Hostname: page-component-cd9895bd7-p9bg8 Total loading time: 0 Render date: 2024-12-23T04:20:51.845Z Has data issue: false hasContentIssue false

Use of MMPI-2 to predict cognitive effort: A hierarchically optimal classification tree analysis

Published online by Cambridge University Press:  03 September 2008

COLETTE M. SMART
Affiliation:
Department of Cognitive Rehabilitation, JFK-Johnson Rehabilitation Institute, Edison, New Jersey
NATHANIEL W. NELSON
Affiliation:
Psychology Service, Minneapolis VA Medical Center, Minneapolis, Minnesota Department of Psychiatry, University of Minnesota, Minneapolis, Minnesota
JERRY J. SWEET*
Affiliation:
Department of Psychiatry & Behavioral Sciences, Evanston Northwestern Healthcare, Evanston, Illinois Feinberg School of Medicine, Northwestern University, Evanston, Illinois
FRED B. BRYANT
Affiliation:
Department of Psychology, Loyola University Chicago, Chicago, Illinois
DAVID T.R. BERRY
Affiliation:
Department of Psychology, University of Kentucky, Lexington, Kentucky
ROBERT P. GRANACHER
Affiliation:
Lexington Forensic Institute, Lexington, Kentucky
ROBERT L. HEILBRONNER
Affiliation:
Feinberg School of Medicine, Northwestern University, Evanston, Illinois Chicago Neuropsychology Group, Chicago, Illinois
*
Correspondence and reprint requests to: Jerry J. Sweet, Neuropsychology Service, Department of Psychiatry and Behavioral Sciences, Evanston Northwestern Healthcare Medical Group, 909 Davis Street, Suite 160, Evanston, IL 60201. E-mail: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Neuropsychologists routinely rely on response validity measures to evaluate the authenticity of test performances. However, the relationship between cognitive and psychological response validity measures is not clearly understood. It remains to be seen whether psychological test results can predict the outcome of response validity testing in clinical and civil forensic samples. The present analysis applied a unique statistical approach, classification tree methodology (Optimal Data Analysis: ODA), in a sample of 307 individuals who had completed the MMPI-2 and a variety of cognitive effort measures. One hundred ninety-eight participants were evaluated in a secondary gain context, and 109 had no identifiable secondary gain. Through recurrent dichotomous discriminations, ODA provided optimized linear decision trees to classify either sufficient effort (SE) or insufficient effort (IE) according to various MMPI-2 scale cutoffs. After “pruning” of an initial, complex classification tree, the Response Bias Scale (RBS) took precedence in classifying cognitive effort. After removing RBS from the model, Hy took precedence in classifying IE. The present findings provide MMPI-2 scores that may be associated with SE and IE among civil litigants and claimants, in addition to illustrating the complexity with which MMPI-2 scores and effort test results are associated in the litigation context. (JINS, 2008, 14, 842–852.)

Type
Research Article
Copyright
Copyright © The International Neuropsychological Society 2008

INTRODUCTION

Psychological and cognitive response validity measures are often administered concurrently in secondary gain (SG) contexts to provide greater understanding with regard to the veracity of individual neuropsychological performances. Regarding psychological response validity measures, the Minnesota Multiphasic Personality Inventory (MMPI-2; Butcher et al., Reference Butcher, Dahlstrom, Graham, Tellegen and Laemmer1989) has been the most widely examined instrument in this area of research, and depending upon the SG setting, MMPI-2 profiles may represent “under-reporting” or “over-reporting” of symptoms. For example, clinicians that administer the MMPI-2 as part of a hiring process (Pope et al., Reference Pope, Butcher and Seelen2000) or in the context of custody litigation (Posthuma & Harper, Reference Posthuma and Harper1998) may reasonably expect respondents to have characteristic underreporting validity and clinical profiles. Conversely, other studies have examined whether select MMPI-2 validity scales (e.g., the F-family: F, Fb, Fp) and clinical scales (e.g., Hs, D, Hy, Pt, Sc) may be differentially sensitive to over-reporting of symptoms in secondary gain (SG) contexts, such as personal injury litigation. Whereas the F-scale and Fp (Arbisi & Ben-Porath, Reference Arbisi and Ben-Porath1995) have been found to be quite sensitive in identifying “rare-symptoms” endorsed by over-reporting and comparison groups (Rogers et al., Reference Rogers, Sewell, Martin and Vitacco2003), other researchers have found F and related scales to be less effective than postrelease scales, such as the Fake Bad Scale (FBS; Lees-Haley et al., Reference Lees-Haley, English and Glenn1991) in identifying response bias among neuropsychological civil litigants (e.g., Larrabee, Reference Larrabee2003). Moreover, examination of clinical scale profiles in addition to validity scale profiles is important in SG contexts considering that some SG groups, such as litigants, may demonstrate clinical scale elevations (e.g., Hs, Hy) in the absence of significantly elevated validity scale elevations (Lanyon & Almer, Reference Lanyon and Almer2002).

As regards cognitive response validity assessment, a substantial literature has documented the sensitivity of various effort measures in SG contexts (see Bianchini et al., Reference Bianchini, Mathias and Greve2001), and forced-choice effort measures are among the most widely administered measures in neuropsychological practice. Less-than-chance performance on forced-choice measures has been suggested as strongly increasing one's confidence in arriving at a diagnosis of malingering (Slick et al., Reference Slick, Sherman and Iverson1999), though cut-offs above the chance-level may also implicate insufficient effort (IE). For instance, the “90% rule” (i.e., raw score cutoffs that are less than 90% correct on forced-choice measures) is a commonly suggested “rule of thumb” and raises the possibility of IE (e.g., Grote et al., Reference Grote, Kooker, Nyenhuis, Smith and Mattingly2000). A previous meta-analysis (Vickery et al., Reference Vickery, Berry, Inman, Harris and Orey2001) found the Digit Memory Test (DMT; Hiscock & Hiscock, Reference Hiscock and Hiscock1989) to be most effective in identifying IE relative to other effort measures examined, including non–forced-choice measures. Similar forced-choice measures, such as the Victoria Symptom Validity Test (VSVT; Slick et al., Reference Slick, Hopp and Strauss1995), the Test of Memory Malingering (TOMM; Tombaugh, Reference Tombaugh1996), Multi-Digit Memory Test (MDMT; Niccolls & Bolter, Reference Niccolls and Bolter1991), Word Memory Test (WMT; Green, Reference Green2003), and the Letter Memory Test (LMT; Inman et al., Reference Inman, Vickery, Berry, Lamb, Edwards and Smith1998) have also demonstrated respective utility in civil and simulating samples.

While response validity research has demonstrated relative progress in evaluation of psychological and cognitive response validity measures in their own right, relatively few studies have examined whether MMPI-2 validity scales can be expected to improve clinical decision-making with regard to cognitive effort. The literature in this area has been somewhat equivocal to date, with some studies suggesting the potential that some psychological response validity scales may moderate cognitive effort (e.g., Gervais, Reference Gervais2005; Nelson et al., Reference Nelson, Sweet, Berry, Bryant and Granacher2007a), and others suggesting relative independence of psychological versus cognitive response validity (e.g., Greiffenstein et al., Reference Greiffenstein, Gola and Baker1995). In the latter exploratory factor analysis (EFA), the authors found that MMPI-2 and cognitive response validity measures loaded on discrete factors, suggesting the possibility of relatively minimal overlap among psychological and cognitive response validity constructs. A more recent EFA (Nelson et al., Reference Nelson, Sweet, Berry, Bryant and Granacher2007a) suggests that the relationship between psychological and cognitive response validity variables is complex: while cognitive effort loaded independently from factors associated with over-reporting of psychological symptoms in general, validity scales whose content reflected over-reporting of somatic/neurotic symptoms (e.g., FBS) had a greater relationship with cognitive effort than over-reporting of psychotic symptoms (e.g., F, Fp, F-K).

One recent postrelease scale, the Response Bias Scale (RBS; Gervais, Reference Gervais2005), was developed with the explicit intention of identifying MMPI-2 items that might be particularly relevant to cognitive effort in civil forensic groups. Specifically, non–head-injury claimant effort performances were obtained on the Word Memory Test (Green, Reference Green2003), and MMPI-2 test items showing particular discrimination of sufficient effort (SE) and IE groups contributed to RBS development. WMT effort performances showed a relative decrease in performance with increasing RBS magnitudes. In an independent study, RBS showed preliminary merit by demonstrating a moderate effect size (d = .65) between SG and non-SG clinical groups (Nelson et al., Reference Nelson, Sweet and Heilbronner2007b). Although cognitive effort was not examined in the latter study, RBS was among the MMPI-2 validity scales to load on the “over-reporting of neurotic symptoms” factor in the Nelson and others' (Reference Nelson, Sweet, Berry, Bryant and Granacher2007a) EFA. This factor demonstrated a greater correlation with cognitive effort than the “over-reporting of psychotic/rarely endorsed symptoms” factor, which provides preliminary support of the notion that RBS and other validity scales whose content reflects “somatic” symptoms (e.g., FBS) might have a unique relationship with cognitive effort.

However, response validity research is most beneficial when it impacts the clinician's everyday practice. EFA, while documenting a possible association among certain psychological and cognitive response validity constructs, is not necessarily the most clinically relevant approach to response validity research, and a variety of other methodological strategies in the context of response validity research are of potentially greater clinical relevance. Provision of base rate MMPI-2 data in sizeable SG groups (e.g., Lees-Haley, Reference Lees-Haley1997; Mittenberg et al., Reference Mittenberg, Patton, Canyock and Condit2002) allows for an understanding of general response validity trends in SG groups, even if it does not provide a thorough dissemination of how or why these trends may be present. Another strategy includes “simulation” research, whereby certain groups are given coached instructions to over-report symptoms on the MMPI-2 or effort measures and comparison groups are given standard instructions (e.g., Bagby et al., Reference Bagby, Nicholson, Buis and Bacchiochi2000; Dearth et al., Reference Dearth, Berry, Vickery, Vagnini, Baser, Orey and Cragar2005; Rogers et al., Reference Rogers, Sewell and Ustad1995). Results of the coached and uncoached groups are then contrasted according to clinically relevant cut-scores, and the clinician is provided with known classification accuracy rates (e.g., specificity, sensitivity, positive and negative predictive validity at varying base rates of malingering). A “known groups” methodology is thought to better account for the “real-world” nature of symptom exaggeration (Rogers, Reference Rogers1997, p. 416). This approach entails a priori identification of symptom exaggeration unrelated to the MMPI-2 (e.g., sufficient vs. insufficient cognitive effort performance), and MMPI-2 profiles or effort performances of over-reporting groups themselves or relative to groups shown to have not exaggerated symptoms are then observed (e.g., Boone & Lu, Reference Boone and Lu1999; Ross et al., Reference Ross, Millis, Krukowski, Putnam and Adams2004). Response validity meta-analyses have also been conducted (e.g., Nelson et al., Reference Nelson, Sweet and Demakis2006; Rogers et al., Reference Rogers, Sewell and Salekin1994, Reference Rogers, Sewell, Martin and Vitacco2003; Vickery et al., Reference Vickery, Berry, Inman, Harris and Orey2001), which may provide the clinician with a variety of potential moderators to consider, such as gender, criminal versus civil litigation context, and type of clinical population examined (e.g., traumatic brain injury, chronic pain, etc.).

Differently, classification tree analysis (CTA) with univariable optimal data analysis (ODA; Yarnold & Soltysik, Reference Yarnold and Soltysik2005) is another approach that may be particularly beneficial to the clinician's everyday practice in the examination of psychological versus cognitive response validity data. ODA generates decision-making “trees” based upon optimal cut-scores in the anticipation of a dichotomous dependent variable. Via inspection of these trees, the clinician is provided a template by which individual cases may be classified according to ODA cut-scores, and then conclude whether individual cases resemble one dichotomous outcome over another. Millis and others (Reference Millis, Ross and Ricker1998) used ODA in the confirmation of neuropsychological test performances in a SG group with histories of mild head injury and a comparison group with histories of moderate and severe TBI. However, we are not aware of any studies to date that have used ODA in the classification of cognitive effort on the basis of MMPI-2 profiles.

In the current study, ODA methodology was applied to better clarify whether MMPI-2 validity scales can improve clinical decision-making with regard to cognitive effort (i.e., IE vs. SE). IE and SE status was established as the class variable from which a decision-making “tree” would be grown based upon MMPI-2 scores in a large group of SG and NSG participants. This methodology seems particularly useful to clinicians because it: (1) closely mimics the diagnostic decision-making process and (2) yields optimal MMPI-2 cut scores in the discrimination of cognitive effort that can be applied in future cases. In the context of previous EFA findings (Nelson et al., Reference Nelson, Sweet, Berry, Bryant and Granacher2007a), it was anticipated that “somatic/neurotic” scales (e.g., FBS, RBS, Md) would take precedence in the discrimination of IE and SE in the current clinical and forensic sample.

METHOD

Participants

All data included in this manuscript were obtained in compliance with ethical regulations of the institutions at which the data were collected, in compliance with the Helsinki Declaration. Case files were obtained from the archival databases of the third, sixth, and seventh authors in compliance with institutional guidelines, resulting in 307 participants who had completed the MMPI-2 and one or more forced-choice effort measures. One hundred twenty-two of these participants were examined in a separate response validity study (Nelson et al., Reference Nelson, Sweet, Berry, Bryant and Granacher2007a). All individuals were referred for neuropsychological evaluation of cognitive complaints. Of these 307 participants, 198 (64.5%) were evaluated in a secondary gain (SG) context, such as personal injury litigation or in association with an independent medical examination or similar proceedings (e.g., disability, workers' compensation). None of the SG participants were involved in criminal litigation. The remaining 109 (35.5%) had no appreciable secondary gain (NSG). Mean age of the sample was 43.2 years (SD = 11.9), with mean education of 13.4 years (SD = 3.1). One hundred ninety-three (62.7%) participants were male, and 114 (37.3%) were female. The large majority of SG individuals were referred for evaluation of cognitive complaints associated with traumatic brain injury (111, 56%), compared with only 17% (19 cases) of the NSG group. The remainder of the latter group's referrals were associated with a variety of conditions (e.g., mild head injury, anoxia, pain, ADHD, epilepsy). For the subset of the sample on which data were available (n = 242), mean IQ was 100.5 (SD = 14.4). There was no significant difference in IQ between the SG and NSG groups (n = 237; t = .754; df = 235; p = .451). Application of the conventional 90% rule (e.g., Grote et al., Reference Grote, Kooker, Nyenhuis, Smith and Mattingly2000; Inman et al., Reference Inman, Vickery, Berry, Lamb, Edwards and Smith1998; Tombaugh, Reference Tombaugh1996) on one or more of the forced-choice effort measures resulted in 182 individuals being classified as having sufficient effort (SE) and 125 as demonstrating insufficient effort (IE).

Measures

Standard MMPI-2 validity scales were examined in the study, including L, F, K, Back Infrequency (Fb), Variable Response Inconsistency Scale (VRIN), and True Response Inconsistency Scale (TRIN). Additional MMPI-2 validity scales included the F-K index (Gough, Reference Gough1950), Infrequency Psychopathology Scale (Fp; Arbisi & Ben-Porath, Reference Arbisi and Ben-Porath1995), the Superlative Scale (S; Butcher & Han, Reference Butcher, Han, Butcher and Spielberger1995), Dissimulation Scale (Ds; Gough, Reference Gough1954), Fake Bad Scale (FBS; Lees-Haley et al., Reference Lees-Haley, English and Glenn1991), Response Bias Scale (RBS; Gervais, Reference Gervais2005), and the Malingered Depression Scale (Md; Steffan et al., Reference Steffan, Clopton and Morgan2003). In addition to MMPI-2 validity scales, data were available for all clinical scales: Hypochondriasis (Hs), Depression (Dep), Hysteria (Hy), Psychopathic Deviate (Pd), Masculinity–Femininity (Mf), Paranoia (Pa), Psychasthenia (Pt), Schizophrenia (Sc), Hypomania (Ma), and Social Introversion (Si). In addition to the MMPI-2, all respondents completed a variety of neuropsychological measures as part of their comprehensive evaluation, and forced-choice effort measures. Effort tests included the Victoria Symptom Validity Test (VSVT; Slick et al., Reference Slick, Hopp and Strauss1995), the Test of Memory Malingering (TOMM; Tombaugh, Reference Tombaugh1996), the Multi-Digit Memory Test (MDMT; Niccolls & Bolter, Reference Niccolls and Bolter1991), the Word Memory Test (WMT; Green, Reference Green2003), and the Letter Memory Test (LMT; Inman et al., Reference Inman, Vickery, Berry, Lamb, Edwards and Smith1998).

Analyses and Procedures

CTA using ODA was used to predict cognitive effort status (i.e., IE or SE) in the sample of 307 participants. Although the concept of ODA had been available previously, the Optimal Data Analysis (ODA) software and general approach is a somewhat new methodology (Bryant, Reference Bryant2005), particularly in the context of neuropsychological research (for a richer, more extensive discussion of this topic, the reader is referred to: Yarnold & Soltysik, Reference Yarnold and Soltysik2005). ODA methodology involves identification of a variable and finding the optimal cut point that will accurately classify the greatest number of individuals on a given class variable (for present purposes, use of an MMPI-2 validity scale to predict cognitive effort status). The null hypothesis for this procedure is that the class variable, in this instance IE, cannot be predicted as a linear cutpoint on the continuous (attribute) variable, and the alternate hypothesis is that the class variable can be predicted using this cutpoint (Yarnold, Reference Yarnold1996).

CTA via ODA consists of constructing a hierarchical decision tree through several different univariate steps. The first step in CTA involves separately conducting univariable ODA analyses for each of the potential predictors or attributes in the model (i.e., MMPI-2 validity and clinical scales), and evaluating their resultant effect strengths. The model yielding the greatest effect strength is then selected. Based on the determined cutpoint for that attribute, some individuals will be classified as SE and some as IE. However, it is expected that some people will be misclassified in both groups. Thus, in an iterative manner, the ODA procedure is repeated to continue to improve classification accuracy using as many of the potential attributes as is necessary. When an attribute no longer improves classification accuracy (as determined by p, effect strength, or number of correct classifications), that branch of the tree is terminated. This procedure is repeated until all branches of the tree have terminated, at which point, a conceptual diagram of the tree can be constructed (Yarnold, Reference Yarnold1996). It should be noted that ODA procedures can accommodate both continuous and categorical (i.e., nominal or binary) predictors, without dummy-coding of variables such as gender and race.

Decision-tree methodology involves “growing” a tree from an initial decision point, with branches that denote different courses of action that result from decisions made at lower points in the tree. The tree terminates in a set of outcomes, namely, the assignment of individuals into one of two dichotomous class variables. Most existing tree methodologies do not explicitly maximize classification accuracy as part of their computational algorithm. By contrast, CTA via ODA is the only methodology to maximize classification accuracy, by constructing a decision tree that explicitly yields the highest percentage of accurately classified individuals in the sample (Bryant, Reference Bryant2005; Yarnold, Reference Yarnold1996).

It is important to note that, although ODA identifies a dichotomous optimal cut score for each predictor in the CTA model, these predictors are not necessarily restricted to having only two levels. Each attribute is analyzed for its predictive power at each potential branch of the tree model, regardless of whether or not the particular attribute has entered the tree at an earlier branch. Thus, an attribute that is dichotomized optimally at one branch can immediately re-enter the tree model with additional cut scores for either side or both sides of the initial dichotomy, if these additional cut scores for the same attribute contribute to classification accuracy more than cut scores for other attributes (e.g., Donenberg et al., Reference Donenberg, Bryant, Emerson, Wilson and Pasch2003). In this way, nonlinear CTA overcomes the problems of unreliability, low statistical power, and underestimation of effect size that arise from treating continuous attributes solely as binary variables (see MacCallum et al., Reference MacCallum, Zhang, Preacher and Rucker2002).

The final CTA model contained predictive attributes that were selected based on the following established procedures. In growing the tree, two rules were used: first, we selected the attribute (and accompanying decision rule) with the strongest effect strength (ES) for sensitivity at each node in the classification tree model. ES is an absolute index of effect size for which 0 = performance expected by chance and 100 = perfect classification accuracy. According to Yarnold and Soltysik (Reference Yarnold and Soltysik2005, p. 61), effect strength values <25% are weak, 25–50% are moderate, 50–75% are relatively strong, 75–90% are strong, and >90% are very strong. Second, of those attributes, we selected those that provided the highest classification accuracy while remaining stable when submitted to a leave-one-out (LOO) jackknife validity analysis (Lachenbruch, Reference Lachenbruch1967; Yarnold & Soltysik, Reference Yarnold and Soltysik2005). More specifically, a jackknife validity analysis examines whether each participant is predicted to be in the IE or SE group using a UniODA model developed from the other N − 1 observations (Ostrander et al., Reference Ostrander, Weinfurt, Yarnold and August1998). This particular LOO analysis is a measure of expected cross-sample generalizability, and provides information on how likely it is that a model will cross-validate and accurately classify future individuals into those with SE and those without. While the “gold standard” on cross-validation is to re-test the model in a second, independent sample, LOO analysis provides a useful alternative for assessing expected cross-sample generalizability in situations where such data are not available.

After the initial tree was constructed, two rules were used to prune the tree. First, we determined the statistical significance of each attribute in the final model by performing a nondirectional Fisher's exact probability test, with alpha = .05. Second, we used a sequentially rejective Bonferroni procedure to further prune the tree, to ensure an experimentwise Type I error rate of p < .05. More specifically, we used a Sidak step-down adjustment procedure (Yarnold & Soltysik, Reference Yarnold and Soltysik2005) to prune nodes from the tree if their type I error exceeded 0.05, controlling for the number of nodes in the final tree model. This latter procedure was used to craft the most parsimonious model while not capitalizing on chance.

RESULTS

After pruning, the final tree (Figure 1) contained two attributes: MMPI-2 Response Bias Scale (RBS) and MMPI-2 Hysteria Scale (Hy). By definition, sensitivity refers to the number of true positives/(true positives + false negatives), while specificity refers to the number of true negatives/(true negatives + false positives) (Table 2). Thus, an IE participant predicted as such was a true positive, an IE participant predicted as SE was a false negative, an SE participant predicted as SE was a true negative, and an SE participant predicted as IE was a false positive. By these guidelines, RBS and Hy accurately classified 69.4% of the sample in terms of whether they gave insufficient effort (sensitivity = 60%) or not (specificity = 75.8%). The overall effect strengths for sensitivity and specificity were 20.0% and 51.6%, respectively, where zero is the performance level expected by chance and 100 is perfect classification accuracy. Thus, the current CTA model has a weak overall sensitivity but relatively strong specificity in predicting whether or not an individual has given insufficient effort on cognitive tests.

Fig. 1. Diagram of the hierarchically optimal classification tree model for predicting sufficient (0) versus insufficient (1) cognitive effort among adult outpatients presenting for neuropsychological evaluation using all 26 predictors and adopting a sequentially rejective Bonferroni adjustment (p < .05) to prune the tree model (n = 307). In this figure, circles represent nodes (or decision points) containing each predictive attribute and its effect strength (ES, in parentheses), arrows represent branches (or predictive pathways), and rectangles represent prediction endpoints (or final classifications). Numbers (probabilities) centered beneath nodes are the generalized p value for each node, based on nondirectional Fisher's exact test. Numbers (inequalities) beside arrows indicate the value of the cut-point for optimally classifying observations into categories for each node (decision rule). Fractions beneath each prediction endpoint represent the number of correct classifications at the endpoint (numerator) and total number of observations at the endpoint (denominator). Numbers in parentheses next to fractions are the predictive value for each endpoint (or percentage of predicted classifications into the given category that were correct).

While sensitivity and specificity are useful, of arguably greater utility to psychologists are the indices of positive and negative predictive validity, where positive predictive validity is the number of true positives/(true positives + false positives) and negative predictive validity is the number of true negatives/(true negatives + false negatives). In the current analyses, positive predictive validity was 63.0%, while negative predictive validity was 73.4%. Overall effect strength of the predictive value was 36.4% which, by Yarnold and Soltysik's (Reference Yarnold and Soltysik2005) standards, constitutes a moderate effect strength.

In examining the actual CTA more closely (Figure 1), at the top of the tree model is the novel MMPI-2 Response Bias Scale (RBS), forming the primary node in the hierarchically optimal tree model (i.e., it is the predictive attribute with the strongest effect size for the total sample). Thus, RBS is essential in determining whether or not someone is likely to have given IE on effort tests. If an individual provides an RBS score less than or equal to 16.5, then that individual is determined with 78.3% accuracy as having given good effort. These individuals comprise 31% of the sample. If, however, RBS is greater than 16.5, then the MMPI-2 Hysteria (Hy) scale enters the model. Those who score T > 79.5 on the Hy scale are classified with 75.0% accuracy as having given IE. Thus, someone who endorses many unusual cognitive complaints (such as those tapped by RBS) in addition to vague and nonspecific somatic concerns (i.e., items on Hy), is likely to have given insufficient effort on cognitive testing. These individuals represent 24% of the sample. By contrast, those who score T ≤ 79.5 on the Hy scale are classified with 64.7% accuracy as haven given SE on cognitive tests, representing 14% of the entire sample.

As RBS is a newer and lesser-known scale that may not be in common usage among neuropsychologists, we re-conducted ODA analyses with all MMPI-2 variables, except for RBS. The same procedures, including growing and pruning rules, were used as outlined in the prior set of analyses. When RBS was removed from the model and after pruning, Hy took precedence in classifying cognitive effort status (see Figure 2), with Pa, Fb, K, and Fp as subsequent predictive attributes. These five scales accurately classified 71.0% of the sample in terms of whether they gave IE (sensitivity = 58.5%) or not (specificity = 79.4%). The overall effect strengths for sensitivity and specificity were 17.0% (weak) and 58.8% (relatively strong), respectively. By contrast, positive predictive validity was 65.7%, while negative predictive validity was 73.9%. Overall effect strength of the predictive value was 39.6%, which constitutes a moderate effect strength.

Fig. 2. Diagram of the hierarchically optimal classification tree model for predicting sufficient (0) versus insufficient (1) cognitive effort among adult outpatients presenting for neuropsychological evaluation, using all predictors except RBS (n = 293). All attributes in this tree model were statistically significant at p < .05, regardless of whether or not the Bonferroni adjustment was imposed.

Of note is that, after eliminating RBS from the analysis, Hy now assumes the primary node in the hierarchically optimal tree model, crucial in determining whether or not someone is likely to have given IE on cognitive tests (Figure 2). Again, an optimal cutting score of T = 79.5 on Hy serves to define the classification tree. On the left branch (Hy: T ≤ 79.5), an individual's score on the Pa scale defines their effort status. That is, when T = 54.5–60 on the Pa scale, that person was classified with 57.1% accuracy as having given IE. When the elevation on Pa was T ≤ 54.5 or >60, that person was classified as having given SE.

By contrast, when the elevation on Hy is T > 79.5, two further decision-points presented themselves, based on the degree of Fb elevation. First a “defensiveness” branch of the tree emerged with T ≤ 68.5 on Fb. If T ≤ 55 on K, that individual was classified with 71.4% accuracy as having given SE, whereas if T > 55 on K, there was 56.1% classification accuracy of IE. This left a second, “eager-to-overreport” branch of the tree, with T > 68.5 on Fb. If T ≤ 48.5 on Fp, that individual was classified with 50.0% accuracy as having given SE, whereas if T > 48.5 on K, there was 83.3% classification accuracy of IE. Looking at relative classification accuracies for these two branches together, it appears that ODA had most utility in predicting effort status in those who scored either consistently low on the scales of interest (i.e., low Fb, low K, SE = 71.4% accuracy) or consistently high (i.e., high Fb, high Fp, IE = 83.3% accuracy). To illustrate the clinical accuracy and statistical results of the tree results in a manner more familiar to clinicians, Tables 1 and 2 provide detailed findings showing the effects of including and omitting RBS.

Table 1. Overall cross-classification tables for the two ODA tree models (i.e., 26 MMPI-2 indices with and without RBS), predicting whether individuals exerted sufficient (0) or insufficient (1) cognitive effort

Note

When omitting RBS, the same attributes in the tree model were statistically significant at nondirectional p < .05, regardless of whether or not a Bonferroni adjustment (i.e., sequentially rejective Sidak procedure, Bonferroni p < .05) was adopted. PAC = percentage of classification accuracy, or the proportion of observations in each level of the class variable that were correctly classified; PV = predictive value, or the proportion of predicted classifications that were actually correct; N = the total number of observations classified by the set of predictors in the particular tree model, excluding observations with missing values on the specific set of attributes used to classify them. p = nondirectional Fisher's exact probability.

Table 2. Classification performance statistics for the two ODA tree models (i.e., 26 MMPI-2 indices with and without RBS) predicting whether individuals exerted sufficient (0) or insufficient (1) cognitive effort

Note

The first CTA model included 23 MMPI subscales, sex, age, and years of education. The second CTA model excluded RBS from the analysis. Omitting RBS, the same attributes were retained in the tree model as being statistically significant at nondirectional p < .05, regardless of whether or not a Bonferroni adjustment (i.e., sequentially rejective Sidak procedure, Bonferroni p <. 05) was adopted. Overall classification accuracy = the total number of actual 1s and 0s that were correctly classified. Sensitivity (insufficient effort) = percentage of classification accuracy for observations with true values of 1 on the class variable. Specificity (sufficient effort) = percentage of classification accuracy for observations with true values of 0 on the class variable. N = the total number of observations classified by the set of predictors in the particular tree model, excluding observations with missing values on the specific set of attributes used to classify them.

In contrast to a model's sensitivity (i.e., the probability that a person who actually belongs in a particular category will be correctly classified as being in that category), a model's predictive value (i.e., the probability that a person classified as being in a particular category actually belongs in that category) varies as a function of the actual base rate in the population and the model's rate of incorrect classifications. For this reason, it is important to assess the impact of different population base-rates on the utility of a model with a given rate of incorrect classifications (Ostrander et al., Reference Ostrander, Weinfurt, Yarnold and August1998; Wainer, Reference Wainer1991). A classification model is efficient if it provides a predictive value greater than the population base-rate (Meehl & Rosen, Reference Meehl and Rosen1955). For example, a model that classifies observations with a predictive value equal to the population base-rate performs no better than chance, and clinicians would be better off not administering the set of measures included in the model and instead simply guessing that the chance of any given observation belonging in the category is equal to the base rate. In this case, the model would be said to lack efficiency.

We computed measures of efficiency (Meehl & Rosen, Reference Meehl and Rosen1955; Yarnold & Soltysik, Reference Yarnold and Soltysik2005, p. 60–61) for both positive predictive value (in classifying insufficient cognitive effort) and negative predictive value (in classifying sufficient cognitive effort) for the Bonferroni-adjusted CTA models with and without the RBS scale. Figure 3 displays these estimates of efficiency for both models. As seen in this figure, both CTA models perform best compared to chance in classifying observations in either category for population base-rates between 0.3 and 0.5. (Note that the base-rate of insufficient cognitive effort for the present sample was roughly 0.4.)

Fig. 3. Estimates of classification efficiency for both positive predictive value (in classifying insufficient cognitive effort) and negative predictive value (in classifying sufficient cognitive effort) as a function of different population base-rates, for the Bonferroni-adjusted CTA model including the RBS scale (top graph) and the Bonferroni-adjusted CTA model excluding the RBS scale (bottom graph).

DISCUSSION

The current study is unique in its use of classification tree methodology; no other studies to date have examined psychological and cognitive response validity measures with this approach. Derivation of an optimal CTA model allows for a greater degree of sophistication in classifying individuals from known groups, rather than applying a “one-size-fits-all” regression model to an entire sample of individuals. That is, optimal CTA methodology more closely mimics the differential diagnostic decision-making process more commonly used in clinical practice, enhancing the practical utility and ecological validity of the MMPI-2 in the forensic context. Thus, rather than examining the same scales for all individuals, different scales with different cut scores are examined in concert, leading to a more tailored approach to classification. All MMPI-2 validity and clinical scales were allowed to compete for inclusion in the model, which after “pruning” of the initial “tree,” resulted in only two variables, which provides the clinician with a parsimonious understanding of the findings. This is an advantage over traditional regression models, where using only the minimum number of variables to create a classification tree that is robust enough to be expected to replicate across samples circumvents capitalization on chance or idiosyncratic response patterns.

The purpose of this study was to investigate, through use of a unique statistical approach (ODA), the degree to which MMPI-2 validity and clinical scales predict the result of cognitive effort tests (IE/SE) in a large group of NSG and SG participants. ODA is a novel yet powerful methodology that mimics the diagnostic decision-making process in the clinical context. The resultant analyses identified optimal classification “branches” of MMPI-2 validity and clinical scales at different cut scores, providing MMPI-2 scores that may be expected to identify sufficient versus insufficient cognitive effort. Consistent with the expectation that over-reporting of somatic symptoms may be more pertinent to cognitive effort than over-reporting of psychotic/rarely endorsed symptoms (Nelson et al., Reference Nelson, Sweet, Berry, Bryant and Granacher2007a), RBS took precedence in classifying cognitive effort in the current sample. This may relate to the original rationale behind RBS development, whereby MMPI-2 test items were chosen on the basis of discrimination of forced-choice effort (WMT) performance. In clinically relevant terms, results of the initial ODA model (see Figure 1) suggest that: (1) low RBS scores (<16.5) tend toward SE, (2) high RBS scores (>16.5) and high Hy scores (>79.5) tend toward IE, and (3) high RBS (>16.5) and low Hy scores (<79.5) tend toward SE.

Additionally, as RBS is a little known and relatively new scale, we decided that a separate ODA with RBS excluded might be of additional benefit to the clinician. Somewhat surprisingly, a clinical scale (Hy), rather than a validity scale, took precedence when RBS was removed from the analysis. Based upon the item content of Hy, results further support the notion that “somatic” symptoms have a unique relationship with cognitive effort in the current clinical and civil forensic sample, and the magnitude of the optimal Hy cutoff (T > 79.5) seems very much relevant to clinical practice and the assessment of psychological response validity. Graham (Reference Graham2000, p. 69) suggests that an elevation of this magnitude is consistent with an individual who “reacts to stress and avoids responsibility by developing physical symptoms”. In this context, present findings suggest that demonstration of insufficient cognitive effort may represent an additional method of avoiding responsibility in litigants and claimants who over-report somatic symptoms. Likely, this is related to the fact that the SG individuals referred for neuropsychological evaluation most often present with a host of somatic complaints that may be expressed particularly on Hy and not necessarily validity scale elevations (Lanyon & Almer, Reference Lanyon and Almer2002; Lees-Haley, Reference Lees-Haley1997). The conceptual role of Hy as the preliminary point of decision-making (i.e., after excluding RBS) is therefore of clinical interest. Based upon the clinician's evaluation of Hy, determination of which pattern of potential symptom exaggeration (somatic or psychiatric) can more likely be made. With significantly elevated Hy, the clinician should be especially mindful of the possibility of somatic malingering, which would consist of concurrent elevations of Hs, Hy, and FBS (Larrabee, Reference Larrabee1998). Without significantly elevated Hy, psychiatric symptom exaggeration may be of greater likelihood. It is of note that, despite being entered as a predictor in both ODA models, the Fake Bad Scale (FBS) failed to enter the model as a significant predictor of effort status regardless of whether the RBS was included or not. This is of interest given the fact that the FBS, like the RBS, was designed for use in the civil litigation context.

Two findings from Figure 2 seem particularly relevant to clinical practice. First, high Hy scores, matched with elevations on two F-family scales (Fb, Fp) tend toward IE. In other words, individuals who demonstrate excessive somatic symptoms, and who simultaneously endorse some degree of psychotic/rarely-endorsed symptoms are also more likely to show IE. Second, individuals who endorse fewer somatic symptoms, and who also endorse minimal psychotic symptoms (Pa) are more likely two show SE. Taken together, IE is more likely associated with endorsement of both “somatic” and “psychotic” symptoms, while SE is more likely associated with lesser endorsement of these same symptoms.

Other findings in Figure 2 are more difficult to grasp in terms of clinical utility. One possible explanation behind the complexity of Figure 2 is the extent of effort variance that somatic symptoms account for in the initial stages of the model. That is, after accounting for the somatic symptoms endorsed on RBS and Hy, it is possible that psychological validity and clinical scales play little role in accurate detection of cognitive effort. Indeed, overall, ODA classification rates were at times satisfactory (as high as 83.3%), while other classification rates were unacceptably low (50.0%). Overall strengths in the ODA model ranged from low (i.e., <25%) to moderate in magnitude (i.e., 25–30%), suggesting that MMPI-2 validity and clinical scales cannot be consistently expected to predict IE versus SE in the current sample. In other words, variable classifications and moderate effect strengths suggest that there is not likely to be a consistent, one-to-one correspondence among MMPI-2 validity and clinical scales and measures of cognitive effort. Such a viewpoint seems consistent with the results of a recent EFA (Nelson et al., Reference Nelson, Sweet, Berry, Bryant and Granacher2007a), which suggested that while somatic over-reporting appears to have a greater relationship with cognitive effort relative to other scales (e.g., F-family), correlations were modest nonetheless. As such, we emphasize that clinicians should never abandon use of cognitive effort tests in favor of MMPI-2 findings. Even with use of a sophisticated and clinician-friendly statistical methodology such as ODA, one cannot assume that MMPI-2 validity and clinical scales will effectively predict IE versus SE in the forensic context.

Literature on the interaction of cognitive and psychological effort variables is sparse to the degree that a priori theorizing about the relationships between such variables would be quite difficult. As such, we view the current findings in the context of theory building and as such are illustrative rather than prescriptive regarding how ODA methodology can be used in the forensic context. We would certainly hope that our findings would provoke further research in this area, using the current results in a more theoretically driven, theory-testing manner. In replicating our findings, we make several recommendations to address limitations of the current research. First, having two large independent samples provides the best means to ascertain whether a model created for one sample will generalize to a second sample. Having two samples will also allow for mixed group validation (MGV; Dawes & Meehl, Reference Dawes and Meehl1966; Frederick, Reference Frederick2000), where it is not necessary to know beforehand the exact proportions of individuals who are in SG and NSG contexts. Third, where possible, having uniform neuropsychological data across participants would allow for quantification of the effect of effort status on test scores and how this differs depending on the SG/NSG context.

In summary, based upon variable classification accuracies generated, current findings provide further evidence that both types of response validity measures (i.e., psychological and cognitive) do not directly correspond with one another, and both are necessary to obtain an accurate understanding of response validity for an individual patient or litigant.

ACKNOWLEDGMENTS

The authors have no financial or other relationship that would constitute a conflict of interest related to the research represented in this study. There was no commercial or other financial support for this project.

References

REFERENCES

Arbisi, P.A. & Ben-Porath, Y.S. (1995). An MMPI-2 infrequent response scale for use with psychopathological populations: The infrequency psychopathology scale F(p). Psychological Assessment, 7, 424431.CrossRefGoogle Scholar
Bagby, R.M., Nicholson, R.A., Buis, T., & Bacchiochi, J.R. (2000). Can the MMPI-2 validity scales detect depression feigned by experts? Assessment, 7, 5562.Google Scholar
Bianchini, K.J., Mathias, C.W., & Greve, K.W. (2001). Symptome validity testing: A critical review. The Clinical Neuropsychologist, 15, 1945.Google Scholar
Boone, K.B. & Lu, P.H. (1999). Impact of somatoform symptomatology on credibility of cognitive performance. The Clinical Neuropsychologist, 13, 414419.CrossRefGoogle ScholarPubMed
Bryant, F.B. (2005). How to make the best of your data. PsycCRITIQUES, 50.Google Scholar
Butcher, J.N., Dahlstrom, W.G., Graham, J.R., Tellegen, A., & Laemmer, B. (1989). Manual for Administration and Scoring of the Minnesota Multiphasic Personality Inventory (2nded.). Minneapolis, MN: University of Minnesota Press.Google Scholar
Butcher, J.N. & Han, K. (1995). Development of an MMPI-2 scale to assess the presentation of self in a superlative manner: The S scale. In Butcher, J.N. & Spielberger, C.D. (Eds.), Advances in Personality Assessment, Vol. 10. (pp. 2550). Mahwah, NJ: Lawrence Erlbaum Associates.Google Scholar
Dawes, R.M. & Meehl, P.E. (1966). Mixed-group validation: A method for determining the validity of diagnostic signs without using criterion groups. Psychological Bulletin, 66, 6367.CrossRefGoogle ScholarPubMed
Dearth, C.S., Berry, T.R., Vickery, C.D., Vagnini, V.L., Baser, R.E., Orey, S.A., & Cragar, D.E. (2005). Detection of feigned head injury symptoms on the MMPI-2 in head injured patients and community controls. Archives of Clinical Neuropsychology, 20, 95110.Google Scholar
Donenberg, G.R., Bryant, F.B., Emerson, E., Wilson, H.W., & Pasch, K.E. (2003). Tracing the roots of early sexual debut among adolescents in psychiatric care. Journal of the American Academy of Child and Adolescent Psychiatry, 42, 594608.Google Scholar
Frederick, R.I. (2000). Mixed group validation: A method to address limitations of criterion group validation in research on malingering detection. Behavioral Sciences and the Law, 18, 693718.Google Scholar
Gervais, R. (2005, April). Development of an Empirically Derived Response Bias Scale for the MMPI-2. Paper presented at the Annual MMPI-2 Symposium and Workshops, Ft. Lauderdale, FL.Google Scholar
Gough, H.G. (1950). The F minus K dissimulation index for the MMPI. Journal of Consulting Psychology, 14, 408413.CrossRefGoogle Scholar
Gough, H.G. (1954). Some common misconceptions about neuroticism. Journal of Consulting Psychology, 18, 287292.CrossRefGoogle ScholarPubMed
Graham, J.R. (2000). MMPI-2: Assessing Personality and Psychopathology. Third Edition. New York: Oxford University Press.Google Scholar
Green, P. (2003). Word Memory Test for Windows: User's Manual and Program. Edmonton, Alberta, Canada: Author. (Revised 2005).Google Scholar
Greiffenstein, M.F., Gola, T., & Baker, J.W. (1995). MMPI-2 validity scales versus domain specific measures in detection of factitious traumatic brain injury. The Clinical Neuropsychologist, 9, 230240.Google Scholar
Grote, C.L., Kooker, E.K., Nyenhuis, D.L., Smith, C.A., & Mattingly, M.L. (2000). Performance of compensation seeking and non-compensation seeking samples on the Victoria Symptom Validity Test: Cross-validation and extension of a standardization study. Journal of Clinical and Experimental Neuropsychology, 22, 709719.Google Scholar
Hiscock, M. & Hiscock, C.K. (1989). Refining the forced-choice method for the detection of malingering. Journal of Clinical and Experimental Neuropsychology, 11, 967974.CrossRefGoogle ScholarPubMed
Inman, T.H., Vickery, C.D., Berry, D.T.R., Lamb, D.G., Edwards, C.L., & Smith, G.T. (1998). Development and initial validation of a new procedure for evaluating adequacy of effort given during neuropsychological testing: The Letter Memory Test. Psychological Assessment, 10, 128139.Google Scholar
Lachenbruch, P.A. (1967). An almost unbiased method of obtaining confidence intervals for the probability of misclassification in discriminant analysis. Biometrics, 23, 639645.CrossRefGoogle ScholarPubMed
Lanyon, R.I. & Almer, E.R. (2002). Characteristics of compensable disability patients who choose to litigate. Journal of the American Academy of Psychiatry and the Law, 30, 400404.Google ScholarPubMed
Larrabee, G.J. (1998). Somatic malingering on the MMMPI and MMPI-2 in personal injury litigants. The Clinical Neuropsychologist, 12, 179188.Google Scholar
Larrabee, G.J. (2003). Detection of symptom exaggeration with the MMPI-2 in litigants with malingered neurocognitive dysfunction. The Clinical Neuropsychologist, 17, 5468.Google Scholar
Lees-Haley, P.R. (1997). MMPI-2 base rates for 492 personal injury plaintiffs: Implications and challenges for forensic assessment. Journal of Clinical Psychology, 53, 745755.3.0.CO;2-L>CrossRefGoogle ScholarPubMed
Lees-Haley, P.R., English, L.T., & Glenn, W.J. (1991). A fake bad scale on the MMPI-2 for personal injury claimants. Psychological Reports, 68, 208210.Google Scholar
MacCallum, R.C., Zhang, S., Preacher, K.J., & Rucker, D.D. (2002). On the practice of dichotomization of quantitative variables. Psychological Methods, 7, 1940.CrossRefGoogle ScholarPubMed
Meehl, P.E. & Rosen, A. (1955). Antecedent probability and the efficiency of psychometric signs, patterns, or cutting scores. Psychological Bulletin, 52, 194216.CrossRefGoogle ScholarPubMed
Millis, S.R., Ross, S.R., & Ricker, J.H. (1998). Detection of incomplete effort on the Wechsler Adult Intelligence Scale-Revised: A cross-validation. Journal of Clinical and Experimental Neuropsychology, 20, 167173.Google Scholar
Mittenberg, W.M., Patton, C., Canyock, E.M., & Condit, D.C. (2002). Base rates of malingering and symptom exaggeration. Journal of Clinical and Experimental Neuropsychology, 24, 10941102.Google Scholar
Nelson, N.W., Sweet, J.J., Berry, D.T.R., Bryant, F.B., & Granacher, R.P. (2007a). Response validity in forensic neuropsychology: Exploratory factor analytic evidence of distinct cognitive and psychological constructs. Journal of the International Neuropsychological Society, 13, 440449.Google Scholar
Nelson, N.W., Sweet, J.J., & Demakis, G. (2006). Meta-analysis of the MMPI-2 Fake Bad Scale: Utility in forensic practice. The Clinical Neuropsychologist, 20, 3958.CrossRefGoogle ScholarPubMed
Nelson, N.W., Sweet, J.J., & Heilbronner, R. (2007b). Examination of the new MMPI-2 Response Bias Scale (Gervais): Relationship with MMPI-2 validity scales. Journal of Clinical and Experimental Neuropsychology, 29, 6772.Google Scholar
Niccolls, R. & Bolter, J. (1991). Multi-Digit Memory Test (Computer Version). Los Angeles, CA: Western Psychological Services.Google Scholar
Ostrander, R., Weinfurt, K.P., Yarnold, P.R., & August, G.J. (1998). Diagnosing attention deficit disorders using the BASC and the CBCL: Test and construct validity analyses using optimal discriminant classification trees. Journal of Consulting and Clinical Psychology, 66, 660672.Google Scholar
Pope, K., Butcher, J., & Seelen, J. (2000). The MMPI, MMPI-2, & MMPI-A in Court (2nded.). Washington, DC: American Psychological Association.Google Scholar
Posthuma, A.B. & Harper, J.F. (1998). Comparison of MMPI-2 responses of child custody and personal injury litigants. Professional Psychology: Research and Practice, 29, 437443.Google Scholar
Rogers, R. (Ed.) (1997). Clinical Assessment of Malingering and Deception (2ndEdition). New York: Guilford.Google Scholar
Rogers, R., Sewell, K.W., Martin, M.A., & Vitacco, M.J. (2003). Detection of feigned mental disorders: A meta-analysis of the MMPI-2 and malingering. Assessment, 10, 160177.Google Scholar
Rogers, R., Sewell, K.W., & Salekin, R.T. (1994). A meta-analysis of malingering on the MMPI-2. Assessment, 1, 227237.CrossRefGoogle Scholar
Rogers, R., Sewell, K.W., & Ustad, L.L. (1995). Feigning among chronic outpatients on the MMPI-2: A systematic examination of fake-bad indicators. Assessment, 2, 8189.Google Scholar
Ross, S.R., Millis, S.R., Krukowski, R.A., Putnam, S.H., & Adams, K.M. (2004). Detecting incomplete effort on the MMPI-2: An examination of the Fake Bad Scale in mild head injury. Journal of Clinical and Experimental Neuropsychology, 26, 115124.Google Scholar
Slick, D.J., Hopp, G.A., & Strauss, E.H. (1995). The Victoria Symptom Validity Test. Odessa, FL: PAR.Google Scholar
Slick, D.J., Sherman, E.M.S., & Iverson, G.L. (1999). Diagnostic criteria for malingered neurocognitive dysfunction: Proposed standards for clinical practice and research. The Clinical Neuropsychologist, 13, 545561.CrossRefGoogle ScholarPubMed
Steffan, J.S., Clopton, J.R., & Morgan, R.D. (2003). An MMPI-2 scale to detect malingered depression (Md Scale). Assessment, 10, 382392.CrossRefGoogle ScholarPubMed
Tombaugh, T.N. (1996). Test of Memory Malingering. Toronto, Ontario: MultiHealth Systems.Google Scholar
Vickery, C.D., Berry, D.T.R., Inman, T.H., Harris, M.J., & Orey, S.A. (2001). Detection of inadequate effort on neuropsychological testing: A meta-analytic review of selected procedures. Archives of Clinical Neuropsychology, 16, 4573.Google Scholar
Wainer, H. (1991). Adjusting for differential base rates: Lord's paradox again. Psychological Bulletin, 109, 147151.Google Scholar
Yarnold, P.R. (1996). Discriminating geriatric and non-geriatric patients using functional status information: An example of classification tree analysis via UniODA. Educational and Psychological Measurement, 66, 656667.Google Scholar
Yarnold, P.R. & Soltysik, R.C. (2005). Optimal Data Analysis: A Guidebook with Software for Windows. Washington, DC: American Psychological Association.Google Scholar
Figure 0

Fig. 1. Diagram of the hierarchically optimal classification tree model for predicting sufficient (0) versus insufficient (1) cognitive effort among adult outpatients presenting for neuropsychological evaluation using all 26 predictors and adopting a sequentially rejective Bonferroni adjustment (p < .05) to prune the tree model (n = 307). In this figure, circles represent nodes (or decision points) containing each predictive attribute and its effect strength (ES, in parentheses), arrows represent branches (or predictive pathways), and rectangles represent prediction endpoints (or final classifications). Numbers (probabilities) centered beneath nodes are the generalized p value for each node, based on nondirectional Fisher's exact test. Numbers (inequalities) beside arrows indicate the value of the cut-point for optimally classifying observations into categories for each node (decision rule). Fractions beneath each prediction endpoint represent the number of correct classifications at the endpoint (numerator) and total number of observations at the endpoint (denominator). Numbers in parentheses next to fractions are the predictive value for each endpoint (or percentage of predicted classifications into the given category that were correct).

Figure 1

Fig. 2. Diagram of the hierarchically optimal classification tree model for predicting sufficient (0) versus insufficient (1) cognitive effort among adult outpatients presenting for neuropsychological evaluation, using all predictors except RBS (n = 293). All attributes in this tree model were statistically significant at p < .05, regardless of whether or not the Bonferroni adjustment was imposed.

Figure 2

Table 1. Overall cross-classification tables for the two ODA tree models (i.e., 26 MMPI-2 indices with and without RBS), predicting whether individuals exerted sufficient (0) or insufficient (1) cognitive effort

Figure 3

Table 2. Classification performance statistics for the two ODA tree models (i.e., 26 MMPI-2 indices with and without RBS) predicting whether individuals exerted sufficient (0) or insufficient (1) cognitive effort

Figure 4

Fig. 3. Estimates of classification efficiency for both positive predictive value (in classifying insufficient cognitive effort) and negative predictive value (in classifying sufficient cognitive effort) as a function of different population base-rates, for the Bonferroni-adjusted CTA model including the RBS scale (top graph) and the Bonferroni-adjusted CTA model excluding the RBS scale (bottom graph).