Hostname: page-component-586b7cd67f-dlnhk Total loading time: 0 Render date: 2024-11-20T09:20:17.148Z Has data issue: false hasContentIssue false

Predicting neuropsychological late effects in pediatric brain tumor survivors using the Neurological Predictor Scale and the Pediatric Neuro-Oncology Rating of Treatment Intensity

Published online by Cambridge University Press:  25 September 2023

Alannah R. Srsich
Affiliation:
The Children’s Hospital of Philadelphia, Philadelphia, PA, USA
Mark D. McCurdy
Affiliation:
LifeStance Health, Northborough, MA, USA
Peter M. Fantozzi
Affiliation:
The Children’s Hospital of Philadelphia, Philadelphia, PA, USA
Matthew C. Hocking*
Affiliation:
The Children’s Hospital of Philadelphia, Philadelphia, PA, USA The University of Pennsylvania, Philadelphia, PA, USA
*
Corresponding author: Matthew C. Hocking; Email: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Objective:

The Neurological Predictor Scale (NPS) quantifies cumulative exposure to tumor- and treatment-related neurological risks. The Pediatric Neuro-Oncology Rating of Treatment Intensity (PNORTI) measures the intensity of different treatment modalities, but research is needed to establish whether it is associated with late effects. This study evaluated the predictive validity of the NPS and PNORTI for neuropsychological outcomes in pediatric brain tumor survivors.

Method:

A retrospective chart review was completed of pediatric brain tumor survivors (PBTS) (n = 161, Mage = 13.47, SD = 2.80) who were at least 2 years from the end of tumor-directed treatment. Attention, intellectual functioning, perceptual reasoning, processing speed, verbal reasoning, and working memory were analyzed in relation to the NPS and PNORTI.

Results:

NPS scores ranged from 1 to 11 (M = 5.57, SD = 2.27) and PNORTI scores ranged from 1 (n = 101; 62.7%) to 3 (n = 18; 11.2%). When controlling for age, sex, SES factors, and time since treatment, NPS scores significantly predicted intellectual functioning [F(7,149) = 12.86, p < .001, R2 = .38] and processing speed [F(7,84) = 5.28, p < .001, R2 = .31]. PNORTI scores did not significantly predict neuropsychological outcomes.

Conclusions:

The findings suggest that the NPS has value in predicting IF and processing speed above-and-beyond demographic variables. The PNORTI was not associated with neuropsychological outcomes. Future research should consider establishing clinical cutoff scores for the NPS to help determine which survivors are most at risk for neuropsychological late effects and warrant additional assessment.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © INS. Published by Cambridge University Press 2023

Childhood brain and central nervous system (CNS) tumors are the second most common childhood malignancy and account for substantial morbidity and mortality (Armstrong et al., Reference Armstrong, Liu, Yasui, Huang, Ness, Leisenring, Hudson, Donaldson, King, Stovall, Krull, Robison and Packer2009; Miller et al., Reference Miller, Ostrom, Kruchko, Patil, Tihan, Cioffi, Fuchs, Waite, Jemal, Siegel and Barnholtz‐Sloan2021). Advancements in therapies for pediatric CNS tumors have reduced mortality rates with approximately 80% surviving beyond 5 years (Miller et al., Reference Miller, Ostrom, Kruchko, Patil, Tihan, Cioffi, Fuchs, Waite, Jemal, Siegel and Barnholtz‐Sloan2021). However, survival is not without cost. The neurological and neurophysiological side effects associated with CNS tumors and their treatments place survivors at risk for adverse neuropsychological outcomes, referred to as neurocognitive “late effects” (Anderson et al., Reference Anderson, Rennie, Ziegler, Neglia, Robison and Gurney2001; Turner et al., Reference Turner, Rey-Casserly, Liptak and Chordas2009). These deleterious effects typically emerge within the first few years following treatment and affect over 40% of pediatric brain tumor survivors (PBTS) (Glauser & Packer, Reference Glauser and Packer1991). Pediatric brain tumor survivors (PBTS) experience late effects across a core set of cognitive domains, including executive function, processing speed, working memory, and attention (Kiehna et al., Reference Kiehna, Mulhern, Li, Xiong and Merchant2006; Palmer et al., Reference Palmer, Armstrong, Onar-Thomas, Wu, Wallace, Bonner, Schreiber, Swain, Chapieski, Mabbott, Knight, Boyle and Gajjar2013). Weaknesses in these domains can range from mild difficulties to disrupted functional outcomes that require ongoing need for support into adulthood (Maddrey et al., Reference Maddrey, Bergeron, Lombardo, McDonald, Mulne, Barenberg and Bowers2005; Robinson et al., Reference Robinson, Kuttesch, Champion, Andreotti, Hipp, Bettis, Barnwell and Compas2010). Moreover, neurocognitive late effects have a significant impact on PBTS’ quality of life by impairing academic, psychosocial, and vocational functioning (Ellenberg et al., Reference Ellenberg, Liu, Gioia, Yasui, Packer, Mertens, Donaldson, Stovall, Kadan-Lottick, Armstrong, Robison and Zeltzer2009; Netson et al., Reference Netson, Ashford, Skinner, Carty, Wu, Merchant and Conklin2016).

As survivorship rates increase, there is a growing need to identify risk factors for neurocognitive late effects. Efforts to identify these risk factors have consistently shown that, in addition to tumor location (Patel et al., Reference Patel, Mullins, O'Neil and Wilson2011), each of the three commonly used treatment modalities (e.g., surgical resection, chemotherapy, and cranial/cranio-spinal radiation) affect normal brain development and negatively impact neurocognitive outcomes. For example, surgical resection and its associated perioperative complications (e.g., hydrocephalus) are associated with impaired intellectual and neurocognitive functioning in PBTS (Hardy et al., Reference Hardy, Bonner, Willard, Watral and Gururangan2008; Ris & Noll, Reference Ris and Noll1994). Cranial radiation therapy (CRT) is associated with significant declines across multiple domains that persist for years posttreatment, with the incidence and severity of neurocognitive risk being dose- and volume-dependent (Lawrence et al., Reference Lawrence, Li, El Naqa, Hahn, Marks, Merchant and Dicker2010; Moxon-Emre et al., Reference Moxon-Emre, Bouffet, Taylor, Laperriere, Scantlebury, Law, Spiegler, Malkin, Janzen and Mabbott2014). Chemotherapy has specific agents that may carry direct risk for cognitive impairment (Verstappen et al., Reference Verstappen, Heimans, Hoekman and Postma2003). Moreover, concomitant chemotherapy and radiation results in greater neurocognitive deficits and academic difficulties than CRT alone (Bull et al., Reference Bull, Spoudeas, Yadegarfar and Kennedy2007; Butler et al., Reference Butler, Hill, Steinherz, Meyers and Finlay1994). Poorer neurocognitive outcomes are also associated with other neurological risk factors, such as endocrine disruption and seizures (Reimers et al., Reference Reimers, Ehrenfels, Mortensen, Schmiegelow, Sønderkaer, Carstensen, Schmiegelow and Müller2003; Vingerhoets, Reference Vingerhoets2006), and patient/demographic factors, such as age at the time of treatment, time since treatment, socioeconomic status (SES), and sex (Radcliffe et al., Reference Radcliffe, Bunin, Sutton, Goldwein and Phillips1994; Peterson & King, Reference Peterson and King2022; Sands et al., Reference Sands, Kellie, Davidow, Diez, Villablanca, Weiner, Pietanza, Balmaceda and Finlay2001; Torres et al., Reference Torres, Ashford, Wright, Xu, Zhang, Merchant and Conklin2021).

Given the complexity of brain tumor treatments, which often involve a multimodal approach combining resection, chemotherapy, and/or radiation therapy, it is challenging to establish a comprehensive endophenotype for classifying neurocognitive outcomes in survivors. Moreover, the appropriate method, timing, and intensity of treatments depend on various tumor-related factors, such as tumor location and histology, and patient demographic factors, including age. Thus, there is a need for refined measures that consider neurological risk and treatment intensity to predict the neurocognitive outcomes of survivors. Despite this, few objective measures quantify the intensity or extent of exposure to tumor-related therapies.

The Neurological Predictor Scale (NPS; Micklewright et al., Reference Micklewright, King, Morris and Krawiecki2008) is a clinician-generated checklist that quantifies both neurological- and treatment-related risk factors. The NPS measures the receipt of tumor-directed treatments (e.g., radiation, surgical resection, chemotherapy, or combination) and presence of neurological complications (e.g., presence of hydrocephalus, seizures, and hormone deficiencies) in one cumulative score. Prior research has demonstrated the predictive validity of the NPS for IQ and neurocognitive skills (King & Na, Reference King and Na2015; McCurdy et al., Reference McCurdy, Rane, Daly and Jacobson2016; Taiwo et al., Reference Taiwo, Na and King2017).

The Pediatric Neuro-Oncology Rating of Treatment Intensity (PNORTI; Hocking et al., Reference Hocking, Hobbie and Fisher2018) was developed by a team of neuro-oncology experts to evaluate the intensity of undergoing certain treatment modalities specific to pediatric brain tumors. The scale classifies treatment variables across varying degrees of radiation and chemotherapy exposures, ranging from low to high intensity. The PNORTI was modeled after the Intensity of Treatment Rating Scale (ITR; Werba et al., Reference Werba, Hobbie, Kazak, Ittenbach, Reilly and Meadows2007), a psychometrically valid measure of the intensity of treatments for childhood malignancies. The validity and utility of the PNORTI in predicting neurocognitive late effects have yet to be established.

The NPS and PNORTI assess treatment-related variables differently. For example, the NPS dichotomizes chemotherapy exposure (i.e., received chemotherapy vs. did not receive chemotherapy), whereas the PNORTI classifies chemotherapy exposure across varying levels of intensity (e.g., low, medium, and high) and incorporates stem cell rescue procedures. Unlike the PNORTI, the NPS measures neurological complications, such as hydrocephalus, seizure medication, and endocrine disruption. When used together, the NPS and the PNORTI may afford clinicians a simple and robust means of capturing both neurological risk factors and the intensity of tumor-directed treatments when evaluating predictors of neurocognitive outcomes in PBTS.

The primary objective of this study is to evaluate the predictive qualities of the NPS and PNORTI. Specifically, this study builds upon previous validation studies with the NPS, utilizing a substantial sample of PBTS, while also evaluating the predictive validity of the PNORTI on neurocognitive outcomes. In accordance with previous findings (Taiwo et al., Reference Taiwo, Na and King2017), we hypothesized that: (1) higher scores on the NPS would be significantly related to poorer posttreatment neuropsychological outcomes while accounting for relevant demographic variables; (2) higher treatment intensity scores on the PNORTI would be significantly related to poorer posttreatment neuropsychological outcomes; and (3) when used in conjunction, both the NPS and PNORTI would provide incremental validity for predicting posttreatment neuropsychological outcomes.

Methods

Participants and procedures

This study was a retrospective chart review, approved by the Institutional Review Board at the pediatric hospital where the research was conducted. All data was obtained in accordance with the ethical standards set forth in the Helsinki Declaration. Potentially eligible participants were identified either through the hospital’s tumor registry, through a clinical evaluation, or through participation in the principal investigator’s (PI) prior research studies. Participants included in the study from the PI’s previous research protocols, as well as those whose neuropsychological testing data were abstracted from clinical evaluation, did not receive any cognitive interventions at our institution as a part of their study enrollment or clinical care based on reviews of their medical records. Participants were included in the current study if they: (1) were between the ages of 5 and 17 years old at the time of neuropsychological evaluation to reflect the hospital’s primary patient population, (2) underwent tumor-directed treatments for a brain tumor (e.g., surgical resection, chemotherapy, or focal, cranial, or craniospinal radiation); and (3) had completed initial tumor-directed treatments at least 2 years prior to the time of data collection. Participants were excluded if they (1) had a multi-system genetic disorder that may affect neurocognitive functioning (e.g., Down syndrome, Beckwith-Weidemann syndrome, Wolf Hirschhorn syndrome), and/or neurofibromatosis; (2) had evidence of neurodevelopmental delays or diagnosed with autism spectrum disorder prior to diagnosis of their brain tumor; and (3) underwent tumor biopsy only (i.e., received no additional tumor-directed therapies). Tumor recurrence or progression after treatment was not an exclusion if survivors were at least 2 years removed from the end of therapy for their primary tumor.

Trained study personnel reviewed medical charts for treatment, neurological, sociodemographic, and neuropsychological variables. Study data were collected and managed using REDCap electronic data capture (Harris et al., Reference Harris, Taylor, Minor, Elliott, Fernandez, O'Neal, McLeod, Delacqua, Delacqua, Kirby and Duda2019; Harris et al., Reference Harris, Taylor, Thielke, Payne, Gonzalez and Conde2009). Tumor location (i.e., supratentorial or infratentorial) was based on clinical documentation and MRI reports. Dates extracted included those of diagnosis, completion of primary tumor-directed therapy, and if applicable, date of recurrence and date of completion for recurrent tumor-directed therapy. Neuropsychological and treatment data were extracted from medical records as well as databases from the PI’s previous research protocols.

Measures

Neurological Predictor Scale

The Neurological Predictor Scale (NPS; Micklewright et al., Reference Micklewright, King, Morris and Krawiecki2008) is a clinician-generated checklist that quantifies tumor-related treatments and neurological sequelae with one cumulative score. The NPS is based on treatment factors (i.e., radiation therapy, chemotherapy, and neurosurgery) and the presence or absence of neurological complications (i.e., hormone deficiency, hydrocephalus, and seizure medication). The NPS scale ranges from 0 to 11, with higher values reflecting increased neurological risk.

Pediatric Neuro-Oncology Rating of Treatment Intensity

The Pediatric Neuro-Oncology Rating of Treatment Intensity (PNORTI; Hocking et al., Reference Hocking, Hobbie and Fisher2018) quantifies the intensity of treatments for pediatric brain tumors. It was developed by neuro-oncology clinicians and consists of three levels that reflect the overall intensity of treatment as an individual goes through it, encompassing factors such as duration, side effects, and recovery time. Level 1 represents patients who received surgical resection, focal radiation, and/or low-intensity chemotherapy. Level 2 characterizes patients who received cranial or cranio-spinal radiation, with or without medium or less intense chemotherapy, or medium intensity chemotherapy alone. Level 3 reflects the most intensive treatment exposure, which includes high-intensity chemotherapy, with or without craniospinal radiation. The intensity of chemotherapy is classified into three levels: (1) low intensity, which includes any outpatient chemotherapy; (2) medium intensity, which comprises any inpatient chemotherapy regimen not included in the high-intensity chemotherapy category; and (3) high intensity, which involves high-dose chemotherapy with a stem cell rescue or cumulative doses of doxorubicin≥300mg/m2 or methotrexate doses (≥1 g/m2) requiring leucovorin rescue. Trained study staff generated PNORTI scores based on treatment data extracted as described above.

Sociodemographic variables

Information, such as race, ethnicity, sex, and insurance type (e.g., private or public), was gathered from the medical record. Childhood Opportunity Index (COI; Noelke et al., Reference Noelke, McArdle, Baek, Huntington, Huber, Hardy and Acevedo-Garcia2020) scores were calculated based on participant’s address at the time of neuropsychological testing. The COI is a validated, census tract-based multidimensional measure of US neighborhood resources and conditions comprised of 29 indicators of social determinants of health across three domains: education, health and environment, and socioeconomic (Acevedo-Garcia et al., Reference Acevedo-Garcia, McArdle, Hardy, Crisan, Romano, Norris, Baek and Reece2014). The overall Child Opportunity Score ranges from 0 to 100, with higher scores reflecting more favorable neighborhood opportunities relative to other neighborhoods across the US.

Neuropsychological data

Due to the retrospective nature of the study, a variety of neurocognitive measures were used as a part of routine clinical care. Efforts were made to combine similar measures based on construct area. Intellectual functioning (IF) was assessed with age-appropriate standardized measures, including the Weschler Intelligence Scale for Children-Fourth and Fifth Editions (WISC-IV, WISC-V, 6–16 years old), the Weschler Adult Intelligence Scale-Fourth Edition (WAIS-IV; 16–90 years old), the Weschler Abbreviated Scale of Intelligence-Second Edition (WASI-II; 6–89 years old), or the Differential Abilities Scales-Second Edition (DAS-II; 2–17 years old). Variability in which measure of IF patients were administered (i.e., Weschler vs. DAS-II scales) was due to neuropsychologist’s preference for battery construction and the child’s age at the time of evaluation. Both the Weschler and DAS scales are founded in the same theoretical model (Cattell-Horn-Carroll Theory of Intelligence) and the literature supports comparable underlying constructs (Alfonso et al., Reference Alfonso, Flanagan and Radwan2005). Further, there is significant evidence supporting strong correlations between the Weschler and DAS scales (Dumont et al., Reference Dumont, Cruse, Price and Whelley1996; Dumont et al., Reference Dumont, Willis and Elliott2009; Kuriakose, Reference Kuriakose2014). Particularly, the Weschler Full-Scale Intelligence Quotient and the DAS-II General Conceptual Ability score are highly correlated.

The Processing Speed Index (PSI) from the age-appropriate Weschler measure assessed Processing Speed (PS) using age-corrected standardized scores, with higher scores indicating greater processing efficiency. Attention was assessed using respective auditory attention subtests from the Wechsler (Digit Span Forward) or DAS-II (Recall of Digits Forward) instruments. Working memory (WM) was assessed using an auditory WM task. Children were administered either the Digit Span Backward subtest from a Weschler measure or Recall of Digits Backward from the DAS-II. Verbal reasoning (VR) and conceptualization abilities were measured using the respective verbal reasoning index and verbal abilities scores from the Weschler or DAS-II scales. Perceptual reasoning (PR) was measured using the respective perceptual reasoning index and nonverbal abilities scores from the Weschler or DAS-II scales.

Sample sizes varied by neuropsychological measures as not all participants completed the same testing battery.

Statistical analyses

Descriptive statistics were computed for relevant demographic, medical, and cognitive variables. Kruskal-Wallis nonparametric tests assessed group differences across PNORTI scores and neuropsychological outcomes. Pearson’s correlations assessed associations between neuropsychological outcomes and NPS and COI scores. Independent samples t-tests and ANOVAs assessed the associations among medical and treatment factors, such as tumor location, recurrence, tumor WHO grade, age at diagnosis, time posttreatment, and sex with neuropsychological outcomes. Chi-squared tests examined group statistics between PBTS who were evaluated using Weschler assessments and the DAS-II. Medical, treatment, and demographic factors that were significantly related to neuropsychological outcomes or were significantly related to group differences were controlled for in subsequent analyses. While controlling for covariates, hierarchical linear regressions assessed the predictive validity of the NPS (Hypothesis 1) and PNORTI (Hypothesis 2) for neuropsychological outcomes. To evaluate the predictive utility of the NPS and PNORTI for neuropsychological outcomes in comparison to individual risk factors (Hypothesis 3), hierarchical linear regressions were used. Two-sided p-values < 0.05 were considered significant. Participants were included in the analyses if they had data for at least one outcome variable. Statistical analyses were performed using IBM SPSS Statistics version 28.0.1.1.

Power analysis

A-priori power analyses indicated that samples sizes of 49–103 participants for multiple regression analyses with two predictors (NPS, PNORTI) and upwards of five covariates were needed to detect anticipated effect sizes ranging from .15 to .35, respectively. With a final sample size of 161, the current study is sufficiently powered to detect medium and large effect sizes.

Results

The medical records of 944 patients were initially reviewed. Out of those, 783 patients were excluded from the study for the following reasons: not having completed a neuropsychological assessment (n = 611), not being 2 years posttreatment (n = 115), or having a preexisting neurodevelopmental delay or an autism spectrum disorder diagnosis prior to brain tumor diagnosis (n = 12). In addition, there were 45 participants who did not undergo tumor-directed therapy, and this group was excluded from the final analyses because only 3 out of the 45 participants had documented neuropsychological testing data. Of those excluded, 56% of patients were male and patients were approximately 9 years old at the time of diagnosis (M = 9.50, SD = 4.23). A final sample of 161 PBTS (57.1% male) aged 6–17 years (M = 13.47, SD = 2.80) was included in the study. Survivors were approximately 7 years post-diagnosis (M = 6.7, SD = 3.68) and 6 years posttreatment (M = 6.13, SD = 3.39) at the time of neuropsychological evaluation. Sample demographic information is presented in Table 1. Over half of the sample had private insurance (n = 96, 59.6%), and COI levels ranged from very low (n = 17, 10.56%), low (n = 16, 9.94%), moderate (n = 22, 13.66%), high (n = 42, 26.09%), and very high (n = 64, 39.75%). The majority of participants were diagnosed with low-grade glioma (39.8%), medulloblastoma (19.3%), ependymoma (11.8%), or craniopharyngioma (10.6%). Less than a fourth of the sample (n = 37, 23%) had a tumor recurrence. NPS scores ranged from 1 to 11 (M = 5.57, SD = 2.27) and PNORTI scores ranged from “Level 1” (n = 101, 62.7%), “Level 2” (n = 42, 26.1%), and “Level 3” (n = 18, 11.2%). Inter-rater reliability was evaluated by randomly selecting 30% of the total sample, yielding a 90% agreement rate for the NPS and a 96% agreement rate for the PNORTI between raters. Table 2 displays means, ranges, and standard deviations of the neuropsychological outcome variables.

Table 1. Participant demographics, diagnoses, and treatment/neurological sequalae

Note. Age at diagnosis and time since treatment are reported in years; PNET = primitive neuro-ectodermal tumor; DNET = dysembryoplastic neuroepithelial tumor; ATRT = Atypical teratoid rhabdoid tumor; *p ≤ 0.05; **p ≤ 0.01.

a Low-grade gliomas included: pilocytic astrocytoma, fibrillary astrocytoma, optic pathway glioma, tectal glioma, oligodendroglioma, ganglioglioma, pleomorphic xanthoastrocytoma.

b High grade gliomas included: anaplstic astrocytyoma, glioblastoma multiforme, diffuse intrinsic pontine glioma.

c Other included: pineoblastoma (n = 1); ependymoblastoma (n = 1), malignant hemangiopericytoma (n = 1).

Table 2. Sample performance across neuropsychological domains

Note. IF = Intellectual Functioning, PSI = Processing Speed Index, DSF = Digit Span Forward, DSB = Digit Span Backward, VR = Verbal Reasoning; PR = Perceptual Reasoning; *p ≤ 0.05; **p ≤ 0.01.

a Standard Score mean = 100, standard deviation = 15.

b Scaled score mean = 10, standard deviation = 3.

Preliminary analyses

Among the 124 survivors without a recurrence of their brain tumor, nearly half (approximately 49%) scored below average (1 standard deviation below the mean) on the measure of PS. Moreover, 20–32% demonstrated below-average performance on measures of IF, VR, PR, and attention, exceeding what would be expected in a normal distribution. In the subset of 37 survivors who experienced a recurrence, approximately 42% had below-average scores on PS, with 25–28% with below-average performance on measures of IF, VR, PR, and attention. There were no significant differences in IF scores between survivors with or without a recurrence on a two-tailed Mann-Whitney U test, U = 2208, z = .13, p = .90. Independent-sample t-tests revealed no significant differences in PS, VC, PR, attention, and working memory scores based on recurrence (p’s > .05). Chi-square analyses and t-tests revealed no significant differences in sex, age at diagnosis, time since treatment, NPS scores, COI and insurance type based on recurrence (p’s > .05).

Tumor location and WHO grade were not related to any cognitive outcomes (ps > 0.05; see Supplemental Table 1) and therefore were not included as covariates in subsequent analyses. Age at diagnosis was significantly correlated with IF, (r = .296, p < .001), PSI (r = .318, p = .002), and auditory WM, (r = .419, p < .001). Time from primary treatment was significantly correlated with PS (r = −.334, p < .001), auditory WM, (r = −.295, p = .005), and attention (r = −.270, p = .011). COI scores were significantly correlated with IF (r = .454, p < .001, N = 157), VR (r = .427, p < .001, N = 92), PR (r = .329, p = .007, N = 67), and PSI (r = .243, p = .020, N = 92). Survivors with public insurance had significantly lower IF (M = 89.70, SD = 1.90, N = 64) scores, t (155) = 4.24, p < .001, d = .688, VR (M = 88.84, SD = 13.19, N = 38) and PSI scores (M = 82.22, SD = 14.63, N = 36) than those with private insurance, t (90) = 4.35, p < .001, d = .917, and t (90) = 2.28, p = .013, d = .487, respectively. Males (M = 100.06, SD = 13.58, N = 34) had significantly higher PR scores than females (M = 88.78, SD = 17.60, N = 33), t (65) = −2.95, p = .004, d = −.720.

Data were normally distributed for participants assessed using the DAS-II and Weschler tests. There were no significant differences in age at diagnosis, age at clinical neuropsychological evaluation, recurrence, tumor location, or sex between those assessed using Weschler instruments and the DAS-II. PBTS administered the DAS-II were a greater number of years posttreatment (M = 7.24, SD = 3.08) than those assessed using the Weschler tests (M = 5.76, SD = 3.37), t (148) = −2.36, p = .020, d = −.446. Therefore, time from primary treatment to neuropsychological evaluation was included as a covariate in subsequent analyses.

Univariate analyses

Pearson bivariate correlations revealed significant correlations between NPS scores and IF (r = −.181, p = .023) and PS (r = −.287, p = .005). NPS scores were not correlated with auditory WM (r = −.060, p = .578), attention (r = −.125, p = .256), verbal reasoning (r = −.114, p = .278), or perceptual reasoning (r = −.034, p = .784). Kruskal-Wallis tests showed no significant differences in any of the neuropsychological outcomes based on PNORTI levels (p’s > 0.05; see Supplemental Table 2).

Exploratory analyses

Given the uneven distribution of participants among PNORTI levels, an exploratory analysis evaluated the impact of different treatment modalities. Specifically, PNORTI Level 1 was divided into two groups: (a) patients who underwent surgery only (n = 54) and (b) patients who received focal RT/low-intensity chemotherapy (n = 47). Two-tailed Mann-Whitney U tests revealed no differences in IF, VR, PR, PS, attention, and auditory working memory scores between the PNORTI Level 1: Surgery Only and PNORTI Level 1: Focal RT/low-intensity chemotherapy groups (p’s > .05)

Kruskal-Wallis tests assessed differences across all PNORTI Levels: PNORTI Level 1a: Surgery only, PNORTI Level 1b: Focal RT/Low-intensity chemotherapy, PNORTI Level 2, and PNORTI Level 3. There were no differences in any of the measured neuropsychological outcomes among the groups (p’s > .05; see Supplemental Table 3).

Multivariate analyses

A hierarchical multiple linear regression (Table 3) tested the predictive strength of NPS scores on IF. Participant sex, age at diagnosis, time from primary treatment to neuropsychological assessment, insurance type, and COI were entered in the first step, followed by NPS scores in the second step. When sex, age at diagnosis, time from primary treatment, insurance type, and COI were included in the first step, the model explained 31% of the variance. Adding NPS scores significantly improved the model ΔR 2 = .04, p = .005, with higher NPS scores predicting lower IF scores, β = −.19, p = .007. The overall model, with NPS scores, included, explained 34% of the variance in IF, F(6,150) = 14.51, p < .001, and had a large effect (Cohen’s f 2 = .58).

Table 3. Hierarchical regression analysis predicting IF from tumor and demographic variables, and neurological risk scores

Note. Higher scores on the NPS indicate greater neurological risk; *p ≤ 0.05; **p ≤ 0.01.

a F(6,150) = 14.51, p < 0.01.

A second hierarchical multiple linear regression (Table 4) tested the predictive strength of the NPS on PS. Participant sex, age at diagnosis, time from primary treatment to neuropsychological assessment, insurance type, and COI were entered in the first step, followed by NPS scores in the second step. When sex, age at diagnosis, time since primary treatment, insurance type, and COI were included in the first step, the model explained 19.3% of the variance in PS. Adding NPS scores significantly improved the model ΔR 2 = .07, p = .005, with higher NPS scores predicting lower PS scores, β = −.26, p = .005. The overall model, with NPS scores, included, explained 25.6% of the variance in PS, F(6,85) = 6.23, p < .001, and had a large effect (Cohen’s f 2 = .44).

Table 4. Hierarchical regression analysis predicting PS from tumor and demographic variables, and neurological risk scores

Note. Higher scores on the NPS indicate greater neurological risk; *p ≤ 0.05; **p ≤ 0.01.

a F(6,85) = 6.23, p < .001.

Combined predictive validity of NPS and PNORTI

Two hierarchical multiple linear regressions evaluated the predictive strength of including both the NPS and PNORTI on IF and PS, respectively (Table 5). The overall models, which included both NPS and PNORTI scores as predictors, significantly predicted IF, F(7,149) = 12.86, p < .001, R 2 = .38, with a large effect (Cohen’s f 2 = .61), and PS, F(7,84) = 5.28, p < .001, R 2 = .31, with a large effect (Cohen’s f 2 = .44). Examination of the individual variables indicated that NPS scores significantly predicted IF [t(149) = −3.19, p = .002] and PS [t(84) = −2.12, p = .037]. PNORTI scores did not significantly predict IF or PS.

Table 5. Regression analysis for PNORTI and NPS predicting IF and processing speed

Note. Cohen’s f 2 of 0.02, 0.15, and 0.35 considered small, medium, and large, respectively.

*p ≤ 0.05; **p ≤ 0.01.

Discussion

Survivors experience a multitude of risk factors following diagnosis, making it important to evaluate and validate discrete tools that measure the influence of risk factors on neuropsychological outcomes. The present study is one of the first to examine the predictive validity of the NPS and PNORTI on neuropsychological late effects in a large sample of PBTS with differing diagnoses and treatment regimens. Overall, results indicate that NPS scores significantly predicted IF and PS years after treatment. Conversely, PNORTI scores did not significantly predict neuropsychological functioning. These findings provide further evidence of the NPS’ ability to measure the neurological factors that impact later neuropsychological outcomes.

NPS scores predicted IF and PS above-and-beyond time since treatment, demographic, and SES variables. These findings are in accordance with previous studies with PBTS showing NPS scores to predict neurocognitive outcomes (McCurdy et al., Reference McCurdy, Rane, Daly and Jacobson2016; Micklewright et al., Reference Micklewright, King, Morris and Krawiecki2008; Taiwo et al., Reference Taiwo, Na and King2017). Collectively, this suggests that the NPS is a valid tool that can quickly and efficiently calculate a child’s risk for deficits in specific neuropsychological domains. The NPS may also be a particularly useful tool in clinical research to avoid issues of low statistical power in studies with small sample sizes that assess interrelated and overlapping neurological risk factors. To further expand upon the scale’s utility, future work should consider establishing clinical cutoff scores for the NPS to help determine which PBTS are most at-risk for neuropsychological late effects and warrant additional assessments and/or intervention.

In the model evaluating the combined predictive validity of the NPS and PNORTI on IF, COI scores accounted for the most variance in the model (β = .386, p < .001). While research on the impact of neighborhood opportunity on cognitive outcomes in PBTS is currently limited, studies have demonstrated the influence of SES factors on cognitive development and academic performance in general (Bradley & Corwyn, Reference Bradley and Corwyn2002; Hackman & Farah, Reference Hackman and Farah2009). Furthermore, the impact of neighborhood opportunity on neurocognitive outcomes in PBTS may be influenced by unique factors related to their medical history and treatment. For example, neighborhoods with higher opportunity may offer greater access to quality schools, individualized education plans, and support systems for learning difficulties than neighborhoods with lower opportunity (Acevedo-Garcia et al., Reference Acevedo-Garcia, McArdle, Hardy, Crisan, Romano, Norris, Baek and Reece2014). This is particularly relevant for PBTS, who face challenges related to their cognitive function and academic performance in the years following treatment. A study by Torres et al. (Reference Torres, Ashford, Wright, Xu, Zhang, Merchant and Conklin2021) demonstrated that SES made a greater relative contribution to IF, academic achievement, and PS in a sample of children with brain tumors treated with photon radiation therapy, compared to other well-established risk factors, such as age at treatment and sex. SES may therefore be a novel predictor of cognitive performance in PBTS, underscoring the need for further research to investigate the impact of neighborhood opportunity, socioeconomic variables, and other social determinants of health on cognitive functioning in this population. Such research is crucial for better understanding potential associations and informing interventions and support strategies to enhance outcomes in PBTS.

Surprisingly, the NPS was not associated with performance on measures of working memory or attention. This contrasts with prior studies establishing the NPS as a predictor of cognitive efficiency and neurocognitive skills in PBTS (Taiwo et al., Reference Taiwo, Na and King2017), and with the well-documented vulnerability of these cognitive domains to tumor-directed treatments during childhood (Conklin et al., Reference Conklin, Ashford, Howarth, Merchant, Ogg, Santana, Reddick, Wu and Xiong2012; Palmer et al., Reference Palmer, Armstrong, Onar-Thomas, Wu, Wallace, Bonner, Schreiber, Swain, Chapieski, Mabbott, Knight, Boyle and Gajjar2013; Robinson et al., Reference Robinson, Kuttesch, Champion, Andreotti, Hipp, Bettis, Barnwell and Compas2010). It is important to note that a majority of the existing studies with the NPS consisted of adulthood survivors of childhood brain tumors who were on average 16 years post-diagnosis (Taiwo et al., Reference Taiwo, Na and King2017; King & Na, Reference King and Na2015). It is possible that contemporary treatments may pose different levels of neurological risks than treatments used over a decade ago, potentially altering the utility of the NPS. For example, in the last decade, proton radiation therapy (PRT) has replaced photon radiation therapy (XRT) as the most common form of radiotherapy for pediatric brain tumors, and research suggests PRT may yield better neurocognitive outcomes compared to XRT (Warren et al., Reference Warren, Raghubar, Cirino, Child, Lupo, Grosshans, Paulino, Okcu, Minard, Ris, Mahajan, Viana, Chintagumpala and Kahalley2022). Moreover, the present study’s sample exhibited relatively low rates of impairment in attention and working memory compared to previous literature. These lower impairment rates may have influenced the observed lack of association between the NPS and attention and working memory performance. Given that these domains are typically impaired in this population, future research should evaluate the associations between the NPS using more nuanced measures of attention and working memory, such as the Continuous Performance Task and N-back tasks.

Contrary to hypotheses, the PNORTI did not predict neuropsychological functioning. It is important to note that the PNORTI was designed to be a measure of the intensity of tumor-directed treatments, and not necessarily a rating system of the probability of developing late effects. While treatment intensity may be related to the risk level for late effects, they may not necessarily be directly related. For instance, although craniospinal radiation is a known risk factor for late effects, it was viewed as not having the same level of treatment intensity as high-dose chemotherapy plus stem cell rescue by neuro-oncology experts during the development of the PNORTI. As a result, craniospinal radiation alone would be classified as a PNORTI Level 2, while high-dose chemotherapy and stem cell rescue would be categorized as PNORTI Level 3. Thus, PNORTI ratings may not necessarily confer an individual’s risk for developing late effects. The relative distribution of PNORTI scores across the present study’s sample should also be considered. PNORTI scores were highly skewed towards Level 1 (n = 101) and Level 2 (n = 42) compared to Level 3 (n = 18). The uneven distribution in scores could have impacted the findings. Moreover, it is also possible that those with higher PNORTI scores might be at greater risk for relapse or death, potentially biasing the present sample towards those with lower risk for adverse outcomes. In fact, 89 patients were excluded from the analyses for not being at least 2 years out from the end of their primary tumor treatment due to recurrence or death.

This study is one of the first to examine the predictive ability of the NPS and PNORTI on neuropsychological late effects in a large sample of PBTS. Despite the strengths of this study, several limitations need to be acknowledged. Given the clinical nature of the sample, measures were selected for administration based on clinical utility, the age of the patient, and clinician preference. As such, not all participants were administered the same measures and the available data for analysis varied by domain. Further, given that most of the sample was referred for neuropsychological evaluation, they may be more likely to demonstrate neurocognitive difficulties, thereby compromising generalization to the broader PBTS population. It is worth noting that the NPS was not initially designed to assess individuals who have experienced recurrences. This study adopted an exploratory approach to include this subset of survivors, which is often overlooked in the existing literature. Lastly, it is important to acknowledge that the PSI has a motor component and use of this metric may underestimate processing speed given graphomotor deficits in this population (Duffner et al., Reference Duffner, Horowitz, Krischer, Friedman, Burger, Cohen, Sanford, Mulhern, James, Freeman, Seidel and Kun1993). Future studies should consider incorporating assessments of oral processing speed or utilizing the symbol search subtest, which entails fewer motor demands than coding.

The present study demonstrates associations between the NPS, broad global intellectual functioning, and processing speed in survivors of childhood brain tumors, supporting the NPS’ ability to predict how cumulative neurological factors impact cognitive outcomes following treatment. Further, the NPS has value in identifying PBTS most at risk for neuropsychological impacts of their tumor and treatments, which has important clinical and research implications. The ability to identify youth at greater risk for neuropsychological late effects can impact monitoring and inform the need for early intervention and long-term care.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S1355617723000589

Acknowledgments

Study data were collected and managed using REDCap electronic data capture tools hosted at CHOP. REDCap (Harris et al., Reference Harris, Taylor, Minor, Elliott, Fernandez, O'Neal, McLeod, Delacqua, Delacqua, Kirby and Duda2019; Harris et al., Reference Harris, Taylor, Thielke, Payne, Gonzalez and Conde2009) is a secure, web-based application designed to support data capture for research studies, providing (1) an intuitive interface for validated data capture; (2) audit trails for tracking data manipulation and export procedures; (3) automated export procedures for seamless data downloads to common statistical packages; and (4) procedures for data integration and interoperability with external sources. This research was supported by the Children’s Hospital of Philadelphia (Division of Developmental and Behavioral Pediatrics). The authors have no potential conflicts of interest to disclose.

References

Acevedo-Garcia, D., McArdle, N., Hardy, E. F., Crisan, U. I., Romano, B., Norris, D., Baek, M., & Reece, J. (2014). The child opportunity index: Improving collaboration between community development and public health. Health Affairs, 33(11), 19481957.CrossRefGoogle ScholarPubMed
Alfonso, V. C., Flanagan, D. P., & Radwan, S. (2005). The impact of the Cattell-Horn-Carroll Theory on test development and interpretation of cognitive and academic abilities. In Contemporary Intellectual Assessment: Theories, Tests, and Issues (pp. 185202). The Guilford Press.Google Scholar
Anderson, D. M., Rennie, K. M., Ziegler, R. S., Neglia, J. P., Robison, L. R., & Gurney, J. G. (2001). Medical and neurocognitive late effects among survivors of childhood central nervous system tumors. Cancer, 92(10), 27092719. https://doi.org/10.1002/1097-0142(20011115)92:10<2709::aid-cncr1625>3.0.co;2-d 3.0.CO;2-D>CrossRefGoogle ScholarPubMed
Armstrong, G. T., Liu, Q., Yasui, Y., Huang, S., Ness, K. K., Leisenring, W., Hudson, M. M., Donaldson, S. S., King, A. A., Stovall, M., Krull, K. R., Robison, L. L., & Packer, R. J. (2009). Long-term outcomes among adult survivors of childhood central nervous system malignancies in the Childhood Cancer Survivor Study. JNCI: Journal of the National Cancer Institute, 101(13), 946958. https://doi.org/10.1093/jnci/djp148 CrossRefGoogle ScholarPubMed
Bradley, R. H., & Corwyn, R. F. (2002). Socioeconomic status and child development. Annual Review of Psychology, 53(1), 371399.CrossRefGoogle ScholarPubMed
Bull, K. S., Spoudeas, H. A., Yadegarfar, G., & Kennedy, C. R. (2007). Reduction of health status 7 years after addition of chemotherapy to craniospinal irradiation for medulloblastoma: A follow-up study in PNET 3 trial survivors on behalf of the CCLG (formerly UKCCSG). Journal of Clinical Oncology, 25(27), 42394245.CrossRefGoogle Scholar
Butler, R. W., Hill, J. M., Steinherz, P. G., Meyers, P. A., & Finlay, J. L. (1994). Neuropsychologic effects of cranial irradiation, intrathecal methotrexate, and systemic methotrexate in childhood cancer. Journal of Clinical Oncology, 12(12), 26212629.CrossRefGoogle ScholarPubMed
Conklin, H. M., Ashford, J. M., Howarth, R. A., Merchant, T. E., Ogg, R. J., Santana, V. M., Reddick, W. E., Wu, S., & Xiong, X. (2012). Working memory performance among childhood brain tumor survivors. Journal of the International Neuropsychological Society, 18(6), 9961005.CrossRefGoogle ScholarPubMed
Duffner, P. K., Horowitz, M. E., Krischer, J. P., Friedman, H. S., Burger, P. C., Cohen, M. E., Sanford, R. A., Mulhern, R. K., James, H. E., Freeman, C. R., Seidel, F. G., & Kun, L. E. (1993). Postoperative chemotherapy and delayed radiation in children less than three years of age with malignant brain tumors. New England Journal of Medicine, 328(24), 17251731.CrossRefGoogle ScholarPubMed
Dumont, R., Cruse, C. L., Price, L., & Whelley, P. (1996). The relationship between the Differential Ability Scales (DAS) and the Wechsler intelligence Scale for Children—Third Edition (WISC-III) for students with learning disabilities. Psychology in the Schools, 33(3), 203209.3.0.CO;2-Q>CrossRefGoogle Scholar
Dumont, R., Willis, J. O., & Elliott, C. D. (2009). Essentials of DAS-II® assessment. John Wiley & Sons Inc.Google Scholar
Ellenberg, L., Liu, Q., Gioia, G., Yasui, Y., Packer, R. J., Mertens, A., Donaldson, S. S., Stovall, M., Kadan-Lottick, N., Armstrong, G., Robison, L. L., & Zeltzer, L. K. (2009). Neurocognitive status in long-term survivors of childhood CNS malignancies: A report from the Childhood Cancer Survivor Study. Neuropsychology, 23(6), 705717.CrossRefGoogle ScholarPubMed
Glauser, T. A., & Packer, R. J. (1991). Cognitive deficits in long-term survivors of childhood brain tumors. Child’s Nervous System, 7(1), 212. https://doi.org/10.1007/bf00263824 CrossRefGoogle ScholarPubMed
Hackman, D. A., & Farah, M. J. (2009). Socioeconomic status and the developing brain. Trends in Cognitive Sciences, 13(2), 6573. https://doi.org/10.1016/j.tics.2008.11.003 CrossRefGoogle ScholarPubMed
Hardy, K. K., Bonner, M. J., Willard, V. W., Watral, M. A., & Gururangan, S. (2008). Hydrocephalus as a possible additional contributor to cognitive outcome in survivors of pediatric medulloblastoma. Psycho-Oncology: Journal of the Psychological, Social and Behavioral Dimensions of Cancer, 17(11), 11571161.CrossRefGoogle ScholarPubMed
Harris, P. A., Taylor, R., Minor, B. L., Elliott, V., Fernandez, M., O'Neal, L., McLeod, L., Delacqua, G., Delacqua, F., Kirby, J., & Duda, S. N. (2019). The REDCap consortium: Building an international community of software platform partners. Journal of Biomedical Informatics, 95, 103208. https://doi.org/10.1016/j.jbi.2019.103208 CrossRefGoogle ScholarPubMed
Harris, P. A., Taylor, R., Thielke, R., Payne, J., Gonzalez, N., & Conde, J. G. (2009). Research electronic data capture (REDCap)--a metadata-driven methodology and workflow process for providing translational research informatics support. Journal of Biomedical Informatics, 42(2), 377381. https://doi.org/10.1016/j.jbi.2008.08.010 CrossRefGoogle ScholarPubMed
Hocking, M. C., Hobbie, W., & Fisher, M. J. (2018). Development of the Pediatric Neuro-Oncology Rating of Treatment Intensity (PNORTI). Journal of Neuro-Oncology, 136(1), 7378. https://doi.org/10.1007/s11060-017-2618-2 CrossRefGoogle ScholarPubMed
Kiehna, E. N., Mulhern, R. K., Li, C., Xiong, X., & Merchant, T. E. (2006). Changes in attentional performance of children and young adults with localized primary brain tumors after conformal radiation therapy. Journal of Clinical Oncology, 24(33), 52835290.CrossRefGoogle Scholar
King, T. Z., & Na, S. (2015). Cumulative neurological factors associated with long-term outcomes in adult survivors of childhood brain tumors. Child Neuropsychology, 22(6), 748760.CrossRefGoogle ScholarPubMed
Kuriakose, S. (2014). Concurrent validity of the WISC-IV and DAS-II in children with autism spectrum disorder. Journal of Psychoeducational Assessment, 32(4), 283294.CrossRefGoogle Scholar
Lawrence, Y. R., Li, X. A., El Naqa, I., Hahn, C. A., Marks, L. B., Merchant, T. E., & Dicker, A. P. (2010). Radiation dose-volume effects in the brain. International Journal of Radiation Oncology* Biology* Physics, 76(3), S20S27.CrossRefGoogle ScholarPubMed
Maddrey, A. M., Bergeron, J. A., Lombardo, E. R., McDonald, N. K., Mulne, A. F., Barenberg, P. D., & Bowers, D. C. (2005). Neuropsychological performance and quality of life of 10 year survivors of childhood medulloblastoma. Journal of Neuro-Oncology, 72(3), 245253. https://doi.org/10.1007/s11060-004-3009-z CrossRefGoogle ScholarPubMed
McCurdy, M. D., Rane, S., Daly, B. P., & Jacobson, L. A. (2016). Associations among treatment-related neurological risk factors and neuropsychological functioning in survivors of childhood brain tumor. Journal of Neuro-Oncology, 127(1), 137144.CrossRefGoogle ScholarPubMed
Micklewright, J. L., King, T. Z., Morris, R. D., & Krawiecki, N. (2008). Quantifying pediatric neuro-oncology risk factors: Development of the neurological predictor scale. Journal of Child Neurology, 23(4), 455458. https://doi.org/10.1177/0883073807309241 CrossRefGoogle ScholarPubMed
Miller, K. D., Ostrom, Q. T., Kruchko, C., Patil, N., Tihan, T., Cioffi, G., Fuchs, H. E., Waite, K. A., Jemal, A., Siegel, R. L., & Barnholtz‐Sloan, J. S. (2021). Brain and other central nervous system tumor statistics, 2021. CA: A Cancer Journal for Clinicians, 71(5), 381406. https://doi.org/10.3322/caac.21693 Google Scholar
Moxon-Emre, I., Bouffet, E., Taylor, M. D., Laperriere, N., Scantlebury, N., Law, N., Spiegler, B. J., Malkin, D., Janzen, L., & Mabbott, D. (2014). Impact of craniospinal dose, boost volume, and neurologic complications on intellectual outcome in patients with medulloblastoma. Journal of Clinical Oncology, 32(17), 17601768.CrossRefGoogle ScholarPubMed
Netson, K. L., Ashford, J. M., Skinner, T., Carty, L., Wu, S., Merchant, T. E., & Conklin, H. M. (2016). Executive dysfunction is associated with poorer health-related quality of life in pediatric brain tumor survivors. Journal of Neuro-Oncology, 128(2), 313321.CrossRefGoogle ScholarPubMed
Noelke, C., McArdle, N., Baek, M., Huntington, N., Huber, R., Hardy, E., & Acevedo-Garcia, D. (2020). Child opportunity index 2.0 technical documentation. https://www.diversitydatakids.org/researchlibrary/research-brief/how-we-built-it Google Scholar
Palmer, S. L., Armstrong, C., Onar-Thomas, A., Wu, S., Wallace, D., Bonner, M. J., Schreiber, J., Swain, M., Chapieski, L., Mabbott, D., Knight, S., Boyle, R., & Gajjar, A. (2013). Processing speed, attention, and working memory after treatment for medulloblastoma: An international, prospective, and longitudinal study. Journal of clinical oncology, 31(28), 34943500.CrossRefGoogle ScholarPubMed
Patel, S., Mullins, W., O'Neil, S., & Wilson, K. (2011). Neuropsychological differences between survivors of supratentorial and infratentorial brain tumours. Journal of Intellectual Disability Research, 55(1), 3040.CrossRefGoogle ScholarPubMed
Peterson, R. K., & King, T. Z. (2022). A systematic review of pediatric neuropscyhological outcomes with proton versus photon radiation therapy: A call for equity access to treatment. Journal of the International Neuropsychological Society, 114. https://doi.org/10.1017/S135561772200819 Google Scholar
Radcliffe, J., Bunin, G. R., Sutton, L. N., Goldwein, J. W., & Phillips, P. C. (1994). Cognitive deficits in long-term survivors of childhood medulloblastoma and other noncortical tumors: Age-dependent effects of whole brain radiation. International Journal of Developmental Neuroscience, 12(4), 327334.CrossRefGoogle ScholarPubMed
Reimers, T. S., Ehrenfels, S., Mortensen, E. L., Schmiegelow, M., Sønderkaer, S., Carstensen, H., Schmiegelow, K., & Müller, J. (2003). Cognitive deficits in long-term survivors of childhood brain tumors: Identification of predictive factors. Medical and Pediatric Oncology, 40(1), 2634.CrossRefGoogle ScholarPubMed
Ris, M. D., & Noll, R. B. (1994). Long-term neurobehavioral outcome in pediatric brain-tumor patients: Review and methodological critique. Journal of Clinical and Experimental Neuropsychology, 16(1), 2142.CrossRefGoogle ScholarPubMed
Robinson, K. E., Kuttesch, J. F., Champion, J. E., Andreotti, C. F., Hipp, D. W., Bettis, A., Barnwell, A., & Compas, B. E. (2010). A quantitative meta-analysis of neurocognitive sequelae in survivors of pediatric brain tumors. Pediatric Blood & Cancer, 55(3), 525531. https://doi.org/10.1002/pbc.22568 CrossRefGoogle ScholarPubMed
Sands, S. A., Kellie, S. J., Davidow, A. L., Diez, B., Villablanca, J., Weiner, H. L., Pietanza, M. C., Balmaceda, C., & Finlay, J. L. (2001). Long-term quality of life and neuropsychologic functioning for patients with CNS germ-cell tumors: From the First International CNS Germ-Cell Tumor Study. Neuro-Oncology, 3(3), 174183.CrossRefGoogle ScholarPubMed
Taiwo, Z., Na, S., & King, T. Z. (2017). The Neurological Predictor Scale: A predictive tool for long-term core cognitive outcomes in survivors of childhood brain tumors. Pediatric Blood & Cancer, 64(1), 172179. https://doi.org/10.1002/pbc.26203 CrossRefGoogle Scholar
Torres, V. A., Ashford, J. M., Wright, E., Xu, J., Zhang, H., Merchant, T. E., & Conklin, H. M. (2021). The impact of socioeconomic status (SES) on cognitive outcomes following radiotherapy for pediatric brain tumors: A prospective, longitudinal trial. Neuro-Oncology, 23(7), 11731182.CrossRefGoogle ScholarPubMed
Turner, C. D., Rey-Casserly, C., Liptak, C. C., & Chordas, C. (2009). Late effects of therapy for pediatric brain tumor survivors. Journal of Child Neurology, 24(11), 14551463. https://doi.org/10.1177/0883073809341709 CrossRefGoogle ScholarPubMed
Verstappen, C. C., Heimans, J. J., Hoekman, K., & Postma, T. J. (2003). Neurotoxic complications of chemotherapy in patients with cancer. Drugs, 63(15), 15491563.CrossRefGoogle ScholarPubMed
Vingerhoets, G. (2006). Cognitive effects of seizures. Seizure, 15(4), 221226. https://doi.org/10.1016/j.seizure.2006.02.012 CrossRefGoogle ScholarPubMed
Warren, E. A. H., Raghubar, K. P., Cirino, P. T., Child, A. E., Lupo, P. J., Grosshans, D. R., Paulino, A. C., Okcu, M. F., Minard, C. G., Ris, M. D., Mahajan, A., Viana, A., Chintagumpala, M., & Kahalley, L. S. (2022). Cognitive predictors of social adjustment in pediatric brain tumor survivors treated with photon versus proton radiation therapy. Pediatric Blood & Cancer, 69(6), e29645.CrossRefGoogle ScholarPubMed
Werba, B. E., Hobbie, W., Kazak, A. E., Ittenbach, R. F., Reilly, A. F., & Meadows, A. T. (2007). Classifying the intensity of pediatric cancer treatment protocols: The intensity of treatment rating scale 2.0 (ITR-2). Pediatric Blood & Cancer, 48(7), 673677. https://doi.org/10.1002/pbc.21184 CrossRefGoogle ScholarPubMed
Figure 0

Table 1. Participant demographics, diagnoses, and treatment/neurological sequalae

Figure 1

Table 2. Sample performance across neuropsychological domains

Figure 2

Table 3. Hierarchical regression analysis predicting IF from tumor and demographic variables, and neurological risk scores

Figure 3

Table 4. Hierarchical regression analysis predicting PS from tumor and demographic variables, and neurological risk scores

Figure 4

Table 5. Regression analysis for PNORTI and NPS predicting IF and processing speed

Supplementary material: File

Srsich et al. supplementary material

Table S1

Download Srsich et al. supplementary material(File)
File 16 KB
Supplementary material: File

Srsich et al. supplementary material

Table S2

Download Srsich et al. supplementary material(File)
File 16.8 KB
Supplementary material: File

Srsich et al. supplementary material

Table S3

Download Srsich et al. supplementary material(File)
File 17.2 KB