Multiscale, multimodal analysis of tumor heterogeneity in IDH1 mutant vs wild-type diffuse gliomas.

Glioma is recognized to be a highly heterogeneous CNS malignancy, whose diverse cellular composition and cellular interactions have not been well characterized. To gain new clinical- and biological-insights into the genetically-bifurcated IDH1 mutant (mt) vs wildtype (wt) forms of glioma, we integrated data from protein, genomic and MR imaging from 20 treatment-naïve glioma cases and 16 recurrent GBM cases. Multiplexed immunofluorescence (MxIF) was used to generate single cell data for 43 protein markers representing all cancer hallmarks, Genomic sequencing (exome and RNA (normal and tumor) and magnetic resonance imaging (MRI) quantitative features (protocols were T1-post, FLAIR and ADC) from whole tumor, peritumoral edema and enhancing core vs equivalent normal region were also collected from patients. Based on MxIF analysis, 85,767 cells (glioma cases) and 56,304 cells (GBM cases) were used to generate cell-level data for 24 biomarkers. K-means clustering was used to generate 7 distinct groups of cells with divergent biomarker profiles and deconvolution was used to assign RNA data into three classes. Spatial and molecular heterogeneity metrics were generated for the cell data. All features were compared between IDH mt and IDHwt patients and were finally combined to provide a holistic/integrated comparison. Protein expression by hallmark was generally lower in the IDHmt vs wt patients. Molecular and spatial heterogeneity scores for angiogenesis and cell invasion also differed between IDHmt and wt gliomas irrespective of prior treatment and tumor grade; these differences also persisted in the MR imaging features of peritumoral edema and contrast enhancement volumes. A coherent picture of enhanced angiogenesis in IDHwt tumors was derived from multiple platforms (genomic, proteomic and imaging) and scales from individual proteins to cell clusters and heterogeneity, as well as bulk tumor RNA and imaging features. Longer overall survival for IDH1mt glioma patients may reflect mutation-driven alterations in cellular, molecular, and spatial heterogeneity which manifest in discernable radiological manifestations

Metabolic Profiling of IDH Mutation and Malignant Progression in Infiltrating Glioma.

Infiltrating low grade gliomas (LGGs) are heterogeneous in their behavior and the strategies used for clinical management are highly variable. A key factor in clinical decision-making is that patients with mutations in the isocitrate dehydrogenase 1 and 2 (IDH1/2) oncogenes are more likely to have a favorable outcome and be sensitive to treatment. Because of their relatively long overall median survival, more aggressive treatments are typically reserved for patients that have undergone malignant progression (MP) to an anaplastic glioma or secondary glioblastoma (GBM). In the current study, ex vivo metabolic profiles of image-guided tissue samples obtained from patients with newly diagnosed and recurrent LGG were investigated using proton high-resolution magic angle spinning spectroscopy (1H HR-MAS). Distinct spectral profiles were observed for lesions with IDH-mutated genotypes, between astrocytoma and oligodendroglioma histologies, as well as for tumors that had undergone MP. Levels of 2-hydroxyglutarate (2HG) were correlated with increased mitotic activity, axonal disruption, vascular neoplasia, and with several brain metabolites including the choline species, glutamate, glutathione, and GABA. The information obtained in this study may be used to develop strategies for in vivo characterization of infiltrative glioma, in order to improve disease stratification and to assist in monitoring response to therapy

Focused ultrasound-enabled brain tumor liquid biopsy

Abstract Although blood-based liquid biopsies have emerged as a promising non-invasive method to detect biomarkers in various cancers, limited progress has been made for brain tumors. One major obstacle is the blood-brain barrier (BBB), which hinders efficient passage of tumor biomarkers into the peripheral circulation. The objective of this study was to determine whether FUS in combination with microbubbles can enhance the release of biomarkers from the brain tumor to the blood circulation. Two glioblastoma tumor models (U87 and GL261), developed by intracranial injection of respective enhanced green fluorescent protein (eGFP)-transduced glioblastoma cells, were treated by FUS in the presence of systemically injected microbubbles. Effect of FUS on plasma eGFP mRNA levels was determined using quantitative polymerase chain reaction. eGFP mRNA were only detectable in the FUS-treated U87 mice and undetectable in the untreated U87 mice (maximum cycle number set to 40). This finding was replicated in GL261 mice across three different acoustic pressures. The circulating levels of eGFP mRNA were 1,500–4,800 fold higher in the FUS-treated GL261 mice than that of the untreated mice for the three acoustic pressures. This study demonstrated the feasibility of FUS-enabled brain tumor liquid biopsies in two different murine glioma models across different acoustic pressures

In vivo investigation of hyperpolarized [1,3-13C2]acetoacetate as a metabolic probe in normal brain and in glioma.

Dysregulation in NAD+/NADH levels is associated with increased cell division and elevated levels of reactive oxygen species in rapidly proliferating cancer cells. Conversion of the ketone body acetoacetate (AcAc) to β-hydroxybutyrate (β-HB) by the mitochondrial enzyme β-hydroxybutyrate dehydrogenase (BDH) depends upon NADH availability. The β-HB-to-AcAc ratio is therefore expected to reflect mitochondrial redox. Previous studies reported the potential of hyperpolarized 13C-AcAc to monitor mitochondrial redox in cells, perfused organs and in vivo. However, the ability of hyperpolarized 13C-AcAc to cross the blood brain barrier (BBB) and its potential to monitor brain metabolism remained unknown. Our goal was to assess the value of hyperpolarized [1,3-13C2]AcAc in healthy and tumor-bearing mice in vivo. Following hyperpolarized [1,3-13C2]AcAc injection, production of [1,3-13C2]β-HB was detected in normal and tumor-bearing mice. Significantly higher levels of [1-13C]AcAc and lower [1-13C]β-HB-to-[1-13C]AcAc ratios were observed in tumor-bearing mice. These results were consistent with decreased BDH activity in tumors and associated with increased total cellular NAD+/NADH. Our study confirmed that AcAc crosses the BBB and can be used for monitoring metabolism in the brain. It highlights the potential of AcAc for future clinical translation and its potential utility for monitoring metabolic changes associated with glioma, and other neurological disorders

Characterization of vascular heterogeneity of astrocytomas grade 4 for supporting patient prognosis estimation, and treatment response assessment

[ES] Los tumores cerebrales son una de las enfermedades más devastadoras en la actualidad por el importante deterioro cognitivo que sufren los pacientes, la elevada tasa de mortalidad y el mal pronóstico. Los astrocitomas de grado 4 conllevan una supervivencia de cinco años en aproximadamente el 5% de los pacientes diagnosticados, siendo los tumores más agresivos y letales del Sistema Nervioso Central (SNC). Los astrocitomas de grado 4 siguen siendo un problema médico complejo aún sin resolver. A pesar de representar más del 60% de los tumores cerebrales malignos en adultos, estos tumores tienen una baja prevalencia relativa y se consideran una enfermedad huérfana, lo que dificulta el desarrollo de nuevos fármacos o tratamientos que puedan beneficiar a los pacientes. La agresividad de estos tumores se debe a diferentes características, como la fuerte angiogénesis, la necrosis, la microproliferación vascular, la capacidad de invasión e infiltración de las células tumorales y un microambiente inmunológico particular. Además, debido a la rápida progresión de los astrocitomas de grado 4, en la zona de la lesión coexisten diferentes regiones específicas que cambian con el tiempo. Esta naturaleza compleja, junto con la marcada heterogeneidad interpaciente, intratumoral y longitudinal, complica el éxito de un único tratamiento eficaz para todos los pacientes. La imagen de resonancia magnética (MRI) supone una técnica útil para caracterizar la morfología y la vascularidad del tumor. El uso de métodos avanzados y robustos para analizar las imágenes de MR recogidas en las fases iniciales del tratamiento de los pacientes permite la delimitación de las diferentes regiones de los astrocitomas de grado 4, convirtiéndose en herramientas útiles para investigadores, radiólogos y neurocirujanos. Además, el cálculo de biomarcadores vasculares de imagen, como los propuestos en esta tesis, facilitaría la caracterización del tumor, la estimación del pronóstico y los enfoques de tratamiento más personalizados. Esta tesis propone cuatro pilares fundamentales para avanzar en el manejo de los astrocitomas de grado 4. Estos incluyen I) la caracterización multinivel del tumor para mejorar las clasificaciones de los gliomas de alto grado del SNC; II) la búsqueda y desarrollo de biomarcadores robustos para estimar el pronóstico de los pacientes desde el momento prequirúrgico; III) así como para evaluar la respuesta a los tratamientos y la selección de los pacientes que pueden beneficiarse de terapias específicas; y IV) el diseño e implementación de estudios clínicos y protocolos para la recogida de datos a largo plazo de cohortes de pacientes notables a nivel internacional. Para abordar estos cuatro pilares, se ha utilizado un enfoque interdisciplinario que combina el análisis de imágenes médicas, técnicas avanzadas de inteligencia artificial y variables moleculares, histopatológicas y clínicas. En conclusión, hemos abordado la influencia de la heterogeneidad interpaciente e intratumoral del astrocitoma de grado 4 para la caracterización y clasificación del tumor, la estimación del pronóstico del paciente y la predicción de las respuestas al tratamiento. Además, se han diseñado e implementado diferentes estudios clínicos que permiten la recogida de datos multinivel de cohortes internacionales de pacientes con astrocitoma de grado 4.[CA] Els tumors cerebrals són una de les malalties més devastadores en l'actualitat per la important deterioració cognitiva que pateixen els pacients, l'elevada taxa de mortalitat i el mal pronòstic. Els astrocitomes de grau 4 comporten una supervivència de cinc anys en aproximadament el 5% dels pacients diagnosticats, sent els tumors més agressius i letals del Sistema Nerviós Central (SNC). Els astrocitomes de grau 4 continuen sent un problema mèdic complex encara sense resoldre. Malgrat representar més del 60% dels tumors cerebrals malignes en adults, aquests tumors tenen una baixa prevalença relativa i es consideren una malaltia òrfena, la qual cosa dificulta el desenvolupament de nous fàrmacs o tractaments que puguen beneficiar als pacients. L'agressivitat d'aquests tumors es deu a diferents característiques, com la forta angiogènesis, la necrosi, la microproliferació vascular, la capacitat d'invasió i infiltració de les cèl·lules tumorals i un microambient immunològic particular. A més, a causa de la ràpida progressió dels astrocitomes de grau 4, en la zona de la lesió coexisteixen diferents regions específiques que canvien amb el temps. Aquesta naturalesa complexa, juntament amb la marcada heterogeneïtat interpacient, intratumoral i longitudinal fa que es complique l'èxit d'un únic tractament eficaç per a tots els pacients. L'imatge de ressonància magnètica (MRI) suposa una tècnica útil per a caracteritzar la morfologia i la vascularitat del tumor. L'ús de mètodes avançats i robustos per a analitzar les imatges de MR recollides en les fases inicials del tractament dels pacients permet la delimitació de les diferents regions dels astrocitomes de grau 4, convertint-se en eines útils per a investigadors, radiòlegs i neurocirugians. A més, el càlcul de biomarcadors vasculars d'imatge, com els proposats en aquesta tesi, facilitaria la caracterització del tumor, l'estimació del pronòstic i els enfocaments de tractament més personalitzats. Aquesta tesi proposa quatre pilars fonamentals per a avançar en el maneig dels astrocitomes de grau 4. Aquests inclouen I) la caracterització multinivell del tumor per a millorar les classificacions dels gliomes d'alt grau del SNC; II) la cerca i desenvolupament de biomarcadors robustos per a estimar el pronòstic dels pacients des del moment prequirúrgic; III) així com per a avaluar la resposta als tractaments i la selecció dels pacients que poden beneficiar-se de teràpies específiques; i IV) el disseny i implementació d'estudis clínics i protocols per a la recollida de dades a llarg termini de cohorts de pacients notables a nivell internacional. Per a abordar aquests quatre pilars, s'ha utilitzat un enfocament interdisciplinari que combina l'anàlisi d'imatges mèdiques, tècniques avançades d'intel·ligència artificial i variables moleculars, histopatològiques i clíniques. En conclusió, hem abordat la influència de l'heterogeneïtat interpacient i intratumoral del astrocitoma de grau 4 per a la caracterització i classificació del tumor, l'estimació del pronòstic del pacient i la predicció de les respostes al tractament. A més, s'han dissenyat i implementat diferents estudis clínics que permeten la recollida de dades multinivell de cohorts internacionals de pacients amb astrocitoma de grau 4.[EN] Brain tumors are one of the most devastating diseases today because of the significant cognitive impairment suffered by patients, high mortality rates, and poor prognosis. Astrocytomas grade 4 bring five-year survival in approximately 5% of diagnosed patients, being the most aggressive and lethal tumors of the Central Nervous System (CNS). Astrocytomas grade 4 continue to be an unresolved complex medical problem. Despite accounting for more than 60% of malignant brain tumors in adults, these tumors have a low relative prevalence and are considered an orphan disease, making difficult developing new drugs or treatments that might benefit patients. The aggressiveness of these tumors is due to different characteristics, such as strong angiogenesis, necrosis, vascular microproliferation, the capacity of the tumor cells to invade and infiltrate, and a particular immune microenvironment. In addition, due to the rapid progression of astrocytomas grade 4, different specific regions coexist in the lesion area which change over time. This complex nature, along with the marked interpatient, intratumor, and longitudinal heterogeneity, makes complicate the success of a single efficient treatment for all patients. Magnetic Resonance Imaging (MRI) represents a useful technique to characterize tumor morphology and vascularity. Using advanced and robust methods to analyze MR images collected from initial stages of patient management allows the delineation of different regions of astrocytomas grade 4, becoming useful tools for researchers, radiologists and neurosurgeons. In addition, the calculation of imaging vascular biomarkers, such as those proposed in this thesis, would facilitate tumor characterization, prognosis estimation and more personalized treatment approaches. This thesis proposes four fundamental pillars to advance the management of astrocytomas grade 4. These include I) the multilevel characterization of the tumor to improve classifications of high-grade CNS gliomas; II) the search and development of robust biomarkers for estimating patient prognosis from the presurgical moment; III) as well as for evaluating the response to treatments and the selection of patients who may benefit from specific therapies; and IV) the design and implementation of clinical studies and protocols for long-term collecting data from internationally remarkable cohorts of patients. To address these four pillars, an interdisciplinary approach has been used that combines medical imaging analysis, advanced artificial intelligence techniques, and molecular, histopathological, and clinical variables. Concluding, we have addressed the influence of both interpatient and intratumor heterogeneity of astrocytoma grade 4 for tumor characterization and classification, patient prognosis estimation and predicting treatment responses. In addition, different clinical studies have been designed and implemented allowing the collection of multilevel data from international cohorts of patients with astrocytoma grade 4.Álvarez Torres, MDM. (2022). Characterization of vascular heterogeneity of astrocytomas grade 4 for supporting patient prognosis estimation, and treatment response assessment [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/18895

Prognostic Significance of Growth Kinetics in Newly Diagnosed Glioblastomas Revealed by Combining Serial Imaging with a Novel Biomathematical Model

Glioblastomas (GBMs) are the most aggressive primary brain tumors characterized by their rapid proliferation and diffuse infiltration of the brain tissue. Survival patterns in patients with GBM have been associated with a number of clinico-pathologic factors, including age and neurological status, yet a significant quantitative link to in vivo growth kinetics of each glioma has remained elusive. Exploiting a recently developed tool for quantifying glioma net proliferation and invasion rates in individual patients using routinely available magnetic resonance images (MRIs), we propose to link these patient-specific kinetic rates of biological aggressiveness to prognostic significance. Using our biologically-based mathematical model for glioma growth and invasion, examination of serial pre-treatment MRIs of 32 GBM patients allowed quantification of these rates for each patient’s tumor. Survival analyses revealed that even when controlling for standard clinical parameters (e.g., age, KPS) these model-defined parameters quantifying biologically aggressiveness (net proliferation and invasion rates) were significantly associated with prognosis. One hypothesis generated was that the ratio of the actual survival time after whatever therapies were employed to the duration of survival predicted (by the model) without any therapy would provide a “Therapeutic Response Index” (TRI) of the overall effectiveness of the therapies. The TRI may provided important information, not otherwise available, as to the effectiveness of the treatments in individual patients. To our knowledge, this is the first report indicating that dynamic insight from routinely obtained pre-treatment imaging may be quantitatively useful in characterizing survival of individual patients with GBM. Such a hybrid tool bridging mathematical modeling and clinical imaging may allow for statifying patients for clinical studies relative to their pretreatment biological aggressiveness

Hypoxic Environment and Paired Hierarchical 3D and 2D Models of Pediatric H3.3-Mutated Gliomas Recreate the Patient Tumor Complexity.

BACKGROUND:Pediatric high-grade gliomas (pHGGs) are facing a very dismal prognosis and representative pre-clinical models are needed for new treatment strategies. Here, we examined the relevance of collecting functional, genomic, and metabolomics data to validate patient-derived models in a hypoxic microenvironment. METHODS:From our biobank of pediatric brain tumor-derived models, we selected 11 pHGGs driven by the histone H3.3K28M mutation. We compared the features of four patient tumors to their paired cell lines and mouse xenografts using NGS (next generation sequencing), aCGH (array comparative genomic hybridization), RNA sequencing, WES (whole exome sequencing), immunocytochemistry, and HRMAS (high resolution magic angle spinning) spectroscopy. We developed a multicellular in vitro model of cell migration to mimic the brain hypoxic microenvironment. The live cell technology Incucyte© was used to assess drug responsiveness in variable oxygen conditions. RESULTS:The concurrent 2D and 3D cultures generated from the same tumor sample exhibited divergent but complementary features, recreating the patient intra-tumor complexity. Genomic and metabolomic data described the metabolic changes during pHGG progression and supported hypoxia as an important key to preserve the tumor metabolism in vitro and cell dissemination present in patients. The neurosphere features preserved tumor development and sensitivity to treatment. CONCLUSION:We proposed a novel multistep work for the development and validation of patient-derived models, considering the immature and differentiated content and the tumor microenvironment of pHGGs