Detalles del proyecto
Descripción
Abstract
This proposal addresses limitations in the delivery of therapies to treat glioblastoma (GBM), a lethal and hard-
to-treat cancer of the brain. We propose regional delivery of chimeric antigen receptor (CAR) T cells for GBM
that bypasses the blood-brain barrier. Failure to sustain the delivery to address T cell exhaustion and proliferation
while considering the GBM-tumor microenvironment (TME) adversely affects therapeutic antitumor efficacy in
both animal models and humans. We develop physiological biomaterial a fibrin-based hydrogel (FBH)
encapsulating CAR-T cells (F-CAR-T) that can afford treatment combinations to close these critical gaps and
lack of knowledge for translation of the CAR-T cell therapy. The MOSAIC Postdoctoral Career Transition Award
proposal demonstrates a resurgence in delivering a cellular therapy approach to treat GBM by understanding
biomaterial and immune mechanisms to improve comprehensive tumor targets. Specific Aims are: 1). Increase
persistence of CAR-T cells and anti-tumor efficacy by co-delivery of cytokines with F-CAR-T in post-resection
GBM model. 2) Determine whether co-delivery of F-CAR-T with TLR 7,8 agonist targeting TAMs can improve
outcomes in partial tumor resection GBM model. 3). Determine whether our innovative F-CAR-T can be additive
when employed in combination with the approved anti-angiogenic drug, Avastin. This study is relevant to the
agency as delivering effective therapies offers fundamental knowledge of relevant approaches to reduce the
GBM burden in humans. Dr. Ogunnaike's career goals are to launch a robust and successful research program
by receiving a tenure-earning faculty position in an academic institution leading multi-disciplinary research to
push the boundaries of biomaterial delivery systems and physiology, from cells to behavior, while mentoring the
next generation of cancer researchers in the field of nanobiotechnology and immune engineering. Her career
development plans are to gain knowledge and skills in the areas of CAR-T cell therapy, GBM TME, drug delivery
and biomaterials. This training is essential for the future studies of advanced delivery and targeted therapy in the
candidate's lab. Dr. Ogunnaike's training will include honing management, technical writing, and effective
research oral communication skills. Her mentors are Dr. Alexander Kabanov, an expert in drug delivery, and Dr.
Gianpietro Dotti, an expert in oncology and CAR-T cell therapy. Her training will be enhanced by collaboration
with Dr. Marina Sokolsky, a director of the Translational Nanoformulations Research with expertise in drug
delivery and gel carriers; Dr. Shawn Hingtgen, an expert in GBM cell therapy and Dr. Timothy Gershon a clinician
scientist both having expertise in GBM animal models. The mentored research will occur within the UNC
Eschelman School of Pharmacy (Dr. Kabanov), UNC School of Medicine (Dr. Dotti), and the UNC Lineberger
Comprehensive Cancer Center where all mentors and collaborates are affiliated.
This proposal addresses limitations in the delivery of therapies to treat glioblastoma (GBM), a lethal and hard-
to-treat cancer of the brain. We propose regional delivery of chimeric antigen receptor (CAR) T cells for GBM
that bypasses the blood-brain barrier. Failure to sustain the delivery to address T cell exhaustion and proliferation
while considering the GBM-tumor microenvironment (TME) adversely affects therapeutic antitumor efficacy in
both animal models and humans. We develop physiological biomaterial a fibrin-based hydrogel (FBH)
encapsulating CAR-T cells (F-CAR-T) that can afford treatment combinations to close these critical gaps and
lack of knowledge for translation of the CAR-T cell therapy. The MOSAIC Postdoctoral Career Transition Award
proposal demonstrates a resurgence in delivering a cellular therapy approach to treat GBM by understanding
biomaterial and immune mechanisms to improve comprehensive tumor targets. Specific Aims are: 1). Increase
persistence of CAR-T cells and anti-tumor efficacy by co-delivery of cytokines with F-CAR-T in post-resection
GBM model. 2) Determine whether co-delivery of F-CAR-T with TLR 7,8 agonist targeting TAMs can improve
outcomes in partial tumor resection GBM model. 3). Determine whether our innovative F-CAR-T can be additive
when employed in combination with the approved anti-angiogenic drug, Avastin. This study is relevant to the
agency as delivering effective therapies offers fundamental knowledge of relevant approaches to reduce the
GBM burden in humans. Dr. Ogunnaike's career goals are to launch a robust and successful research program
by receiving a tenure-earning faculty position in an academic institution leading multi-disciplinary research to
push the boundaries of biomaterial delivery systems and physiology, from cells to behavior, while mentoring the
next generation of cancer researchers in the field of nanobiotechnology and immune engineering. Her career
development plans are to gain knowledge and skills in the areas of CAR-T cell therapy, GBM TME, drug delivery
and biomaterials. This training is essential for the future studies of advanced delivery and targeted therapy in the
candidate's lab. Dr. Ogunnaike's training will include honing management, technical writing, and effective
research oral communication skills. Her mentors are Dr. Alexander Kabanov, an expert in drug delivery, and Dr.
Gianpietro Dotti, an expert in oncology and CAR-T cell therapy. Her training will be enhanced by collaboration
with Dr. Marina Sokolsky, a director of the Translational Nanoformulations Research with expertise in drug
delivery and gel carriers; Dr. Shawn Hingtgen, an expert in GBM cell therapy and Dr. Timothy Gershon a clinician
scientist both having expertise in GBM animal models. The mentored research will occur within the UNC
Eschelman School of Pharmacy (Dr. Kabanov), UNC School of Medicine (Dr. Dotti), and the UNC Lineberger
Comprehensive Cancer Center where all mentors and collaborates are affiliated.
Estado | Finalizado |
---|---|
Fecha de inicio/Fecha fin | 1/9/22 → 31/8/24 |
Enlaces | https://projectreporter.nih.gov/project_info_details.cfm?aid=10690558 |
Financiación
- National Institute of Neurological Disorders and Stroke: USD115,503.00
- National Institute of Neurological Disorders and Stroke: USD115,503.00
!!!ASJC Scopus Subject Areas
- Biotecnología
- Investigación sobre el cáncer
- Inmunología
- Oncología
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