Management Of Glioblastoma Research Articles

BIOM-63. LONG-TERM SURVIVAL AND MOLECULAR CHARACTERIZATION OF IDH-WILDTYPE GLIOBLASTOMA IN AN ASIAN COHORT

Abstract BACKGROUND Glioblastoma (GB), the most aggressive form of brain tumor, presents a significant clinical challenge with a devastating prognosis. Globally, the median overall survival (OS) for GB is typically 12-15 months, largely due to its inherent resistance to chemotherapy and radiotherapy. However, some patients exhibit prolonged survival, and their specific demographic and genomic characteristics remain poorly defined. Understanding the clinical profile of these exceptional responders holds great promise for informing improved management strategies for GB. METHODS In a retrospective two-center study conducted in Hong Kong (IRB: UW 21-189), we recruited 80 patients diagnosed with IDH wildtype glioblastoma. All patients underwent next-generation sequencing as part of their treatment. Long-term survivor (LTS) was defined as >=36 months from diagnosis, while medium-term survivor (MTS) was defined as >=18 months, and <18 months as short-term survivors (STS). When appropriate, descriptive statistics were used to report frequency with percentage or median with range. Fisher’s exact test was employed to analyze categorical variables, while continuous variables were assessed using the Kruskal-Wallis test. All statistical analyses were conducted using R (version 4.2.3). Result: Among the cohort of 80 recruited patients, the median survival was 18.8 months (95% CI 17.2-24.8). Notably, 21% (n=17) were LTS, 31% (n=25) were MTS, and 48% (n=38) were STS. A statistically significant variation (p < 0.05) was evident across three groups: gender distribution, the number of resections performed, the proportion of patients receiving genomic-guided treatment, and their participation in clinical trials. However, no significant difference was observed in MGMT promoter status and ECOG score. CONCLUSION Identifying these clinical factors enhances the clinical management of GB. The implications of these findings underscore the potential importance of incorporating genomic-guided treatment in both local and global clinical practices in GB.

CSIG-21. THE ROLE OF GUT MICROBIOTA IN GLIOBLASTOMA: INSIGHTS FROM MICROBIOME-GENE EXPRESSION INTERACTIONS

Abstract Glioblastoma, the most aggressive form of primary brain tumor, remains a formidable clinical challenge due to its invasiveness and resistance to therapy. Emerging evidence suggests that the gut microbiome plays a crucial role in modulating cancer progression through complex interactions with host physiology. In this study, we investigated the influence of gut microbiota and tumor gene expression by analyzing stool and tissue samples from glioblastoma patients. Utilizing 16S rRNA sequencing of stool samples and NanoString gene expression analysis of tumor tissue samples, we explored the relationship between gut microbiome taxa and gene expression levels in tissue. Pathway analysis using KEGG and Gene Ontology databases was employed to elucidate the functional implications of these interactions. Our findings reveal contrasting effects of specific gut microbiota taxa and gene expression, with Fusobacterium demonstrating a potential oncogenic role, while Bifidobacteriaceae and Akkermansiaceae display potential tumor-suppressive effects. Fusobacterium is associated with the upregulation of key oncogenes and pathways promoting cancer cell survival, growth, and metabolism, whereas Bifidobacteriaceae and Akkermansiaceae are linked to the downregulation of genes involved in pathways promoting cancer cell survival and proliferation, such as MAPK signaling and stress response pathways, potentially inhibiting cancer cell growth. These results highlight the intricate interplay between gut microbiota composition and cancer biology and underscore the potential of gut microbiota modulation as a therapeutic strategy in glioblastoma management.

NIMG-27. RADIOMETHYLOMICS FOR NON-INVASIVE PREDICTION OF TUMOR PHENOTYPES AND SURVIVAL IN GLIOBLASTOMA

Abstract BACKGROUND DNA methylation profiling has become a pivotal tool in neuro-oncology. However, little is known about the impact of methylation profiling on radiological imaging in IDH-wildtype glioblastoma (GBM). This study explored the potential of radiomics to non-invasively predict molecular characteristics based on the methylation profiling of GBM. METHODS This study included a multi-sampling cohort of 32 patients with 113 samples and a single-sampling cohort of 87 patients with 87 samples, which underwent genome-wide methylation analysis and were classified as GBM by the DKFZ/Heidelberg CNS tumor classifier. We performed two different methylation-based deconvolution analyses. Deconvolution 1 estimated the fractions of tumor subtypes (RTK_I, RTK_II, MES_TYP, and MES_ATYP) and cell types in the microenvironment. Deconvolution 2 inferred the abundance of malignant cell states (stem-like and differentiated cell components) and cell types in the microenvironment. We derived 6084 radiomic features from preoperative multi-parametric MRI in each patient. RESULTS In the multi-sampling cohort, Deconvolution 1 and Deconvolution 2 demonstrated that tumor subclass components and immune components exhibited heterogeneous distribution across samples within patients; however, the stem-like to differentiated cell ratio was preserved across samples within patients. In the entire cohort, patients with tumors exhibiting a high proportion of the stem-like component, defined as stem-like tumors, had significantly shorter overall survival. Stem-like tumors exhibited significantly higher levels of the RTK_I component and lower proportions of the RTK_II component compared to non-stem-like tumors. A machine learning model that utilizes support vector machines to classify stem-like tumors using radiomic features achieved a mean AUC of 0.71 (95% confidence interval: 0.56–0.85) in nested cross-validation. CONCLUSIONS We showed that radiomethylomics can be used to predict tumor composition and patient survival from preoperative MRI in GBM. Based on these promising results we will increase our power with additional samples to facilitate a personalized approach to GBM management.

Marine-Derived Therapeutics for the Management of Glioblastoma: A Case Series and Comprehensive Review of the Literature

Introduction: Glioblastoma is a fatal intracranial neoplasm that is refractory to treatment, with inevitable disease recurrence and progression to death. Marine-derived compounds, including those found in nutraceutical products, may provide therapeutic benefit in the setting of glioblastoma. We present two patient cases whose courses demonstrate a compelling role for marine-derived products in the management of glioblastoma. Cases: Case 1 describes a patient with MGMT promoter unmethylated glioblastoma who went on to complete standard of care chemoradiation along with concurrent use of a majority sea cucumber (MSC) blend known as SeaCare® (SeaCare, Torrington, CT, USA). Her survival of over 2 years significantly exceeds the recognized median survival time of glioblastoma. Case 2 describes a patient with a complicated course who experienced dramatic improvement after the initiation of the MSC blend, with an exceptional survival time of over 4 years post-diagnosis. Discussion: The mechanisms of marine-derived products that underlie these dramatic clinical effects are likely multifaceted but may hinge on the modification of the tumor immune microenvironment and suppression of tumorigenic effects. Specifically, the change in tumor-associated macrophages (TAMs) within the tumor microenvironment is central to this complex interplay. Conclusions: Ultimately, the use of marine products in the treatment of glioblastoma may present a novel and promising therapeutic strategy that warrants further investigation.

Downregulation of CTRP1 Reduces Radio-resistance in Glioblastoma Cells by Inhibiting the Expression of CD133 after X-ray and Carbon Ion Irradiation

Glioblastomas (GBMs), the most prevalent primary malignant brain tumors, present significant challenges due to their invasive nature, high recurrence rates, and limited treatment options. Radiotherapy is a cornerstone in the management of GBMs; however, resistance to treatment poses a substantial obstacle. This study investigates the role of adipokine C1q/TNF-related protein 1 (CTRP1) in the radio-sensitivity of GBMs, utilizing both X-ray and carbon ion irradiation. Expression analyses revealed elevated CTRP1 and CD133 levels in GBMs tissues, which were associated with poor patient survival. Carbon ion irradiation demonstrated superior growth inhibition compared to X-ray, particularly in U87 (high CD133) cells. Moreover, CTRP1 expression increased following radiation exposure, especially after X-ray treatment. Knockdown of CTRP1 enhanced radio-sensitivity by reducing cell proliferation and increasing apoptosis, while exacerbating oxidative stress. Bioinformatics analysis revealed CTRP1's involvement in DNA damage repair pathways. Our findings establish a novel connection between CTRP1 and cellular radio-sensitivity. Targeting CTRP1, especially in U87 (high CD133) cells, enhances GBMs radio-sensitivity, offering potential therapeutic avenues.

Evolution of Molecular Biomarkers and Precision Molecular Therapeutic Strategies in Glioblastoma.

Glioblastoma is the most commonly occurring malignant brain tumor, with a high mortality rate despite current treatments. Its classification has evolved over the years to include not only histopathological features but also molecular findings. Given the heterogeneity of glioblastoma, molecular biomarkers for diagnosis have become essential for initiating treatment with current therapies, while new technologies for detecting specific variations using computational tools are being rapidly developed. Advances in molecular genetics have made possible the creation of tailored therapies based on specific molecular targets, with various degrees of success. This review provides an overview of the latest advances in the fields of histopathology and radiogenomics and the use of molecular markers for management of glioblastoma, as well as the development of new therapies targeting the most common molecular markers. Furthermore, we offer a summary of the results of recent preclinical and clinical trials to recognize the current trends of investigation and understand the possible future directions of molecular targeted therapies in glioblastoma.

P01.08.A HYOXIA-INDUCED EXPRESSION OF ARHGAP FAMILY MEMBERS PROMOTES GLIOBLASTOMA DISSEMINATION

Abstract BACKGROUND The Rho GTPase activating proteins (ARHGAPs) perform vital roles in the regulation of the Rho GTPases with direct effect on cellular plasticity and cell migration/invasion. We recently reported on the role of five ARHGAPs, identified by a microarray screen, in morphological plasticity in established and patient-derived Glioblastoma (GBM) cell lines and associated clinical relevance in terms of tumour recurrence after treatment. We established that the ARHGAPs either promoted or targeted cell migration/invasion by allowing cells to undergo morphological changes in preparation for dissemination. We also showed that co-expression of two ARHGAPs, 12 and 29, is associated with reduced time to recurrence after initial treatment in patients. ARHGAP activity has been also reported in metastatic cancers including breast and colorectal cancer highlighting the biological relevance of these, as yet understudied, proteins. MATERIAL AND METHODS Here, we explored the GBM microenvironment and the effect of hypoxia on ARHGAP expression and localisation in glioma cell lines. RESULTS Using immunocytological and in vitro migration and invasion assays we were able to ascertain that ARHGAP4, 12, 22, 25 and 29 acquired subcellular distributions different to those recorded under normoxia and expression also decreased or increased under hypoxia. We also found that the effect of the migrastatic inhibitor 6-bromo-indirubin-3′-oxime (BIO) targeting GSK-3 signalling was potentiated when cells were challenged with the drug under hypoxic conditions. CONCLUSION Our results confirm our initial findings of biological relevance of the ARHGAPs in cellular activities and highlight important roles for the ARHGAPs for promoting migratory/invasive activity and behaviour in GBM cells. We also conclude that migrastatic inhibitors will exert enhanced activity on GBM cells under hypoxic conditions making them excellent candidates for complement treatment with cytotoxic drugs or radiotherapy for an improved management of GBM.

Unlocking the Potential of Circulating miRNAs as Biomarkers in Glioblastoma

Using microRNAs (miRNAs) as potential circulating biomarkers in diagnosing and treating glioblastoma (GBM) has garnered a lot of scientific and clinical impetus in the past decade. As an aggressive primary brain tumor, GBM poses challenges in early detection and effective treatment with significant current diagnostic constraints and limited therapeutic strategies. MiRNA dysregulation is present in GBM. The intricate involvement of miRNAs in altering cell proliferation, invasion, and immune escape makes them prospective candidates for identifying and monitoring GBM diagnosis and response to treatment. These miRNAs could play a dual role, acting as both potential diagnostic markers and targets for therapy. By modulating the activity of various oncogenic and tumor-suppressive proteins, miRNAs create opportunities for precision medicine and targeted therapies in GBM. This review centers on the critical role and function of circulating miRNA biomarkers in GBM diagnosis and treatment. It highlights their significance in providing insights into disease progression, aiding in early diagnosis, and potential use as targets for novel therapeutic interventions. Ultimately, the study of miRNA would contribute to improving patient outcomes in the challenging landscape of GBM management.

Efficacy and Cognitive Outcomes of Gamma Knife Radiosurgery in Glioblastoma Management for Elderly Patients.

Gamma Knife Radiosurgery (GKRS), a specific type of Stereotactic Radiosurgery (SRS), has developed as a significant modality in the treatment of glioblastoma, particularly in conjunction with standard chemotherapy. The goal of this study is to evaluate the efficacy of combining GKRS with surgical resection and chemotherapy in enhancing therapeutic effects for glioblastoma patients aged 55 years and older. This prospective clinical study, conducted in accordance with the STROBE guidelines, involved 49 glioblastoma patients aged 55 years and older, treated between January 2013 and January 2023. Data were collected prospectively, and strict adherence to the STUPP protocol was maintained. Only patients who conformed to the STUPP protocol were included in the analysis. Due to concerns regarding the cognitive impairment associated with conventional radiotherapy, and at the patients' request, a radiosurgery plan was offered. Radiosurgery was administered for 4-8 weeks following surgical resection. Any patients who had not received previous radiotherapy received open surgical tumor removal, followed by GKRS along with adjuvant chemotherapy. In this prospective clinical study of 49 glioblastoma patients aged 55 years and older, the average lifespan post-histopathological diagnosis was established at 22.3 months (95% CI: 12.0-28.0 months). The median time before disease progression was 14.3 months (95% CI: 13.0-29.7 months). The median duration until the first recurrence after treatment was 15.2 months, with documented cases varying between 4 and 33 months. The Gamma Knife Radiosurgery (GKRS) treatment involved a median marginal recommended dose of 12.5 Gy, targeting an average volume of 5.7 cm3 (range: 1.6-39 cm3). Local recurrence occurred in 21 patients, while distant recurrence was identified in 8 patients. Within the cohort, 34 patients were subjected to further therapeutic approaches, including reoperation, a second GKRS session, the administration of bevacizumab and irinotecan, and PCV chemotherapy. A cognitive function assessment revealed that the patients treated with GKRS experienced significantly less cognitive decline compared to the historical controls, who were treated with conventional radiotherapy. The median MMSE scores declined by 1.9 points over 12 months, and the median MoCA scores declined by 2.9 points. This study demonstrates that Gamma Knife Radiosurgery (GKRS), when integrated with surgical resection and adjuvant chemotherapy, offers a substantial benefit for glioblastoma patients aged 55 years and older. The data reveal that GKRS not only prolongs overall survival and progression-free survival but also significantly reduces cognitive decline compared to conventional radiotherapy. These findings underscore the efficacy and safety of GKRS, advocating for its incorporation into standard treatment protocols for older glioblastoma patients. The potential of GKRS to improve patient outcomes while preserving cognitive function is compelling and warrants further research to optimize and confirm its role in glioblastoma management.

Extracellular Vesicle-Based Characterization of Stem Cell Phenotype in Glioblastomas.

Glioblastoma (GB) is the most common brain malignancy occurring in adult patients having an extremely low overall survival. Therefore, it is paramount to establish reliable and accurate diagnostic and prognostic markers to guide a personalized and more effective treatment. Molecular characterization of the tumor is the ultimate goal in GB management and comprises, among others, the study of the extracellular vesicles (EVs). Not only do they carry within their cargo molecules involved in shaping a favorable microenvironment for GB development, but EVs also present surface markers mirroring the phenotype of the donor cells. Our study aims to assess the dynamic evolution of EV-positive surface biomarkers and EV-derived proteins involved in maintaining and transferring a stem cell phenotype to the cells from GB surroundings. We performed a prospective observational study on GB patients operated on in the Neurosurgery Clinic of the Emergency Clinical County Hospital of Târgu Mureș, Romania. GB-derived EVs were isolated from the patients' plasma using a density gradient ultracentrifugation protocol. The expression of EVs positive to four epitopes specific to stem cells (CD44, CD133, CD326/EpCAM, and SSEA4) was followed in three moments in time, preoperatively, seven days, and three months postoperatively, respectively, and quantified by a bead-based multiple analysis using flow cytometry. Moreover, NANOGP8, a protein within GB cargo capable of promoting a stem cell phenotype, was dynamically evaluated using the Western blot technique. Our study showed a statistically significant decrease of all surface markers and NANOGP8 immediately after tumor ablation. Nonetheless, the long-term follow-up of the patients revealed an extremely variable evolutionary pattern reflecting the high heterogeneity of GB. Further studies are necessary to either confirm or infirm the accuracy of these markers in early diagnosing GB, in predicting the outcome of this disease, and in guiding an individualized therapy.

Recent Advances in Marine-Derived Nanoformulation for the Management of Glioblastoma.

Glioma is the most common and aggressive type of central nervous system tumor as categorized by the World Health Organization. Glioblastoma (GBA), in general, exhibits a grim prognosis and short life expectancy, rarely exceeding 14months. The dismal prognosis is primarily attributed to the development of chemoresistance to temozolomide, the primary therapeutic agent for GBA treatment. Hence, it becomes imperative to develop novel drugs with antitumor efficacy rooted in distinct mechanisms compared to temozolomide. The vast marine environment contains a wealth of naturally occurring compounds from the sea (known as marine-derived natural products), which hold promise for future research in the quest for new anticancer drugs. Ongoing advancements in anticancer pharmaceuticals have led to an upswing in the isolation and validation of numerous pioneering breakthroughs and improvements in anticancer therapeutics. Nonetheless, the availability of FDA-approved marine-derived anticancer drugs remains limited, owing to various challenges and constraints. Among these challenges, drug delivery is a prominent hurdle. This review delves into an alternative approach for delivering marine-derived drugs using nanotechnological formulations and their mechanism of action for treating GBA.

Radiotherapeutic advances in the management of glioblastoma.

Glioblastoma remains a fatal diagnosis despite continuous efforts to improve upon the current standard backbone management paradigm of surgery, radiation therapy, systemic therapy and Tumor Treating Fields. Radiation therapy (RT) plays a pivotal role, with progress recently achieved in multiple key areas of research. The evolving landscape of dose and fractionation schedules and dose escalation options for different patient populations is explored, offering opportunities to better tailor treatment to a patient's overall status and preferences; novel efforts to modify treatment volumes are presented, such as utilizing state-of-the-art MRI-based linear accelerators to deliver adaptive therapy, hoping to reduce normal tissue exposure and treatment-related toxicity; specialized MR techniques and functional imaging using novel PET agents are described, providing improved treatment accuracy and the opportunity to target areas at risk of disease relapse; finally, the role of particle therapy and new altered dose-rate photon and proton therapy techniques in the treatment paradigm of glioblastoma is detailed, aiming to improve tumor control and patient outcome by exploiting novel radiobiological pathways. Improvements in each of these aforementioned areas are needed to make the critical necessary progress and allow for new approaches combining different advanced treatment modalities. This plethora of multiple new treatment options currently under investigation provides hope for a new outlook for patients with glioblastoma in the near future.

A cancer-associated fibroblasts related risk score (CAFscore) helps to guide prognosis and personal treatment for Glioblastoma

BackgroundRecent studies have identified the presence of cancer-associated fibroblasts (CAFs) within glioblastoma (GBM), yet their biological roles and underlying mechanisms remain poorly understood. This study aimed to construct a CAF-related prognostic model to guide patient prognosis and treatment strategies.MethodWe employed various bioinformatics methods, including enrichment analysis, Weighted Gene Co-expression Network Analysis (WGCNA), Lasso regression analysis, and machine learning techniques such as XGBoost and Random Forest, to develop a novel risk index termed CAFscore. Patients were stratified into high and low CAFscore groups for subsequent survival analysis. The area under the curve (AUC) and concordance index (C-index) for CAFscore were calculated and compared against other clinical characteristics and existing prognostic models. Drug sensitivity assessments were conducted using the Oncopredict package. Functional validation of key genes was performed through scratch and invasion assays in GBM cells.ResultsOur analyses revealed four core CAF-related genes, leading to the establishment of CAFscore. Notably, patients in the high CAFscore group exhibited significantly reduced survival and exhibited enrichment in epithelial-mesenchymal transition (EMT) and inflammation response pathways. Furthermore, CAFscore showed a significant negative correlation with the sensitivity to irinotecan and its analogs, while demonstrating a positive correlation with sensitivity to 505,124 (a TGFβRI inhibitor). LRP10 emerged as a central gene within the CAFscore, displaying markedly elevated expression in GBM and a strong association with CAF infiltration. Silencing LRP10 significantly inhibited the invasive capabilities of GBM cells.ConclusionThis study presented the first CAF related prognostic model (CAFscore) in GBM, and demonstrated that the model could effectively guide patient prognosis and potentially inform personalized treatment strategies. The core gene of CAFscore, LRP10, was significantly overexpressed in GBM and might play a pivotal role in regulating CAF infiltration as well as tumor invasion and metastasis, highlighting LRP10 as a promising therapeutic target for GBM management.

In vivo pharmacokinetic study of carmustine in rats after giving single-dose of carmustine API solution, flexible liposomes, in situ nasal gel, optimized flexible liposomes embedded in situ nasal gel, and marketed formulation

Carmustine is used in the treatment of glioblastoma (GBM). GBM is a well-known life-threatening type of cancerous tumor. GBM covers 60.00% among all primary brain tumors, with an occurrence of 74,000 cases across the globe. Management for GBM is still very difficult because most of the medicines are unable to cross the blood-brain barrier (BBB). The present work observed that flexible liposomes embedded in situ nasal gel of carmustine is the best brain-targeted medicine delivery system for the management of GBM through the nasal route. To evaluate in vivo pharmacokinetic parameters of carmustine formulations administered through nasal routes in Wistar rats. In this work, different pharmacokinetic parameters were determined for carmustine formulations viz. carmustine API (Active Pharmaceutical Ingredient) solution, flexible liposomes, in situ thermoreversible intranasal gel, optimized flexible liposomes embedded in situ thermoreversible intranasal gel via intranasal administration in rats, and compared with marketed intravenous injection of carmustine administered through intravenous route. Carmustine was estimated with the help of a validated high-performance liquid chromatography (HPLC) approach. Three to four-months-old normal Wistar rats of either sex, having a weight of 200-250 grams were used in this study. Intranasal administration of optimized flexible liposomes embedded in situ nasal gel showed greater Cmax (∼two-fold), AUC0→t (∼three-fold), AUC0→∞ (∼six-fold), and decreased Tmax (1h) data in the brain, than commercial intravenous injection of carmustine. The plasma concentration of carmustine administered through nasal route was found to be comparatively lower than intravenous administration, indicating lower systemic exposure to carmustine via the nasal route. In vivo pharmacokinetics results revealed that the optimized flexible liposomes embedded in situ nasal gel of carmustine can effectively deliver carmustine to brain by nasal drug delivery system in Wistar rats.

Risk Factors of Distant Recurrence and Dissemination of IDH Wild-Type Glioblastoma: A Single-Center Study and Meta-Analysis.

Isocitrate dehydrogenase (IDH) wild-type glioblastoma (GBM) is a highly aggressive brain tumor with a high recurrence rate despite adjuvant treatment. This study aimed to evaluate the risk factors for non-local recurrence of GBM. In the present study, we analyzed 104 GBMs with a single lesion (non-multifocal or multicentric). Univariate analysis revealed that subventricular zone (SVZ) involvement was significantly associated with non-local recurrence (hazard ratio [HR]: 2.09 [1.08-4.05]). Tumors in contact with the trigone of the lateral ventricle tended to develop subependymal dissemination (p = 0.008). Ventricular opening via surgery did not increase the risk of non-local recurrence in patients with SVZ involvement (p = 0.190). A systematic review was performed to investigate the risk of non-local recurrence, and 21 studies were identified. A meta-analysis of previous studies confirmed SVZ involvement (odds ratio [OR]: 1.30 [1.01-1.67]) and O-6-methylguanine DNA methyltransferase promoter methylation (OR: 1.55 [1.09-2.20]) as significant risk factors for local recurrence. A time-dependent meta-analysis revealed a significant association between SVZ involvement and dissemination (HR: 1.69 [1.09-2.63]), while no significant association was found for distant recurrence (HR: 1.29 [0.74-2.27]). Understanding SVZ involvement and specific tumor locations associated with non-local recurrence provides critical insights for the management of GBM.

Local therapy in glioma: An evolving paradigm from history to horizons (Review).

Despite the implementation of multimodal treatments after surgery, glioblastoma (GBM) remains an incurable disease, posing a significant challenge in neuro-oncology. In this clinical setting, local therapy (LT), a developing paradigm, has received significant interest over time due to its potential to overcome the drawbacks of conventional therapy options for GBM. The present review aimed to trace the historical development, highlight contemporary advances and provide insights into the future horizons of LT in GBM management. In compliance with the Preferred Reporting Items for Systematic Review and Meta-Analysis Protocols criteria, a systematic review of the literature on the role of LT in GBM management was conducted. A total of 2,467 potentially relevant articles were found and, after removal of duplicates, 2,007 studies were screened by title and abstract (Cohen's κ coefficient=0.92). Overall, it emerged that 15, 10 and 6 clinical studies explored the clinical efficiency of intraoperative local treatment modalities, local radiotherapy and local immunotherapy, respectively. GBM recurrences occur within 2 cm of the radiation field in 80% of cases, emphasizing the significant influence of local factors on recurrence. This highlights the urgent requirement for LT strategies. In total, three primary reasons have thus led to the development of numerous LT solutions in recent decades: i) Intratumoral implants allow the blood-brain barrier to be bypassed, resulting in limited systemic toxicity; ii) LT facilitates bridging therapy between surgery and standard treatments; and iii) given the complexity of GBM, targeting multiple components of the tumor microenvironment through ligands specific to various elements could have a synergistic effect in treatments. Considering the spatial and temporal heterogeneity of GBM, the disease prognosis could be significantly improved by a combination of therapeutic strategies in the era of precision medicine.

Identification of new targets for glioblastoma therapy based on a DNA expression microarray

This study provides a comprehensive perspective on the deregulated pathways and impaired biological functions prevalent in human glioblastoma (GBM). In order to characterize differences in gene expression between individuals diagnosed with GBM and healthy brain tissue, we have designed and manufactured a specific, custom DNA microarray. The results obtained from differential gene expression analysis were validated by RT-qPCR. The datasets obtained from the analysis of common differential expressed genes in our cohort of patients were used to generate protein-protein interaction networks of functionally enriched genes and their biological functions. This network analysis, let us to identify 16 genes that exhibited either up-regulation (CDK4, MYC, FOXM1, FN1, E2F7, HDAC1, TNC, LAMC1, EIF4EBP1 and ITGB3) or down-regulation (PRKACB, MEF2C, CAMK2B, MAPK3, MAP2K1 and PENK) in all GBM patients. Further investigation of these genes and enriched pathways uncovered in this investigation promises to serve as a foundational step in advancing our comprehension of the molecular mechanisms underpinning GBM pathogenesis. Consequently, the present work emphasizes the critical role that the unveiled molecular pathways likely play in shaping innovative therapeutic approaches for GBM management. We finally proposed in this study a list of compounds that target hub of GBM-related genes, some of which are already in clinical use, underscoring the potential of those genes as targets for GBM treatment.

Erratum: Optimizing the management of glioblastoma per neurosurgical approach and therapeutic interventions on patient outcomes: A systematic review and meta-analysis

Erratum: Optimizing the management of glioblastoma per neurosurgical approach and therapeutic interventions on patient outcomes: A systematic review and meta-analysis

Second surgery for relapsed glioblastoma: an observational study on criteria for patient selection in real life.

Aim: There is little consensus on salvage management of glioblastoma after recurrence, for lack of evidence.Materials &methods: A retrospective study of treatments in patients with recurrent glioblastoma.Results: Surgery at recurrence was related to better overall survival (OS) and progression-free survival (PFS). Surgery at recurrence, Karnofsky index, MGMT methylation status, younger age at diagnosisand number of chemotherapy cycles were positive factors for OS and PFS. The benefit of OS was relevant for a second surgery performed at least 9months after the first one. Systemic treatments after the second surgery were linked to an improved PFS.Conclusion: Younger age, Karnofsky index, MGMT methylation statusand a median time between surgeries ≥9months may be criteria for eligibility for surgery at recurrence.

Targeted Alpha Therapy for Glioblastoma: Review on In Vitro, In Vivo and Clinical Trials.

Glioblastoma (GB), a prevalent and highly malignant primary brain tumour with a very high mortality rate due to its resistance to conventional therapies and invasive nature, resulting in 5-year survival rates of only 4-17%. Despite recent advancements in cancer management, the survival rates for GB patients have not significantly improved over the last 10-20 years. Consequently, there exists a critical unmet need for innovative therapies. One promising approach for GB is Targeted Alpha Therapy (TAT), which aims to selectively deliver potentially therapeutic radiation doses to malignant cells and the tumour microenvironment while minimising radiation exposure to surrounding normal tissue with or without conventional external beam radiation. This approach has shown promise in both pre-clinical and clinical settings. A review was conducted following PRISMA 2020 guidelines across Medline, SCOPUS, and Embase, identifying 34 relevant studies out of 526 initially found. In pre-clinical studies, TAT demonstrated high binding specificity to targeted GB cells, with affinity rates between 60.0% and 84.2%, and minimal binding to non-targeted cells (4.0-5.6%). This specificity significantly enhanced cytotoxic effects and improved biodistribution when delivered intratumorally. Mice treated with TAT showed markedly higher median survival rates compared to control groups. In clinical trials, TAT applied to recurrent GB (rGB) displayed varying success rates in extending overall survival (OS) and progression-free survival. Particularly effective when integrated into treatment regimens for both newly diagnosed and recurrent cases, TAT increased the median OS by 16.1% in newly diagnosed GB and by 36.4% in rGB, compared to current standard therapies. Furthermore, it was generally well tolerated with minimal adverse effects. These findings underscore the potential of TAT as a viable therapeutic option in the management of GB.