellutino et al., 1996). Converging evidence indicates that

significant improvement can be attained on speech‑based and phonological reading measures (Foorman et al., 1998; Lovett et al., 1994; Olson, Wise, Ring, & Johnson, 1997; Torgesen, Alexander, et al., 2001; Torgesen, Wagner, Rashotte, Alexander, & Conway, 1997; Torgesen, Wagner, Rashotte, Lindamood, et al., 1999; Vellutino et al., 1996), confirming that phonologically based decoding and early reading skills are clearly “teachable aspects of reading for most children” (Moats & Foorman, 1997, p. 188).

Despite the improvements observed in children’s phono‑logically based word attack and decoding skills, training gains do not always generalize to word identification, text reading, fluency, and comprehension skills. In fact, gener‑alization of remedial gains has proved a formidable hurdle (Lovett, Ransby, Hardwick, Johns, & Donaldson, 1989; Torgesen, Alexander, et al., 2001; Torgesen, Wagner, Rashotte, et al., 1997), particularly to long‑term fluency and comprehen‑sion. Other research has characterized transfer‑of‑learning difficulties in RD as specific to printed language learning; they are not evident on other learning tasks with similar cognitive demands but no phonological processing requirements (Benson, 2000; Benson, Lovett, & Kroeber, 1997).

Torgesen et al. (1997a) suggested that the generalization problem reflects the complexity of the processing impairments seen in more severely disabled readers. In one of the most influential intervention studies to date, Torgesen et al. (1997a, Torgesen, Alexander, et al., 2001) found that poor readers made dramatically significant gains in phoneme awareness and word attack but were essentially unchanged in fluency.

Many questions remain concerning whether or not processing‑speed and fluency deficits are amenable to current treatment methods and whether intervention should focus on connected‑text, word‑level, and/or underlying, sublexical–lexical processes (e.g., letter‑pattern recognition). Some fluency training efforts have targeted the word level and have shown gains in connected text reading, fluency, and comprehension measures (Levy, 2001; A. Tan & Nicholson, 1997), but in general, addressing fluency at the sublexical and lower processing level has received relatively little attention. For years, the assumption was that greater accu‑racy in alphabetic decoding would generalize to improved fluency; increasing evidence, however, failed to support this assumption (Torgesen, Rashotte, & Alexander, 2001).

Relatively more evidence is available concerning the effectiveness of remediation directed to the core deficit in strategy learning and metacognitive control. Meta‑analyses have revealed that children with RD are closer in performance to their non‑disabled peers when intervention programs include explicit strategy instruction (Swanson et al., 1999). The strategy deficits of children at risk for reading acquisition failure encompass all aspects of reading for meaning, exposi‑tory text comprehension, and written expression. There is growing recent evidence that low‑achieving readers can make gains in reading comprehension with systematic instruction

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4 Journal of Learning Disabilities XX(X)

and practice on reading comprehension strategies (Mason, 2004; Vaughn et al., 2000). In fact, explicit strategy training and metacogniti ve instruction can provide an important com‑ponent of effective remediation for RD in the acquisition of both decoding accuracy and reading comprehension skills.

Evidence from our Toronto site provides strong empiri‑cal support for this speculation (Lovett, Lacerenza, Borden, et al., 2000). When phonological reading interventions were combined with the teaching of specific word identification strategies, and these strategies were implemented, practiced, and evaluated using self‑directing dialogue, severely dis‑abled readers demonstrated superior outcomes and steeper learning curves than when they received an equal amount of intervention in phonological or strategy training condi‑tions separately. The combined intervention conditions were associated with the greatest generalization of treatment gains for this sample of children with severe RD.

The assessments and interventions included in this study address the multidimensional nature of reading skills and the heterogeneous profiles of disabled readers. Focus is placed on the need for multiple‑component interventions for RD, the need to remediate the core deficits that limit reading acquisition, and the importance of facilitating the develop‑ment of word identification and decoding skills, reading flu‑ency, and reading comprehension abilities. A multidimensional approach to the study of RD and its effective remediation was undertaken within a factorial design that addresses the following questions:

1. Do multiple‑component remedial reading inter‑ventions produce greater gains than those target‑ing phonological reading processes alone?

2. Do multiple‑component interventions with differ‑ent metacognitive and language emphases differ from each other in their effect on reading growth and reading outcomes for children with RD?

3. Do remedial outcomes and rate of growth differ for struggling readers who vary in socioeconomic status, race, and IQ?

4. Do struggling readers demonstrate remedial growth on all dimensions of reading skill (decod‑ing accuracy, reading rate, comprehension)?

5. Are intervention‑related gains maintained on 1‑year follow‑up?

MethodStudy Overview

This study was a controlled evaluation of different reading remediation programs offered to children within public schools. Study participants included second‑ and third‑grade children initially referred by their teachers. Selection was based on a screening assessment using explicit criteria to

define RD. The study design involved random assignment of small groups of struggling readers, and their teachers, to one of four remediation conditions. The factorial design of the study attempted to develop four randomly assigned groups of struggling readers, such that each group included equal numbers of Caucasian and Black students, of students with average or below‑average family socioeconomic situ‑ations, and of students with average or below‑average IQ. Groups of four children from each sample were taught one of four remedial programs (PHAB + CSS, MATH + CSS, PHAB + WIST (PHAST), PHAB + RAVE‑O; conditions described below) by trained teachers for 70 contact hours during the school year. All children were evaluated at the beginning (0 hours), in the middle (35 hours), at the end of the 70 hours of instruction, and at 1‑year follow‑up.

ParticipantsParticipants were initially recruited in three large metro‑politan areas (Atlanta, Boston, and Toronto) on the basis of teacher identification as struggling readers. General inclu‑sion criteria consisted of the following: English as a first and primary language, age between 78 months (6 years 6 months) and 102 months (8 years 6 months), grade level at first or second grade at time of screening, and normal hearing and vision. Nine hundred fifty‑eight children were referred (see Figure 1). Children were further selected from this pool based on their performance on a screening battery that included the Kaufman Brief Intelligence Test (K‑BIT; Kaufman & Kaufman, 1990), Woodcock Reading Mastery Test–Revised (WRMT‑R; Woodcock, 1987), the Wide Range Achievement Test–3 (WRAT‑3; Wilkinson, 1993), and a brief demographic and history form completed by their par‑ents. Children were excluded if they had repeated a grade, achieved a K‑BIT Composite score below 70, or had a seri‑ous psychiatric or neurological illness. The co‑occurrence of a disorder common in RD populations (e.g., ADHD) did not exclude a child. The goal in excluding children who were repeating a grade was to control for the amount of previous educational experience of the children. In practice, however, this was not an issue because at every site, very few children referred to the project were repeating a grade.

Socioeconomic status. A parent/guardian was asked to complete a questionnaire that included basic demographic information used to evaluate socioeconomic status and ethnic‑ity. SES data from all sites were derived using two American SES scales (Entwisle & Astone, 1994; Nakao & Treas, 1992) and one Canadian SES scale (Blishen, Carroll, & Moore, 1987; Edwards‑Hewitt & Gray, 1995). Our goal was to develop an index for systematically identifying children’s families as average to above‑average SES (classified as Aver‑age SES) or below‑average SES (Low SES). To this end, a systematic evaluation of the reliability and concordance of the different scales and their combination was undertaken

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Morris et al. 5

and the results used to classify the children (see Cirino et al., 2002). The particular differences or actual levels of SES provided by the scales were not as critical as an accurate ranking of children.

Selection Criteria for Inclusion in RemediationNeither universally accepted nor universally validated criteria for defining samples or subtypes of RD children exist (Morris

et al., 1998). The current study used a sampling strategy and measurement model that allowed for the objective testing of different conceptual (categorical vs. dimensional), defini‑tional, and subtype models of RD and comparison of the inter‑action of such classification results with treatment outcomes.

The K‑BIT Composite standard score was used in screening as an index of intellectual ability, and reading levels were measured using one or more of the following indices: (a) a Reading total score calculated by averaging

958 Participants Screened Years 1-553% Cauc., 58% Male, 59% met RD criteria1

9% Discrepancy only, 25% Low Achievement only, 65% Both

305 RD2 participated in Study Years 1-5

279 completed 1 full year of intervention

83 Atlanta, 84 Boston, 112 Toronto

52% Cauc., 61% Male, 77% had 1 Yr FU3

8% Discrepancy only, 28% Low Achievement

only, 64% Both

68 Math + CSS Yrs 1-5

23 ATL, 16 BOS, 29 TOR

52% Cauc, 60% Male

69 PHAB + CSS Yrs 1-524 ATL, 13 BOS, 32 TOR

51% Cauc., 71% Male, 72% had 1 Yr FU

69 PHAB + RAVE-O Yrs 1-517 ATL, 32 BOS, 20 TOR

52% Cauc., 58% Male, 80% had 1 Yr FU

73 PHAST4 Yrs 1-519 ATL, 23 BOS, 31 TOR

52% Cauc., 56% Male, 78% had 1 Yr FU

7 Left Early3 Cauc., 3 ATL, 1 BOS, 3 TOR

26 Left during Yr 112 Cauc., 15 Male

9 Left After Math/BeforeReading

7 Cauc., 4 ATL, 3 BOS, 2 TOR

7 Left During Y2 Reading3 Cauc., 3 ATL, 1 BOS, 3 TOR

5 Left Early2 Cauc., 3 ATL, 2 TOR

6 Left Early3 Cauc., 3 ATL, 3 BOS

8 Left Early3 Cauc., 3 ATL, 3 BOS, 2 TOR

Figure 1. Participant screening, selection, attrition, and final sample who completed 70 hours of remediation1Out of 911 participants with K-BIT Composite scores greater than 69 and from whom K-BIT and all screening reading scores were obtained.2Plus 10 non-reading-disabled participants.3162 participants out of the 211 who completed 1 year of reading intervention (and not including MATH + CSS participants).4PHAST = PHAB + WISTRD = reading disability; CSS = Classroom Survival Skills; PHAB = Phonological Analysis and Blending/Direct Instruction; PHAST = Phonological and Strategy Training; RAVE-O = Retrieval, Automaticity, Vocabulary, Engagement with language, and Orthography; Cauc. = Caucasian; FU = follow-up; ATL = Atlanta; BOS = Boston; TOR = Toronto.

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6 Journal of Learning Disabilities XX(X)

the standard scores of the WRMT‑R Passage Compre‑hension, WRMT‑R Word Identification, WRMT‑R Word Attack, and WRAT‑3 Reading subtests; (b) the WRMT‑R Basic Skills Cluster score; and/or (c) the WRMT‑R Total Short Scale score. These different options were used to increase the heterogeneity of the samples’ reading profiles.

Children were included in the study if they met criteria for either a Low Achievement (LA) or an Ability‑Achievement Regression Corrected Discrepancy (DISC) determination of a reading disability (Fletcher et al., 1994). The LA crite‑ria required that a child’s K‑BIT Composite standard score was greater than 70, and at least one of their reading stan‑dard score indices was 85 (approx. the 16th percentile) or less. The DISC criteria required that at least one of the child’s reading standard score indices was at least one stan‑dard error of the estimate (approximately 13 standard score points) below their regression‑predicted reading score. This was calculated using the K‑BIT Composite standard score and an average .60 correlation between the reading and IQ scores. This classification resulted in a broadly defined sample of children with reading problems.

Of the 958 referred children, 565 children met one of these inclusion criteria: 64% met both LA and DISC RD criteria, 8% met only the DISC criteria, and 28% met only the LA criteria. Consistent with previous findings, 72% met the DISC criteria, and 92% the LA criteria.

The study used a 2 × 2 × 2 factorial design, with Race (Caucasian, Black), IQ (Average = ≥90, Below Average = 70–89), and Socioeconomic Status (Average, Low) as

critical sampling factors. The study attempted to obtain at least eight (n = 8) children in each factorial cell (total n = 64) for each of the four remediation program conditions (total study goal n = 256). No site was allowed to provide more than five (of the 8) children in any cell in any remediation condition. The final number of participants from each of the three cities was nearly comparable, with Atlanta, Boston, and Toronto contributing 31%, 29%, and 39% of the sample, respectively. Both socioeconomic groups and IQ levels were fairly evenly represented in all three cities. Twice as many participants from Atlanta were Black as opposed to White, and the reverse pattern was evident in Toronto.

These criteria and sampling requirements resulted in 305 children who were enrolled in one of the four remediation groups, with 279 completing the 70 hours of remediation and relevant remediation‑related evaluations. These 279 children are the focus of this report (see Note 1). Table 1 describes the actual final sample for each condition and the basic screening and pre‑intervention results for each remediation sample.

MeasuresBoth nationally normed, standardized, and experimental mea‑sures were used (Cirino et al., 2002; Lombardino et al., 1999) to increase sensitivity in monitoring change. This battery was given before remediation began (time 0), immediately fol‑lowing 35 hours of remediation (time 35), at the end of 70 hours of remediation (time 70), and at 1‑year follow‑ up. Because there was little information concerning the

Table 1. Demographic Data of Those Who Were Included in Growth Models (n = 279)

MATH + CSS PHAB + CSS PHAB + RAVE-O PHAST

Demographic ATL BOS TOR ATL BOS TOR ATL BOS TOR ATL BOS TOR

Total n 23 16 29 24 13 32 17 32 20 19 23 31Average age (mos.) 94.56 96.76 92.46 94.32 95.02 91.17 93.84 92.48 89.80 94.02 97.29 93.45 at BLAverage IQ 89.09 93.00 91.24 89.29 95.08 90.68 89.94 96.55 87.05 88.47 96.61 90.57IQ SD 11.13 13.24 10.86 12.49 10.77 9.13 9.41 14.27 7.52 8.90 14.20 8.51BL Reading avg. 76.60 78.90 76.84 77.83 79.40 77.60 81.00 80.44 78.95 78.01 83.18 77.24BL Reading avg. SD 9.89 8.08 9.48 9.91 9.39 7.46 5.07 7.54 5.73 8.81 9.02 6.27Ethnicity

Caucasian 6 11 17 5 9 21 4 11 17 6 8 21Black 17 4 12 19 4 10 12 4 12 13 10 9

Socioeconomic status Average 9 8 17 12 5 15 12 14 10 9 12 10Low 14 7 12 12 8 16 4 15 10 10 6 20

IQ Average 10 10 13 9 9 15 9 19 8 7 11 17Low 13 5 16 15 4 16 7 10 12 12 7 13

IQ score = Kaufman Brief Intelligence Test (K-BIT) Composite IQ; Reading avg. = average of scores on Woodcock Reading Mastery Test–Revised (WRMT-R) Word Attack, Word Identification, and Passage Comprehension and Wide Range Achievement Test–3 (WRAT-3) Reading at baseline (BL); CSS = Classroom Survival Skills; PHAB = Phonological Analysis and Blending/Direct Instruction; RAVE-O = Retrieval, Automaticity, Vocabulary, Engagement with language, and Orthography; PHAST = Phonological and Strategy Training; ATL = Atlanta; BOS = Boston; TOR = Toronto.

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Morris et al. 7

performance of young children with RD on these measures, we performed an extensive test–retest evaluation on a sub‑sample of 78 children from the 1st year of this study to evalu‑ate their reliability, the impact of practice effects, and their relationship to other related measures. These results, reported in detail in Cirino et al. (2002), indicated that overall test reli‑ability for this group of impaired readers was good, practice effects were minimal, and the experimental and nationally normed measures showed the expected relationships. Because of the extensiveness of the standardized and experimental evaluations conducted in this study, only results from the standardized, nationally normed reading measures will be reported here, although many of the experimental measures (see Cirino et al., 2002, for listing) showed similar findings.

Woodcock Reading Mastery Test–Revised. Three subtests of the WRMT‑R (Form G; Woodcock, 1987) were used: noncontextual word reading (Word Identification), non‑word decoding (Word Attack), and a cloze comprehension measure (Passage Comprehension). The Basic Skills Clus‑ter score is the composite of Word Identification and Word Attack; the Total Reading–Short Form is the composite of Word Identification and Passage Comprehension.

Wide Range Achievement Test–3. The WRAT‑3 (Wilkinson, 1993) measures both individual letter identification and word reading (Reading), the writing of letters and words to dictation (Spelling), and the timed solving of oral and writ‑ten mathematical problems (Arithmetic). The inclusion of this measure was partly to assist with assessing preachievement abilities, so as to help address floor effects on other measures for low‑performing children.

Reading efficiency test. Word Reading Efficiency and Non-word Reading Efficiency (Torgesen, Wagner, & Rashotte, 1997b) were the research versions and predecessor of the Test of Word Reading Efficiency (TOWRE; Torgesen, Wagner, & Rashotte, 1999). The Word Reading Efficiency measure included two lists of 104 real words (lists A & B) that increased in difficulty. The Nonword Reading Efficiency measure included two lists of 63 pronounceable nonwords (lists A & B). The mean number of words read on both forms in 45 seconds provided a measure of reading rate. Grade‑level normative data from the research version were used to compute standard scores (Torgesen, 1996).

Gray Oral Reading Test–III (GORT; Wiederholt & Bryant, 1992). This is a test that requires the child to orally read paragraphs of increasing difficulty and then answer compre‑hension questions. Oral reading rate and accuracy are both evaluated. This measure was completed only at preassessment (time 0) and postassessment (time 70) points.

Teacher and Program Fidelity ConsiderationsTwo of the most difficult features to control in reading inter‑vention research are teacher background and consistency and quality of program implementation, which frequently interact.

Moats (1994, 2004) has argued eloquently for the necessity of ensuring that all teachers meet an appropriate level of compe‑tence and for ongoing monitoring and feedback to ensure con‑sistent quality of instruction. All teachers in this study were hired specifically to go into one or two schools in a city and provide any of the four instructional programs being evalu‑ated. This helped to control for some of the teacher‑specific variance in background and motivation that occurs when using a school’s own teachers or when embedding teachers within only one intervention condition, thus allowing for a confound between teacher‑specific and program‑specific effects. The allocation of teachers to all instructional condi‑tions allowed teachers to be based at a specific school and multiple instructional groups from that school to be randomly assigned to different conditions. Another rationale for having all teachers teach all four intervention programs was that three conditions were based on the same core component (PHAB), which, when taught by the same teacher, would guarantee better consistency for that component, allowing the unique components of each of the intervention programs to better dif‑ferentiate themselves. Concerns about cross‑condition con‑tamination are complex because the programs were designed to share half of their components but also to have unique aspects built on those shared components.

The teachers in the study were experienced and certified teachers, with a median of 7 years of teaching experience, and most teachers already having, or in the process of obtain‑ing, graduate degrees in education. All were trained a priori to a level of specified competence during an intensive week‑long training program held at the Toronto site and were led by the developers of the intervention programs. Training activi‑ties included (a) an overview of current research related to reading development and reading disabilities, (b) direct train‑ing of each intervention and its components, (c) practice fol‑lowed by immediate feedback on the skills and strategies of the interventions, and (d) questions and discussion. A senior research teacher at each site served as the teacher trainer/mentor and provided ongoing monitoring and feedback on teachers’ performances. The teacher trainer visited the research classrooms a minimum of four times over the 70 hours to view and model lessons and to support the teachers. Indepen‑dent review, feedback, and corrections were provided as needed. A series of independent videotaped evaluations was also conducted for all teachers to determine if the interven‑tions were being carried out in the prescribed manner. All teachers from all sites, and the instructional program devel‑opers, were also part of a project listserv that provided teachers the opportunity to ask the other teachers or program developers about handling specific instructional components or challenges. The listserv ensured that all teachers across sites had consistent and timely information.

To increase implementation consistency and program integ‑rity, each intervention program had a day‑to‑day, explicit Scope and Sequence plan that was followed by all teachers

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and that allowed for integrity monitoring. Each teacher com‑pleted a daily “teacher’s log,” which detailed their instruc‑tional activities for each lesson period based on the Scope and Sequence; at the end of each instructional period, teachers detailed what content they had completed that day, the chil‑dren in attendance, children’s response to instruction, and any instructional or behavioral issues that affected instruc‑tion during that period. The teacher logs were reviewed by project staff regularly to ensure adequate progress and integ‑rity of program requirements. Random videotaped obser‑vations of the actual instructional lessons confirmed their accuracy. In addition, a senior/lead teacher at each site observed all teachers using an observational checklist four to five times during the 70 hours of instruction and provided specific implementation feedback to individual teachers to ensure that they were following the Scope and Sequence plans and instructional program expectations, that there was no cross‑intervention program contamination, and that they were actively engaged in positive instructional activities with their students. All teachers were rated on a 5‑point scale with regard to their ability to follow the Scope and Sequence of the different programs and provide consistent instructional experiences for their groups of children. When evaluated, this rating did not account for significant variance in the remedial outcomes of study participants.

Any teacher unable to consistently and effectively pro‑vide the different instructional programs was observed more frequently, given more support and feedback, and, if program implementation could not be achieved at expected levels, was discontinued on the project. Discontinuation happened only twice over the course of the project.

Any teacher could be randomly assigned to teach any of the four instructional programs to any of the randomly assigned groups in their city’s schools. Because of this, in our data analysis modeling, we included an “instructional group” factor that captured the systematic variance involved in a specific group of children with a specific teacher in a specific school. It is unfortunate that, given the sample sizes, number and types of groups taught by specific teachers, and more general design considerations, it was not possible to achieve a complete factorial design that could easily parti‑tion teacher‑ or school‑effect variance from the results.

The rationale and outline of the teacher training and mentoring procedures used in all of our intervention research are described in detail in a recent publication (Lovett et al., 2008). Additional information on training and implementa‑tion of the RAVE‑O Program components can be found in Wolf et al. (2009).

Remediation program designParticipants with similar single‑word reading levels (WRMT‑R and WRAT‑3 Reading raw scores) were assigned to an

instructional group of four children, and these groups were randomly assigned to one of four intervention programs (see detailed descriptions below). Seventy treatment ses‑sions were conduct ed within each program during the aca‑demic school year. Children were typically seen in a pull‑out format for 60 minutes a day, 5 days a week. Because we were in multiple cities, school districts, and schools, we allowed previous and current curricula to vary randomly to better evaluate the general izabi lity of our spe‑cific program results.

The intervention design included five components (PHAB, WIST, RAVE‑O, CSS, MATH) that were com‑bined, two at a time, into four different treatment programs. Two programs were control or contrast conditions (MATH + CSS; PHAB/DI + CSS, which became PHAB + CSS) and two represented experimental, multidimensional treatment programs (PHAB/DI + WIST, which became PHAST; PHAB/DI + RAVE‑O, which became PHAB + RAVE‑O). Every intervention program devoted equal time to its two components. The PHAB in each reading intervention aver‑aged 30 minutes of instructional time in every lesson. This was exactly true for PHAB + CSS and for PHAB + RAVE‑O. On average, across the 70 instructional hours of PHAST, exactly half of the instructional time was devoted to PHAB teaching. The distribution of phonological training changed, however, over the course of the 70‑hour program. In the early parts of the program, 45 minutes would be devoted to PHAB training and 15 minutes to WIST training; in later parts of the program, the instructional balance shifted such that 15 minutes would be devoted to PHAB and 45 minutes to the strategy training activities of WIST. The phonological parts of the program served as a framework on which the word identification strategies were scaffolded in PHAST.

Remediation Program ComponentsThe Classroom Survival Skills component (CSS). The CSS

control component was used twice in the present design. The CSS control treatment was paired with the phonologi‑cal component, PHAB, and with the alternate treatment control program, MATH. Participants received the same amount of intervention time and professional attention as those in the multiple‑component reading programs, but they received no direct reading remediation in CSS. The CSS lessons, 30 minutes in length, trained class room etiquette, life skills, and organizational strategies, with an empha‑sis on academic problem solving and self‑help tech niques. Parts of the program were developed using lessons adapted for research purposes from the Skills for School Success program (Archer & Gleason, 1991).

In terms of experi mental design, the inclusion of a CSS component ensures that any reading effects obtained for the PHAB + CSS condition are due just to the PHAB

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component. When this condition is compared to the PHAST (PHAB + WIST) or the PHAB + RAVE‑O conditions, it allows for a direct comparison of the additional effect of the WIST and RAVE‑O components above and beyond the PHAB component alone. In this design, the treatment programs’ effectiveness may be attribut ed to specific program content rather than to involvement in an active academic interven‑tion program or to the benefits of receiving individual atten‑tion from an experi enced special education teacher.

The Mathematics Program component (MATH). It has been estimated that 50% to 60% of children with RD exhibit poor mathematics performance (Badian, 1983). The MATH com‑ponent thus provided an active, appropriate instructional pro‑gram to teach a range of basic math concepts, number facts, computational skills, and specific problem‑solving strategies through direct instruction and dialogue/metacognitive meth‑ods. The inclusion of a math program, paired with the CSS program, provides a stricter control for changes in self‑esteem, perception by self and others, and motivation, as well as a more stringent control comparison for the specific effects of the experimental reading intervention programs. After the 70‑hour posttreatment assessment, participants in the MATH + CSS control groups were offered a place in PHAST or PHAB + RAVE‑O for ethical reasons.

Phonological Analysis and Blending/Direct Instruction compo-nent (PHAB). The PHAB program focuses on remediating basic phonological analysis and blending deficits and forms a foundation on which the current multidimensional inter‑ventions are based. PHAB trains sound analysis and blend‑ing skills and directly teaches letter‑sound and letter‑ cluster‑sound correspondences. Content is introduced in a highly structured sequence of steps, with multiple opportu‑nities for overlearning, until children reach a defined “mas‑tery” criterion. The PHAB program focuses on instruction in word segmentation and sound blending skills and attempts to remediate the core phonological deficits of disabled readers, so that reliable letter‑sound knowledge and effec‑tive decoding and word identification skills can be acquired. The program uses many elements of direct instructional materials developed by Engelmann and his colleagues at the University of Oregon, specifically, the Reading Mastery Fast Cycle I/II Program (Engelmann & Bruner, 1988).

Word Identification Strategy Training component (WIST; Lovett et al., 1994). The WIST program instructs children in the acquisition, use, and monitoring of four different word identification strategies: (a) word identification by analogy, (b) seeking the part of the word that you know, (c) attempt‑ing variable vowel pronunciations, and (d) “peeling off” prefixes and suffixes in a multisyllabic word. Every WIST lesson begins with instructional time devoted to the prereq‑uisite skills necessary to use the strategies effectively. This skill‑building part of the lesson includes learning and prac‑ticing 120 key word patterns (Gaskins et al., 1986), learning

different vowel pronunciations, and learning variant vowel combinations (ea, oo, ow, ie) and affixes (pre, re, un, ing, ly, ment). Most of the lesson is reserved for explicit WIST strategy instruction and application, with some discussion of explicit metacognitive issues such as strategy implemen‑tation, strategy choice, and self‑monitoring. The WIST pro‑gram emphasizes explicit training of the specific WIST strategies and extensive dialogue‑directed practice with their implementation. In addition, the program teaches a system of metacognitive mnemonics to help the children acquire general routines important to effective strategy application and evaluation (e.g., the SAME [select, apply, monitor, evaluate] Plan).

PHAST program (PHAB + WIST; Lovett, Lacerenza, &Borden, 2000). Research findings from the Toronto site have demonstrated the efficacy of a sequential combination of phonologically and strategy‑based interventions (Lovett, Lacerenza, Borden, et al., 2000) and lend support to an integration of these approaches into a single intervention program. Called PHAST for “The Phonological and Strategy Training Program,” this program uses PHAB’s program of phonological remediation as a framework on which each of the four WIST strategies are introduced and scaffolded. By 70 hours of intervention, children acquire a phonological letter‑sound decoding strategy (“Sounding Out”), a word identification‑by‑analogy strategy (“Rhyming”), a strategy for separating affixes in multisyllabic words (“Peeling Off”), a strategy for seeking familiar parts of unfamiliar words (“I Spy”), and a strategy for attempting variable vowel pro‑nunciations (“Vowel Alert”). Thus, the PHAST program allows evaluation of a multidimensional intervention that addresses phonological core deficits, orthographic and morphological components, and the more general strategy learning deficiencies associated with RD.

RAVE-O program (Retrieval, Automaticity, Vocabulary, Engage-ment with language, and Orthography; Wolf, Miller, & Donnelly, 2000). The RAVE‑O program extends traditional emphases on phonological decoding processes to incorporate systematic emphases on four other targeted linguistic systems, critical to fluent comprehension. These include orthography, semantics, syntax, and morphology. The program directly addresses pro‑cesses potentially underlying weaknesses in subtypes of chil‑dren with RD who exhibit NSD and fluency problems (see Katzir, Kim, Wolf, Morris, & Lovett, 2008; Wolf & Bowers, 1999). Based on theoretical accounts of reading fluency and comprehension (Wolf & Katzir‑Cohen, 2001), RAVE‑O’s basic premise is that the more the child knows about a word (i.e., phonemes, orthographic patterns, semantic meanings, syntactic uses, and morphological roots and affixes), the faster the word is decoded, retrieved, and comprehended. Children learn a group of core words each week that exemplify these critical linguistic principles and learn daily to make explicit connections across these linguistic systems. Core words are

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first introduced with their multiple meanings, and then each word’s phoneme‑level information is connected to its ortho‑graphic patterns. Children learn orthographic “chunks” in multiple and creative formats, including specifically designed computerized games that include varying rates of presentation (Wolf & Goodman, 1996).

A range of metacognitive strategies enables children to segment the most common orthographic and morphologi‑cal units in words. For example, the strategy called “Ender Benders” helps children quickly recognize common mor‑pheme endings that change (that is, “bend”) the word’s meaning. Daily dual instruction in vocabulary and explicit retrieval strategies serves to enhance semantic growth and the speed and accuracy of lexical retrieval, often problem‑atic in children with RD. Fluent comprehension for connected text is addressed through metacognitive comprehension strategies implemented with a series of specially written RAVE‑O Minute Stories, whose controlled vocabulary incor‑porates the phonemic and orthographic patterns, multiple meanings, and varied syntactic contexts of core words.

ResultsSuccess of Randomization

Random assignment to intervention condition was designed to ensure equivalent mean baseline skills at the beginning of the intervention year. Multivariate analysis of variance did not indicate significant differences between the four groups at baseline in mean K‑BIT or WISC‑III IQ scores, or on standardized reading measures (WRMT, WRAT, GORT, TOWRE). Overall F tests for group differences were signifi‑cant, however, for key measures of baseline reading‑related skills (Word Blending, Elision, and Test of Word Finding). In all cases, PHAST group means were significantly higher than those for the PHAB + RAVE‑O condition. However, dif‑ferences for remediation condition become nonsignificant when analyses are run controlling for baseline phonological processing skills (Elision + Word Blending raw scores).

Data Analysis StrategyIndividual growth curve methodology was used to analyze changes on each reading measure and the correlates of these changes over the course of the 70‑hour remediation and at 1‑year follow‑up. See Table 2 for unadjusted standard score results for all reading measures at all time points and Table 3 for the unadjusted raw score results for all outcome mea‑sures at all time points. Separate models were constructed to analyze growth and outcomes at the 70‑hour posttest and at the 1‑year follow‑up. The 1‑year follow‑up models did not include the children participating in the MATH + CSS con‑trol group who crossed over following the 70 hours

of remediation into one of the multicomponent reading remediation programs for ethical reasons, therefore affect‑ing the overall sample size and total variance estimates and making direct comparisons with the 70‑hour outcome results difficult. Post hoc analysis of the MATH + CSS group’s response to the PHAB + RAVE‑O or PHAST reme‑diation program allowed for a within‑study replication evaluating the effect of these two remediation programs.

Individual growth parameters were estimated using SAS‑Proc Mixed and restricted maximum likelihood (REML)estimation procedures. In addition to time (0‑hour baseline; 35‑hour, 70‑hour posttest; 1‑year follow‑up) being nested within individual children, individual children were nested within instructional group (groups of four children taught together) and intervention condition (four remediation pro‑grams), with IQ (low, average), SES (low, average), and race (Black, Caucasian) as primary factors within the design. Age and initial levels (baseline) of phonological processing and rapid naming were used as covariates. Because of the com‑plexity of this four‑level model, the process and results of model building will be described only for prototypical read‑ing outcome measures, with results from the most parsimo‑nious final models summarized for the remaining variables.

All continuous predictors and covariate variables were grand‑mean centered at either the 70‑hour posttest or the 1‑year follow‑up depending on the analysis. Using this approach, the intercepts in these models represented the chil‑dren’s expected performance at the end of the remediation program or 1 year later. Specifically, the intercept is the CSS + Math (control) children’s expected level—so that estimates for the intervention conditions represent raw score differences (increases) for the remediation program groups, as compared to the control children’s mean. Changes over time, or slope, in these models represent mean incremental change in raw scores from one time point to the next, and an interaction with slope suggests different rates of change depending on the children’s characteristics. Initial analysis focused on children’s change over the course of the remediation programs. In general, vari‑ous models evaluating linear growth with random or fixed intercepts or slopes were evaluated, along with curvilinear components to assess whether the outcome measure or aca‑demic skill plateaued over time. The model with random inter‑cepts and growth (slope) terms will be typically presented unless otherwise noted. If significant variance was revealed in the individual intercepts and slopes in the unconditional model, then conditional model building evaluated the extent that outcomes, or rates of change, varied for instructional con‑ditions or teaching group, as well as for factors such as IQ, SES, race, age, or a child’s initial phonological processing or rapid naming abilities, and various interaction terms. Predictors/covariates with mean parameter values that did not differ from zero in these models were dropped in order to develop the most parsimonious models. Changes in model fit

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were also evaluated by examining chi‑square differences in –2 residual log‑likelihood (LL) estimates in nested models.

A final model will be reported that is the most parsimo‑nious conditional model in which only primary factors of focus (IQ, SES, race) and significant fixed effect terms from the fully conditional model were retained. It should be noted that maximum likelihood (ML) estimation proce‑dures were used during earlier model building but that final estimates were obtained using REML. The decision to include random terms for slope and intercept was deter‑mined a priori. Random terms for slope were dropped only for untenable models. Slightly different best reduced

models did characterize different outcome measures; over‑all, however, a highly consistent pattern of results was revealed. In general, after taking into account the influence of instructional condition and teaching group, these pre‑dictors reduced the intercept or outcome variance by another 10% to 25%. Contrasts focused on outcomes (inter‑cepts), investigating whether the interventions resulted in different final levels of performance following remedia‑tion, or if the rates of change (slopes) or deceleration in growth (quadratic) varied as a function of treatment condi‑tion (intervention condition by slope interaction and inter‑vention condition by quadratic interaction, respectively).

Table 2. Achievement Measures: Unadjusted Standard Score Means and Standard Deviations for Each Outcome Measure at Each Testing Point

Baseline 35 Hours 70 Hours 1 Yr Follow-Up

Outcome Measure M SD M SD M SD M SD

WRMT-R Word Attack PHAST 74.01 10.58 80.51 11.32 83.01 9.92 81.20 11.15PHAB + RAVE-O 75.03 8.06 83.17 9.04 84.45 9.75 84.76 12.61PHAB + CSS 72.40 9.64 77.06 11.03 77.88 12.02 75.84 15.83MATH + CSS 73.09 11.39 74.00 13.94 73.07 15.22 78.21 14.29

Word Reading Efficiency Nonwords PHAST 81.76 5.56 89.59 9.48 86.27 7.34 85.65 10.69PHAB + RAVE-O 80.28 3.19 85.61 6.85 88.12 7.59 88.14 11.05PHAB + CSS 79.79 4.37 81.39 4.29 83.20 4.88 82.11 10.11MATH + CSS 80.32 3.83 84.26 6.61 83.00 6.92 83.05 9.96

WRMT-R Word Identification PHAST 78.29 10.00 80.41 10.52 83.27 10.42 81.27 11.74PHAB + RAVE-O 79.63 7.81 80.65 9.16 83.81 8.20 82.15 11.77PHAB + CSS 77.86 10.53 78.99 11.00 80.48 11.31 75.93 14.96MATH + CSS 78.40 10.55 78.09 12.05 77.69 13.46 77.46 14.42

WRAT-3 Reading PHAST 80.48 9.04 82.12 9.44 86.97 10.16 87.16 11.30PHAB + RAVE-O 77.94 5.75 80.00 8.22 85.29 9.63 89.38 11.05PHAB + CSS 77.93 8.72 79.12 8.04 81.32 8.81 82.16 12.96MATH + CSS 78.82 9.05 78.75 9.90 77.85 11.27 84.21 12.54

Word Reading Efficiency Real Words PHAST 69.86 9.98 76.31 12.74 81.21 12.44 81.15 15.43PHAB + RAVE-O 68.43 7.32 74.93 10.04 80.97 10.98 84.12 15.01PHAB + CSS 68.32 9.47 72.94 11.10 77.77 12.40 76.76 16.73MATH + CSS 67.69 6.75 72.41 9.96 75.65 12.09 76.44 15.73

WRMT-R Passage Comprehension PHAST 77.86 9.55 81.01 10.82 82.86 10.64 81.77 12.46PHAB + RAVE-O 76.68 10.98 79.39 10.17 82.21 10.26 82.48 12.99PHAB + CSS 76.43 12.02 78.80 10.60 79.61 11.24 78.18 15.52MATH + CSS 77.04 11.91 75.90 14.32 76.32 14.64 78.35 13.46

GORT Oral Reading Quotient PHAST 74.22 8.62 — — 77.38 9.98 79.69 14.60PHAB + RAVE-O 75.33 7.63 — — 81.73 10.51 80.37 13.74PHAB + CSS 74.64 7.20 — — 77.66 11.87 77.32 14.36MATH + CSS 73.20 9.47 — — 75.32 10.96 75.48 13.33

WRMT-R = Woodcock Reading Mastery Test–Revised; WRAT-3 = Wide Range Achievement Test–3; CSS = Classroom Survival Skills; PHAB = Phonological Analysis and Blending/Direct Instruction; RAVE-O = Retrieval, Automaticity, Vocabulary, Engagement with language, and Orthography; PHAST = Phonological and Strategy Training.

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Three orthogonal contrasts were specified. The first con‑trast was the overall contrast between the reading interven‑tion programs and the control condition (MATH + CSS)—that is, were the reading intervention programs beneficial? The second contrast compared the multidimensional interven‑tions to the phonological‑only control program (PHAST and PHAB + RAVE‑O vs. PHAB + CSS)—that is, did the multiple‑component models produce different results from

the phonological control program? The third contrast was between the two multidimensional interventions (PHAST vs. PHAB + RAVE‑O)—that is, did the two multiple‑com‑ponent interventions differ from each other? The 1‑year follow‑up models included only the three active reading interventions because the MATH + CSS group was not included. Two program contrasts were available in these models: the contrast between the multidimensional

Table 3. Achievement Measures: Unadjusted Raw Score Means and Standard Deviations for Outcome Measures at Each Testing Point

Baseline 35 Hours 70 Hours 1 Yr Follow-Up

Outcome Measure M SD M SD M SD M SD

WRMT-R Word Attack PHAST 3.26 4.09 8.46 6.04 11.68 6.67 15.28 7.66PHAB + RAVE-O 1.74 2.24 8.22 5.03 11.65 6.20 16.95 8.70PHAB + CSS 1.49 2.19 5.47 4.66 7.49 5.36 12.41 8.56MATH + CSS 2.22 3.01 4.77 4.18 5.77 5.47 13.31 7.71

Word Reading Efficiency Nonwords PHAST 4.00 4.54 11.45 8.79 7.42 5.22 13.33 9.47PHAB + RAVE-O 1.77 1.88 6.66 5.82 8.07 4.99 13.08 9.61PHAB + CSS 1.34 1.73 3.50 2.97 4.98 3.81 9.10 8.39MATH + CSS 2.40 2.80 5.96 4.92 4.14 3.94 9.93 6.85

WRMT-R Word Identification PHAST 21.51 13.49 30.47 14.37 38.51 12.41 48.22 11.20PHAB + RAVE-O 16.65 11.01 27.25 11.50 35.70 10.34 47.32 11.12PHAB + CSS 17.01 12.63 25.75 13.65 32.21 13.24 41.33 15.77MATH + CSS 17.33 11.88 25.41 13.39 29.15 14.73 43.04 14.00

WRAT-3 Reading PHAST 20.36 3.51 22.25 3.89 25.03 4.16 27.30 4.35PHAB + RAVE-O 18.43 2.53 21.19 3.15 23.84 3.42 27.72 3.98PHAB + CSS 18.23 3.60 20.52 3.45 22.31 3.44 25.25 4.87MATH + CSS 18.87 3.12 20.57 3.35 21.12 4.00 26.28 4.47

Word Reading Efficiency Real Words PHAST 14.79 10.80 21.15 12.76 25.80 12.31 36.89 13.18PHAB + RAVE-O 10.41 7.65 16.50 9.59 22.49 10.61 36.08 12.51PHAB + CSS 11.46 9.70 16.04 11.32 20.72 12.44 31.16 15.37MATH + CSS 11.39 7.64 16.04 10.18 19.18 11.95 31.88 13.93

WRMT-R Passage Comprehension PHAST 10.16 6.97 15.89 8.78 19.68 8.12 25.61 8.52PHAB + RAVE-O 7.59 6.30 13.01 7.17 17.74 7.61 25.33 9.01PHAB + CSS 7.86 6.83 12.96 8.01 15.87 8.44 22.93 10.40MATH + CSS 8.15 5.93 12.03 8.44 14.71 8.85 23.00 8.70

WRAT-3 Spelling PHAST 17.35 2.70 18.96 2.87 20.33 2.64 21.89 2.62PHAB + RAVE-O 16.99 1.87 18.42 1.82 19.48 1.98 21.68 2.30PHAB + CSS 16.69 2.67 17.90 2.41 19.10 2.85 20.80 3.11MATH + CSS 16.66 2.60 18.07 2.63 18.37 3.13 21.15 2.88

WRAT-3 Arithmetic PHAST 18.07 3.43 19.90 2.94 21.15 3.69 25.14 4.39PHAB + RAVE-O 17.48 3.17 19.71 2.59 20.76 2.81 23.62 3.38PHAB + CSS 17.16 3.65 19.00 4.18 20.43 3.94 23.69 4.27MATH + CSS 17.96 3.14 20.10 3.54 21.21 3.79 23.47 3.93

WRMT-R = Woodcock Reading Mastery Test–Revised; WRAT-3 = Wide Range Achievement Test–3; CSS = Classroom Survival Skills; PHAB = Phonological Analysis and Blending/Direct Instruction; RAVE-O = Retrieval, Automaticity, Vocabulary, Engagement with language, and Orthography; PHAST = Phonological and Strategy Training.

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interventions and the phonological‑only control program (PHAST and PHAB + RAVE‑O vs. PHAB + CSS) and the contrast between the two multidimensional interventions (PHAST vs. PHAB + RAVE‑O).

Nonword Reading Models (WRMT-R Word Attack; TOWRE NWRE)Results of the first conditional model using Word Attack raw scores as the outcome measure at 70‑hour posttest revealed significant fixed effects for intervention condition and for instructional group (both ps < .001) and a signifi‑cant interaction between the linear growth term and instruc‑tional group (p < .05). Adding these fixed effects to the model decreased random variance around the intercept by 60%. These results indicate that outcomes at the end of intervention (the intercept) differed across intervention con‑ditions, and both outcome and rate of change over time (the slope/linear growth) differed by teaching groups. Significant variability remained for the intercept and slope, however, indicating that additional predictors of these parameters were needed for a more complete model.

In the most parsimonious model (Table 4), 70‑hour post‑test outcome continued to be significantly different across intervention condition (p < .001). Outcome and rate of lin‑ear growth were also significantly (p < .001) affected by teaching group. Outcome and growth rates were not differ‑ent for the factors of IQ, race, or SES. Outcome was signifi‑cantly affected by both initial phonological processing and rapid naming (p < .001), but growth rate was only affected by initial rapid naming (p < .05). The inclusion of baseline measures of phonological processing and rapid naming reduced unexplained variance around the intercept by an additional 27%, as compared to the first conditional model with instructional condition and teaching group alone.

Individual outcome contrast comparisons using model‑based means estimates revealed significant differences between the three reading programs and the MATH + CSS control condition and between the two multidimensional programs and the phonological control condition. PHAST and PHAB + RAVE‑O were associated with superior out‑comes to the PHAB + CSS condition. Post hoc comparisons indicated that the PHAB + CSS condition was associated with better outcomes on this measure than the MATH + CSS program. Significant differences in WRMT‑R Word Attack 70‑hour posttest scores were not found between the two multidimensional programs. Contrasts comparing dif‑ferences in the rate of skill growth between treatment groups were nonsignificant.

At 1‑year follow‑up, the first conditional model again revealed significant outcome differences for intervention condition and teaching group (p < .01) and a significant interaction between intervention condition and rate of

linear growth (p < .01). Although outcomes continued to be differentiated by intervention condition and teaching group 1 year later, continued change in long‑term growth was still being affected by intervention condition.

In the most parsimonious 1‑year follow‑up model, long‑term outcomes were still being affected by intervention con‑dition (p < .01) and teaching groups (p < .05), and growth rates were different for the intervention conditions (p < .01). One‑year outcomes showed significant effects for initial phonological processing and naming speed (p < .01), whereas growth showed a marginal interaction with initial naming speed (.05 < p < .06). The effects of baseline naming speed on skill growth were somewhat attenuated by the end of the follow‑up year (p = .06). The addition of these base‑line covariates reduced the amount of unexplained variance in the intercept by only 8.6% at the 1‑year follow‑up.

At 1‑year follow‑up, outcomes (p < .01) and rates of linear growth (p < .05) were significantly different between the two multidimensional programs and the phonological‑only control condition. The contrast between the PHAST and PHAB + RAVE‑O reflected a faster rate of skill growth for students in the PHAB + RAVE‑O condition (p < .03) after 1 year and a marginally better mean outcome score (.05 < p < .10).

For the TOWRE Nonword Reading Efficiency (NWRE) measure (see Table 5), intervention condition (p < .001), teaching group (p < .01), and initial phonological process‑ing skills and rapid naming speed, but not SES, IQ, or race, significantly affected outcome scores at 70‑hour posttest. No other predictors contributed to posttest scores or skill growth on Nonword Reading Efficiency.

Students participating in one of the multidimensional reading interventions did not outperform math or phono‑logical control students on Nonword Reading Efficiency; results for the PHAST and PHAB + RAVE‑O interventions were not significantly different. At the 1‑year follow‑up, stu‑dents receiving the two multidimensional interventions out‑performed the phonological control on the TOWRE NWRE. To be elaborated in a future study, baseline phonological processing and rapid naming skills remained strongly asso‑ciated with outcome scores at follow‑up as well.

Summary for Nonword Reading ModelsAt the end of 70 hours of instruction, students participating in the multidimensional intervention programs (PHAST, PHAB + RAVE‑O) demonstrated significantly stronger word attack skills, and these differences continued to be evident on follow‑up testing 1 year later. The phonologi‑cal‑only control program was significantly stronger than the math control program. Teaching groups affected both rates of skill growth (slope) and outcome scores (intercept) at the end of intervention, but these effects were attenuated by follow‑up 1 year later. Significant curvilinear growth

by guest on May 23, 2011ldx.sagepub.comDownloaded from

14

Tabl

e 4.

Sig

nific

ant

Fixe

d Ef

fect

s in

Bes

t R

educ

ed M

odel

for W

RM

T-R

Rea

ding

Mea

sure

s

W

ord

Att

ack

Wor

d ID

Pa

ssag

e C

omp.

Ba

sic

Skill

s To

tal R

eadi

ng

70

Hrs

1

Yr

70 H

rs

1 Y

r 70

Hrs

1

Yr

70 H

rs

1 Y

r 70

Hrs

1

Yr

Follo

w-U

p

Follo

w-U

p

Follo

w-U

p

Follo

w-U

p

Follo

w-U

p

Fixe

d ef

fect

s

Inte

rven

tion

31.0

8***

6.

81**

19

.74*

**

5.89

**

9.81

***

28

.96*

**

7.38

***

19.4

6***

4.

01*

Gro

up

2.73

***

1.46

* 2.

54**

* 2.

02**

* 2.

11**

* 2.

23**

* 2.

10**

* 1.

72**

2.

13**

* 2.

11**

*In

terv

entio

n ×

Slop

e

5.06

**

7.87

***

6.75

**

2.17

a 4.

64**

3.

10*

4.92

**

3.84

**

5.71

**G

roup

× S

lope

1.

97**

*

2.64

***

2.23

***

2.37

***

2.08

***

2.19

***

2.01

***

2.39

***

2.64

***

SES

5.37

* 5.

35*

5.41

* 2.

78a

4.36

* 5.

19*

IQ

4.92

*

Et

hnic

ity

2.89

a 2.

77*

2.

83*

Age

5.

96*

5.28

*

BL P

HO

N

26.4

4***

27

.46*

**

22.3

5***

15

.50*

**

4.74

* 8.

05**

36

.52*

**

23.7

5***

21

.82*

**

15.0

1***

BL R

AN

lett

ers

16.3

8***

6.

99**

38

.62*

**

15.5

4***

26

.65*

**

16.3

4***

45

.00*

**

20.4

6***

46

.08*

**

24.9

7***

Line

ar g

row

th

10.0

3**

12.8

4***

10

0.23

***

102.

59**

* 43

.92*

**

80.3

8***

31

.96*

**

12.0

0***

60

.80*

**

64.5

6***

Cur

vilin

ear

grow

th

16.8

3***

52

.52*

**

24.2

8***

12

6.76

***

8.21

**

24.9

0***

90

.08*

**

293.

41**

* 49

.79*

**

150.

56**

*O

ther

inte

ract

ions

BL R

AN

× In

terv

entio

n

4.

15**

2.98

*

3.45

* BL

RA

N ×

Slo

pe

5.00

* 3.

65a

Et

hnic

ity ×

Inte

rven

tion

2.64

a 3.

27*

2.28

a 3.

19*

Cur

vilin

ear ×

Inte

rven

tion

3.17

*

SE

S ×

Inte

rven

tion

3.

34*

In

terv

entio

n co

ntra

sts

(out

com

e)

R

eadi

ng C

ondi

tions

vs.

68

.15*

**

52

.38*

**

24

.48*

**

75

.00*

**

51

.92*

**

M

ATH

+ C

SS

Rea

ding

Con

ditio

ns v

s.

25.3

6***

10

.27*

* 5.

97**

10

.58*

* 4.

72*

11

.76*

**

12.3

9***

4.

29*

5.82

*

PHA

B +

CSS

PH

AST

vs.

PHA

B +

RA

VE-

O

3.

16a

In

terv

entio

n co

ntra

sts

(slo

pe)

M

ultic

ompo

nent

vs.

MAT

H +

CSS

17

.87*

**

7.

06**

M

ultic

ompo

nent

vs.

PHA

B +

CSS

4.81

* 4.

86*

7.63

**

3.85

a

6.71

* 4.

57*

4.03

* PH

AST

vs.

PHA

B +

RA

VE-

O

5.

16*

5.

74*

8.

68**

5.16

*

8.93

**

Onl

y F

valu

es w

ith p

< .1

0 ar

e re

port

ed. S

ES =

soc

ioec

onom

ic s

tatu

s; B

L =

base

line

scor

es; W

RM

T-R

= W

oodc

ock

Read

ing

Mas

tery

Tes

t–Re

vised

; CSS

= C

lass

room

Sur

viva

l Ski

lls; R

eadi

ng C

ondi

tions

=

PHA

ST, P

HA

B +

RA

VE-

O, P

HA

B +

CSS

; M

ultic

ompo

nent

= P

HA

ST, P

HA

B +

RA

VE-

O; G

roup

= t

each

ing

grou

p; P

HO

N =

Pho

nolo

gy; R

AN

= R

apid

Aut

omat

ized

Nam

ing.

a p <

.10.

*p

< .0

5. *

*p <

.01.

***

p <

.001

.

by guest on May 23, 2011ldx.sagepub.comDownloaded from

15

Tabl

e 5.

Sig

nific

ant

Fixe

d Ef

fect

s in

Bes

t R

educ

ed M

odel

N

onw

ord

W

RAT

Rea

ding

W

ord

Rea

ding

Effi

cien

cy

Rea

ding

Effi

cien

cy

WR

AT S

pelli

ng

WR

AT A

rith

met

ic

70

Hrs

1

Yr

70 H

rs

1 Y

r 70

Hrs

1

Yr

70 H

rs

1 Y

r 70

Hrs

1

Yr

Follo

w-U

p

Follo

w-U

p

Follo

w-U

p

Follo

w-U

p

Follo

w-U

p

Fixe

d ef

fect

s

Inte

rven

tion

22.0

1***

6.

12**

9.

49**

*

11.7

0***

3.

87*

17.0

5***

3.

56*

G

roup

1.

53*

1.96

***

2.56

***

1.70

**

2.11

***

2.

95**

* 2.

64**

* 1.

46*

Inte

rven

tion ×

Slop

e 7.

04**

* 6.

49**

3.

12*

4.51

**

4.

34*

4.70

**

Gro

up ×

Slo

pe

1.

84**

2.

08**

* 1.

45*

1.72

**

1.79

**

1.52

* SE

S 5.

79*

6.

01*

5.

68*

5.18

* 9.

31**

IQ

4.

18*

Ethn

icity

Age

10

.36*

* BL

PH

ON

17

.65*

**

19.0

6***

10

.89*

**

6.87

**

12.1

9***

15

.45*

**

25.5

6***

12

.89*

**

11.8

7***

BL

RA

N le

tter

s 36

.69*

* 26

.19*

**

37.4

2***

26

.06*

**

9.11

**

9.18

**

36.0

1***

23

.46*

**

12.7

6***

Li

near

gro

wth

58

.56*

**

10

1.00

***

362.

45**

* 3.

40a

42.3

7***

12

.65*

**

42.8

8***

8.

64**

C

urvi

linea

r gr

owth

6.

38**

11.1

2***

15

.58*

**

10.2

3**

Oth

er in

tera

ctio

ns

BL

PH

ON

× S

lope

2.

89a

Qua

drat

ic ×

Inte

rven

tion

2.85

*

2.95

*

Et

hnic

ity ×

Inte

rven

tion

2.72

* 3.

36*

3.15

* 2.

98a

3.85

**

BL R

AN

× S

lope

15

.27*

**

10.6

1***

4.22

**

IQ

× In

terv

entio

n

2.

58*

2.

65*

BL R

AN

× In

terv

entio

n

4.

52**

In

terv

entio

n co

ntra

sts

(out

com

e)

R

eadi

ng C

ondi

tions

vs.

53

.03*

**

25

.02*

**

44

.97*

**

M

ATH

+ C

SSM

ultic

ompo

nent

vs.

PHA

B +

CSS

9.

98**

10

.74*

**

3.

91*

7.

19**

6.52

* PH

AST

vs.

PHA

B +

RA

VE-

O

3.27

a

3.29

a

In

terv

entio

n co

ntra

sts

(slo

pe)

R

eadi

ng C

ondi

tions

vs.

15

.77*

**

7.

29**

13.7

3***

M

ATH

+ C

SSM

ultic

ompo

nent

vs.

PHA

B +

CSS

4.

28*

3.93

*

4.03

*

4.95

*

PHA

ST v

s. PH

AB

+ R

AV

E-O

8.76

**

4.

94*

4.

12*

Onl

y F

valu

es w

ith p

< .1

0 ar

e re

port

ed. S

ES =

soc

ioec

onom

ic s

tatu

s; B

L =

base

line

scor

es; W

RA

T =

Wid

e Ra

nge

Achi

evem

ent T

est;

CSS

= C

lass

room

Sur

viva

l Ski

lls; R

eadi

ng C

ondi

tions

= P

HA

ST, P

HA

B +

R

AV

E-O

, PH

AB

+ C

SS;

Mul

ticom

pone

nt =

PH

AST

, PH

AB

+ R

AV

E-O

; Gro

up =

tea

chin

g gr

oup;

PH

ON

= P

hono

logy

; RA

N =

Rap

id A

utom

atiz

ed N

amin

g.a p

< .1

0. *

p <

.05.

**p

< .0

1. *

**p

< .0

01.

by guest on May 23, 2011ldx.sagepub.comDownloaded from

16 Journal of Learning Disabilities XX(X)

suggests that the rate of change, overall, slowed somewhat over time. Outcomes (at 70 hours or follow‑up) were not dif‑ferentially affected by demographic factors such as ethnic‑ity, IQ, and SES, whereas baseline levels of phonological processing and rapid naming skills affected outcome both at the end of treatment and at the 1‑year follow‑up. Baseline rapid naming skills affected rate of nonword reading skill growth during the year of active intervention; these effects were only marginal when follow‑up scores were included in the model. PHAST and PHAB + RAVE‑O were associ‑ated with equivalent but superior outcomes and steeper growth over the course of the interventions, whereas at 1‑year follow‑up, PHAB + RAVE‑O enjoyed an advan‑tage in continued linear growth. It is noteworthy that chil‑dren receiving the two multidimensional interventions maintained their gains and demonstrated superior, contin‑ued growth a year following the 70‑hour interventions.

Word Identification Models (WRMT-R Word Identification, TOWRE WRE, WRAT Reading)Significant differences among intervention conditions and teaching groups were also found for Word Identification raw scores (see Table 4) at the end of 70 hours (p < .001). Curvilinear growth was also significant (p < .001), suggest‑ing a change in growth rate over the intervention time. Mean outcome scores and growth rates did not vary sys‑tematically as a function of IQ, SES, or race. Initial phono‑logical skills and rapid naming speed significantly affected outcome scores (p < .001) but not rate of skill growth. The interaction between initial naming speed and intervention condition was also significant (p < .01), indicating that the effect of initial naming speed varied systematically as a function of intervention condition.

Comparisons of adjusted group means indicated higher posttest means and stronger rates of skill growth for stu‑dents receiving one of the three reading interventions in comparison to the MATH + CSS control condition, and for the PHAST and PHAB + RAVE‑O programs relative to the PHAB + CSS control program. Significant differences in mean outcome score or growth rate between the two mul‑tidimensional reading interventions were not found.

At 1‑year follow‑up, significant differences in outcome score and growth rate were still evident for intervention conditions (p < .01) and teaching groups (p < .001). Initial phonological skill and rapid naming speed continued to significantly (p < .001) predict outcome scores as well.

Students receiving multidimensional interventions con‑tinued to demonstrate higher outcome scores (p < .01) and faster rates of skill growth (p < .01) than students receiving the phonological‑only control intervention. The contrast between PHAST and the PHAB + RAVE‑O programs was significant for linear slope (p < .05) a change from the intervention period results.

Intervention condition (all ps < .001), teaching group (all ps < .05), and initial phonological processing skills and rapid naming speed significantly affected outcome scores on both the TOWRE Word Reading Efficiency and the WRAT Reading measures at 70‑hours posttest. Outcome scores on these measures were also significantly associated with SES but did not interact with instructional condition. Linear growth varied systematically as a function of inter‑vention condition also for both measures, and as a function of teaching group on TOWRE Word Reading Efficiency.

Students participating in one of the three reading inter‑ventions outperformed math control students on these read‑ing measures. Students in the multidimensional interventions outperformed the phonological control students on only the WRAT Reading subtest, and scores for the PHAST and PHAB + RAVE‑O interventions were not significantly dif‑ferent from each other on any measure. Growth rate differ‑ences between the reading intervention and the math control groups were demonstrated on both WRAT Reading and the TOWRE Word Reading Efficiency measures, although stu‑dents in the multidimensional reading interventions demon‑strated faster skill growth than students in the phonological control condition on only the WRAT Reading.

At the 1‑year follow‑up, significant differences in out‑come scores across intervention conditions persisted for WRAT Reading. Students receiving one of the two multidi‑mensional interventions (PHAB + RAVE‑O) outperformed phonological controls on both measures at the 1‑year follow‑up, demonstrating a faster rate of growth on the WRAT Read‑ing and TOWRE WRE measures over the intervention and follow‑up periods. All posttest differences in adjusted mean scores for the two multidimensional intervention groups were attenuated on follow‑up assessment, although growth rate on WRAT Reading and TOWRE WRE still appeared stronger for students receiving PHAB + RAVE‑O than for PHAST students. Baseline phonological processing and rapid naming skills remained strongly associated with outcome scores at follow‑up as well. Teaching group effects on out‑come scores were still evident on both measures, but SES was not associated with either performance on follow‑up.

WRMT-R Passage Comprehension ModelsUsing Passage Comprehension raw score as the outcome measure at 70‑hours posttest (see Table 3), significant fixed effects for intervention condition and teaching group were found for all models (see Table 4), with teaching group also predicting linear growth rate (p < .001). Outcome scores for the PHAB + RAVE‑O and PHAST interventions were com‑parable, and both were significantly higher than the mean out‑come score for students receiving the phonological control program (p < .05), which was better than the math control program. Students participating in any reading interven‑tion program attained a higher comprehension skill level than

by guest on May 23, 2011ldx.sagepub.comDownloaded from

Morris et al. 17

students in the math control condition (p < .001). Curvilinear growth was also significant (p < .01), suggesting a changing growth rate over the intervention time period. Unlike the pre‑ceding measures, two of the demographic factors (SES, IQ) predicted outcomes (p < .05) but did not interact with treat‑ment condition or predict linear growth. Outcomes were also significantly affected by initial level of phonological skill (p < .05) and rapid naming speed (p < .001). Rate of skill growth over the intervention year was not significantly affected by intervention condition or any of the other covariates.

At 1‑year follow‑up, however, the effects of intervention condition on comprehension skill levels were somewhat attenuated. The association between intervention condition and outcome score was non‑significant, although rate of skill growth was still significantly affected by intervention condition (p < .01). The only significant contrast was a stronger rate of growth over the 2‑year period for children in the PHAB + RAVE‑O program relative to that for the PHAST program. Outcome score was still affected by teach‑ing group (p < .001), SES (p < .05), and baseline phonologi‑cal skills (p < .01) and naming speed (p < .001), however, and the rate of skill growth continued to vary significantly across individual teaching groups (p < .001). None of these interacted with intervention condition or predicted growth at 1‑year follow‑up. The model‑adjusted means estimates are presented for Passage Comprehension in Figure 2.

Spelling and Arithmetic SkillsIntervention condition (p < .001), teaching group, and ini‑tial phonological processing skill and rapid naming speed significantly affected outcome scores (see Table 5) on the WRAT Spelling measure at 70‑hour posttest. Outcome scores on WRAT Spelling were also significantly associ‑ated with SES but did not interact with instructional con‑dition. Linear growth varied systematically as a function of intervention condition and as a function of teaching group (see Table 5).

Teaching group, SES, and initial phonological processing and rapid naming speed were significantly related to posttest WRAT Arithmetic scores. There were no significant con‑trasts between the intervention groups in either rate of skill growth or 70‑hour posttest score on WRAT Arithmetic.

Standardized Text Reading MeasureThe Gray Oral Reading Test is reported separately because although it has a composite score (Oral Reading Quotient [ORQ]), separate scores are also available for assessment of the accuracy and rate with which connected texts are read aloud, and there is a separate score for Comprehension (see Table 6). The GORT data are also described separately because the test was not administered at the 35‑hour testing

point, and only 75% of the total sample of 279 participants provided pretest, posttest, and follow‑up data on the GORT. The models reported below are based on an imbalanced cell distribution; older children with a higher proportion of low SES participants and a lower proportion of African American children contributed GORT data from the PHAST program relative to the PHAB + RAVE‑O program. The best reduced models for the ORQ and for the three subcom‑ponents are summarized in Table 7, as well as the associ‑ated contrasts at both 70‑hour posttest and 1‑year follow‑up outcomes.

In the most parsimonious model, 70‑hour posttest and linear growth continues to be significant for intervention condition on the ORQ and on all three component measures (all ps < .01). Teaching group also predicted outcome on all measures but was predictive of slope on only two measures (Accuracy and Rate). As with the other standardized mea‑sures, initial levels of letter naming speed were a significant predictor of 70‑hour posttest outcomes on all four GORT scores and also significantly predicted the amount of linear growth on the Accuracy and Rate component scores. Although IQ was related to GORT Comprehension outcomes at 70‑hour posttest, IQ did not predict outcomes or slopes on the other GORT scores. Similarly, there were no significant fixed SES or race effects in these models, although SES did interact with intervention condition for Accuracy and Reading Rate scores, but not for ORQ or Comprehension.

A number of significant contrasts were revealed in these four sets of models. A significant difference was revealed between the active reading interventions and the CSS +

0

2

4

6

8

10

12

Pre 35 hours 70 hours

WR

MT-

R

Wo

rd A

ttac

kA

dju

sted

Mea

n R

aw S

core

PHAB+CSSPHASTPHAB+RAVE-OCSS+MATH

6

8

10

12

14

16

18

20

Pre 35 hours 70 hours

WR

MT-

R P

assa

ge

Co

mp

reh

ensi

on

Ad

just

ed M

ean

Raw

Sco

re

PHAB+CSSPHASTPHAB+RAVE-O

CSS+MATH

Figure 2. Woodcock Reading Mastery Test–Revised (WRMT-R) Word Attack and Passage Comprehension adjusted raw score by remediation condition over time

by guest on May 23, 2011ldx.sagepub.comDownloaded from

18 Journal of Learning Disabilities XX(X)

MATH control condition for 70‑hour posttest outcomes on all four GORT scores (ps < .001) and for linear growth on the Accuracy and Rate component scores (ps < .01). Con‑trasts comparing the two multidimensional interventions to the phonological‑only control program were found on Accu‑racy and Rate for outcome and were also highly significant for linear growth on the Rate measure (p < .001) and mar‑ginally significant for Accuracy growth (p = .06). This con‑trast for ORQ was also marginal for outcome (.05 < p < .07) but significant for slope (p < .05). The third contrast, between PHAST and PHAB + RAVE‑O, was significant for ORQ outcome (p < .05) and linear growth (p < .01) and for Comprehension linear growth (p < .05), whereas outcome was borderline (.05 < p < .06). The pattern of results from these models for the 70‑hour posttest is presented in Figure 3. Superior outcomes and steeper learning curves were found for the two multidimensional interventions, with this advan‑tage seen particularly on the Rate score. Superior growth on the ORQ and the Comprehension scores was found for the PHAB + RAVE‑O intervention relative to the PHAST pro‑gram, with better ORQ outcomes and a marginally superior outcome on the Comprehension score also associated with the PHAB + RAVE‑O program.

One‑year follow‑up models revealed a significant effect for intervention condition in predicting outcomes on the composite ORQ (p < .05). Intervention condition also pre‑dicted continued growth over the follow‑up year for the ORQ and the Rate scores (p < .05). Teaching group was

highly predictive of long‑term follow‑up outcomes and lin‑ear growth on all four GORT scores (p < .05). Initial letter naming speed again predicted all four GORT measures at 1‑year follow‑up (ps < .01) and continued growth over time on the Accuracy and Rate scores (ps < .001). Contrasts at 1‑year follow‑up on the ORQ and the Comprehension score demonstrated significant, superior outcomes for the two multidimensional programs. There were no differences between the PHAST and the PHAB + RAVE‑O programs in terms of follow‑up outcome or growth on any of the GORT measures.

DiscussionAs argued in Snow and Juel (2005), comparative interven‑tion studies should not be considered a “horse race.” Rather, we conceptualize this study as one step toward realizing Lyon’s (1999) goal for reading intervention research: understanding what works best in which pro‑grams for what students under which conditions. In this context, this design allows us to evaluate the relative ben‑efits of different linguistic and metacognitive emphases in interventions for young struggling readers. The issue of whether there exist meaningful subtype × treatment inter‑actions in these data will be the focus of a future report, as will additional outcome data on word identification learn‑ing, vocabulary (Barzillai, Wolf, Lovett, & Morris, 2010), and other fluency measures.

Table 6. GORT-3 Raw Scores and Standardized Oral Reading Quotient (ORQ) at Each Testing Point

Baseline 70 Hours 1 Yr Follow-Up

GORT-3 Score M SD M SD M SD

Accuracy PHAST 1.02 2.20 3.88 4.68 7.51 6.67PHAB + RAVE-O 0.36 1.12 3.95 4.93 8.12 6.88PHAB + CSS 0.15 0.47 2.54 3.94 7.02 7.17MATH + CSS 0.11 0.41 2.31 3.50 6.12 6.36

Rate PHAST 0.44 0.70 2.37 3.03 4.23 4.32PHAB + RAVE-O 0.26 0.58 1.77 2.10 4.75 4.85PHAB + CSS 0.41 0.91 1.33 2.01 4.03 4.35MATH + CSS 0.19 0.47 0.91 1.37 3.93 4.07

Comprehension PHAST 5.15 4.93 9.77 6.58 15.18 8.60PHAB + RAVE-O 5.22 4.67 11.56 6.23 14.67 7.51PHAB + CSS 5.02 4.27 9.66 6.38 13.51 8.39MATH + CSS 4.46 4.75 8.04 6.44 12.15 7.93

ORQ PHAST 74.22 8.62 77.38 9.98 79.69 14.60PHAB + RAVE-O 75.33 7.63 81.73 10.51 80.37 13.74PHAB + CSS 74.64 7.20 77.66 11.87 77.32 14.36MATH + CSS 73.20 9.47 75.32 10.96 75.48 13.33

GORT-3 = Gray Oral Reading Test–III; CSS = Classroom Survival Skills; PHAB = Phonological Analysis and Blending/Direct Instruction; RAVE-O = Retrieval, Automaticity, Vocabulary, Engagement with language, and Orthography; PHAST = Phonological and Strategy Training..

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19

Tabl

e 7.

Sig

nific

ant

Fixe

d Ef

fect

s in

Bes

t R

educ

ed G

ORT

Mod

els

O

RQ

A

ccur

acy

Rat

e C

ompr

ehen

sion

70

Hrs

1

Yr

Follo

w-U

p 70

Hrs

1

Yr

Follo

w-U

p 70

Hrs

1

Yr

Follo

w-U

p 70

Hrs

1

Yr

Follo

w-U

p

Fixe

d ef

fect

s

Inte

rven

tion

6.93

***

3.90

* 8.

64**

*

10.3

9***

4.93

**

Gro

up

2.43

***

2.68

***

4.90

***

3.56

***

5.17

***

4.20

***

1.87

**

2.86

***

Inte

rven

tion ×

Slop

e 6.

64**

* 3.

20*

3.77

**

2.67

a 9.

14**

* 4.

38**

* 3.

99**

G

roup

× S

lope

1.63

* 2.

10**

* 1.

90**

3.

48**

* 2.

66**

*

1.47

*SE

S

IQ

3.46

a 4.

05*

4.13

* Et

hnic

ity

A

ge

37.8

3***

BL

PH

ON

5.65

*

BL R

AN

lett

ers

13.9

9***

8.

92**

13

.61*

**

31.6

5***

14

.34*

**

40.4

0***

9.

38**

7.

25**

Line

ar g

row

th

38.1

0***

130.

37**

* 42

.63*

**

183.

62**

* 63

.24*

**

134.

03**

* 22

.86*

**C

urvi

linea

r gr

owth

5.04

**

3.

27a

11

.55*

**

O

ther

inte

ract

ions

Inte

rven

tion ×

SES

3.70

**

3.

72*

3.55

*

Inte

rven

tion ×

IQ

3.83

**

2.

59a

BL R

AN

× S

lope

4.

57*

19.1

3***

4.

39*

26.9

8***

Inte

rven

tion

cont

rast

s (o

utco

me)

Rea

ding

Con

ditio

ns v

s. M

ATH

+ C

SS

13.8

5***

16.3

2***

23.0

6***

10.2

5***

M

ultic

ompo

nent

vs.

PHA

B +

CSS

3.

47a

5.85

* 7.

87**

8.31

**

3.97

*PH

AST

vs.

PHA

B +

RA

VE-

O

4.18

*

3.66

a In

terv

entio

n co

ntra

sts

(slo

pe)

R

eadi

ng C

ondi

tions

vs.

MAT

H +

CSS

6.

15**

13.0

0***

M

ultic

ompo

nent

vs.

PHA

B +

CSS

4.

95*

3.

61a

14

.56*

**

PHA

ST v

s. PH

AB

+ R

AV

E-O

8.

91**

5.26

*

Onl

y F

valu

es w

ith p

< .1

0 ar

e re

port

ed. G

OR

T =

Gra

y O

ral R

eadi

ng T

est;

OR

Q =

Ora

l Rea

ding

Quo

tient

(st

anda

rd s

core

); SE

S =

soci

oeco

nom

ic s

tatu

s; B

L =

base

line

scor

es; C

SS =

Cla

ssro

om

Surv

ival

Ski

lls; R

eadi

ng C

ondi

tions

= P

HA

ST, P

HA

B +

RA

VE-

O, P

HA

B +

CSS

; M

ultic

ompo

nent

= P

HA

ST, P

HA

B +

RA

VE-

O; G

roup

= t

each

ing

grou

p; P

HO

N =

Pho

nolo

gy; R

AN

= R

apid

Aut

omat

ized

Nam

ing.

a p <

.10.

*p

< .0

5. *

*p <

.01.

***

p <

.001

.

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20 Journal of Learning Disabilities XX(X)

The present interventions are conceptualized on a contin‑uum, including small group programming using classroom survival skills and math interventions (CSS + MATH, an alternate intervention control group), to intensive phonologi‑cally based reading intervention coupled with classroom sur‑vival skills training (PHAB + CSS, the phonological‑only control), to two multiple‑component reading interventions that include the same intensive phonologically based read‑ing intervention coupled with other intervention approaches (PHAST and PHAB + RAVE‑O).

The phonological‑only control condition in this design can be questioned on the grounds of not equating the amount of reading instruction offered in the PHAB + CSS program versus the two multidimensional reading interventions. A deliberate decision was made to hold the amount of phono‑logical intervention constant among the three active reading interventions. In this way, the present design would allow an evaluation of the specific contributions of the extra‑phonological emphases present in PHAB + RAVE‑O and PHAST. Previous data from our Toronto site provided a 70‑hour phonological‑only comparison.

Lovett, Lacerenza, Borden, et al. (2000) reported results from a crossover design comparing a double dose of PHAB/DI with the PHAB/DI + WIST program, the precursor to the PHAST program. This study included random assignment of small groups of disabled readers to one of five conditions: PHAB/DI → WIST, WIST → PHAB/DI, PHAB/DI × 2, WIST × 2, or CSS + MATH. Each instructional sequence

provided 70 hours of intervention. Superior outcomes and steeper learning curves were observed following both com‑bined interventions, regardless of sequence. Although both the double PHAB/DI and double WIST programs yielded positive outcomes on standardized measures of word iden‑tification, decoding, and passage comprehension, greater gains were realized by children receiving both phonological and strategy‑based interventions. This previous design pro‑vided a 70‑hour treatment intervention with the same teacher–student ratio as the present study and therefore is highly relevant to interpretation of the present results.

The multiple‑component programs used in this design shared three component emphases (phonology, orthography, and morphology) and the use of metacognitive strategies but differed in specific instructional emphases on word identifi‑cation and on semantic development. The PHAST program integrates phonologically and strategy‑based approaches to word identification learning, focusing extra instructional attention on (a) subsyllabic orthographic patterns; (b) mor‑phological segments; (c) variant vowel pronunciations; and (d) a program of “metacognitive decoding” in the form of direct teaching of five word identification strategies. The PHAB + RAVE‑O program adds to these same phonologi‑cal, orthographic, and morphological components more emphases on linguistic components involved in word knowl‑edge, specifically, (a) semantic depth, semantic flexibility, and lexical retrieval; (b) syntactic knowledge; and (c) morpho‑syntactic knowledge (often conveyed using metacognitive strategies). The ultimate goals of both multiple‑component programs were shared—to improve basic reading skills, to facilitate the development of independent reading, and to lay the groundwork for fluent reading comprehension. Both programs included some shared and some different empha‑ses in intervention, and both programs provided explicit and different motivational components. Including two alternate multidimensional approaches in the present design allowed us to investigate more systematically questions concerning the contribution of different language processes to the develop‑ment of word identification and reading comprehension skills.

Semantic development. The relationship between semantic growth (vocabulary) and reading comprehension is well documented (Beck & McKeown, 2006; Beck, McKeown, & Kucan, 2002; Biemiller, 1999, 2001; Moats, 2001; Stanovich, 1985); the contribution of individual differences in vocabu‑lary knowledge to accuracy and fluency in word recognition, however, is not well understood. As Juel (2005) noted, how‑ever, a critical problem in most phonics‑based programming is the misguided assumption that struggling readers, particu‑larly those with different dialects, different languages spoken in the home, and/or impoverished language backgrounds, know the meaning of the words they are trying to decode.

There exists a growing body of knowledge about the contribution of different forms of linguistic knowledge to word recognition. Yates, Locker, and Simpson (2003)

0

1

2

3

4

5

6

Pre 70 Hours

GO

RT

Acc

ura

cyA

dju

sted

Mea

n R

aw S

core

PHAB+CSS

PHAST

PHAB+RAVE-O

CSS+MATH

4

5

6

7

8

9

10

11

12

Pre 70 Hours

GO

RT

Rea

din

gC

om

pre

hen

sio

nA

dju

sted

Mea

n R

aw S

core

PHAB+CSS

PHAST

PHAB+RAVE-O

CSS+MATH

Figure 3. Gray Oral Reading Test–III (GORT) Text Reading Accuracy and Passage Comprehension adjusted raw by remediation condition over time (only two time points)

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Morris et al. 21

demonstrated that enhanced semantic knowledge improved the speed of lexical retrieval. Specifically, they found that the richer the “semantic neighborhood” for a given word (i.e., the more associated words, meanings, etc.), the faster the representation of that word was retrieved on lexical decision tasks. Wydell, Vuorinen, Helenius, and Salmelin (2003) found, in a Magnetoencephalographic (MEG) study, that processes recruited in the superior temporal cortex for reading words were significantly faster for known words than for unknown or pseudowords; this cortical region sub‑serves both phonological and semantic processing. Increased semantic knowledge for a given word shortened the time that word was processed both phonologically and semantically.

The multilayered semantic emphases in the RAVE‑O program allowed us to investigate these contributions to word identification, word attack, and reading comprehen‑sion. Explicit instruction in vocabulary, semantic flexibility, and lexical retrieval strategies were components unique to RAVE‑O. The approach draws on the premise that more in‑depth knowledge of words (e.g., multiple meanings, seman‑tic neighborhood associates, morphosyntactic elements) facilitates both accuracy and fluency in word recognition, oral reading fluency, and the comprehension of connected text. The present test battery allowed comparison of speed and accuracy in reading and thus permitted a first step toward examining this premise in an intervention context.

As expected, the active reading interventions proved supe‑rior to the control group on all standardized reading and spell‑ing measures at 70 hours, with the exception of the Nonword Reading Efficiency measure. The two multiple‑component programs demonstrated superior 70‑hour outcomes to the phonological control group on the majority of standardized measures of word identification. Significant contrasts were revealed between the multiple‑component and phonological‑only interventions for posttest outcomes on all WRMT‑R measures, WRAT‑3 Reading, and Accuracy and Rate scores on the GORT. The PHAST and PHAB + RAVE‑O programs were associated with superior outcomes of equiv‑alent magnitude on all standardized measures except the GORT ORQ. On the GORT ORQ composite of fluency plus comprehension, superior outcomes and greater growth during intervention were revealed for children in the PHAB + RAVE‑O condition. These latter results may reflect the additional contribution of semantic components to connected text reading.

What is more striking from the present analyses is the extent to which the two multiple‑component programs demonstrated superior outcomes and continued growth 1 full year after the interventions ended. At the 1‑year follow‑up, children who had received either the PHAST or PHAB + RAVE‑O programs continued to show a signifi‑cant advantage relative to the PHAB + CSS participants on almost all tests of reading and spelling skill, including spelling and word efficiency measures (WRAT‑3 Spelling

and WRE), which had failed to show this advantage at immediate posttest. The superiority of the PHAST and PHAB + RAVE‑O programs for these disabled readers is well illustrated here and replicated across multiple mea‑sures of reading and spelling achievement 1 year after the interventions ended.

PHAB + RAVE‑O devoted daily time to direct decod‑ing skills but spent equal time building up semantic, ortho‑graphic, and morphosyntactic knowledge. PHAST allocated equivalent time to decoding but supplemented it with explicit word identification strategies and training on other aspects of orthographic and morphological structure. The immediate and maintained success of both programs suggests that dif‑ferent pathways exist to successful reading remediation.

Semantic instruction in PHAB + RAVE‑O contributed to vocabulary growth and improved semantic flexibility. Children in the PHAB + RAVE‑O group demonstrated superior vocabulary outcomes, both on instructed words on the RAVE multiple definition task (Barzillai et al., 2010) and in providing multiple meanings to new vocabu‑lary items on the standardized WORD‑R. As testimony to the overall relationship between word identification and word knowledge, both multidimensional programs were superior to the PHAB + CSS program, which was better than the control program on trained words. Only the PHAB + RAVE‑O intervention group demonstrated supe‑riority on the standardized vocabulary measure, both at 70 hours and at 1‑year follow‑up.

Morphology. An often‑neglected dimension of language concerns morphology and its contribution to word identifi‑cation, vocabulary, syntax, and comprehension develop‑ment (Berninger, Abbott, Billingsley, & Nagy, 2001; Carlisle & Rice, 2002; Henry, 2003; Moats, 2001, 2004). Both mul‑tidimensional programs incorporate considerable emphases on strategies for the quick recognition of morphemes and for understanding how they change the meaning of the word. The term Ender Benders was used as a mnemonic strategy in the PHAB + RAVE‑O program to illustrate how different morphemes like ed, er, and s can change a noun to a verb (e.g., jam to jammed), an action to a person who performs that action (e.g., move to mover), and a singular word to a plural (e.g., ram to rams). The metacognitive term Ender Bender itself incorporates the principle of morpho‑logical transformation.

In PHAST, a somewhat different approach to morphol‑ogy instruction is employed. One of the five PHAST strate‑gies, Peeling Off, involves recognition and segmentation of morphemes in multisyllabic word identification. Children are taught the prefixes and suffixes of English, beginning with the most frequently occurring affixes. As affixes are introduced, prefixes are mounted as green leaves and suf‑fixes as orange leaves on a “peeling off” tree.

Orthography. Another shared emphasis by the multidi‑mensional programs is a focus on subsyllabic segments and

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22 Journal of Learning Disabilities XX(X)

common orthographic patterns. PHAB + RAVE‑O empha‑sizes rapid recognition and practice of the most frequent orthographic patterns in English through a series of activi‑ties and computerized games called Speed Wizards (Wolf & Goodman, 1996) that allow for repeated practice and multi‑ple exposures to these patterns.

Similarly, PHAST integrates work on different levels of subsyllabic segmentation, teaching the phonological Sound‑ing Out strategy with its emphasis on the smallest subsyllabic units, and the Rhyming strategy with its focus on onset‑rime segmentation. To learn the Rhyming strategy, children acquire over time 120 keywords representing the 120 most frequently occurring spelling patterns in English. These keywords are from the list developed for the original Benchmark School Word Identification/Vocabulary Development Program (Gaskins et al., 1986).

It can be speculated that this attention to morphology and orthography in the multidimensional programs, PHAST and PHAB + RAVE‑O, facilitated the development not only of word recognition but also of spelling knowledge and resulted in superior spelling achievement for both programs at 1‑year follow‑up.

Fluent comprehension. A final question is whether the vocabulary, orthographic, syntactic, and morphological emphases of PHAB + RAVE‑O and the orthographic, mor‑phological, and metacognitive emphases of PHAST were associated with advantages in oral reading fluency and reading comprehension greater than that associated with the PHAB + CSS program. Consistent with recent work on multiple pathways to fluency (Katzir et al., 2008; Wolf & Katzir‑Cohen, 2001), both multidimensional programs proved superior to the phonological control program on measures of oral reading fluency, text reading accuracy (GORT subscores), and passage comprehension (WRMT‑R) at 70 hours and on GORT ORQ and Comprehension at 1‑year follow‑up.

Whether the added vocabulary and syntactic emphases of PHAB + RAVE‑O resulted in greater comprehension gains than the metacognitive and strategy instruction focus of PHAST is not resolved by these data. The GORT Reading Quotient represents the best index of fluency and compre‑hension in the present battery. The PHAB + RAVE‑O pro‑gram demonstrated superior outcomes and greater linear growth on the ORQ at 70 hours, and a trend favoring PHAB + RAVE‑O was found on the Comprehension subscore at posttest. These findings demonstrate the efficacy of PHAB + RAVE‑O in facilitating fluent reading comprehension fol‑lowing only 70 hours of intervention.

These two treatment‑specific findings are qualified by two other findings. Both multidimensional programs were associated with equivalent outcomes on WRMT‑R Passage Comprehension at 70 hours and at 1‑year testing and achieved equivalent long‑term outcomes on the GORT Oral Reading

Quotient at follow‑up. The WRMT‑R Passage Comprehen‑sion test employs a “cloze” procedure to measure compre‑hension, where the child must retrieve a specific one‑word answer. Given the lexical retrieval issues identified in pre‑vious research on RD (German, 1992; Wolf & Goodglass, 1986; Wolf & Obregon, 1992), the cloze procedure may not be an optimal method for evaluating comprehension in read‑ers with RD. It is certainly confounded with decoding skills. Appropriate measures of reading comprehension for strug‑gling readers are scarce (Keenan, Betjemann, & Olson, 2008). It is not clear whether demonstrated gains in vocabu‑lary for PHAB + RAVE‑O children did not improve perfor‑mance beyond PHAST on this test because of test demands on retrieval skills or whether it is simply that they did not translate into relatively greater comprehension gains than PHAST, because of the extra linguistic and metacogni‑tive emphases of PHAST, which also supported improved comprehension.

Other interpretations may be considered. First, there are alternate pathways to successful comprehension, and both PHAST and PHAB + RAVE‑O demonstrate two effective pathways to improved reading comprehension for young impaired readers. Results at 1‑year follow‑up are equally strong for both multidimensional programs on reading com‑prehension, and both programs maintain clear superiority over other groups on the ORQ and the GORT Compre‑hension subscore. PHAB + RAVE‑O has a significant advantage over PHAST immediately following interven‑tion, however, this is not maintained on the GORT Reading Quotient at follow‑up testing. Two possible interpretations are that the progress made by the PHAST children allows them to catch up with the progress shown earlier by the PHAB + RAVE‑O group, perhaps because growth by both groups on word attack and word identification skills resulted in more reading experience over the following year. Another possibility is compatible with one of the the‑oretical premises of the RAVE‑O program: Fluent compre‑hension is dependent on evolving word knowledge, particularly semantic and morphosyntactic knowledge, as reading skills become more sophisticated in older grades. When there are no active emphases on these skills (as in the follow‑up year), the general gains are maintained, but the advantage seen earlier from vocabulary and other lin‑guistic emphases on word knowledge dissipates.

Word identification speed and reading rate. All three reading interventions were associated with significant improvement in word reading efficiency on the TOWRE, demonstrating superior outcomes at 70 hours and greater growth during intervention than for the control group. The two multiple‑component interventions were superior at 1‑year follow‑up on both Word and Nonword Reading Efficiency measures to the phonological control condition and demonstrated greater continued growth. PHAB + RAVE‑O children

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Morris et al. 23

demonstrated an advantage over children in the PHAST program in the rate of linear growth over the follow‑up period, although actual outcomes for PHAB + RAVE‑O and PHAST were equivalent. Finally, the PHAST children demonstrated significantly faster keyword identification immediately after their program ended but not at follow‑up. The only measure of text reading rate was provided by the GORT: On the Reading Rate score, PHAB + RAVE‑O and PHAST children demonstrated significant improvement in rate relative to the phonological control condition on 70‑hour outcomes and linear growth over the course of the intervention. No effects were observed at 1‑year follow‑up.

While both multiple‑component interventions were asso‑ciated with improvements in specific dimensions of reading rate at 70 hours, and some at long‑term follow‑up, treatment‑related improvements in word identification processes were easier to measure than growth in specific aspects of reading comprehension and reading fluency.

The importance of explicit strategy instruction. The PHAST and the PHAB + RAVE‑O programs both include explicit strategy instruction as part of the intervention, an emphasis supported by previous research (Lovett, Lacerenza, Borden, et al., 2000; Swanson et al., 1999). Explicit strategy training and metacogniti ve monitoring are necessary to address and prevent generalization failures during remediation, and they provide an important component of effective remediation for RD in the acquisition of both decoding accuracy and reading comprehension skills (Lovett, Lacerenza, Borden, et al., 2000; Mason, 2004; Vaughn et al., 2000).

Young impaired readers in PHAST learned to use a Game Plan to self‑direct their selection, implementation, and monitoring of the five PHAST strategies. Struggling readers acquire the prerequisite skills they need for strategy implementation and a self‑talk dialogue structure that allows them to become competent independent readers. Subsequent development of the PHAST Comprehension Track in our current research classrooms (Lovett et al., 2005) supple‑ments the word identification strategies with a set of comple‑mentary text comprehension strategies. The goal throughout is to equip the children with the skills and strategies they need to become fluent and enthusiastic readers.

In the PHAB + RAVE‑O program, children learn an assortment of metacognitive word tricks to help them quickly recognize and segment syllable patterns, common affixes, and their associated meanings. The “Sam Spade” strategies target accuracy in lexical retrieval, and three spe‑cific comprehension strategies aid prediction, comprehen‑sion monitoring, and integration of independent thinking about the text.

Both multiple‑component programs were successful in demonstrating generalized gains in reading skill that were evident in decoding and word recognition, text reading accuracy, reading rate, and reading comprehension. It might

be argued that part of the superiority of both interventions relative to the phonological control condition is directly due to the inclusion of strategy training and metacognitive com‑ponents in their instructional designs.

Cognitive-affective and motivational elements of effective inter-vention. There are many aspects of the multiple‑component interventions to which their efficacy can be attributed. One of the most important may be that different explicit thera‑peutic elements are woven into the instructional content of lessons in both programs. Integral to the success of the PHAST and the PHAB + RAVE‑O programs are methods to enhance self‑esteem around the reading task and to foster engagement with language and print.

The PHAST program deliberately undertakes the retrain‑ing of unproductive attributions and misguided beliefs about effort and achievement, attempting to build perceptions of self‑efficacy around the reading task and other learning challenges. Specific attributional retraining is woven into the strategy dialogue structure in every PHAST lesson for‑mat. Children learn that success on a task is a matter of whether the appropriate strategy was selected and applied and whether they were flexible and persisted when first attempts were unsuccessful. Another therapeutic component of the PHAST program involves its use of low‑frequency complex multisyllabic words as “challenge” words on which the children practice their strategies. Children who previ‑ously struggled with one‑syllable words work through such “college words” as “unintelligible,” in preparation for more sophisticated texts.

In a similar vein, the power of engagement with language is an implicitly therapeutic focus of the RAVE‑O interven‑tion, along with an emphasis on incremental success at each step of learning. Daily lessons include opportunities for the teacher and children to “play with” the multiple dimensions of words, while simultaneously giving them successes in reading them. Imaginative and whimsical activities are incorporated in the instruction, with a “novel mnemonic” provided for each type of metacognitive strategy that helps memory and retrieval. The teacher’s own love and knowl‑edge of language is actively used to engage the children in new attitudes toward language and reading. Children are encouraged to think for themselves while reading text and, in the process, to view themselves as successful learners.

Much remains unmeasured that is relevant to understand‑ing individual and group differences in intervention response. Instructional group emerged in our results as an important and highly significant fixed effect in predicting outcomes and growth both during the intervention period and even during the 1 year following intervention. This cannot be dis‑missed as a teacher effect, because participating teachers taught multiple programs within the design. Rather, the rela‑tionships and dynamic within the group and between the group and the teacher likely resulted in differences both in implementation variables, such as pacing of instruction, and

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24 Journal of Learning Disabilities XX(X)

in a wealth of contextual, motivational, and relational vari‑ables that affected the children’s engagement, motivation, and attributions about the program and their own progress.

Recent work by Frijters at our Toronto site (Frijters et al., 2004; Frijters, De Palma, Barron, & Lovett, 2005) indicates that motivational differences among disabled readers medi‑ate their response to intervention. Frijters’s work confirms that motivation for reading is not a unitary construct and that different preintervention motivational profiles can be identi‑fied in children with RD. These profiles predict responsive‑ness to remediation, indicating that motivation mediates remedial response. In addition, motivation appears to be amenable to modification in its interaction with intervention (Frijters et al., 2005; Frijters, Dodsworth, Lovett, Sevcik, & Morris, 2009).

There are significant limitations to this study that must be acknowledged. As noted earlier, the phonological con‑trol condition was not equated for amount of reading intervention time with the two multiple‑component inter‑ventions. We have argued that the 70‑hour phonological‑only condition from our previous work provides this comparison historically, but the comparison is outside the present design. We are limited therefore in the conclu‑sions we can reach based on results from the phonologi‑cal‑only comparison. We are also limited in our ability to measure changes in reading comprehension and reading fluency. Measures of these aspects of reading skill are not as well developed as those available for the assessment of word identification and decoding processes. Finally, although we report clear effects attributable to instruc‑tional group, we lack the ability to interpret these effects with our current battery, the program observations, and the lesson diaries completed each day.

Despite these limitations, this research demonstrates gen‑eralization of program benefits across a far broader popula‑tion of disabled readers than ever assessed before. Results reveal that systematic, intense, linguistically informed inter‑ventions are associated with positive outcomes for young impaired readers of high or low IQ and from a range of eth‑nic backgrounds and environmental circumstances. Interven‑tions that incorporate multiple components of language and that target a range of core deficits consistently produce superior effects to control programs that emphasize predomi‑nantly phonologically based reading instruction or alternate academic programming. These advantages are seen across the entire range of reading skills, including fluency and com‑prehension, historically the most difficult to facilitate.

Positive results following both PHAB + RAVE‑O and PHAST highlight the significance of teaching all struggling readers about the structure of their language from phono‑logical and orthographic structure within syllables, to vari‑able pronunciations of vowels and vowel combinations, to semantic knowledge of words and morphemes. Successful remediation enables language learning across different oral

and written language systems and enhances motivation and involvement. In the process, these forms of multidimensional intervention equip children both with the critical desire to learn and with a metalinguistic knowledge base that gives them a never‑before‑experienced “edge” over many, more able readers in their classrooms.

Acknowledgments

In Atlanta, Boston, and Toronto, we are especially grateful to the 305 original children who participated in these remedial programs for their interest, enthusiasm, and effort. There were many other children who were screened to be in this program whom we also thank. We also gratefully acknowledge their parents, teachers, and schools for their commitment and support during the course of this study. The cooperation and contribution of the principals and staff of all participating schools, all of whom offered space and opportunities for our programs, are much appreciated.

In Atlanta, we acknowledge the students and families from the Fulton County School system, administrators, especially Nancy Shelley, participating schools, their principals and staffs, particularly Susan Grabel; our research teachers—Eileen Cohen, Mary Bucklen, Sonja Ross, Marsha Harps, Sharon Hill, Brenda Everson, Phyllis McNeal; and members of our research team—Paul Cirino, Christopher Chin, Fontina Rashid, Heloise Ledesma, Amy Smith, Ayanay Smith, Nicole Mickley, Becky Doyle, Justin Wise, Christopher Wolfe, Hye K. Pae, Cynthia Arrington, Janet Montgomery, Jennifer Harrison, Lisa Norris, Kelly Cukro‑wicz, and Laina Jones.

In Boston, we acknowledge the students and their families from Medford, Somerville, Dorchester schools; our research teachers— Katharine Donnelly‑Adams, Terry Joffe, Joanna Christodoulou, Fran Lunney, Anne Knight, Alice O'Rourke; and members of our research team—Kathleen Biddle, Terry Deeney, Beth O’Brien, Julie Jeffery, Lynne Miller, Alyssa Goldberg O’Rourke, Chip Gidney, Wendy Galante, Tami Katzir, Joanna Christodoulou, and Gordon Goodman.

In Toronto, we acknowledge the students and their families from the Toronto Catholic District School Board, the Toronto District School Board, and the Peel District School Board; our research teachers—Léa Lacerenza, Susan Borden, Loretta Lapa, Phillipa Beggs, Kim Lewis, Gail Markson, Denis Murphy, Jody Chong, Tammy Cohen, Vicky Grondin; and our research team members—Maria De Palma, Meredith Temple, Naomi Badger, and the late Nancy Benson.

Declaration of Conflicting Interests

The authors declared no potential conflicts of interest with respect to the authorship and/or publication of this article.

Financial Disclosure/Funding

The research reported here was supported by a National Institutes of Child Health and Human Development Grant (HD30970) to Georgia State University, Tufts University, and The Hospital for Sick Children/University of Toronto.

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Morris et al. 25

Note

1. Not all children who met either a LA or DISC criteria were entered into the remediation study, because the study design called for a very explicit sampling strategy. It should be noted that because of some limited attrition (8.5%) during the inter‑vention year (see Figure 1), there was an attempt to replace lost participants in specific sample cells during the following school year. Data from children who left the study during the remediation program are not included in any results presented here, although attrition analysis did not suggest attrition to be systematic in any obvious way. Eleven percent left the study during the year that followed the remediation; no attempt was made to replace these children in the study because they had received the full remediation program and evaluations related to it. Their data were lost to the follow‑up analysis. Attrition analysis did not identify any systematic relationships with these students and other demographic or academic attributes. The stringency of the design resulted at times in situations where no children were available to meet the needs of a particular cell from a given school; overselection, therefore, occurred in some sampling cells to ensure consistent instructional group sizes throughout the study. Out of the 279 students (see Figure 1) who completed the full year of intervention (in either the math or reading groups), 23 (11%) students were not available for follow‑up testing 1 year later. Out of the 68 students who ini‑tially received MATH + CSS, 9 (13%) were not available for the additional year of (reading) intervention and 7 more (10%) were not available for the follow‑up testing 1 year later. Attri‑tion analysis did not identify any systematic relationships with these students and other demographic or academic attributes.

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About the Authors

Robin D. Morris is the vice president for research and Regents Professor of Psychology at Georgia State University. He also holds a joint appointment in the Department of Educational Psychology and Special Education in the College of Educa‑tion. His current research is focused on reading and language development, reading disabilities and dyslexia, bilingual lan‑guage and reading development, and neuroimaging of the devel‑oping brain.

Maureen W. Lovett is a senior scientist in the Neurosciences and Mental Health Program at The Hospital for Sick Children, a Pro‑fessor of Pediatrics, Medical Sciences, and Human Development and Applied Psychology at the University of Toronto. She is founder

and director of the hospital's Learning Disabilities Research Pro‑gram, a clinical research unit that develops and evaluates inter‑ventions for developmental reading disabilities. Her research focuses on questions about the effective remediation of decoding, word identification, fluency, and reading comprehension deficits in struggling readers of elementary, middle, and high school age.

Maryanne Wolf is the John DiBiaggio Professor of Citizenship and Public Service, director of the Center for Reading and Lan‑guage Research, and a professor in the Eliot‑Pearson Depart‑ment of Child Development at Tufts University. Her recent research interests include reading intervention, early prediction, fluency and naming speed, cross‑linguistic studies of reading, the relationship between entrepreneurial talents and dyslexia, and the uses of brain imaging in understanding dyslexia and treatment changes.

Rose A. Sevcik is a professor of psychology at Georgia State Uni‑versity, Atlanta. Her research has focused on the language, com‑munication, and reading acquisition of children and youth with developmental disabilities.

Karen A. Steinbach is clinical research project manager of the Learning Disabilities Research Program at The Hospital for Sick Children. She has overseen the implementation of several large multisite grant‑funded studies. She supervises and trains psychol‑ogy staff, and coordinates and directs all assessment and program‑ming offered in our elementary‑level research classrooms.

Jan C. Frijters is a developmental psychologist and an associate professor at Brock University, Departments of Child and Youth Studies and Psychology. His primary research areas are the study of motivation for reading, the role of motivation in reading dis‑ability and reading interventions, and the development of motiva‑tion for reading throughout childhood.

Marla B. Shapiro operates a private practice in Rockville, Mary‑land and also serves as a consultant to the College Board. She is a licensed psychologist and nationally certified school psychologist; her training, research, and clinical practice have focused on acquired brain injuries and developmental variations in children, adoles‑cents, and young adults. She has also worked with federally funded reading research teams exploring reading disabilities across the lifespan, and with clinical research teams studying children with ADHD, cancer, NF1, mTBI, and sports‑related concussions.

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For many elementary-school children the achievement of reading with fluent comprehension—that is, the ability to

read quickly and accurately enough to understand and think about text—remains an essential, but elusive goal. The most used intervention for these children involves “repeated read-ing” methods, where children read the same text several times till accuracy and fluency are achieved. Proponents of repeated reading make several important assumptions about these implicit methods: 1) fluency represents the end result of decod-ing instruction; 2) fluency gains on practiced texts generalize to new texts; 3) repeated exposures teach new vocabulary words and reinforce orthographic patterns; and 4) fluency gains advance comprehension. Growing evidence from several research directions indicates that these assumptions do not hold for many struggling readers.

In this article, we present an overview of a very different intervention for fluent comprehension, the RAVE-O program, based on a developmental, multicomponent model of fluent comprehension. The assumptions underlying RAVE-O share with repeated reading methods the goals of teaching new vocabulary and reinforcing orthographic pattern knowledge, but have explicit emphases on these and additional major lin-guistic systems such as syntactic knowledge and morphological processes. Indeed, we argue that the fallacies in past assump-tions about indirect reading instruction (i.e., it teaches basic phonological knowledge and decoding principles through exposure and immersion in texts) extend to instruction for flu-ent comprehension in children with reading difficulties.

Research BackgroundThe first body of evidence comes from research in the cog-

nitive neurosciences regarding how the brain learns to read in typical development and fails to read in children with reading disabilities (Pugh, Sandak, Frost, Moore, & Mencl, 2005; Wolf, 2007). An examination of the young reader’s first “reading cir-cuit” illustrates the many components involved—from visual pattern recognition systems to varied cognitive and linguistic systems (Tan, Spinks, Eden, Perfetti, & Siok, 2005; Sandak, Mencl, Frost, & Pugh, 2004). Multiple linguistic systems are essential to understand the many dimensions contained within a spoken or written word: phonology, morphology, syntax, semantics, and pragmatics, with orthography necessary for written words. Each system activates discrete areas of the brain when we read. A leitmotiv in this research and RAVE-O is that everything the child knows about oral language contributes to the development of written language.

To bring the multiple emphases in the RAVE-O program to life, we would like you, the reader, to analyze what you know about any single word. In the process, you’ll have a bird’s eye

perch from which to view many of the different linguistic sys-tems important to reading and oral language. Consider the word duck. First, the reader begins to process visual features of letters and of the word’s shape and to discern the size, shape, and spacing of each symbol. Discerning meaningful visual symbols is an evolutionarily adaptive ability that has developed over thousands of years of token-based economies, hieroglyphic drawings, and other early writing systems (Wolf, 2007). The ability to store representations of visual patterns and connect that information to linguistic knowledge and writing conven-tions provides the foundation for an individual’s orthographic knowledge (Wolf, 2007). During reading, children use their orthographic knowledge to discriminate between letters and recognize common letter patterns in their language. The ability to rapidly identify visual chunks in words (e.g., vowel digraphs, consonant blends, and morpheme units) ultimately increases the speed of reading.

To read duck, orthographic knowledge must become auto-matically connected to corresponding sound or phoneme-based knowledge. The individual visual symbols, d, u, c, and k, carry virtually no meaning until paired with their analogous sounds. The alphabetic principle—beginning with the cognitive understanding that each visual letter corresponds to a sound—underlies children’s capacity to learn their language’s sound-symbol correspondences. To read the word duck, children must recognize each symbol, connect the corresponding sounds or phonemes, and blend them together to form the word.

In the process, they utilize the repertoire of skills we call phonological processes. The phonological awareness and pro-ficiency required to segment and blend phonemes in words is honed over hours of explicit instruction and repeated practice. Extensive research confirms the effectiveness of direct sound-symbol instruction on the development of phoneme awareness and decoding skills (Adams, 1990, Lundberg, 1991; Stanovich, 1991; Torgesen et al., 1999). This evidence demonstrates that children benefit most when common structures of sounds are explicitly taught, particularly when special attention is paid to distinctions between onsets, such as d, rimes, such as uck, and syllable patterns (Goswami & East, 2000). Instruction which provides this phonological foundation alongside multiple exposures to common orthographic patterns results in more efficient word recognition.

Phonological and orthographic knowledge are not the only linguistic components key to reading fluency. Rich semantic knowledge both plays a significant role in children’s reading comprehension and impacts fluent word recognition. Semantic knowledge refers both to the size of a vocabulary, and also to the strength and depth of individual word knowledge.

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Serious Word PlayHow Multiple Linguistic Emphases in RAVE-O Instruction Improve Multiple Reading Skillsby Maryanne Wolf, Stephanie Gottwald, and Melissa Orkin

The International Dyslexia Association Perspectives on Language and Literacy Fall 2009 21

(Frishkoff, Collins-Thompson, Perfetti, & Callan, 2008). Think of the multiple meanings of the word duck. When functioning as a noun, it represents a web-footed, swimming bird; as a verb, it means to avoid. In fact, a great many of the most common children’s words have more than one meaning. The more knowledgeable children are about a word, its multiple mean-ings, and various pragmatic and syntactic contexts of use, the more rapidly the word is processed during reading (Locker, Simpson & Yates, 2003). As a result, children can move into more sophisticated text-level reading with greater fluency and thus, have more time for understanding. In short, the semantic system not only affects the speed of accessing the word, but also impacts deeper comprehension of text.

The implications of this conclusion are significant. Investigations into “word poverty” (Moats, 2000) and the effects of impoverished word environments have demonstrated the significant and long-term impact of a child’s vocabulary size on his or her reading comprehension (Stanovich, 1985). Moats (2001), for example, estimates that there is a significant word gap between lower and higher income children who enter first grade. The significance of this finding is brought home by Biemiller (2005) who found that kindergarten children with a vocabulary in the bottom 25% remain behind in vocab-ulary and comprehension into middle school and often beyond.

Related to both semantic and orthographic knowledge is the least studied linguistic component of reading—morphological awareness—which refers to the conventions that govern word formation, and the ways in which roots and affixes create new word meanings. For example, adding the suffix morpheme s to the root duck, creates the plural noun ducks; adding ing creates the present participle ducking; adding ed creates the past verb form ducked. Such morphological knowledge also provides disambiguating syntactic information (e.g., ed rapidly clarifies that ducked is the verb form). In addition, because the role a word has in sentence structure helps determine its meaning, this collective morphosyntactic information aids comprehension.

Morphological awareness is particularly important in English, which is a morphophonemic language that represents both morphemes and phonemes in its spelling. Words that are irregularly spelled no longer seem as arbitrary in their spelling when children understand their morphemic roots. For example, the word muscle connects this seemingly irregularly spelled word to its basic roots. In so doing, it illumines the semantic relationships among words like muscle, muscular, and muscu-lature (see Chomsky & Halle, 1968). From this perspective, by conveying semantic, syntactic, and orthographic information, morphological knowledge contributes to the development of spelling, faster word recognition, and fluent comprehension.

Another less emphasized component in fluency interven-tion concerns syntactic knowledge. Knowledge of how words are used within different grammatical or syntactic contexts is essential for the child’s fluency and comprehension, along with a variety of increasingly sophisticated sentence constructions and literary conventions.

In sum, what does the young human brain learn to do when it reads a single word? It uses an exquisitely precise visual sys-tem to recognize letters and familiar letter patterns; it connects this information to the stored, corresponding phonemes; and almost simultaneously, it connects this same information to the meaning(s) of the word, to its grammatical uses, the potential morphemes, and how this word is used in social contexts (i.e., pragmatic knowledge). Most importantly, the brain must retrieve, connect, and integrate all this information in a fraction of a second to have time to comprehend the word in text.

RAVE-O InterventionThe RAVE-O program is an innovative reading program

whose purpose is to teach the young reading brain how to build up and connect all these sources of visual, cognitive, and lin-guistic information and rapidly retrieve them during reading. Based on theoretical accounts of reading fluency and compre-hension (Wolf & Katzir-Cohen, 2001), the program attempts to simulate what the brain does when it tries to read a single word with fluency and comprehension. RAVE-O’s basic premise is that the more the child knows about a word (i.e., phonemes, orthographic patterns, semantic meanings, syntactic and prag-matic uses, and morphological roots and affixes), the faster the word is decoded, retrieved, and comprehended. RAVE-O is not so much a wholly new program, as it is the application of some best teaching practices and some newly-designed practices to systematically address multiple linguistic, cognitive, and affec-tive systems.

Each week children learn all the relevant phonological, orthographic, semantic, and syntactic content for a small group of core words and learn to make explicit connections across these linguistic systems. Making these connections is key to re-enacting what the brain’s “reading circuit” does. For exam-ple, with the word jam, the instructor first reviews the individ-ual phonemes, /j/ + /a/ + /m/, and then teaches the child to find the chunks in jam. That is, the rime (the part of the syllable that consists of the vowel and any consonants that come after the vowel) (/am/) and the onset or beginning consonant (/j/). This step consolidates sound-level knowledge and connects it to let-ter patterns. In turn, this knowledge is immediately connected to the semantic base. The word jam possesses at least three common meanings and can be used in different syntactic con-texts (as noun and verb). Moreover, jam can be easily changed by the addition of different morphemes (e.g., jams, jamming, unjammed) to show how words can change but still have their root visible. The uniqueness of RAVE-O is that explicit attention is given to learning and connecting each of the five major lin-guistic components in every word, in every unit.

The overall structure of the RAVE-O curriculum emphasizes systematic instruction with a repeating format within each unit and each individual lesson. The general movement is from accu-racy to speed: from the multicomponential introduction of words, through activities that build accuracy in letter-pattern and word recognition, to building speed and understanding in ever increasing levels of complexity in words and connected text.

Serious Word Play continued from page 21

22 Perspectives on Language and Literacy Fall 2009 The International Dyslexia Association

The International Dyslexia Association Perspectives on Language and Literacy Fall 2009 23

Games and activities exemplify the progression from activities that emphasize accuracy of retrieval early in the unit to speed of retrieval by the end of the unit. For example, a variety of activities and games are used to enhance the child’s ability to connect multiple linguistic processes. Spelling-Pattern Cards are small color-coded cards that are divided into starters, rimes, and affixes and teach phoneme patterns and morphemes. Speed Wizards is a set of computerized games designed to reinforce these same sets of processes at different levels of complexity and three speeds of recognition. Word Webs are a regularly recurring semantic exercise that provides a simple, visual way of illustrat-ing how words are interconnected and that gives visual images to aid memory. All of these game-like activities offer whimsical means to teach children to connect individual phonemes, to orthographic units, to meanings, to uses. In turn, these connec-tions facilitate rapid decoding and comprehension processes and improve spelling along the way.

A range of metacognitive strategies (called Magic Tricks) enables children to segment the most common orthographic and morphological units in words. The tricks are quick, often humorous mnemonics that teach key strategies about words. For example, the strategy called “Ender Benders” helps children quickly recognize common morpheme endings that “bend” (i.e., change) the word’s meaning. The “Think Thrice” compre-hension trick is a set of three comprehension strategies to enhance the child’s prediction, comprehension-monitoring, and analytical and inferential skills.

Within every unit, fluent comprehension for connected text is addressed through metacognitive comprehension strategies implemented with a series of specially written RAVE-O Minute Stories. The stories’ controlled vocabulary incorporates the pho-nemic and orthographic patterns, multiple meanings, and var-ied syntactic contexts of core words. The Minute Stories are multipurpose vehicles for facilitating more automatic rates within phonological, orthographic, syntactic, and semantic systems at the same time that they reinforce connections across these systems. In the process, the stories build overall fluency and comprehension skills. An important affective dimension in these stories is that the content provides a platform for exploring feelings struggling readers often have about learning to read.

Although these tricks and emphases on word play may appear deceptively fun-filled, what we hope to achieve with them is very serious. Children who are struggling readers need to learn the interconnected nature of words, and they usually don’t. These strategies are elaborated in the weekly lessons for the teachers and provide a foundation for many of the most important comprehension skills used in all later learning. The end goal of RAVE-O, therefore, is ultimately not about how rapidly children read, but about how well they understand and enjoy what they read.

Summary of ResultsThe effects of RAVE-O with struggling readers have

now been studied for 10 years in 3 research contexts: 1) a pull-out intervention during the school day; 2) an intensive summer-school remediation program; and 3) an after-school intervention. In each of these studies, RAVE-O is combined with a systematic phonological analysis and blending program

(such as SRA Reading Mastery or Orton-Gillingham) and taught to small groups of four children.

Recent results come from a three-city, federally funded (National Institute for Child Health and Human Development), randomized treatment-control study. In this study, children who represented the most impaired readers in grades 2 and 3 were randomly assigned to four treatment conditions and were con-trolled for socioeconomic status (SES), race, and IQ. Each group received 70 hours of treatment throughout the school year. Each of the sessions had one-half hour with a phonological decoding program. RAVE-O and another theoretically multi-dimensional treatment (PHAST; see Lovett’s extensive work in references) went beyond a phonological approach to include different multidimensional emphases in the second half-hour. Specifically, PHAST employed multiple emphases on phono-logical, orthographic, and morphological processes, as well as distinctive metacognitive strategies for word identification and comprehension.

We compared the effects of the four types of treatment on an extensive battery of tests on all aspects of reading—from accu-racy and fluency in word attack to comprehension—and on many language measures. When compared to a control group receiving a math treatment, the RAVE-O group and the PHAST group outperformed the control group on every measure. When compared to a group who received only the systematic phono-logical analysis and blending treatment, the RAVE-O and PHAST groups again proved better on every measure. When compared to PHAST, RAVE-O made similar significant gains on standardized measures of decoding, and superior gains on the GORT-3 Oral Reading Quotient, a combined fluency and com-prehension score, and on measures of vocabulary and semantic flexibility (see overview in Morris, Lovett, Wolf, et al., submitted 2009). In other words, students who received instruction in programs that emphasized multiple dimensions of linguistic knowledge, performed equally well or better on every word attack and word identification measure (the specific emphases of the more unidimensional decoding treatment). RAVE-O also outperformed all other treatments in vocabulary and the GORT fluency-comprehension measure.

The theoretical implications of these outcome data are critical. The premise of RAVE-O is that the plural linguistic emphases will enhance decoding, as well as vocabulary and comprehension. The fact that RAVE-O spent far less time on specific decoding skills and yet made comparable or superior gains in word attack and word identification to programs which spent more of their instructional time on these skills is compel-ling evidence supporting the theoretical premise of RAVE-O: the more the child knows about a word, the faster and better the word will be decoded and understood.

In addition, and very importantly, this NICHD study demon-strated that impaired reading children could make significant gains in reading regardless of initial SES, race, or IQ factors (Morris et al., submitted 2009; Wolf et al., 2009). The latter set of results cannot be overemphasized. It suggests that despite these known impediments to achievement, the two multidi-mensional interventions produced similar gains in children from privileged and unprivileged backgrounds regardless of

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IQ level or race. This result directly answers the question wheth-er the linguistic demands in RAVE-O are too heavy for children in poverty or for children with lower cognitive aptitudes.

In fact, these results point to the success and the importance of explicit emphases on the multiple dimensions of language in our interventions. They also raise the issue of assessing and knowing the needs of each individual child before decid-ing what type of intervention is most appropriate. There are no silver bullets or one best program. Future analyses by our NICHD group will examine differential treatment response by subtype. Understanding research on different forms of remediation—what works best for which child and when—is like having a “toolbox” from which to create better-tailored teaching. It is not that many of our children can’t learn to read; it is that we haven’t found the right ways to teach them. The onus is upon us, their teachers, not the children, to find ways that work. Within that context, our collective findings under-score that explicit teaching of multiple linguistic systems propels our teachers and our students.

ReferencesAdams, M. J. (1990). Beginning to read: Thinking and learning about print. Cambridge,

MA: MIT Press.

Biemiller, A. (2005). Size and sequence in vocabulary development: Implications for choosing words for primary grade vocabulary instruction. In A. Heibert & M. Kamil (Eds.), Teaching and learning vocabulary: Bringing research to practice (pp. 223–242). Mahwah, NJ: Erlbaum.

Chomsky, N., & Halle, M. Sound Pattern of English. New York: Harper and Row, 1968. Reprint. Cambridge, MA and London: The MIT Press, 1991.

Frishkoff, G. A., Collins-Thompson, K., Perfetti, C. A., & Callan, J. (2008). Measuring incremental changes in word knowledge: Experimental validation and implica-tions for learning assessment. Behavioral Research Methods 40(4), 907–925.

Goswami, U., and East, M. (2000). Rhyme and analogy in beginning reading: Conceptual and methodological issues. Applied Psycholinguistics, 21, 63–93.

Locker, L. Jr., Simpson, G. B., & Yates, M. (2003). Semantic neighborhood effects on the recognition of ambiguous words. Memory & Cognition, 31(4), 505–515.

Lovett, M. W., Borden, S. L., DeLuca, T., Lacerenza, L., Benson, N. J., & Brackstone, D. (1994). Treating the core deficits of developmental dyslexia: Evidence of trans-fer-of-learning following phonologically- and strategy-based reading training programs. Developmental Psychology, 30(6), 805–822.

Lovett, M. W., Lacerenza, L., & Borden, S. L. (2000). Putting struggling readers on the PHAST track: A program to integrate phonological and strategy-based remedi-al reading instruction and maximize outcomes. Journal of Learning Disabilities, 33(5), 458–476.

Lovett, M. W., Lacerenza, L., Borden, S. L., Frijters, J. C., Steinbach, K. A., & Palma, M. D. (2000). Components of effective remediation for developmental reading disabilities: Combining phonological and strategy-based instruction to improve outcomes. Journal of Educational Psychology, 92(2), 263–283.

Lundberg, I., & Höien, T. (1991). Initial enabling knowledge and skills in reading acquisition: Print awareness and phonological segmentation. In D. J. Sawyer & B. J. Fox (Eds.), Phonological awareness in reading: The evolution of current per-spectives (pp. 73–95). New York: Springer-Verlag.

Moats, L. (2000). Speech to print: Language essentials for teachers. Baltimore, MD: Paul H. Brookes Publishing.

Moats, L. C. (2001). Overcoming the language gap. American Educator, 25(2), 4–9.

Morris, R., Lovett, M., & Wolf, M. (submitted 2009). Treatment effects of multi-dimensional approaches to reading intervention in children with reading disabilities.

Pugh, K. R., Sandak, R., Frost, S. J., Moore, D., & Mencl, W. E. (2005). Examining reading development and reading disability in English language learners: Potential contributions from functional neuroimaging. Learning Disabilities Research & Practice, 20(1), 24–30.

Sandak, R., Mencl, W. E., Frost, S. J., & Pugh, K. R. (2004). The neurological basis of skilled and impaired reading: Recent findings and new directions. Scientific Studies of Reading, 8(3), 273–292.

Stanovich, K. E. (1985). Explaining the variance in reading ability in terms of psy-chological processes: What have we learned? Annals of Dyslexia, 35, 67–96.

Stanovich, K. E. (1991). Changing models of reading and reading acquisition. In L. Rieben & C. A. Perfetti (Eds.), Learning to read: Basic research and its implications (pp. 19–31). Hillsdale: Erlbaum.

Tan, L. H., Spinks, J. A., Eden, G. F., Perfetti, C. C., and Siok, W. T. (2005). Reading depends on writing in Chinese. Proceedings of the National Academy of Sciences, 24, 8781–8785.

Torgensen, J., Wagner, R., Rashotte, C., Rose, E., Lindamood, P., Conway, T., et al. (1999). Preventing reading failure in young children with phonological process-ing disabilities: Group and individual responses to instruction. Journal of Educational Psychology, 91(4), 579–593.

Wolf, M., & Katzir-Cohen, T. (2001). Reading fluency and its intervention. Scientific Studies of Reading (Special Issue on Fluency), 5, 211–238.

Wolf, M. (2007). Proust and the squid: The story and science of the reading brain. New York: Harper Collins.

Wolf, M., Barzillai, M., Gottwald, S., Miller, L., Spencer, K., Norton, E., et al. (2009). The RAVE-O Intervention: Connecting Neuroscience to the Classroom. Mind, Brain, and Education, 3(2), 84–93.

Maryanne Wolf, Ph.D., is Director of the Center for Reading and Language Research at Tufts University and Professor of Child Development in the Eliot-Pearson Department of Child Development. She has received many awards includ-ing the Norman Geschwind Lecture Award for neuroscience research in dyslexia. She is the author of many articles and books, including Proust and the Squid: The Story and Science of the Reading Brain, which recently received the Marek Award from the New York International Dyslexia Association.

RAVE-O is a program designed by the first author, with assis-tance from the Center for Reading and Language Research and many teachers. Although it is not at this moment a com-mercially available program, it may be in the future.

Stephanie Gottwald, M.A., is the Research Coordinator at the Center for Reading and Language Research at Tufts University, where she is also pursuing a Ph.D. in literacy and language development. She received her master’s degree in linguistics from Boston College, where she began her work studying child language acquisition and syntax. She is the recipient of a Fulbright Scholarship to Germany. She is cur-rently the primary RAVE-O trainer and an international speaker on reading development and disabilities.

Melissa Orkin is a doctoral student studying under Dr. Maryanne Wolf and Dr. Fred Rothbaum. Her research inter-ests focus on how emotions affect learning. More specifi-cally, she is investigating the ways in which the beliefs and goals of children with reading disabilities relate to their ability to handle academic challenges. Melissa received a B.A. in Psychology from Arizona State University and an M.A. in Applied Child Development from Tufts University.

24 Perspectives on Language and Literacy Fall 2009 The International Dyslexia Association

Serious Word Play continued from page 23

MIND, BRAIN, AND EDUCATION

The RAVE-O Intervention:Connecting Neuroscienceto the ClassroomMaryanneWolf1, Mirit Barzillai1, Stephanie Gottwald1, Lynne Miller1, Kathleen Spencer1,Elizabeth Norton1, Maureen Lovett2, and Robin Morris3

ABSTRACT—This article explores the ways in whichknowledge from the cognitive neurosciences, linguistics, andeducation interact to deepen our understanding of reading’scomplexity and to inform reading intervention. We firstdescribe how research on brain abnormalities and namingspeed processes has shaped both our conceptualization ofreading disabilities and the design of a multicomponentreading intervention, the RAVE-O program.We then discussthe unique ways this program seeks to address the multipleand varied sources of disruption in struggling readers. Finally,we present efficacy data for the RAVE-O reading interventionacross multiple school settings.

Wonderful ideas are not born (Duckworth, 1996), theyare connected. Each wonderful idea rests on the humanmind’s ability to make novel connections out of familiarperceptions and concepts. Underlying this ability is oneof the brain’s unique design features: the capacity ofalready existent circuits of neurons to forge whole newpathways among themselves. Because of this plasticity, weare genetically poised to make novel neuronal connections,the basis of all cognitive breakthroughs. The brain’sacquisition of reading is a penultimate example of this:to read, the brain must build new connections amongcircuits designed thousands of years ago for older visual,auditory, linguistic, and cognitive operations. Such a newarrangement of circuits makes reading both a remarkable

1The Center for Reading and Language Research, Tufts University2University of Toronto, Hospital for Sick Children3Georgia State University

Address correspondence toMaryanneWolf, The Center for Reading andLanguage Research, Miller Hall, Tufts University, Medford, MA 02155;e-mail: [email protected]

achievement and potentially vulnerable to multiple sources ofdifficulties.

Appreciating the complexity and vulnerability of thereading process requires a new form of novel connec-tion: the bringing together of knowledge bases fromtypically unconnected disciplines—in this case, linguis-tics, education, and the cognitive neurosciences. In thisarticle, we first present a case study of how the-oretical insights and questions from these disciplinesinformed the design of a research intervention programfor children with reading difficulties. We then summa-rize findings demonstrating the efficacy of this interven-tion for children with dyslexia in different school-relatedsettings.

CASE STUDY OF AN IDEA: HOWTHE STUDYOF THE BRAIN AND ITS ‘‘DISCONNECTIONS’’ LED

TO EDUCATIONAL INSIGHTS

Four decades ago, two converging but unconnected insightsemerged from educational and neurological research aboutthe prediction of reading ability and disability. The firstwas that children’s knowledge of letter names representedone of the best predictors of reading (Chall, 1967, 1983;Johnson & Myklebust, 1964; Roswell & Natchez, 1971). Thesecond highlighted the importance of the connections amongbrain systems for cognitive and linguistic functions such asreading (Geschwind, 1974). Using a case study by Frenchneurologist Dejerine of a patient with alexia (i.e., acquiredreading loss), Geschwind illustrated how different forms ofreading breakdown resulted from disconnections betweenparticular areas of the brain. Dejerine’s patient with ‘‘classicalexia’’ could ‘‘see’’ theworld using his intact right visual areas,but couldnot ‘‘read’’ letters, numbers, ormusical notesbecausethat information could not be connected to left hemispherelinguistic areas. Intriguingly, the patient could not name colors.

84! 2009 the Authors

Journal Compilation ! 2009 International Mind, Brain, and Education Society and Blackwell Publishing, Inc. Volume 3—Number 2

MaryanneWolf et al.

Based on this observation, Geschwind hypothesized thatreading and color naming must share similar cognitive, per-ceptual, and linguistic requirements and similar neurologicalstructures. He went one step further bridging neuroscienceand education by hypothesizing that children’s color namingmight provide a unique measure of reading readiness.

Martha Bridge Denckla, Geschwind’s student, pursued hishypothesis among children with dyslexia and found thatthey could name colors accurately but not rapidly. The timeit took for the brain to perform this visual–verbal functionwas key, not accuracy. Denckla and Rudel (1974, 1976a,1976b) found that serial naming speed for basic symbolsdifferentiated childrenwith dyslexia from average readers andfrom children with different learning disabilities. Continuingthis line of work, Wolf and her colleagues demonstratedthe predictive capacity of rapid automatized naming (RAN)and rapid alternating stimulus (RAS) measures, for readingdevelopment over the school years (Wolf, Bally, & Morris,1986; Wolf & Denckla, 2004).

Findings from three decades of rigorous study giveoverwhelming support to the original insights about theprediction and differentiation capacities of RAN (see reviewsin Wolf & Bowers, 1999; Wolf, 2007) in English as well asacross a variety of orthographies (see de Jong & van derLeij, 2003; Frith,Wimmer, & Landerl, 1998; Georgiou, Parrila,Kirby, & Stephenson, 2008; Ho, Tsang, & Lee, 2002; Katzir,Breznitz, Shaul, & Wolf, 2004; Lopez-Escribano & Katzir,2008; van den Bos, 1998) The nagging question remains, why isthis so? Why are naming speed tasks such ‘‘universal’’ (Tan,Spinks, Eden, Perfetti, & Siok, 2005) predictors of readingfailure, particularly given research indicating the primacy ofphonological processes in explanations of dyslexia in English?The search for answers spans languages and disciplines andhas become the basis for a new conceptualization of dyslexia,fluency, and intervention.

CONCEPTUALIZING NAMING-SPEED PROCESSES

Geschwind began to answer the question of why namingspeed could predict reading ability with his observation thatnaming processes and reading must share similar cognitivedemands and underlying neural circuitry. This insight framedour current understanding of rapid naming as a kind of‘‘minicircuit’’ made up of many of the same processes usedin reading—including phonology—but going well beyond.Thus, just as fluent reading draws on the synchronized andefficient translationof visualpatterns to theirphonological andsemantic representations, so toodoes the act of naming a letter.In thisway, RANandRAS tests provide a uniquewindow intothe integrity and speed of the components required for fluentreading before the child ever learns to read. If this premise iscorrect, then an analysis of the specific cognitive and linguistic

processes underlying letter namingwould provide a view intosome of the original circuits necessary for reading in the brainand a blueprint for what to target in interventions.

This view of naming speed, however, has been repeatedlychallenged because prevailing hypotheses have long centeredon phonological processes as the basis of dyslexia. To preservetheir parsimonious explanation, many researchers suggestedthat rapid naming processes would be best subsumed underthe rubric of phonology (Schatschneider, Carlson, Francis,Foorman, & Fletcher, 2002;Wagner & Torgesen, 1987). If thelatter view is held, there would be little reason to expandcurrent understanding of dyslexia intervention, which islargely phonologically based. If, however, phoneme awarenessand naming speed are considered the tips of at least twodifferent but overlapping sources of reading breakdown, ourdiagnosis, understanding, and efforts to treat children withdyslexia would need to be expanded.

These differing conceptualizations of naming-speeddeficits—as an aspect of phonological weakness versus anindex of additional sources of reading disruption—reflectthe tension between unidimensional and multidimensionalaccounts of reading and reading failure. Thus, efforts to under-stand differences between naming-speed and phonologicalprocesses have implications for far larger issues around thecomplexity of the reading circuitry and the universality ofdyslexia. If both processes are manifestations of the sameunderlying phonological system, then both processes shouldbe impaired in each child with a reading difficulty, shouldbe equally predictive across all languages, and should showsimilar brain activation patterns. Described below, converg-ing evidence from subtyping analyses, cross-linguistic studies,and brain-imaging studies gives little support to any of theseassertions and consistently documents a dissociation betweenmost processes underlying naming speed and phonology. Thiswork reinforces the need for a more comprehensive view ofreading difficulties and intervention.

NEUROLOGICAL AND BEHAVIORAL CHALLENGESTO THE UNIDIMENSIONAL VIEWOF READING

Wolf and Bowers (1999) explored the question of whethernaming speed and phonology represent different sources offailure in English using subtyping methods. They found foursubtypes of reading-impaired children characterized by thepresence, absence, or combination of two core deficits inphonologyandnamingspeed. Importantly, thedata illuminedarelatively unrecognized subtype of poor readers characterizedby adequate phonological and decoding skills, early naming-speed deficits, and later reading fluency and comprehensiondifficulties. This fluency-based subtype would be completelyunpredicted by the more parsimonious phonological view ofreading failure. Furthermore, the most intractable subtype

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exhibited both or double deficits and represented the mostseverely impaired subtype across all measures, particularlyin reading fluency. This subtypying approach was namedthe double-deficit hypothesis, as a heuristic to underscore theneed to include but go beyond phonological deficits inexplanations of reading failure in English and in otherlanguages (See also Escribano, 2007; Ho et al., 2002; Manis,Doi, & Bhadha, 2000). As such, the double-deficit hypothesisconstitutes a ‘‘transitional hypothesis’’ in preparation formorecomprehensive classifications. One of its major contributionswas to underscore the need to understand that there are at leasttwomajor sources of deficits in our reading-disabled children,and that at least 70% of these children have fluency-relatedissues. It also helped spur cross-linguistic investigations thatfurther illuminated the role of processes underlying namingspeed as sources of reading breakdown, independent ofphonology.

For example, as mentioned earlier, although naming-speed measures reliably predict reading difficulties acrossorthographies, the effect is particularly robust for languageswith more transparent orthographies (Holopainen, Ahonen,& Lyytinen, 2001; Korhonen, 1995; Landerl &Wimmer, 2000;Tressoldi, Stella, & Faggella, 2001; Verhagen, Aarnoutse, &van Leeuwe, 2008). In these languages, phoneme–graphemecorrespondence rules are relatively simple, and dyslexia doesnot always involve a failure to learn to decode words. Rather,it involves a failure to read fluently with comprehension (seeWimmer, Mayringer, & Landerl, 2000). The predictive powerofnamingspeed in thesecases suggests that rapidnamingtasksare indexing some processes that are separate fromphonology,but equally important to reading. Thus, the cross-linguisticliterature points to the importance of understanding andaccounting for the heterogeneity of reading difficulties acrossorthographies (Tan et al., 2005).

Neurological investigations mirror these findings andprovide new evidence for the differentiation of namingspeed from phonological processes. In one brain-imagingstudy, Misra, Katzir, Wolf, and Poldrack (2004) investigatedthe neural substrates underlying rapid naming for lettersand objects and found activation in inferior frontal cortex,temporal–parietal areas, and the ventral visual stream.Notably, these regions were largely nonoverlapping withknown sites for phonological tasks indicating that the tasksrepresent distinct processes with separate contributionsto reading. Research by Eden and her colleagues alsoshows similar nonoverlapping neural sites for these tasks(Turkeltaub, Gareau, Flowers, Zeffiro, & Eden, 2003).

Case Study of an Isolated Fluency Deficit—How BrainAbnormalities can Inform Educational TheoryFurther support for the importance of processes involvedin fluency for reading takes the form of a case study

involving individuals with a congenital brain malformation,periventricular nodular heterotopia (PNH). This conditionleads to inefficiently organized white fiber tracts in thebrain and affords a rare opportunity to investigate thebehavioral consequences of a specific deficit in the integrityof the connections between brain regions. Based on ourconceptualization of reading’s complexity, we would expectindividualswith this condition to have a selective deficit in therapidandefficient integrationof information fromseveralbrainregions, resulting in dysfluent reading. This is exactly whatthe evidence suggests. Individuals with PNH exhibit normalintelligence, attention, working memory, and phonologicalskills but have an isolated deficit in reading fluency and rapidnaming (Chang et al., 2007). Particularly revealing is that themost reading-impaired individuals in this population are thosewith the most widespread disruptions to the white mattertracts. These findings are further bolstered by increasingevidence of a relationship between white matter integrity andreading ability both in normal readers and dyslexics (Deutschet al., 2004;Klingberg et al., 2000;Niogi&McCandliss, 2006).In this way, the profiles of individuals with PNH providecompelling support for a dissociation between fluency-relatednaming-speed processes and phonological processes. Theyalso attest to the importance of efficient connections betweenand among brain regions involved in the reading circuit, whichhas critical implications for intervention.

BROADENING OUR VIEWOF READING AND ITSINTERVENTION

To summarize thus far, the behavioral and neurologicalevidence forces us to recognize that reading involves acomplex circuit of linguistic and cognitive processes, each ofwhich contribute to decoding and fluent comprehension. Thismeans that successful reading depends on the integrity, speed,and automatic connections among all these subprocesses.Within this context, research on the naming-speed taskultimately implies that the more unidimensional accountsof reading disabilities provided by phonological core-deficit explanations, although indisputably important, areinsufficient.

Support for this more comprehensive view of readingcomes from cognitive and linguistic research emphasizing theimportance of high-quality orthographic, semantic, morpho-syntactic, and phonological lexical representations, as wellas the binding, or connections between and among them forfluent reading and comprehension (Adams, 1990; Berninger,Abbot, Billingsley, & Nagy, 2001; Foorman, 1994; Henry,2003; Perfetti, 2007; Seidenberg & McClelland, 1989). Forexample, richsemanticknowledge facilitateswordrecognitionand is strongly related to comprehension (Beck, Perfetti,& McKeown, 1982; Nation & Snowling, 1998). Similarly,

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well-represented orthographic and morphological knowledgeconsistently predicts word reading and comprehension(Berninger et al., 2001; Carlisle, 2000; Cunningham, Perry,& Stanovich, 2001; Katzir et al., 2006a; Kieffer & Lesaux,2007; Reed, 2008).

Recent research in cognitive neuroscience underscoresthe importance of the developing connections between andamong these component systems in reading (Lavric, Clapp, &Rastle, 2007; Norton, Kovelman,& Petitto, 2007; Shankweileret al., 2008), and also the importance of addressing eachone in interventions (Sandak et al., 2004a). Imaging studiescomparing novice and expert readers document themovementfrom an effortful set of processes that draws on many brainareas to one that is more efficient and streamlined (see Pughet al., 2000; Sandak,Mencl, Frost, & Pugh, 2004b; Turkeltaubet al., 2003). This research underscores that the developingreading circuit needs time and practice to build high-qualityrepresentations in each component and to connect themautomatically. Most importantly, it implies that the quality,efficiency, and connections among all these representationsshould be explicit goals for reading intervention.

Together, these neurological, behavioral, and educationaldata refocus our attention on the need to understand allthe processes involved in reading acquisition and readingbreakdown. When we examine children and adults withdyslexia across languages, rare brain abnormalities, andreading subtypes, we are faced first with the extraordinarycomplexity of the reading circuit and then with the multiplepotential sources of breakdown. Such an expanded, moreuniversal view of dyslexia implies that intervention basedlargely on phonological processes, and decoding accuracyis necessary but insufficient to meet the diverse needsof struggling readers (see Katzir et al., 2006b). Evidencefrom phonologically based interventions confirms that theseinterventions work well in the improvement of decodingskills, but not as well in fluency and comprehension (Lyon &Moats, 1997). Thus,we conclude that although phonologicallybased interventions are a critical platform for early readingskills (see Foorman & Al Oitoba, 2009), explicit attentionto those additional processes underlying rate, fluency, andcomprehension are of equal importance for the developmentof the fluent comprehending reader.

CONNECTING THEORY TO THE CLASSROOM

Over the last decade,much of our research has been directed tounderstanding the development and multicomponent natureof reading fluency (see Wolf & Katzir-Cohen, 2001; Wolf,2001) and applying this knowledge to intervention. Forexample, Wolf and Katzir-Cohen (2001) argue the following:

In its beginnings, reading fluency is the product of the initialdevelopment of accuracy and the subsequent development ofautomaticity in underlying sublexical processes, lexical processes,andtheirintegrationinsingle-wordreadingandconnectedtext.Theseinclude perceptual, phonological, orthographic, and morphologicalprocesses at the letter-, letter-pattern, and word-level; as well assemantic and syntactic processes at the word-level and connected-text level. After it is fully developed, reading fluency refers to a levelof accuracy and rate, where decoding is relatively effortless; whereoral reading is smoothandaccuratewith correct prosody; andwhereattention can be allocated to comprehension (p. 219).

This view of fluency emphasizes several key elements:first, the development of rapidly functioning, high-qualityorthographic, phonological, semantic, syntactic, and morpho-logical representational systems; second, automatic connec-tions between and among these systems; and, third, extensivelearning and practice to ensure that automatic decodingbecomes a bridge to fluent comprehension. Within such adevelopmental framework, efforts to address fluency need tobegin at the start of the reading acquisition process, not afterreading is already acquired (see Kame’enui& Simmons, 2001).

This approach to fluency provides the theoretical basisfor an intervention designed to address as many of thesecognitive and linguistic processes as possible. Describedin detail elsewhere (Wolf, Gottwald, Galante, Norton, &Miller, 2009; Wolf, Miller, & Donnelly, 2000), the Retrieval,Automaticity, Vocabulary, Engagement with Language, andOrthography (RAVE-O) program represents our evolvingknowledge from the cognitive neurosciences, linguistics,and education, and its integration with best classroompractices. The program simultaneously addresses both theneed to explicitly teach phonological, orthographic, semantic,syntactic, and morphological information in a systematic,sequenced fashion as well as the importance of teachingexplicitconnectionsamongthese linguistic systems(Adams, 1990;Berninger et al., 2001; Foorman, 1994; Henry, 2003; Seidenberg&McClelland, 1989).

At its most basic, the RAVE-O program is about teachingyoung readers to enrich and connect all their knowledge abouta word as fast as possible. Within a more physiologicalcontext, the RAVE-O program places heavy emphaseson representational processes within each component inthe brain’s reading circuit. This includes representationsof common letter patterns, multiple semantic meanings,phonological representations, and the most used morphemesand syntactic uses of words in the children’s lexicon.Very importantly, the design and sequence of the programseek to make the initially ‘‘novel’’ connections among theserepresentations as automatic as possible. In so doing, we hopeto simulate what the typical reading brain circuit does duringthe earliest stages of acquisition and fluency. Over the courseof the intervention,we hope to propel the developmentalmove

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from the use of a more laborious route (found in most earlyreaders) to the use of a more streamlined route used by fluentreaders (see Pugh et al., 2000; Sandak et al., 2004b).

These principles are applied in the RAVE-O classroomin several ways. To begin, all children receive some formof an explicit decoding program in their school, whichinvolves intensive work on phoneme awareness, letter-sound correspondence rules, and so on (see Lovett et al.,1994). Then within the RAVE-O program, they are taughta group of core words each week that exemplify criticalphonological, orthographic, andsemanticprinciples. Syntacticand morphological principles are gradually added afterinitial work has begun in the program. Each core wordis chosen on the basis of: (a) shared phonemes with thephonological treatment program; (b) sequenced orthographicpatterns that represent most of the most common letterpatterns in English; and (c) semantic richness (e.g., eachcore word has at least three different meanings). Thus,the core words enable teachers to foster an awareness ofthe different linguistic components (semantics, phonology,orthography, morphology, and syntax) involved in readingand to make explicit connections between and among thesecomponents. In the following section, we briefly exploresome of the ways our intervention achieves these endsby examining how the program develops representationsin each linguistic component and the connections amongthem.

PhonologyAlthough we assume that each child receives systematicattention to core phonological knowledge within theschool’s program, we leave nothing to chance. The programincorporates phonological principles and teaches explicitconnections between phonology and all other componentsin every lesson as discussed below.

OrthographyBased on the importance of orthographic knowledge forreading fluency, many activities focus on the automaticrecognition of orthographic patterns at the sublexical andlexical levels and their use within the connected-text level.Other activities stress orthographic connections to the otherlinguistic components. For example, the trained orthographicpatterns in RAVE-O correspond to the phonemes in thecore words and to the individual phonemes in the classroomphonological program (e.g., ‘‘a,’’ ‘‘t,’’ and ‘‘m’’ become ‘‘at’’and ‘‘am,’’ along with their word families; see work of Juel& Solso, 1981). Based on Reitsma’s (1983) and Levy’s (2001)work emphasizing the need by impaired readers for multipleexposures in order to learn letter and word patterns, there isdaily emphasis on practice and rapid recognition of the most

frequent orthographic letter patterns in English. Evolvingcomputerized games (see SpeedWizards, Wolf & Goodman,1996) and manipulative materials (e.g., letter dice, soundsliders, cards, etc.) are used daily to allow formaximal practicewith the orthographic patterns and to increase the speed oforthographic pattern recognition (i.e., onset and rime) in anengaging fashion.

MorphologySimilar to the approach to teaching orthographic patterns,the RAVE-O program explicitly emphasizes morphologi-cal knowledge and its connection to the orthographic,phonological, semantic, and syntactic aspects of wordsthrough a series of metacognitive terms and strategies. Forexample, the term ‘‘Ender Benders,’’ which itself illustrates theways in which morphemes can transform words, serves as amnemonic illustrating the ways in which morphemes such as‘‘ed,’’ ‘‘er,’’ and ‘‘s’’ can change a noun to a verb (e.g., ‘‘ram’’ to‘‘rammed’’), an action to a person who performs that action(e.g., ‘‘move’’ to ‘‘mover’’), and a singular word to a plural(e.g., ‘‘bug’’ to ‘‘bugs’’). The use of these terms helps readersunderstand how common morphemes work to expand wordsand to alter their meanings. This knowledge is rarely taughtin an explicit manner, but is known to critically facilitatefaster word identification, vocabulary, and comprehension(Berninger et al., 2001; Carlisle, 2000; Henry, 2003; Kieffer &Lesaux, 2007; Reed, 2008).

SyntaxKnowledge of how words are used within differentgrammatical or syntactic contexts is essential for the child’sfluency and comprehension, along with the need to becomefamiliar with a variety of increasingly sophisticated sentenceconstructions and literary conventions. RAVE-O directlyaddresses how morphemes can change the grammatical roleof words and how different sentence contexts influencewhich particular word meaning to use when. Although arelatively small amount of time was previously devoted to thedevelopment of syntactic knowledge, new iterations ofRAVE-O give increased attention to understanding basic syntacticprinciples at the word, sentence, and story levels.

Semantic KnowledgeThe RAVE-O program places a heavy emphasis on fosteringdeep, rich, and flexible semantic knowledge. Toward theseends, the multiple meanings of core words are introduced andthoroughly discussed to illumine their different connotationsand connections with other words. Furthermore, imagisticcards that depict the word in varied semantic contexts (e.g.,for the word ‘‘track,’’ image cards depict railroad tracks,

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animal tracks, and a detective ‘‘tracking’’) are used to engagestudents in an exploration of a word’s related images anddifferent syntactic roles. Image cards for the word ‘‘ram,’’ forexample, provide pictures of the animal, the act of ramming,a battering ram, and computer ram. In so doing, these imagesserve as a visualmnemonic that aidsword retrieval (a commonchallenge in dyslexia) and reinforces the word’s semanticrichness.

Vocabulary growth is conceptualized as essential to bothrapid retrieval (in oral and written language) and also toimproved comprehension, the ultimate goal in the program.Word-retrieval skills are taught through a variety of ways,including a set of metacognitive strategies, influenced by earlyresearch with aphasia patients with dysnomia (see Goodglass& Kaplan, 1972).

Fluency and Comprehension: Integrating AcrossSubcomponentsA series of comprehension stories (e.g., minute stories, minutemysteries, and minute heroes) accompany each week of RAVE-Oand directly address fluency and comprehension in severalways. The controlled vocabulary in the timed and untimedstories both incorporates the week’s particular orthographicandmorphological patterns, and also emphasizes the multiplemeanings of the week’s core words, and often their differentsyntacticuses.Thestoriesprovideasuperbvehicle for repeatedreading practice, which, in turn, helps fluency in connectedtext.

Thus, the minute stories are multipurpose vehicles forfacilitating fluency in phonological, orthographic, syntactic,and semantic systems at the same time that they build upknowledge about more sophisticated sentence structures anda range of comprehension skills. Such a multicomponential,multilayeredapproach is apedagogical analogue to the insightsby Sandak and Pugh and their colleagues (see Sandak et al.,2004b) into the multiple neurological substrates subservingword identification and comprehension.

Within this multicomponential approach, fluency isconceptualized as the bridge to fluent comprehension. Fluentcomprehension, in turn, is conceptualized as the bridge tothe reader’s own best thoughts. RAVE-O teaches a set ofthree comprehension strategies, the ‘‘ThinkThrice’’ strategies,each of which embodies well-known skills from predictionto comprehension monitoring. The final strategy, Think forYourself, explicitly elicits the reader’s insights into the text. Inso doing, we hope to teach new readers a set toward criticalthinkingandanexpectationandbelief in theirown intellectualcontributions. We consciously aim to nurture from the startthewell-knowncapacity of individualswithdyslexia to ‘‘thinkoutside the box.’’

EngagementThe end goal of RAVE-O is not about how rapidly childrenread, but about howwell they understand and enjoywhat theyread. Critical to this ultimate goal, every daily lesson inRAVE-O incorporates an additional system too little discussed bymany researchers—the affective-motivational one. The secretweapons of the RAVE-O program are the game-like whimsyin every dimension of the theoretically motivated activitiesand the daily, systematic efforts to help each child find andfeel success. We want our children to read and to appreciatethe richness of oral and written language. We want them toremember and easily retrieve what they know. By engagingthem and ensuring that they find success often, we seekto empower what are often linguistically disenfranchisedchildren and give them a sense of the fluidity of their growingknowledge (Dweck, 2000). Such a method of instructiondemands a special involvement from teachers. Throughout theprogram, therefore, we strive in as many ways as we can toengage not only the learner’s interests but also the teacherand the teacher’s own love of language. Our goal is a groupof mutually engaged teachers and learners with a mutualappreciation for words.

EFFICACY OF RAVE-O

We have now studied the RAVE-O program in a varietyof contexts: school-based intervention, summer school, andafter-school settings. Along with our colleagues, RobinMorris in Atlanta and Maureen Lovett in Toronto, wehave studied the efficacy of RAVE-O alongside anotherhighly effective multidimensional program, the metacognitivestrategy program by Lovett called PHAST (Lovett et al.,1994; Lovett, Steinbach, & Frijters, 2000). This program,which combines a phonological analysis and blendingprogram (PHAB) with a word identification strategyprogram (WIST), emphasizes phonological, orthographic,morphological, and affective components. We compared thetwo multidimensional programs with two control conditions:the more traditional phonological analysis program (PHAB),taught alongside a study skills program, and a classroomcontrol condition that included a math and a study skillsprogram (classroom control).

In our first 5-year randomized treatment-control study, 279impaired readers in the second and third grades received 70 hrof treatment in one of the control conditions, or in one of themultidimensional programs, each combined with half an hourof the phonology program.The effects of these conditionswerecomparedacrossanextensivebatteryof testscoveringmultipleaspects of reading from single-word decoding to connectedtext reading and comprehension aswell as languagemeasures.As summarized in Table 1 and described in detail in a recentquantitativepaper, the results fromthis studystronglysupport

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Table 1Summary of findings at the single word, connected text, comprehension, fluent comprehension, and vocabulary levels from the longitudinalinvestigation of reading interventions in second and third graders with RD!

Skills Measured Results after 70 hours of intervention

Word level skillsWRMTWord Attack RAVE-O= PHAST > PHAB > Classroom ControlWRMTWord Identification RAVE-O= PHAST > PHAB > Classroom ControlWRE RAVE-O = PHAST = PHAB > Classroom ControlWRAT Reading RAVE-O= PHAST > PHAB > Classroom Control

Connected text level skillsGORT Accuracy RAVE-O = PHAST > PHAB > Classroom ControlGORT Rate RAVE-O = PHAST > PHAB > Classroom Control

ComprehensionGORT Comprehension RAVE-O >!! PHAST > PHAB > Classroom ControlWRMT Passage Comprehension RAVE-O= PHAST > PHAB > Classroom Control

Fluent ComprehensionGORT Oral Reading Quotient RAVE-O > PHAST > PHAB > Classroom Control

Vocabulary KnowledgeNo. of multiple meanings onWord-R RAVE-O > PHAST, PHAB, Classroom ControlExperimental multiple meanings measure RAVE-O > PHAST, PHAB, Classroom Control

RAVEO= RAVE-O intervention, including half an hour of PHAB. PHAST= PHAST intervention, including half an hour of PHABPHAB= Study Skills program/PHAB Intervention. Classroom Control= Study Skills program/Math program.WRE = Test ofWord Reading Efficiency, early version of the Test ofWord Reading Efficiency (Torgesen, Wagner, & Rashotte, 1999)WRMT = Woodcock Reading Mastery Test-Revised (Woodcock, 1987); WRAT = Wide Range Achievement Test-3 (Wilkinson, 1993); GORT = Gray Oral ReadingTest (Wiederholt & Bryant,1992); Word-R= Multiple Meanings subtest of the ElementaryWord-R test (Huisingh, Zachman, Blagden, & Orman, 1990)!all values p<.05 or less!!.05<p<.06

the efficacy of bothmultidimensional programs in general, andin RAVE-O’s approach in particular, for advancing children’sreading performance at the letter-pattern, word, and textlevels (see Morris et al. 2009).

There were significant differences in every reading andlanguagemeasure at every level betweenchildrenwho receivedthe RAVE-O program and both the classroom control andthe phonological control condition. Specifically, the childrenin the RAVE-O group outperformed the latter groups onmeasures of decoding, word reading, connected text reading,and comprehension. We expected and found no significantdifferences in decoding and word recognition between themultidimensional programs (RAVE-O and PHAST), whichproduced similarly significant gains on every standardizedmeasure of word identification and reading.

Of keen importance to our goals, however, is that therewere additional significant differences achieved by children inRAVE-O inmeasures of vocabulary (Barzillai,Wolf,Morris,&Lovett, 2009) and connected text-level fluent comprehensionmeasured on the Gray Oral ReadingQuotient (ORQ). In otherwords, children in the RAVE-O group made equal or greaterimprovements on the word-attack and word-identificationmeasures, and outperformed children in the other treatmentgroups on measures of vocabulary and fluent comprehensionon theORQ. The latter have been extremely difficult to changein previous large intervention studies.

Additional investigations revealed that the positiveoutcomes forRAVE-OandPHASTwere trueacross all readers,

regardlessof IQ levels, ethnicbackgrounds, andsocioeconomiccircumstances (Morris et al., 2009). Taken together, theseresults support a multidimensional view of reading and itsintervention with heterogeneous struggling readers. The factthat children in the RAVE-O intervention (a) spent far lesstime on specific decoding skills and more time enhancingconnections across orthographic, semantic, morphological,and sytanctic processes; (b) made gains in word readingmeasures comparable or superior to programs that spentmore time solely on these skills; and (c) made superior gainson measures of vocabulary and fluent comprehension on theORQ provides compelling evidence in support of such amultidimensional view of reading and intervention.

Based on these strong efficacy results, we began a seriesof interventions in other settings with other populations.Donnelly Adams (2009) investigated the use of RAVE-O ina summer school setting and found significant improvementin both listening and reading comprehension, sight-wordreading, and reading fluency for an intensive, half-day,4-week RAVE-O intervention. In addition, we are working tounderstand the potential of RAVE-O to address the multipleissues of childrenwith comorbid reading and social-emotionalchallenges. Toward these ends, we (Pierce, Katzir, Noam, &Wolf, 2007) are studying RAVE-O along with a resiliencyprogram (Noam, Winner, Rhein, & Molad, 1996) in an after-school setting with this population. Furthermore, futureanalyses will focus on differential treatment outcomes forsubtypes of impaired readers. In this way, we hope to better

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understandwhich childrenwithwhat defining characteristicsare most helped by a particular intervention (see Francis et al.,2005); for, there is no ‘‘one size fits all’’ intervention.

The RAVE-O program itself continues to evolve withfeedback from teachers who use it in their classrooms. One ofour most valuable resources concerning the long-term efficacyof the intervention are these teachers whose observations andsuggestions shape each version of the program. For example,in another ongoing study, Miller, Wolf, Anton-Oldenburg,& Ellison (2009) are working with classroom teachers toexpand the present RAVE-O to a first-grade implementation.The past success of the RAVE-O intervention and its futureiterationsaretestamenttothepowerof thereciprocal,dynamicinteractions between neuroscience and classroom practice.

In summary, we have chronicled here the case history ofan idea that emerged from the observations of a 20th-centuryneurologist about the brain of a 19th-century patient withstroke. The research program that emerged became the basisof a comprehensive, highly successful intervention programfor many children with dyslexia. The theoretical basis of theRAVE-O program is the reading brain and what it does everytime a single word is read. From Chall’s prescience aboutletter naming prediction to functional magnetic resonanceimaging (fMRI) studies of this same process, every aspectof this intervention research program has been influencedby the increasing connections between education and theneurosciences.

Acknowledgements—Support for this research was provided bythe following: the National Institute of Child Health andHuman Development grant HD30970; the Department ofEducation, grant CFDA #84.305W Institute for EducationSciences/Interagency Education Research Initiative; the PiperFoundation, Phoenix, AZ; and Recording for the Blind andDyslexic. We are also grateful to Barbara and Brad Evans fortheir generosity in supporting this work. Finally, we thankour participants and their families for their cooperation andsupport.

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