Global ETD Search

41	Cellular immunotherapy of pancreatic ductal adenocarcinoma: Discovery and evaluation of novel target candidates Schäfer, Daniel 26 March 2021 (has links) No description available. 610
42	Strategies to Improve the Usability and Efficacy of CAR-T cell Therapy in NHL Jackson, Zachary Gene 26 May 2023 (has links) No description available. Biomedical Research Bioinformatics Immunology Oncology CAR CAR-T Automated Manufacturing Single Cell TIGIT NHL Immunotherapy Adoptive cell therapy T cell Checkpoint Blockade ICB
43	Influence of Culture Conditions on Ex Vivo Expansion of T Lymphocytes and Their Function for Therapy: Current Insights and Open Questions Sudarsanam, Harish, Buhmann, Raymund, Henschler, Reinhard 20 October 2023 (has links) Ex vivo expansion of T lymphocytes is a central process in the generation of cellular therapies targeted at tumors and other disease-relevant structures,which currently cannot be reached by established pharmaceuticals. The influence of culture conditions on T cell functions is, however, incompletely understood. In clinical applications of ex vivo expanded T cells, so far, a relatively classical standard cell culture methodology has been established. The expanded cells have been characterized in both preclinical models and clinical studies mainly using a therapeutic endpoint, for example antitumor response and cytotoxic function against cellular targets, whereas the influence of manipulations of T cells ex vivo including transduction and culture expansion has been studied to a much lesser detail, or in many contexts remains unknown. This includes the circulation behavior of expanded T cells after intravenous application, their intracellular metabolism and signal transduction, and their cytoskeletal (re)organization or their adhesion, migration, and subsequent intra-tissue differentiation. This review aims to provide an overview of established T cell expansion methodologies and address unanswered questions relating in vivo interaction of ex vivo expanded T cells for cellular therapy. info:eu-repo/classification/ddc/610 ddc:610
44	Development of more precise and efficient antibodies for cancer targeting : membrane associated form specific anti-mesothelin antibodies and CAR as an example / Développement d'anticorps plus précis et efficaces pour le ciblage du cancer : anticorps et CAR anti-mésothéline spécifiques de la membrane comme exemple. Asgarov, Kamal 13 December 2016 (has links) Utilistions d'anticorps monoclonaux est une partie prometteuse de la thérapie du cancer. À ce jour, il existe plus de 30 anticorps monoclonaux approuvés pour la thérapie contre le cancer. Plus de 350 anticorps se situent également dans différentes phases du développement clinique. La mésothéline est l'une des cibles les plus prometteuses pour l'immunothérapie. La mésothéline est présente à des niveaux relativement faibles dans les cellules mésothéliales de la plèvre, du péritonéum et du péricarde normaux, mais est fortement exprimée dans un certain nombre de cancers différents, y compris les mésothéliomes, le cancer de l'estomac, les carcinomes à cellules squameuses, le cancer de la prostate, le cancer du pancréas, le cancer du poumon et le cancer de l'ovaire. La mésothéline est une glycoprotéine liée au glycosylphosphatidylinositol (GPI) synthétisée sous la forme d'un précurseur de 69 kDa et transformée de façon protéolytique en une forme sécrétée à 30 kDa (anciennement appelée Facteur de potentialisation des mégacaryocytes (MPF)) et une forme liée à la membrane de 40 kDa. Par ailleurs, il peut être clivé par une protéase et peut produire une forme de mésothéline soluble. Il a été déjà montré que cette forme soluble de mésothéline agit comme un ligand et neutralise les anticorps thérapeutiques ciblant la mésothéline. Par conséquent, les anticorps ne pouvaient pas atteindre les cellules cancéreuses et reste inefficaces. Dans notre travail, nous avons décidé de développer un anticorps discriminant spécifique à la forme associée à la membrane pour surmonter l'antagonisme produit par les formes solubles de mésothéline. Pour ce but, nous avons utilisé une nouvelle méthode d'immunisation de souris, que nous avons d'abord toléré la souris avec une mésothéline soluble et ensuite ré-immunisée avec des cellules exprimant la mésothéline. En utilisant la technologie de phage display, nous avons obtenu près de 150 clones de ciblant mésothéline dans 34 familles de VH-CDR3 parmi lesquelles nous avons identifié seulement 2 familles qui se lient à la mésothéline membranaire avec une affinité élevée et ne reconnaissent aucune autre forme soluble de mésothéline. Ici, nous proposons qu'ils puissent être des bons candidats pour être utilisés pour la thérapie contre le cancer de qui permet de passer à travers la barrière de mésothéline soluble. Pour démontrer leur efficacité pour une utilisation thérapeutique, nous avons construit une CAR avec le sc-Fv d'un anticorps discriminant de la forme membranaire. / Antibody based immune treatment is a promising component of cancer therapy. To date there are more than 30 approved monoclonal antibodies for cancer therapy. More than 350 antibodies are also in different phases of clinical development. Mesothelin is one of the most promising targets for immunotherapy. It is present at relatively low levels in mesothelial cells of the pleura, peritoneum and pericardium of healthy individuals, but is highly expressed in a number of different cancers, including mesotheliomas, stomach cancers, squamous cell carcinomas, as well as prostate, pancreatic, lung, and ovarian cancers. Mesothelin is a glycosylphosphatidylinositol (GPI)-linked glycoprotein synthesized as a 69 kDa precursor and proteolytically processed into a 30 kDa NH2-terminal secreted form (formerly referred to as Megakaryocyte Potentiating Factor (MPF)) and a 40 kDa membrane-bound form. Besides that it can be cleaved by a protease leading to the production of a soluble, shedded, form of mesothelin. It has already been shown that this soluble form of mesothelin acts as a ligand and neutralizes the mesothelin targeting therapeutic antibodies. Therefore antibodies could not reach cancer cells and remained inefficient. In our work we decided to develop discriminating antibodies specific to a membrane associated form so as to overcome the antagonism produced by soluble forms of mesothelin. To this aim we used a novel method of mouse immunization, in which we first tolerized the mouse with soluble mesothelin before immunization with mesothelin expressing cells. By using phage display technology we obtained nearly 150 mesothelin recognizing clones in 34 VH-CDR3 families, among which we identified only 2 families that bind membrane mesothelin with high affinity and do not recognize any other soluble form of mesothelin. Here we suggest that this Fab can be effective candidates to be used for mesothelin expressing cancer therapy being allowed to pass through the soluble mesothelin barrier. To show their efficacy for therapeutic use we constructed a CAR with the sc-Fv of a membrane-form discriminating antibody Mésothéline Affichage de phages Tolérance immunitaire Immunisation Cellules T de CAR Anticorps monoclonaux Séquence VH-CDR3 1H7 Mesothelin Phage display Tolerized immunization Immunisation CAR T cells Monoclonal antibodies VH-CDR3 Sequence 1H7 616.9
45	Nový chimérický antigenní receptor (CAR) pro terapii infekce lidským cytomegalovirem (HCMV) / New chimeric antigen receptor (CAR) for therapy of human cytomegalovirus (HCMV) infection Kroutilová, Marie January 2018 (has links) Human cytomegalovirus (HCMV, Herpesviridae) can cause severe complications in the infected individuals undergoing hematopoietic stem cell transplantation. Nowadays, these patients are treated using antivirotics or HCMV-specific T cells derived from the seropositive graft donor. This study explored the possibility of redirecting HCMV-non-specific T cells from a seronegative donor towards HCMV-infected cells via chimeric antigen receptor (CAR), i.e. artificially designed T cell receptor. Viral glycoprotein B (gB) has been selected as a target for this receptor. Published sequence of a single chain variable fragment of a human antibody was used for the design of the CAR against gB (gBCAR). After the verification of production and surface localization in cell lines, gBCAR was being introduced into human T cells via lentiviral vectors. Human fetal lung fibroblasts (LEP) infected with HCMV were used as target cells after the expression of gB at their surface was demonstrated. gBCAR functionality was evaluated by the incubation of modified T cells with infected cells and subsequent analysis of media for IFNγ concentration, which was significantly higher in the setting of gBCAR T cells incubated with HCMV-LEP than in the control incubations. The results obtained show the specificity of gBCAR against...
46	Taking Lessons from CAR-T Cells and Going Beyond: Tailoring Design and Signaling for CAR-NK Cells in Cancer Therapy Ruppel, Katharina Eva, Fricke, Stephan, Köhl, Ulrike, Schmiedel, Dominik 08 June 2023 (has links) Cancer immunotherapies utilize the capabilities of the immune system to efficiently target malignant cells. In recent years, chimeric antigen receptor (CAR) equipped T cells showed promising results against B cell lymphomas. Autologous CAR-T cells require patientspecific manufacturing and thus extensive production facilities, resulting in high priced therapies. Along with potentially severe side effects, these are the major drawbacks of CAR-T cells therapies. Natural Killer (NK) cells pose an alternative for CAR equipped immune cells. Since NK cells can be safely transferred from healthy donors to cancer patients, they present a suitable platform for an allogeneic “off-the-shelf” immunotherapy. However, administration of activated NK cells in cancer therapy has until now shown poor anti-cancer responses, especially in solid tumors. Genetic modifications such as CARs promise to enhance recognition of tumor cells, thereby increasing anti-tumor effects and improving clinical efficacy. Although the cell biology of T and NK cells deviates in many aspects, the development of CAR-NK cells frequently follows within the footsteps of CART cells, meaning that T cell technologies are simply adopted to NK cells. In this review, we underline the unique properties of NK cells and their potential in CAR therapies. First, we summarize the characteristics of NK cell biology with a focus on signaling, a fine-tuned interaction of activating and inhibitory receptors. We then discuss why tailored NK cellspecific CAR designs promise superior efficacy compared to designs developed for T cells. We summarize current findings and developments in the CAR-NK landscape: different CAR formats and modifications to optimize signaling, to target a broader pool of antigens or to increase in vivo persistence. Finally, we address challenges beyond NK cell engineering, including expansion and manufacturing, that need to be addressed to pave the way for CAR-NK therapies from the bench to the clinics. info:eu-repo/classification/ddc/610 ddc:610
47	Improving NK and T Cell Immunotherapies for Hematologic Malignancies Wong, Derek Perseus 26 May 2023 (has links) No description available. Biology Biomedical Research Immunology Medicine Molecular Biology Oncology immunotherapy CAR-T cell therapy BAFF hematologic malignancies B cell cancers mantle cell lymphoma non-Hodgkin lymphoma multiple myeloma acute lymphoblastic leukemia NK cells Cdk5 p35 cytotoxicity TGF-beta immunosuppression
48	The Cells' Journey: A Study On Karolinska's Management Of CAR-T Cells. Henriksson, Joel January 2022 (has links) Karolinska University Hospital's problem regarding the CAR-T cells' journey has been impacting thetreatment of patients and therefore a solution was in dire need to be presented. Visual mappingmethods have been used to review and map the journey with the aim of identifying factors that seemto be impacted. Previous research concerns user journey mapping, mapping methods andcollaboration theories. To carry out the mapping of the cells' journey, semi-structured interviews werecarried out with selected experts within the research area. These experts consisted of the unit managerat the apheresis clinic at Karolinska, a medically responsible researcher at the apheresis clinic atKarolinska and a senior patient operation manager at Bristol Myers Squibb. Their expertise andexperiences were the basis for the visual mapping, and this provided deep insights into the researcharea where the problem has been identified. Lastly, the data was mapped to create a visual map oftheir current management approach regarding CAR-T cell therapy where their experiences around theproblems could be identified. As a result, a solution to the identified factors that expose the cells tothe risks is presented with several visual maps and a proposed solution for a redesign withinKarolinska. Collaboration User Journey Map Visual Mapping Karolinska CAR-T Cell therapy Cancer treatment. Philosophy Filosofi Other Medical Sciences Annan medicin och hälsovetenskap

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