Opening of the blood-brain barrier to antitumor agents
Oregon Health & Science University, Portland OR
Investigators
Linked publications & trials
Abstract
DESCRIPTION (provided by applicant): The overall hypothesis guiding the OHSU Blood-Brain Barrier (BBB) Program for the past three decades has been that the BBB and blood-tumor barrier, as well as the blood-cerebral spinal fluid (CSF) barrier, limit agent delivery and therefore dose intensity in brain tumors. We have tested the hypothesis that increased dose intensity may be achieved by increasing drug delivery to brain tumor with osmotic BBB disruption (BBBD). Another approach to increasing dose intensity is to deplete glutathione, an endogenous anti-oxidant which inactivates alkylating chemotherapeutics. Since dose intensification can increase chemotherapy toxic side effects, we will use thiols that mimic the activity of glutathione, including sodium thiosulfate and N- acetylcysteine, to reduce chemotherapy toxicities, as we have during the last 8 years of this Javits Award. In Specific Aim 1 of this revised proposal, we will assess the potential for enhancing chemotherapy dose intensity for intracerebral medulloblastoma as a model of primitive neuroectodermal tumors within brain parenchyma, by using BBBD and by depleting glutathione stores in conjunctions with thiol rescue. Additionally we will evaluate new imaging techniques for assessing efficacy in solid brain tumors. These studies will test the hypothesis that lowering glutathione concentrations will safely improve alkylating chemotherapy efficacy. Specific Aim 2 will utilize the chemo-enhancement and protection strategies of Aim 1 to improve alkylating chemotherapy efficacy against disseminated medulloblastoma in the leptomeninges and CSF, and will use novel imaging techniques to monitor hydrocephalus and chemotherapy efficacy. Specific Aim 3 will evaluate thiol chemoprotection for models of platinum-induced ototoxicity. We hypothesize that thiol chemoprotection separated from chemotherapy by timing, route of administration, and utilizing the neurovascular barriers, will allow increased chemotherapy doses while reducing chemotherapy toxicity in normal tissues. Specific Aim 4 will translate the chemoprotection and enhanced delivery into a Phase I/II clinical trial in CNS embryonal tumors. Our overall hypothesis is that by modulating the timing and route of administration of chemo-enhancers, chemotherapy, and chemoprotection, toxicity at the blood-neural barriers can be decreased while increasing anti-tumor efficacy.
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