Major Changes in 2021 World Health Organization Classification of Central Nervous System Tumors.

The World Health Organization (WHO) published the fifth edition of the WHO Classification of Tumors of the Central Nervous System (WHO CNS5) in 2021, as an update of the WHO central nervous system (CNS) classification system published in 2016. WHO CNS5 was drafted on the basis of recommendations from the Consortium to Inform Molecular and Practical Approaches to CNS Tumor Taxonomy (cIMPACT-NOW) and expounds the classification scheme of the previous edition, which emphasized the importance of genetic and molecular changes in the characteristics of CNS tumors. Multiple newly recognized tumor types, including those for which there is limited knowledge regarding neuroimaging features, are detailed in WHO CNS5. The authors describe the major changes introduced in WHO CNS5, including revisions to tumor nomenclature. For example, WHO grade IV tumors in the fourth edition are equivalent to CNS WHO grade 4 tumors in the fifth edition, and diffuse midline glioma, H3 K27M-mutant, is equivalent to midline glioma, H3 K27-altered. With regard to tumor typing, isocitrate dehydrogenase (IDH)-mutant glioblastoma has been modified to IDH-mutant astrocytoma. In tumor grading, IDH-mutant astrocytomas are now graded according to the presence or absence of homozygous CDKN2A/B deletion. Moreover, the molecular mechanisms of tumorigenesis, as well as the clinical characteristics and imaging features of the tumor types newly recognized in WHO CNS5, are summarized. Given that WHO CNS5 has become the foundation for daily practice, radiologists need to be familiar with this new edition of the WHO CNS tumor classification system. Online supplemental material and the slide presentation from the RSNA Annual Meeting are available for this article. ©RSNA, 2022.

Local detection of microvessels in IDH-wildtype glioblastoma using relative cerebral blood volume: an imaging marker useful for astrocytoma grade 4 classification.

BACKGROUND: The microvessels area (MVA), derived from microvascular proliferation, is a biomarker useful for high-grade glioma classification. Nevertheless, its measurement is costly, labor-intense, and invasive. Finding radiologic correlations with MVA could provide a complementary non-invasive approach without an extra cost and labor intensity and from the first stage. This study aims to correlate imaging markers, such as relative cerebral blood volume (rCBV), and local MVA in IDH-wildtype glioblastoma, and to propose this imaging marker as useful for astrocytoma grade 4 classification. METHODS: Data from 73 tissue blocks belonging to 17 IDH-wildtype glioblastomas and 7 blocks from 2 IDH-mutant astrocytomas were compiled from the Ivy GAP database. MRI processing and rCBV quantification were carried out using ONCOhabitats methodology. Histologic and MRI co-registration was done manually with experts' supervision, achieving an accuracy of 88.8% of overlay. Spearman's correlation was used to analyze the association between rCBV and microvessel area. Mann-Whitney test was used to study differences of rCBV between blocks with presence or absence of microvessels in IDH-wildtype glioblastoma, as well as to find differences with IDH-mutant astrocytoma samples. RESULTS: Significant positive correlations were found between rCBV and microvessel area in the IDH-wildtype blocks (p < 0.001), as well as significant differences in rCBV were found between blocks with microvascular proliferation and blocks without it (p < 0.0001). In addition, significant differences in rCBV were found between IDH-wildtype glioblastoma and IDH-mutant astrocytoma samples, being 2-2.5 times higher rCBV values in IDH-wildtype glioblastoma samples. CONCLUSIONS: The proposed rCBV marker, calculated from diagnostic MRIs, can detect in IDH-wildtype glioblastoma those regions with microvessels from those without it, and it is significantly correlated with local microvessels area. In addition, the proposed rCBV marker can differentiate the IDH mutation status, providing a complementary non-invasive method for high-grade glioma classification.

Clinical implications of molecular analysis in diffuse glioma stratification.

The revised 4th edition of the 2016 World Health Organization Classification of Tumors of the Central Nervous System (2016 CNS WHO) has introduced the integrated diagnostic classification that combines molecular and histological diagnoses for diffuse gliomas. In this study, we evaluated the molecular alterations for consecutive 300 diffuse glioma cases (grade 2, 56; grade 3, 62; grade 4, 182) based on this classification. Mutations in the isocitrate dehydrogenase (IDH) genes were common in lower grade glioma (LGG: grade2-3), and when combined with 1p/19q status, LGGs could be stratified into three groups except for four cases (Astrocytoma, IDH-mutant: 44; Oligodendroglioma, IDH-mutant and 1p/19q codeleted: 37; Astrocytoma, IDH-wildtype: 33). 1p/19q-codeleted oligodendrogliomas were clinically the most favorable subgroup even with upfront chemotherapy. In contrast, IDH-wildtype astrocytomas had a relatively worse prognosis; however, this subgroup was more heterogeneous. Of this subgroup, 11 cases had TERT promoter (pTERT) mutation with shorter overall survival than 12 pTERT-wildtype cases. Additionally, a longitudinal analysis indicated pTERT mutation as early molecular event for gliomagenesis. Therefore, pTERT mutation is critical for the diagnosis of molecular glioblastoma (WHO grade 4), regardless of histological findings, and future treatment strategy should be considered based on the precise molecular analysis.

The presence of TIM-3 positive cells in WHO grade III and IV astrocytic gliomas correlates with isocitrate dehydrogenase mutation status.

Diffuse gliomas are aggressive brain tumors that respond poorly to immunotherapy including immune checkpoint inhibition. This resistance may arise from an immunocompromised microenvironment and deficient immune recognition of tumor cells because of low mutational burden. The most prominent genetic alterations in diffuse glioma are mutations in the isocitrate dehydrogenase (IDH) genes that generate the immunosuppressive oncometabolite d-2-hydroxyglutarate. Our objective was to explore the association between IDH mutation and presence of cells expressing the immune checkpoint proteins galectin-9 and/or T cell immunoglobulin and mucin-domain containing-3 (TIM-3). Astrocytic gliomas of World Health Organization (WHO) grades III or IV (36 IDH-mutant and 36 IDH-wild-type) from 72 patients were included in this study. A novel multiplex chromogenic immunohistochemistry panel was applied using antibodies against galectin-9, TIM-3, and the oligodendrocyte transcription factor 2 (OLIG2). Validation studies were performed using data from The Cancer Genome Atlas (TCGA) project. IDH mutation was associated with decreased levels of TIM-3+ cells (p < 0.05). No significant association was found between galectin-9 and IDH status (p = 0.10). Most TIM-3+ and galectin-9+ cells resembled microglia/macrophages, and very few TIM-3+ and/or galectin-9+ cells co-expressed OLIG2. The percentage of TIM-3+ T cells was generally low, however, IDH-mutant tumors contained significantly fewer TIM-3+ T cells (p < 0.01) and had a lower interaction rate between TIM-3+ T cells and galectin-9+ microglia/macrophages (p < 0.05). TCGA data confirmed lower TIM-3 mRNA expression in IDH-mutant compared to IDH-wild-type astrocytic gliomas (p = 0.013). Our results show that IDH mutation is associated with diminished levels of TIM-3+ cells and fewer interactions between TIM-3+ T cells and galectin-9+ microglia/macrophages, suggesting reduced activity of the galectin-9/TIM-3 immune checkpoint pathway in IDH-mutant astrocytic gliomas.

Differentiating Nonenhancing Grade II Gliomas from Grade III Gliomas Using Diffusion Tensor Imaging and Dynamic Susceptibility Contrast MRI.

BACKGROUND: Contrast enhancement in a brain tumor on magnetic resonance imaging is typically indicative of a high-grade glioma. However, a significant proportion of nonenhancing gliomas can be either grade II or III. While gross total resection remains the primary goal, imaging biomarkers may guide management when surgery is not possible, especially for nonenhancing gliomas. The utility of diffusion tensor imaging and dynamic susceptibility contrast magnetic resonance imaging was evaluated in differentiating nonenhancing gliomas. METHODS: Retrospective analysis was performed on imaging data from 72 nonenhancing gliomas, including grade II (n = 49) and III (n = 23) gliomas. Diffusion tensor imaging and dynamic susceptibility contrast data were used to generate fractional anisotropy, mean diffusivity, axial diffusivity, and radial diffusivity as well as cerebral blood volume, cerebral blood flow, and mean transit time maps. Univariate and multivariate logistic regression and area under the curve analyses were used to measure sensitivity and specificity of imaging parameters. A subanalysis was performed to evaluate the utility of imaging parameters in differentiating between different histologic groups. RESULTS: Logistic regression analysis indicated that tumor volume and relative mean transit time could differentiate between grade II and III nonenhancing gliomas. At a cutoff value of 0.33, this combination provided an area under the curve of 0.71, 70.6% sensitivity, and 64.3% specificity. Logistic regression analyses demonstrated much higher sensitivity and specificity in the differentiation of astrocytomas from oligodendrogliomas or identification of grades within these histologic subtypes. CONCLUSIONS: Diffusion tensor imaging and dynamic susceptibility contrast imaging can aid in differentiation of nonenhancing grade II and III gliomas and between histologic subtypes.

Astrocytoma: A Hormone-Sensitive Tumor?

Astrocytomas and, in particular, their most severe form, glioblastoma, are the most aggressive primary brain tumors and those with the poorest vital prognosis. Standard treatment only slightly improves patient survival. Therefore, new therapies are needed. Very few risk factors have been clearly identified but many epidemiological studies have reported a higher incidence in men than women with a sex ratio of 1:4. Based on these observations, it has been proposed that the neurosteroids and especially the estrogens found in higher concentrations in women's brains could, in part, explain this difference. Estrogens can bind to nuclear or membrane receptors and potentially stimulate many different interconnected signaling pathways. The study of these receptors is even more complex since many isoforms are produced from each estrogen receptor encoding gene through alternative promoter usage or splicing, with each of them potentially having a specific role in the cell. The purpose of this review is to discuss recent data supporting the involvement of steroids during gliomagenesis and to focus on the potential neuroprotective role as well as the mechanisms of action of estrogens in gliomas.

The expression level of cannabinoid receptors type 1 and 2 in the different types of astrocytomas.

Astrocytomas, the most prevalent primary brain tumors, can be divided by histology and malignancy levels into four following types: pilocytic astrocytoma (grade I), diffuse fibrillary astrocytoma (grade II), anaplastic astrocytoma (grade III), and glioblastoma multiforme (grade IV). For high grade astrocytomas (grade III and grade IV), blood vessels formation is considered as the most important property. The distribution of cannabinoid receptors type 1 (CB1) and cannabinoid receptor type 2 (CB2) in blood vessels and tumor tissue of astrocytoma is still controversial. Asrocytoma tissues were collected from 45 patients under the condition of tumor-related neurosurgical operation. The expression of CB1 and CB2 receptors was assessed using immunofluorescence, quantitative real-time RT-PCR and western blotting. The results indicated an increased expression of CB1 receptors in tumor tissue. There was a significant difference in the mount of CB2 receptors in blood vessels. More was observed in the grade III and glioblastoma (grade IV) than astrocytoma of grade II and control. This study suggested that, the expression increase of cannabinoid receptors is an index for astrocytoma malignancy and can be targeted as a therapeutic approach for the inhibition of astrocytoma growth among patients.

A novel DNA damage response signature of IDH-mutant grade II and grade III astrocytoma at transcriptional level.

PURPOSE: The WHO classification for IDH-mutant grade II and grade III astrocytoma may not be as prognostically meaningful as expected. We aimed to develop a novel classification system based on the DNA damage response signature. METHODS: We developed the gene signature of DNA damage response with 115 samples from The Cancer Genome Atlas (TCGA) database. The dataset from Chinese Glioma Genome Atlas (CGGA) database with 41 samples was used as the validation set. Lasso Cox regression model was applied for selection of the best signature. Gene set enrichment analysis (GSEA) and gene ontology (GO) analysis were implemented to reveal its biological phenotype. RESULTS: A two-gene DNA damage response signature (RAD18, MSH2) was developed using the lasso Cox regression model based on the TCGA dataset. Its prognostic efficiency was validated in the CGGA cohort. The result of Cox regression analysis showed that the signature has a better predictive accuracy than the WHO grade. The risk score was an independent prognostic factor for the overall survival of the IDH-mutant grade II and grade III astrocytoma. GSEA and GO analysis confirmed enhanced processes related to DNA damage response in high-risk group. CONCLUSION: We developed a two-gene signature which can effectively predict the prognosis of patients with IDH-mutant grade II and grade III astrocytoma. It suggests a novel classification of astrocytoma with better prognostic accuracy based on the expression of DNA damage response genes.

[Classification of the types of pediatric posterior fossa brain tumors based on routine MRI using wavelet transformation analysis of whole tumor].

Objective: To evaluate the classification of the types of pediatric posterior fossa brain tumors based on routine MRI (T(1)WI, T(2)WI and ADC) using wavelet transformation analysis of whole tumor. Methods: MRI images of medulloblastoma (n=59), ependymoma (n=13) and pilocytic astrocytoma (n=27) confirmed by pathology before treatments in Children's Hospital of Nanjing Medical University from January 2014 to February 2019 were enrolled in this retrospective study as well as the clinical data of age, gender and symptoms. Registration was performed among the three sequences and wavelet features of ROI were acquired. Afterwards, the top ten features were ranked and trained among groups by using random forest classifier. Finally, the results were compared and analyzed according to the classification. Results: The top ten contribution three sequences and wavelet features of ROI were acquired from the ADC sequence. The random forest classifier achieved 100% accuracy on training data and was validated best accuracy (86.8%) when combined of first and third wavelet features. The sensitivity was 100%, 94.8%, 76.9%, and the specificity was 97.6%, 88.0%, 98.8% respectively. Conclusions: Features based on wavelet transformation of ADC sequence of entire tumor can provide more quantitative information, which could provide help in the differential diagnosis of pediatric posterior fossa brain tumors. The optimum combination to distinguish three pediatric posterior fossa brain tumors is sixth and twelfth wavelet features of ADC sequence.

[Analysis of the clinical impact of the diagnostic reclassification of brain gliomas according to the World Health Organization classification (2016)]. / Análisis del impacto clínico de la reclasificación diagnóstica de gliomas cerebrales según la clasificación de la Organización Mundial de la Salud (2016).

INTRODUCTION: Since the introduction of genetic and molecular criteria in the 2016 World Health Organization (WHO) classification of brain tumours, there has been a diagnostic reclassification between certain astrocytomas and oligodendro-gliomas with histological and genetic discordances, the prognosis of which is unknown. AIM: To analyse the implications of the diagnostic reclassification of brain gliomas according to the 2016 WHO criteria, especially depending on isocitrate dehydrogenase (IDH) mutation and 1p19q codeletion. PATIENTS AND METHODS: We conducted a retrospective study of gliomas treated from 1 January 2012 to 31 December 2016, with analyses of clinicoradiological aspects and prognoses, and with available and complete follow-up until 31 March 2019. RESULTS: From a total of 147 brain gliomas, a molecular diagnosis and a diagnostic re-evaluation were carried out in 69 cases (grade II-IV astrocytomas or oligodendrogliomas). Twenty-four reclassified gliomas were detected, usually oligodendro-gliomas that became astrocytomas, and which showed greater survival, derived from their not being classified as grade IV. The reclassified gliomas, all grades II/III, mostly began with seizures, without focus, with single lesions, < 17 cm3 and with oedema, although with similar survival rates. The prognostic factors were: young age, focus, grade II and no contrast enhancement or necrosis, or multiplicity. No variations were detected according to the molecular pattern with IDH mutation or codeletion. CONCLUSION: The changes in diagnosis after the WHO classification of 2016 present specific clinical-radiological characteristics in this series, but no greater survival, although, due to the habitual survival in these cases, they would require a longer follow-up time.

TITLE: Análisis del impacto clínico de la reclasificación diagnóstica de gliomas cerebrales según la clasificación de la Organización Mundial de la Salud (2016).Introducción. Desde la introducción de los criterios genéticos y moleculares en la clasificación de la Organización Mundial de la Salud (OMS) de tumores cerebrales de 2016, se ha producido una reclasificación diagnóstica entre determinados astrocitomas y oligodendrogliomas con discordancias histológicas y genéticas, cuyo pronóstico se desconoce. Objetivo. Analizar las implicaciones de la reclasificación diagnóstica de los gliomas cerebrales según los criterios de la OMS de 2016, especialmente según la mutación de la isocitrato deshidrogenasa (IDH) y la codeleción 1p19q. Pacientes y métodos. Estudio retrospectivo de los gliomas tratados desde el 1 de enero de 2012 hasta el 31 de diciembre de 2016, con análisis de los aspectos clinicorradiológicos y pronósticos, y con seguimiento disponible y completo hasta el 31 de marzo de 2019. Resultados. De 147 gliomas cerebrales, en 69 (astrocitomas u oligodendrogliomas de grados II-IV) se realizaron un diagnóstico molecular y una reevaluación diagnóstica. Se detectaron 24 gliomas reclasificados, habitualmente oligodendrogliomas que pasaron a astrocitomas, y que mostraron mayores supervivencias, derivadas de la no reclasificación en grado IV. Los gliomas reclasificados, todos de grados II/III, comenzaron mayoritariamente con crisis, sin focalidad, con lesiones únicas, < 17 cm3 y con edema, aunque con similar supervivencia. Los factores pronósticos fueron: edad joven, focalidad, grado II y no captación de contraste o necrosis, o multiplicidad. No se detectaron variaciones según el patrón molecular con mutación en la IDH o codeleción. Conclusión. Los cambios diagnósticos tras la clasificación de la OMS de 2016 presentan características clinicorradiológicas específicas en esta serie, aunque no mayores supervivencias, si bien, por la supervivencia habitual en estos casos, precisarían un mayor tiempo de seguimiento.

Análisis del impacto clínico de la reclasificación diagnóstica de gliomas cerebrales según la clasificación de la Organización Mundial de la Salud (2016) / Analysis of the clinical impact of the diagnostic reclassification of brain gliomas according to the World Health Organization classification (2016)

Introducción: Desde la introducción de los criterios genéticos y moleculares en la clasificación de la Organización Mundial de la Salud (OMS) de tumores cerebrales de 2016, se ha producido una reclasificación diagnóstica entre determinados astrocitomas y oligodendrogliomas con discordancias histológicas y genéticas, cuyo pronóstico se desconoce. Objetivo: Analizar las implicaciones de la reclasificación diagnóstica de los gliomas cerebrales según los criterios de la OMS de 2016, especialmente según la mutación de la isocitrato deshidrogenasa (IDH) y la codeleción 1p19q. Pacientes y métodos. Estudio retrospectivo de los gliomas tratados desde el 1 de enero de 2012 hasta el 31 de diciembre de 2016, con análisis de los aspectos clinicorradiológicos y pronósticos, y con seguimiento disponible y completo hasta el 31 de marzo de 2019. Resultados: De 147 gliomas cerebrales, en 69 (astrocitomas u oligodendrogliomas de grados II-IV) se realizaron un diagnóstico molecular y una reevaluación diagnóstica. Se detectaron 24 gliomas reclasificados, habitualmente oligodendrogliomas que pasaron a astrocitomas, y que mostraron mayores supervivencias, derivadas de la no reclasificación en grado IV. Los gliomas reclasificados, todos de grados II/III, comenzaron mayoritariamente con crisis, sin focalidad, con lesiones únicas, <17 cm3 y con edema, aunque con similar supervivencia. Los factores pronósticos fueron: edad joven, focalidad, grado II y no captación de contraste o necrosis, o multiplicidad. No se detectaron variaciones según el patrón molecular con mutación en la IDH o codeleción. Conclusión: Los cambios diagnósticos tras la clasificación de la OMS de 2016 presentan características clinicorradiológicas específicas en esta serie, aunque no mayores supervivencias, si bien, por la supervivencia habitual en estos casos, precisarían un mayor tiempo de seguimiento

Introduction: Since the introduction of genetic and molecular criteria in the 2016 World Health Organization (WHO) classification of brain tumours, there has been a diagnostic reclassification between certain astrocytomas and oligodendrogliomas with histological and genetic discordances, the prognosis of which is unknown. Aim: To analyse the implications of the diagnostic reclassification of brain gliomas according to the 2016 WHO criteria, especially depending on isocitrate dehydrogenase (IDH) mutation and 1p19q codeletion. Patients and methods: We conducted a retrospective study of gliomas treated from 1 January 2012 to 31 December 2016, with analyses of clinicoradiological aspects and prognoses, and with available and complete follow-up until 31 March 2019. Results: From a total of 147 brain gliomas, a molecular diagnosis and a diagnostic re-evaluation were carried out in 69 cases (grade II-IV astrocytomas or oligodendrogliomas). Twenty-four reclassified gliomas were detected, usually oligodendrogliomas that became astrocytomas, and which showed greater survival, derived from their not being classified as grade IV. The reclassified gliomas, all grades II/III, mostly began with seizures, without focus, with single lesions, <17 cm3 and with oedema, although with similar survival rates. The prognostic factors were: young age, focus, grade II and no contrast enhancement or necrosis, or multiplicity. No variations were detected according to the molecular pattern with IDH mutation or codeletion. Conclusion: The changes in diagnosis after the WHO classification of 2016 present specific clinical-radiological characteristics in this series, but no greater survival, although, due to the habitual survival in these cases, they would require a longer follow-up time

WT1 in astrocytomas: Comprehensive evaluation of immunohistochemical expression and its potential utility in different histological grades.

BACKGROUND: Wilms' tumor 1 (WT1) mutation has recently been detected in gliomas. Growing data indicate that WT1 mutation plays a causal role in gliomagenesis and is overexpressed in most glioblastomas. An emerging immunotherapy targeting WT1 has shown to be effective in resistant glioblastomas in clinical trials. WT1 expression and its potential utility in various grades of astrocytomas is still unclear and needs further elucidation. The evaluation of WT1 can be done by molecular or immunohistochemical methods. As immunohistochemistry is easier with wider routine use, immunoexpression of this biomarker was studied. AIM: The aim of this study was to characterize WT1 immunoexpression across different histological grades of astrocytomas to routinely aid in diagnosis and reproducibility and to assess the association between WT1 and immunomarker isocitrate dehydrogenase (IDH1). MATERIAL AND METHODS: This was an observational prospective study on 79 cases of astrocytomas. RESULTS: Seventy-nine astrocytomas including 11 recurrent tumors were assessed for WT1 by immunohistochemistry. WT1 expression was detected in all astrocytomas (100%). The control group of reactive gliosis was negative. WT1 score correlated with histological tumor grades (P < 0.001) with higher score in higher grade. It was also observed that different tumor grades depicted two distinct expression patterns. WT1 score and pattern were valuable in differentiating high- and low-grade astrocytomas. CONCLUSION: This study supports the oncogenic role of WT1 in astrocytomas. WT1 was found to be valuable in distinguishing different grades of astrocytomas. WT1 can aid in differentiating neoplastic process from reactive gliosis, particularly in recurrent tumors. Higher expression in glioblastomas supports its immunotherapy potential.

Evaluation of EZH2 expression, BRAF V600E mutation, and CDKN2A/B deletions in epithelioid glioblastoma and anaplastic pleomorphic xanthoastrocytoma.

INTRODUCTION: Epithelioid glioblastoma (EGBM) and anaplastic pleomorphic xanthoastrocytoma (APXA) are two rare entities with different prognoses. However, they share certain morphological and molecular features. MATERIALS AND METHODS: To better recognize EGBM and APXA and identify the prognostic factors associated with these tumors, EZH2 status, BRAF V600E mutations, and CDKN2A/B deletions were assessed in 15 APXA and 13 EGBM cases. RESULTS: The expression level of EZH2 was found to increase with tumor grade. Overexpression of EZH2 occurred in 69.2% (9/13) of EGBM cases and 20% (3/15) of APXA cases. In addition, 72.7% (8/11) of EGBM and 12.5% (1/8) of APXA cases harbored a CDKN2A homozygous deletion based on fluorescence in situ hybridization. BRAF V600E mutations were detected in 80% (8/10) of EGBM cases and 42.9% (3/7) of APXA cases. Furthermore, EGBM, which exhibited co-existing low-grade glioma-like lesions, was found to have strong EZH2 expression and high Ki-67 indexes only in epithelioid cells and not in low grade lesions. Univariate analysis demonstrated that abundant epithelioid cells, extensive necrosis, EZH2 overexpression and BRAF V600E mutations were significantly associated with decreased overall survival in EGBM and APXA patients (P < 0.05). CONCLUSIONS: The results suggested that testing for EZH2 expression and BRAF V600E mutations might be helpful to evaluate the prognoses of EGBM and APXA patients. The presence of heterogeneous EZH2 expression in biphasic EGBMs could also contribute to malignant progression.

Practical procedures for the integrated diagnosis of astrocytic and oligodendroglial tumors.

The publication of the 2016 World Health Organization Classification of Tumors of the Central Nervous System (2016 WHO CNS) represented a major change in the classification of brain tumors. However, many pathologists in Japan cannot diagnose astrocytic or oligodendroglial tumors according to the 2016 WHO CNS due to financial or technical problems. Therefore, the Japan Society of Brain Tumor Pathology established a committee for molecular diagnosis to facilitate the integrated diagnosis of astrocytic and oligodendroglial tumors in Japan. We created three levels of diagnoses: Level 1 was defined as simple histopathological diagnosis using hematoxylin and eosin staining and routine cell lineage-based immunostaining. Level 2 was defined as immunohistochemical diagnosis using immunohistochemical examinations using R132H mutation-specific IDH1, ATRX, and/or p53 antibodies. Level 3 was defined as molecular diagnosis, such as diagnosis based on 1p/19q status or the mutation status of the IDH1 and IDH2 genes. In principle, astrocytic and oligodendroglial tumors should be diagnosed based on the 2016 WHO CNS and/or cIMPACT-NOW criteria; however, the findings obtained through our diagnostic flowchart can be added to the histological diagnosis in parentheses. This classification system would be helpful for pathologists with limited resources.

Neuroimaging-Based Classification Algorithm for Predicting 1p/19q-Codeletion Status in IDH-Mutant Lower Grade Gliomas.

BACKGROUND AND PURPOSE: Isocitrate dehydrogenase (IDH)-mutant lower grade gliomas are classified as oligodendrogliomas or diffuse astrocytomas based on 1p/19q-codeletion status. We aimed to test and validate neuroradiologists' performances in predicting the codeletion status of IDH-mutant lower grade gliomas based on simple neuroimaging metrics. MATERIALS AND METHODS: One hundred two IDH-mutant lower grade gliomas with preoperative MR imaging and known 1p/19q status from The Cancer Genome Atlas composed a training dataset. Two neuroradiologists in consensus analyzed the training dataset for various imaging features: tumor texture, margins, cortical infiltration, T2-FLAIR mismatch, tumor cyst, T2* susceptibility, hydrocephalus, midline shift, maximum dimension, primary lobe, necrosis, enhancement, edema, and gliomatosis. Statistical analysis of the training data produced a multivariate classification model for codeletion prediction based on a subset of MR imaging features and patient age. To validate the classification model, 2 different independent neuroradiologists analyzed a separate cohort of 106 institutional IDH-mutant lower grade gliomas. RESULTS: Training dataset analysis produced a 2-step classification algorithm with 86.3% codeletion prediction accuracy, based on the following: 1) the presence of the T2-FLAIR mismatch sign, which was 100% predictive of noncodeleted lower grade gliomas, (n = 21); and 2) a logistic regression model based on texture, patient age, T2* susceptibility, primary lobe, and hydrocephalus. Independent validation of the classification algorithm rendered codeletion prediction accuracies of 81.1% and 79.2% in 2 independent readers. The metrics used in the algorithm were associated with moderate-substantial interreader agreement (κ = 0.56-0.79). CONCLUSIONS: We have validated a classification algorithm based on simple, reproducible neuroimaging metrics and patient age that demonstrates a moderate prediction accuracy of 1p/19q-codeletion status among IDH-mutant lower grade gliomas.

Importance of GFAP isoform-specific analyses in astrocytoma.

Gliomas are a heterogenous group of malignant primary brain tumors that arise from glia cells or their progenitors and rely on accurate diagnosis for prognosis and treatment strategies. Although recent developments in the molecular biology of glioma have improved diagnosis, classical histological methods and biomarkers are still being used. The glial fibrillary acidic protein (GFAP) is a classical marker of astrocytoma, both in clinical and experimental settings. GFAP is used to determine glial differentiation, which is associated with a less malignant tumor. However, since GFAP is not only expressed by mature astrocytes but also by radial glia during development and neural stem cells in the adult brain, we hypothesized that GFAP expression in astrocytoma might not be a direct indication of glial differentiation and a less malignant phenotype. Therefore, we here review all existing literature from 1972 up to 2018 on GFAP expression in astrocytoma patient material to revisit GFAP as a marker of lower grade, more differentiated astrocytoma. We conclude that GFAP is heterogeneously expressed in astrocytoma, which most likely masks a consistent correlation of GFAP expression to astrocytoma malignancy grade. The GFAP positive cell population contains cells with differences in morphology, function, and differentiation state showing that GFAP is not merely a marker of less malignant and more differentiated astrocytoma. We suggest that discriminating between the GFAP isoforms GFAPδ and GFAPα will improve the accuracy of assessing the differentiation state of astrocytoma in clinical and experimental settings and will benefit glioma classification.

Molecular classification of diffuse gliomas.

In this study we assessed whether gliomas could be subdivided into different molecular subtypes by immunohistochemistry (IHC) reminiscent of those first described by Verhaak et al. in 2010 (classical, proneural, mesenchymal and neural). We also evaluated the prognostic significance of single molecular factors and searched for significant correlations between markers. In this study, we included 146 patients with glioblastomas (GBMs) and 26 with diffuse astrocytomas (DAs). The glioma samples were tested for PDGFRA, IDH1 R132H, CD44, p53, Ki-67, p21 and p27 expression. We found that gliomas could be subdivided into molecular subtypes by IHC. Fifty per cent of GBMs were of the proneural subtype, 18.5% of mesenchymal subtype and 31.5% were not otherwise classified. However, most of the DAs (92.3%) belonged to the proneural subtype. No prognostic role was found for the molecular subtypes, but predictive roles were noted. Both proneural and mesenchymal molecular subtypes showed a benefit from the addition of chemotherapy and radiotherapy; however, the mesenchymal subtype showed a greater response. Interestingly, the mesenchymal subtype did not receive any benefit from the addition of radiotherapy compared with palliative management and surgery alone. Regarding single molecular markers, only IDH1 R132H was found to have a prognostic role for GBMs. There was a trend towards better survival in tumours with lower PDGFRA expression (p = 0.066). In DAs, PDGFRA and Ki-67 expression had prognostic roles. The following statistically significant correlations were found in GBMs: Ki-67/p53, Ki-67/p27 and p53/PDGFRA; in DAs: p53/PDGFRA, CD44/PDGFRA, and p21/PDGFRA.