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Composite scores for executive function items: Demographic heterogeneity and relationships with quantitative magnetic resonance imaging

Published online by Cambridge University Press:  03 September 2008

PAUL K. CRANE*
Affiliation:
Department of Medicine, University of Washington, Seattle, Washington
KAAVYA NARASIMHALU
Affiliation:
Department of Medicine, University of Washington, Seattle, Washington
LAURA E. GIBBONS
Affiliation:
Department of Medicine, University of Washington, Seattle, Washington
OTTO PEDRAZA
Affiliation:
Department of Psychiatry and Psychology, Mayo Clinic, Jacksonville, Florida
KALA M. MEHTA
Affiliation:
Division of Geriatrics, Department of Medicine, University of California-San Francisco, San Francisco, California
YUXIAO TANG
Affiliation:
Department of Internal Medicine and Rush Institute for Healthy Aging, Rush University Medical Center, Chicago, Illinois
JENNIFER J. MANLY
Affiliation:
Taub Institute for Research on Alzheimer's Disease and the Aging Brain, the Sergievsky Center, and Department of Neurology, Columbia University, New York, New York
BRUCE R. REED
Affiliation:
Department of Neurology, University of California-Davis, Sacramento, California VA Northern California Health Care System, Martinez, California
DAN M. MUNGAS
Affiliation:
Department of Neurology, University of California-Davis, Sacramento, California
*
Correspondence and reprint requests to: Paul Crane, Box 359780, Harborview Medical Center, 325 Ninth Avenue, Seattle, WA 98104. E-mail: pcrane@u.washington.edu
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Abstract

Accurate neuropsychological assessment of older individuals from heterogeneous backgrounds is a major challenge. Education, ethnicity, language, and age are associated with scale level differences in test scores, but item level bias might contribute to these differences. We evaluated several strategies for dealing with item and scale level demographic influences on a measure of executive abilities defined by working memory and fluency tasks. We determined the impact of differential item functioning (DIF). We compared composite scoring strategies on the basis of their relationships with volumetric magnetic resonance imaging (MRI) measures of brain structure. Participants were 791 Hispanic, white, and African American older adults. DIF had a salient impact on test scores for 9% of the sample. MRI data were available on a subset of 153 participants. Validity in comparison with structural MRI was higher after scale level adjustment for education, ethnicity/language, and gender, but item level adjustment did not have a major impact on validity. Age adjustment at the scale level had a negative impact on relationships with MRI, most likely because age adjustment removes variance related to age-associated diseases. (JINS, 2008, 14, 746–759.)

Information

Type
Research Article
Copyright
Copyright © The International Neuropsychological Society 2008
Figure 0

Fig. 1. Schematic representation of relationships analyzed in this study. Ability is represented in an oval at the top. Ability is reflected by item responses on a cognitive test (depicted in boxes as i1 through in+m). Demographic characteristics may directly impact Ability (depicted by the solid arrow between Demographics and Ability) and may be associated with item bias (depicted by the dotted arrows to the items with differential item functioning, abbreviated in the Figure as DIF, specifically items in+1 through in+m). Formulas are used to obtain composite scores from the observed item responses, depicted in the figure by the solid arrows between the item responses and the composite score. Traditional test theoretic composite score formulas include summing up observed responses or summing up average scores. Traditional test theoretic composite score formulas that account for demographic heterogeneity apply the same adjustment to all the items (depicted in the figure as the four dashed arrows extending from Demographics to the solid arrows extending from all of the items to the composite score). Modern psychometric theory formulas (known as item response theory or IRT) empirically calibrate item difficulty across the range of cognitive ability levels, resulting in nonlinear relationships between traditional composite scores and IRT scores. IRT formulas that account for DIF apply adjustments for demographics only to those items found with DIF (depicted in the figure with the rightmost two dashed arrows extending from Demographics to the solid arrows extending from items in+1 through in+m to the composite score). Finally, we compared these composites based on their strength of relationship with MRI measures of white matter hyperintensity and total brain volume. These evaluations included scale-level accounting for demographic heterogeneity, indicated in the figure by the solid arrow extending from Demographics to the composite score and the double headed arrows between the composite score and MRI, and between MRI and demographics. Note that measurement error is not depicted in the Figure.

Figure 1

Table 1. Summary of composite scoring techniques for executive function assessment tools

Figure 2

Table 2. Demographic characteristics of participants with and without MRIa

Figure 3

Table 3. Differential item functioning for executive function items related to age, education, gender, and ethnicity/language group

Figure 4

Fig. 2. Impact on estimated executive function scores of differential item functioning related to gender, age, education, and race separately, and related to all four covariates simultaneously. The x-axis maps the distribution of the difference scores obtained between individuals' executive function scores accounting for DIF and executive function scores that ignore DIF (i.e., If DIF made no impact on scores, then the difference in scores would be 0). All scores were transformed such that 1 standard deviation is 15 points. For each adjustment strategy, the distribution is illustrated with a box-and-whiskers plot (the box defines the 25th, 50th, and 75th percentiles, while the whiskers define 1 ½ times the interquartile range; individual observations more extreme than this are indicated with dots). The vertical lines indicate the median value of the standard error of measurement for the population and twice the median value of the standard error of measurement for the population; the range of the standard error of measurement was 3.9 to 7.3 points. Differences when accounting for DIF greater than the median standard error of measurement are referred to as “salient scale-level differential functioning.”

Figure 5

Table 4. Variance of composite executive function scores explained by MRI variables and ethnicity/language group, education, and gender (but not age)

Figure 6

Fig. 3. Incremental variance explained by structural MRI variables in Executive Function composite scores not adjusting for age (gray bars) and adjusting for age (black bars). Values represent the R2 for a full model with both MRI variables and demographics minus the R2 for a model with only demographics [see the shaded column in Table 4 labeled “Both MRI variables (C-A)”]. Age was included as a demographic variable in the age adjusted model and was not included in the model without age adjustment. Adjusted T scores were adjusted for gender, ethnicity/language, and education, but not age.

Figure 7

Fig. A1. Schematic representation of the executive function bi-factor confirmatory factor analysis. Abbreviations: Exec Fxn = executive function; Anim 1 = animal fluency, 1st 30 seconds; Anim 2 = animal fluency, 2nd 30 seconds; Spmkt 1 = supermarket items, 1st 30 seconds; Spmkt 2 = supermarket items, 2nd 30 seconds; Spmkt cat = number of categories of supermarket items over 60 seconds; F1 = words beginning with f produced in the 1st 30 seconds; F2 = words beginning with f produced in the 2nd 30 seconds; L1 = words beginning with l produced in the 1st 30 seconds; L2 = words beginning with l produced in the 2nd 30 seconds; DSPB = digit span backwards; VSPB = visual span backwards; LSTSRT 1 = list sorting 1; LSTSRT 2 = list sorting 2.

Figure 8

Table A1. Table A1: Bi-factor model results of executive function items

Figure 9

Fig. A2. Handling of items by their differential item functioning (DIF) status. In this schematic there are a total of (n + m) items included in the test; n of these items are found with DIF, while m items do not have DIF.