Investigación de la Leucemia Mieloide Aguda mediante el desarrollo de modelos in vitro e in vivo

González Romero, Elisa

07 April 2022

[ES] La leucemia mieloide aguda (LMA) se trata de un grupo heterogéneo de desórdenes hematológicos producidos por alteraciones genéticas en las células precursoras mieloides. Las mutaciones en la enzima Isocitrato deshidrogenasa 2 (IDH2) son unas de estas alteraciones. Las mutaciones más frecuentes en esta proteína afectan a las posiciones R140 y R172, provocando una ganancia de función con la producción del oncometabolito D-2-hidroxiglutarato (2-HG). A pesar de que ambas inducen la producción de 2-HG, la mutación R172 produce mayor cantidad de oncometabolito, presenta menos concurrencias con otras alteraciones genéticas y se asocia a una peor respuesta a la quimioterapia y un mayor riesgo de recaída. Los modelos de investigación han permitido conocer el papel de las mutaciones genéticas en el desarrollo de la enfermedad. A pesar de ello, es necesario desarrollar nuevos modelos que expresen de forma endógena estas mutaciones para estudiar en profundidad las vías moleculares afectadas. Por todo ello, en esta Tesis se han desarrollado nuevas estrategias de edición génica mediante el sistema CRISPR/Cas9 con el objetivo de desarrollar nuevos modelos in vitro e in vivo de mutaciones implicadas en LMA. Debido a la baja eficiencia de transfección de los plásmidos CRISPR en las líneas celulares leucémicas, el método más empleado para introducir los elementos CRISPR han sido principalmente vectores lentivirales. Para evitar los inconvenientes de este tipo de vectores, en esta Tesis se ha desarrollado una estrategia alternativa para la introducción de la nucleasa Cas9 y los guías CRISPR. El gen codificante de la Cas9 se introdujo en el genoma de células NB4 mediante transducción con lentivirus, generando una línea celular con expresión constitutiva de la nucleasa. Por otro lado, se desarrolló un sistema sencillo de producción de los guías CRISPR mediante PCR con los elementos esenciales para su expresión y la expresión del reportero GFP de forma opcional. Con el objetivo de optimizar la técnica y probar su eficiencia en distintas dianas se modificaron dos genes implicados en LMA. Estos fueron el gen IDH2, en el cuál se buscó introducir la mutación R172, y el gen MYBL2. Finalmente, las eficiencias de edición obtenidas se compararon con el uso de complejos de ribonucleoproteínas CRISPR, muy utilizados por su alta eficiencia. Mientras que los complejos de ribonucleoproteínas presentaron una mayor eficiencia de corte, la eficiencia de edición de la mutación R172 fue similar en ambas estrategias. Mediante secuenciación masiva se confirmó y caracterizó esta edición y se comprobó que la maquinaria de edición no había producido cortes inespecíficos en regiones similares del genoma. Por tanto, la nueva metodología desarrollada permitió editar de forma precisa líneas celulares leucémicas con eficiencias similares a otras técnicas CRISPR más extendidas y sin producir efectos inespecíficos no deseados. Por otro lado, gracias a la gran conservación evolutiva del gen IDH2, los residuos R140 y R172 se encuentran conservados en la proteína idh-2 de Caenorhabditis elegans. Se empleó la estrategia co-CRISPR para desarrollar y seleccionar cepas mutantes con las mutaciones ortólogas a R140 y R172, y una cepa con ambas mutaciones. A pesar de la conservación, no se observó el aumento del oncometabolito 2-HG esperado en las cepas mutantes en comparación con la cepa salvaje control N2. Un estudio exhaustivo de las vías implicadas nos serviría para desarrollar modelos de investigación con las alteraciones moleculares observadas en los pacientes. Para concluir, la estrategia desarrollada de introducción de elementos CRISPR en líneas celulares, junto a los modelos producidos en C. elegans, permitirán en futuros estudios investigar en detalle los efectos moleculares de mutaciones detectadas en pacientes de LMA, su implicación en el desarrollo y pronóstico de la LMA y comprender su papel en la estratificación de los pacientes. / [CA] La leucèmia mieloide aguda (LMA) es tracta d'un grup heterogeni de desordres hematològics produïts per alteracions genètiques en les cèl·lules precursores mieloides. Les mutacions en l'enzim Isocitrato deshidrogenasa 2 (IDH2) son d'aquestes alteracions. Les mutacions més freqüents en aquesta proteïna afecten a les posicions R1240 i R172, produint un guany de funció amb la producció de l'oncometabolit D-2-hidroxiglutarat (2-HG). A pesar que ambdues indueixen la producció de 2-HG, la mutació R172 produeix mes quantitat de oncometabolit, presenta menys co ocurrències con altres alteracions genètiques i s'associa a una pitjor resposta a la quimioteràpia i un major risc de recaiguda. Els models d'investigació han permés conéixer el paper de les mutacions genètiques en el desenvolupament de la malaltia. Malgrat això, és necessari desenvolupar nous models que expressen de manera endògena aquestes mutacions per a estudiar en profunditat les vies moleculars afectades. Per tot això, en aquesta Tesis s'han desenvolupat noves estratègies d'edició gènica mitjançant el sistema CRISPR/Cas9 amb l'objectiu de desenvolupar nous models in vitro i in vivo de les mutacions implicades en la LMA. Degut a la baixa eficiència de transfecció dels plasmids CRISPR en les línies cel·lulars leucèmiques, el mètode més emprat per a introduir els elements CRISPR han sigut principalment vectors lentivirals. Per a evitar els inconvenients d'aquesta mena de vectors, en aquesta Tesis s'ha desenvolupat una estratègia alternativa per a la introducció de la nucleasa Cas9 i els guies CRISPR. El gen codificant de la Cas9 es va introduir al genoma de cèl·lules NB4 mitjançant transducció amb lentivirus, generant una línia cel·lular amb expressió constitutiva de la nucleasa. D'altra banda, es va desenvolupar un sistema fàcil de producció dels guies CRISPR mitjançant PCR amb els elements essencials d'expressió i amb l'expressió del reporter GFP de manera opcional. Amb l'objectiu d'optimitzar la tècnica i provar la seua eficiència en diferents dianes es van modificar dos gens implicats en LMA. Aquests van ser el gen IDH2, en el qual es va buscar introduir la mutació R172, i el gen MYBL2. Finalment, les eficiències d'edició obtingudes amb la nova estratègia es van comparar amb l'ús de complexos ribonucleotproteïnes CRISPR, molt utilitzats per la seua alta eficiència. Mentre que els complexos de ribonucleoproteïnes van presentar una major eficiència de tall, l'eficiència d'edició de la mutació R172 va ser similar en les dues estratègies. Mitjançant seqüenciació massiva es va confirmar i caracteritzar aquesta edició i es va comprovar que la maquinària d'edició no havia produït talls inespecífics en regions similars del genoma. D'aquesta manera, la nova metodologia desenvolupada permet editar de manera precisa línies cel·lulars leucèmiques amb eficiències similars a altres tècniques CRISPR més esteses i sense produir efectes inespecífics no desitjats. D'altra banda, gràcies a la gran conservació evolutiva del gen IDH2, els residus R140 i R172 es troben conservats en la proteïna idh-2 de Caenorhabditis elegans. Es va utilitzar l'estratègia co-CRISPR per a desenvolupar i seleccionar ceps mutants amb les mutacions ortòlogues a R140 i R172, i un cep amb dues mutacions. Malgrat l'alta conservació, no es va observar l'augment del oncometabolit 2-HG esperat en els ceps mutants en comparació amb el cep salvatge control N2. Un estudi exhaustiu de les vies implicades ens serviria per a desenvolupar models d'investigació amb les alteracions moleculars observades en els pacients. Per a concloure, l'estratègia desenvolupada d'introducció d'elements CRISPR en línies cel·lulars, al costat dels models produïts en C. elegans permetran en estudis futurs investigar detalladament els efectes moleculars de mutacions detectades en pacients, la seua implicació en el desenvolupament i prognosi de la LMA i comprendre el seu paper en l'estratificació dels pacients. / [EN] Acute Myeloid Leukaemia (AML) is a heterogeneous group of haematological disorders caused by genetic alterations in myeloid precursors. Mutations in the Isocitrate dehydrogenase enzyme are among these alterations. The most frequent mutations in this protein affect R140 and R172 positions, leading to a gain of function with the production of the oncometabolite D-2-hydroxyglutarate (2-HG). Although both induce the 2-HG production, the R172 mutation generates greater amount of oncometabolite, has fewer co-occurrences with other genetic alterations and is associated with worse chemotherapy response and higher relapse risk. Research models have made possible to study the role of genetic mutations in disease development. Despite this progress, new models with endogenous expression of these mutations are needed to study in depth the molecular pathways involved. Therefore, in this Thesis we have developed new gene editing strategies using the CRISPR/Cas9 system with the aim of developing new in vitro and in vivo models of mutations involved in AML. Regarding in vitro model, due to the low transfection efficiency of CRISPR plasmids in leukemic cell lines, the most commonly method used for introducing CRISPR elements have been mainly lentiviral vectors. To avoid the disadvantages of this type of vectors, in this Thesis we have developed an alternative strategy for introducing Cas9 nuclease and CRISPR guides. The gene encoding the Cas9 was introduced into NB4 genome by lentiviral transduction producing a stable cell line that constitutively express the nuclease. On the other hand, a simple system for the production of CRISPR guides by PCR with essential elements of expression was developed and with GFP reporter expression optionally. In order to optimise the technique and test its efficiency in different targets, two genes involved in AML were modified. These were IDH2 gene, in which R172 mutation was introduced, and MYBL2 gene. Finally, editing efficiencies obtained with the new strategy were compared with CRISPR ribonucleoproteins methodology, widely used for its high efficiency. Whereas ribonucleoprotein complexes showed higher cut efficiencies, the efficiency of edition of R172 mutation efficiency was similar in both strategies. These results were validated and characterized by means of next generation sequencing, and no off-target effects were found. Therefore, the new developed methodology allows precise gene editing in leukemic cell lines with similar efficiencies with other popular CRISPR techniques and without off-target effects. On the other hand, thanks to the high evolutive conservation of IDH2 gene R140 and R172 residues are conserved in Caenorhabditis elegans idh-2 protein. The co-CRISPR strategy was used to produce and select mutant strains with ortholog mutations to R140, R172 and one strain with both mutations. Despite the high conservation, the expected increase in oncometabolite 2-HG concentration was not detected in mutant strains compared to the N2 wild type strain. A comprehensive study of the pathways involved would help us to develop a research model with molecular alterations noticed in patients. In conclusion, the new developed strategy for CRISPR elements introduction in cell lines, together with C. elegans models, will allow an in-depth research of molecular effect of mutations detected in patients, its implication in AML progression and prognosis and understand their role in patient stratification. / González Romero, E. (2022). Investigación de la Leucemia Mieloide Aguda mediante el desarrollo de modelos in vitro e in vivo [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/181891 / TESIS

Secuenciación masiva

Ribonucleoproteínas

Isocitrato deshidrogenasa 2 (IDH2)

Edición génica

CRISPR/Cas9

Leucemia mieloide aguda

Caenorhabditis elegans

Acute Myeloid Leukaemia (AML)

Gene editing

Isocitrate dehydrogenase 2 (IDH2)

Ribonucleoproteins

Massive sequencing

R-2-hydroxyglutarate modulates DNA Replication via Integrated Stress Response

Sharma, Jyoti

06 1900

Les gènes de l'isocitrate déshydrogénase (IDH) sont mutés dans 70 à 80 % des gliomes de bas grade. Les enzymes mutantes IDH qui en résultent présentent une activité de gain de fonction, produisant du R-2-hydroxyglutarate (R-2-HG), appelé oncométabolite en raison de son accumulation anormale dans les tumeurs et de ses activités oncogéniques potentielles. Parmi les caractéristiques du cancer telles que la reprogrammation métabolique et épigénétique, le stress réplicatif et la stabilité du génome ont été peu caractérisés dans les cancers IDH-mutants. Par conséquent, cette étude vise à étudier l'impact de l'accumulation de R-2-HG sur la réplication de l'ADN et sa contribution au stress réplicatif dans les cancers IDH-mutants. Nous avons étudié la dynamique de la fourche de réplication dans des astrocytes humains normaux et confirmé les résultats dans d'autres lignées cellulaires normales et cancéreuses. Nous avons constaté que le traitement exogène par l'octyl-R-2-HG entravait la progression de la fourche de réplication et retardait par conséquent l'achèvement de la phase S. L'évaluation des niveaux de phosphorylation des protéines RPA, CHK1 et H2AX a révélé que la réponse classique au stress réplicatif (RSR) n'était pas activée. Un état cellulaire dans lequel la réplication de l'ADN est altérée sans activation de la RSR a notamment été décrit dans la littérature comme résultant de l'activation de la réponse au stress intégré (ISR). Cependant, l'activation de la RSI dans les cancers mutants IDH n'est pas bien étudiée. En évaluant les marqueurs d'activation de la RSI, tels que la phosphorylation de l'eIF2α et les niveaux de protéines ATF4, nous avons montré que l'octyl-R-2-HG activait la RSI. De plus, le blocage de l'ISR a partiellement sauvé la fourche de réplication et la progression de la phase S. Nous avons répliqué cette étude oncométrique. Nous avons reproduit ce défaut de réplication de l'ADN lié à l'oncométabolite ainsi que l'effet de sauvetage partiel de l'ISRIB lors de l'induction de la surexpression du gène IDH mutant. Nos résultats indiquent que la production de R-2-HG associée à la mIDH peut inhiber la dynamique normale de réplication de l'ADN via la signalisation ISR. / The isocitrate dehydrogenase (IDH) genes are mutated in 70-80% of low-grade gliomas. The resulting IDH mutant enzymes exhibit gain-of-function activity, producing R-2-hydroxyglutarate (R-2-HG), which is referred to as an oncometabolite due to its abnormal accumulation in tumours and potential oncogenic activities. Among the hallmarks of cancer such as metabolic and epigenetic reprogramming, replicative stress and genome stability have been poorly characterized in IDH-mutant cancer. Therefore, this study aims to investigate the impact of R-2-HG accumulation on DNA replication and its contribution to replicative stress in IDH-mutant cancers. We investigated replication fork dynamics in normal human astrocytes and confirmed the results in other normal and cancer cell lines. We found that exogenous treatment with octyl-R-2-HG impaired replication fork progression and consequently delayed S-phase completion. Assessment of RPA, CHK1 and H2AX protein phosphorylation levels revealed that the classical Replicative Stress Response (RSR) was not activated. Among others, a cell state in which DNA replication was impaired without activation of the RSR has been described in the literature as a result of activation of the Integrated Stress Response (ISR). However, ISR activation in IDH-mutant cancers is not well studied. Hence, by assessing ISR activation markers such as eIF2α phosphorylation and ATF4 protein levels, we showed that octyl-R-2-HG activated ISR. Moreover, blocking ISR partially rescued the replication fork and S-phase progression. We replicated this oncometabolite-related DNA replication defect as well as ISRIB’s partial rescue effect upon induction of mutant IDH gene overexpression. Our results indicate that mIDH-associated R-2-HG production possibly inhibits normal DNA replication dynamics via ISR signalling.

Isocitrate dehydrogenase

IDH mutations

Tumorigenesis

Octyl-R-2-HG

Oncometabolite

DNA replication

Replicative stress

Integrated Stress Response

Astrocytes

Isocitrate déshydrogénase

Tumorigenèse

Réplication de l'ADN

Stress Réplicatif

Réponse Intégrée au Stress

Mutations IDH

Biochemistry / Biochimie (UMI : 0487)

Vliv stresu na NADP-dependentní enzymy ve vyšších rostlinách. / The influence of stress on NADP-dependent enzymes in higher plants.

Kovaľová, Terézia

January 2012

Biotic stress in the form of viral infection, as well as abiotic salt stress, cause leaves injuries, stomata closure and decreased rate of photosynthesis. These factors lead to the limitation of plant growth and to reduced amount of coenzyme NADPH. However NADPH is an important coenzyme for many metabolic pathways such as synthesis of fatty acids, amino acids and secondary metabolites involved in stress responses. NADPH is also a coenzyme for key enzymes of antioxidant system and for many regulatory enzymes. NADP-dependent enzymes are alternative source of NADPH in plants under stress conditions. In this work, activities of four NADP-dependent enzymes: Glucose-6-phosphate dehydrogenase (G6PDH, EC 1.1.1.49), NADP-isocitrate dehydrogenase (NADP-ICDH, EC 1.1.1.42), NADP-malic enzyme (decarboxylating) (NADP-ME, EC 1.1.1.40) and Shikimate dehydrogenase (SDH, EC 1.1.1.25) were studied. Activities of all these enzymes but SDH increased in leaves of tobacco plants (Nicotiana tabacum L.) infected by PVYNTN , The most sensitive enzymes to viral infection were NADP-ICDH and NADP-ME, whose activity was increased in comparison with control plants 3-fold and 2,4-fold, respectively. Changes in activity of studied enzymes were also determined in plants exposed to viral infection in combination with heat-shock...

DEVELOPMENT OF AMBIENT IONIZATION MASS SPECTROMETRY FOR INTRAOPERATIVE CANCER DIAGNOSTICS AND SURGICAL MARGIN ASSESSMENT

Clint M Alfaro (6597242)

15 May 2019

<div> Advancements in cancer treatments have increased rapidly in recent years, but cures remain elusive. Surgical tumor resection is a central treatment for many solid malignancies. Residual tumor at surgical margins leads to tumor recurrence. Novel tools for assessing residual tumor at surgical margins could improve surgical outcomes by helping to maximize the extent of resection. Ambient ionization-mass spectrometry (MS) methods generate and analyze ions from minimally prepared samples in near-real-time (e.g. seconds to minutes). These methods leverage the high sensitivity and specificity of mass spectrometry for analyzing gas phase ions and generating those ions quickly and with minimal sample preparation. Recent work has shown that differential profiles of ions, corresponding to phospholipids and small metabolites, are detected from cancerous and their respective normal tissue with ambient ionization-MS methods. When properly implemented, ambient ionization-MS could be used to assess for tumor at surgical margins and provide a molecular diagnosis during surgery. </div><div><br></div><div>The research herein reports efforts in developing rapid intraoperative ambient ionization-MS methods for the molecular assessment of cancerous tissues. Touch spray (TS) ionization and desorption electrospray ionization (DESI) were utilized to analyze kidney cancer and brain cancer.</div><div><br></div><div> As a demonstration of the applicability of TS-MS to provide diagnostic information from fresh surgical tissues, TS-MS was used to rapidly analyze renal cell carcinoma and healthy renal tissue biopsies obtained from human subjects undergoing nephrectomy surgery. Differential phospholipid profiles were identified using principal component analysis (PCA), and the significant ions were characterized using multiple stages of mass spectrometry and high resolution/exact mass MS. The same TS-MS analyzed renal tissues were subsequently analyzed with DESI-MS imaging to corroborate the TS-MS results, and the significant DESI-MS ions were also characterized with MS.</div><div><br></div><div>Significant efforts were made in developing and evaluating a standalone intraoperative DESI-MS system for analyzing brain tissue biopsies during brain tumor surgery. The intraoperative DESI-MS system consists of a linear trap quadrupole mass spectrometer placed on a custom-machined cart that contains all hardware for operating the mass spectrometer. This instrument was operated in the neurosurgical suites at Indiana University School of Medicine to rapidly analyze brain tissue biopsies obtained from glioma resection surgeries. A DESI-MS library of normal brain tissue and glioma was used to statistically classify the brain tissue biopsies collected in the operating room. Multivariate statistical methodologies were employed to predict the disease state and tumor cell percentage of the samples. A DESI-MS assay for detecting 2-hydroxyglutarate (2HG), the oncometabolic product of the isocitrate dehydrogenase (IDH) mutation (a key glioma prognostic marker), was developed and applied to determine the IDH mutation status during the surgical resection. The strengths, weaknesses, and areas of future work in this field are discussed. </div><div><br></div>

Cancer

Biomarkers

Medical Biochemistry: Lipids

Clinical Chemistry (diagnostics)

Cancer Diagnosis

Analytical Biochemistry

Ambient ionization mass spectrometry

Molecular cancer diagnostics

Tumor infiltration

Isocitrate dehydrogenase mutation

2-hydroxyglutarate

Lipid biomarkers

Molecular pathology

DESI-MSI imaging

N-acetylaspartate

Surgical margin assessment

Intraoperative cancer tissue diagnostics

Glioma markers

Neurological smears

Renal cell carcinoma

Multivariate statistics

Glioblastoma multiforme presenting as postpartum depression: a case report

Petzold, Johannes, Severus, Emanuel, Meyer, Shirin, Bauer, Michael, Daubner, Dirk, Krex, Dietmar, Juratli, Tareq A.

25 February 2019

Background Alterations of mental status are characteristic of psychiatric disorders but may also result from a multitude of organic causes. Generally, physical examination and blood analysis are a part of basic psychiatric differential diagnostics, whereas more sophisticated procedures (for example, brain imaging) are applied only in cases with pathologic diagnostic findings. Our report challenges this approach by describing a case of glioblastoma multiforme presenting as postpartum depression without abnormalities in basic differential diagnostics. Case presentation A 28-year-old white woman who had been in outpatient treatment for postpartum depression was taken to the psychiatric emergency room. The psychopathological assessment, however, showed mild disorientation and severe deficits of long-term memory. Moreover, she complained of stabbing, bilateral headaches, but results of her physical examination and blood analysis were unremarkable. Magnetic resonance imaging of the brain was performed, which showed a contrast-enhanced mass lesion in the left frontal lobe. The patient underwent urgent tumor resection, and histologic results revealed an IDH-mutant glioblastoma multiforme. The patient was discharged with a substantially improved psychopathology and without neurological deficits. Conclusions This report adds to the evidence that postpartum depression may have organic causes in some cases, a fact that needs to be considered in the clinical setting. Atypical neurocognitive findings in a psychiatric interview may alone justify brain imaging, despite normal physical examination and blood analysis results.

info:eu-repo/classification/ddc/610

ddc:610

Ambient Ionization Mass Spectrometry for Intraoperative and High-Throughput Brain Cancer Diagnostics

Hannah Marie Brown (12476919)

29 April 2022

<p>My research has focused on the development and translation of ambient ionization mass spectrometry (MS)-based platforms in clinical and surgical settings, specifically in the area of brain cancer diagnostics and surgical decision making. Ambient ionization MS methods, such as those described herein, generate and analyze gas phase ions with high sensitivity and specificity from minimally prepared samples in near-real-time, on the order of seconds to minutes, rendering them well suited to point-of-care applications. We used ambient ionization MS methods, specifically desorption electrospray ionization mass spectrometry (DESI-MS) and extraction nanoelectrospray ionization mass spectrometry (nESI-MS) to molecularly characterize brain cancer biopsies. The characterization was made using diagnostic compounds identified as markers of disease state, tissue composition, tumor type, and genotype in human brain tissue. Methods were developed and validated offline in the laboratory and translated to clinical and surgical settings, thereby generating chemical information on prognostic features intraoperatively and providing valuable information that would be otherwise unavailable. We believe that, with approval, the methodologies described can assist physicians and improve patient outcomes by providing analytical tools and molecular information that can inform surgical decision making and adjuvant treatment strategies, complementing and not interfering with standard of care protocols.</p> <p><br></p> <p>We have successfully demonstrated the use of desorption electrospray ionization mass spectrometry (DESI-MS) for the expedient molecular assessment of human glioma tissue biopsies based on lipid profiles and prognostic metabolites, both at the tumor core and near surgical margins, in two small-scale, clinical studies. Maximal surgical resection of gliomas that avoids non-infiltrated tissue is associated with survival benefit in patients with glioma. The infiltrative nature of gliomas, as well as their morphological and genetic diversity, renders treatment difficult and demands an integrated imaging and diagnostic approach during surgery to guide clinicians in achieving maximal tumor resection. Further, the estimation of tumor cell percentage (TCP), a measure of tumor infiltration at surgical margins, is not routinely assessed intraoperatively. </p> <p>We have previously shown that rapid, offline molecular assessment of tumor infiltration in tissue biopsies is possible and believe that the same assessment performed intraoperatively in biopsied tissue near surgical margins could improve resection and better inform patient management strategies, including postoperative radiotherapy. Using a DESI-MS spectral library of normal brain tissue and glioma biopsies to generate a statistical model to classify brain tissue biopsies intraoperatively, multivariate statistical approaches were used to predict the disease state and tumor cell percentage (TCP) of each biopsy, thereby providing an measure of tumor infiltration at surgical margins via molecular indicators. In addition to assessment of tumor infiltration, we have developed DESI-MS assays for detecting the oncometabolite 2-Hydroxyglutarate (2HG) to detect isocitrate dehydrogenase (IDH) mutations in gliomas intraoperatively. Knowledge of IDH genotypes at the time of surgical resection could improve patient outcomes, as more aggressive tumor resection of IDH-mutated gliomas is associated with increased survival. While assessments of IDH genotype are typically not available until days after surgery, we have demonstrated the ability to provide this information is less than five minutes. An intraoperative DESI-MS system has successfully been used in a proof-of-concept clinical study and intraoperative performance validation of this platform is ongoing. The findings of these two studies as well as strengths, weaknesses, and areas of improvement for upcoming future iterations of the research are discussed.</p> <p><br></p> <p>Point-of-care applications necessitate the adaptation of MS methodologies to smaller devices. Miniature mass spectrometers (Mini MS) boast small footprints, simple operation, and low power consumption, noise levels, and cost, making them attractive candidates for point-of-care use. In a small-scale clinical study, we demonstrated the first application of a Mini MS for determination of IDH mutation status in gliomas intraoperatively. This study paves a path forward for the application of Mini MS in the OR. With its small footprint and low power consumption and noise level, this application of miniature mass spectrometers represents a simple and cost-effective platform for an important intraoperative measurement. </p> <p><br></p> <p>While MS-based methods of tissue analysis can detect molecular features of interest and rapidly produce large quantities of data, their inherent speed is rarely utilized because they are traditionally coupled with time-consuming separation techniques (e.g., chromatography). Ambient ionization MS, specifically DESI-MS, is well suited for high-throughput applications due to its lack of sample preparation and purification techniques. In an attempt to rapidly characterize microarrays of tissue biopsies, we developed a high-throughput DESI-MS (HT-DESI-MS) method for the rapid characterization of disease state, human brain tumor type, glioma classification, and detection of IDH mutations in tissue microarrays (TMA) of banked and fresh human brain tissue biopsies. We anticipate that HT-DESI-MS analysis of TMAs could become a standard tool for the generation of spectral libraries for sample classification, the identification of biomarkers through large-scale studies, the correlation of molecular features with anatomical features when coupled to digital pathology, and the assessment of drug efficacy. </p>

Cancer

Biomarkers

Medical Biochemistry: Lipids

Clinical Chemistry (diagnostics)

Cancer Diagnosis

Analytical Biochemistry

Intraoperative cancer diagnostics

Molecular pathology

Point-of-care diagnostics

Ambient ionization mass spectrometry

High-throughput mass spectrometry

Desorption electropray ionization

Nanoelectrospray ionization

Brain cancer

Glioma tumors

Meningioma tumors

Pituitary tumors

Isocitrate dehydrogenase mutation

2-Hydroxyglutarate

Tumor infiltration

Surgical margin delineation

Lipid biomarkers