大場 茂生

Abstract Differentiating pseudoprogression (PsP) from recurrence in cases of glioblastoma (GBM) after chemoradiotherapy is challenging, with neuroimaging as the only non-invasive method. In this study, we aimed to identify a blood biomarker for precise disease monitoring and investigated the role of Ataxin-2 (ATXN2). Blood samples (n = 45) from patients with suspected recurrence, including eight with PSP, were analyzed. In addition, tumor tissue samples (n = 22), including those from seven patients who also provided blood samples, were examined. Protein levels were assessed using quantitative proteomics and ELISA. ATXN2 levels were measured via western blotting, and localization was determined through immunohistochemistry and immunocytochemistry. ATXN2 knockdown was performed in glioma cell lines to assess its effects on proliferation, migration, and invasion. Proteomics identified ATXN2 as a potential biomarker. ELISA showed significantly higher serum ATXN2 levels in recurrence than in PsP (p = 0.028). ATXN2 ≥ 11.0 ng/mL and ≥ 8 months post-chemoradiotherapy distinguished recurrence from PsP (AUC = 0.82, sensitivity = 67.6%, specificity = 87.5%). ATXN2 was highly expressed in GBM tissues, localized in neurons and glioma cells, and its knockdown enhanced proliferation, migration, and invasion via ERK phosphorylation. ATXN2, highly expressed in GBM, may serve as a potential blood biomarker for distinguishing PsP from recurrence.

Compared to oligodendrogliomas, astrocytomas may have a relatively higher frequency of intracranial remote recurrence, despite generally favorable prognoses. Previous studies identified 8q gain, particularly in the terminal region, as a poor prognostic factor. This study evaluated MYC expression and its relationship with copy number gain at 8q24.21, in relation to recurrence patterns in astrocytomas, with a particular focus on intracranial remote recurrence. A retrospective analysis was conducted on 27 patients treated between 2006 and 2019. MYC expression was assessed by immunohistochemistry (IHC), and copy number status by metaphase comparative genomic hybridization and next-generation sequencing. Recurrence patterns were categorized as local or remote.Among 43 specimens analyzed by IHC, MYC expression was observed in 72%, with higher positivity in recurrent (80%) than initial (61%) specimens, though the difference was not statistically significant (p = 0.30). Copy number analysis showed a significant increase in 8q24.21 copy number in specimens from cases with remote recurrence compared to those with local recurrence (p = 0.033). However, no significant correlation was found between MYC copy number and protein expression (p = 0.055). These findings suggest that MYC is frequently expressed in astrocytomas, but its expression does not significantly reflect 8q gain or recurrence pattern.

Karnofsky Performance Status (KPS) is a widely used scale to assess performance status. KPS ≥ 50% implies that patients can live at home. Therefore, maintaining KPS ≥ 50% is important to improve the quality of life of patients with glioblastoma, whose median survival is less than 2 years. This study aimed to identify the factors associated with survival time with maintenance of KPS ≥ 50% (survival with KPS ≥ 50%) in patients with glioblastoma, IDH-wildtype. Ninety-eight patients with glioblastomas, IDH-wildtype, who were treated with concomitant radiotherapy (RT) and temozolomide (TMZ) followed by maintenance TMZ therapy, and whose KPS at the start of RT was ≥ 50%, were included. The median survival with KPS ≥ 50% was 13.3 months. In univariate analysis, preoperative KPS (≥ 80%), KPS at the start of RT (≥ 80%), residual tumor size (< 2 cm3), methylated MGMT promotor, and implantation of BCNU wafer were associated with survival with KPS ≥ 50%. In multivariate analysis, KPS at the start of RT (≥ 80%), methylated MGMT promotor, and residual tumor size (< 2 cm3) were significantly associated with increased survival with KPS ≥ 50%. A strategy of maximum possible tumor resection without compromising KPS is desirable to prolong the survival time with KPS ≥ 50%.

Posterior Quadrant Disconnection is a surgical technique designed to suppress seizure propagation while preserving motor and sensory functions in patients with drug-resistant epilepsy. Although seizure outcomes following this procedure have been reported, detailed evaluations of its impact on higher cognitive functions remain limited. This study aimed to assess the long-term seizure and cognitive outcomes following PQD in the non-dominant hemisphere, thereby evaluating the efficacy and safety of the procedure. In this case, the patient with drug-resistant epilepsy underwent preoperative evaluation using stereo electroencephalography (SEEG) to identify seizure onset zones and functional mapping related to visuospatial cognition. Following this assessment, PQD was performed. Postoperative outcomes were monitored over a 2-years period, focusing on seizure control and higher cognitive function. The patient achieved Engel class I status postoperatively, indicating complete seizure cessation. While transient hemispatial neglect was observed immediately after surgery, gradual improvement was noted over time. Furthermore, visual memory and cognitive functions showed a tendency to improve, and there were no significant declines in facial recognition or scene recognition abilities. These findings suggest that PQD can effectively improve seizure outcomes while minimizing long-term impacts on cognitive functions. This case highlights the potential of PQD to offer substantial seizure control with limited permanent effects on higher cognitive functions. By providing valuable insights into the safety and efficacy of PQD in the non-dominant hemisphere, this study underscores its viability as a treatment option for selected cases of drug-resistant epilepsy.

BACKGROUND: To improve the outcome in newly diagnosed glioblastoma patients with maximal resection, we aimed to evaluate the efficacy and safety of implantation of carmustine wafers (CWs), radiation concomitant with temozolomide and bevacizumab, and maintenance chemotherapy with six cycles of temozolomide and bevacizumab. METHOD: This prospective phase II study enrolled glioblastoma patients considered candidates for complete resection (> 90%) of a contrast-enhanced lesion. The CWs were intraoperatively implanted into the resection cavity after achieving maximal resection. Patients without a measurable contrast-enhanced lesion on magnetic resonance imaging within 48 h after resection received concomitant radiotherapy and chemotherapy with temozolomide and bevacizumab, followed by maintenance treatment with up to six cycles of temozolomide and bevacizumab. The primary endpoint was the 2-year overall survival rate in glioblastoma patients with protocol treatment. RESULTS: From October 2015 to April 2018, we obtained consent for the first registration from 70 patients across 17 institutions in Japan, and 49 patients were treated according to the protocol. We evaluated the safety in 49 patients who were part of the second registration and the efficacy in 45 glioblastoma patients treated according to the protocol. The profile of hematological and most of the non-hematological adverse effects was similar to that in previous studies, but stroke occurred in 12% of cases (6/49 patients). The estimated 2-year overall survival rate was 51.3%. CONCLUSION: Implantation of CWs, followed by concomitant radiation, temozolomide, and bevacizumab, and six cycles of temozolomide and bevacizumab may offer some benefit to survival in Japanese glioblastoma patients with maximal resection. TRIAL ID: jRCTs021180007.