The first objective of this program is to define single agents and combinations of agents which are highly active in vitro against human gliomas, and which have appropriate properties for use in the polymer release system. Agents to be evaluated include chemotherapeutic drugs, differentiating agents, exotoxins, and anti-glioma antibodies. Agents and combinations which are active in vitro will be evaluated for activity against an established tumor in vivo after release from biodegradable polymers in a flank glioma xenograft system. in this system the agent or combination of agents, incorporated into a polymer disk, will be place in direct apposition to the established glioma xenograft. Those compounds and combinations which are active in vivo will be studied in Program l for neurotoxicity after polymer release in the brain, and for activity against intracranially established rat and human gliomas in a rat model. The second objective of this program is to work with Program 3 to develop approaches to increasing the diffusion distance of agents in the brain, after intracranial release from polymers. Previous work in Program 3 established that macromolecules diffuse much further in the brain than low molecular weight compounds. Therefore, a major component of the work will be the further development, with Program 3, of the concept of agents bound to macromolecules through labile bonds, such that the agents are released over time and space as the macromolecules diffuse through the brain. A third objective is to evaluate the potential of drug containing microspheres for direct implantation in tumors, for release from polymers adjacent to tumors, and for intrathecal administration for the treatment of intrathecal tumor. Finally, this program will provide chemical support to the other programs of this NCDDC by synthesizing radiolabeled agents for diffusion and pharmacokinetic studies.

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Research Program--Cooperative Agreements (U19)
Project #
5U19CA052857-10
Application #
6395690
Study Section
Project Start
1999-07-26
Project End
2000-08-31
Budget Start
Budget End
Support Year
10
Fiscal Year
1999
Total Cost
Indirect Cost
Name
Johns Hopkins University
Department
Type
DUNS #
045911138
City
Baltimore
State
MD
Country
United States
Zip Code
21218
Gabikian, Patrik; Tyler, Betty M; Zhang, Irma et al. (2014) Radiosensitization of malignant gliomas following intracranial delivery of paclitaxel biodegradable polymer microspheres. J Neurosurg 120:1078-85
Tyler, Betty; Wadsworth, Scott; Recinos, Violette et al. (2011) Local delivery of rapamycin: a toxicity and efficacy study in an experimental malignant glioma model in rats. Neuro Oncol 13:700-9
Slager, Joram; Tyler, Betty; Shikanov, Ariella et al. (2009) Local controlled delivery of anti-neoplastic RNAse to the brain. Pharm Res 26:1838-46
Sampath, Prakash; Rhines, Laurence D; DiMeco, Francesco et al. (2006) Interstitial docetaxel (taxotere), carmustine and combined interstitial therapy: a novel treatment for experimental malignant glioma. J Neurooncol 80:9-17
Legnani, Federico G; Pradilla, Gustavo; Thai, Quoc-Anh et al. (2006) Lactacystin exhibits potent anti-tumor activity in an animal model of malignant glioma when administered via controlled-release polymers. J Neurooncol 77:225-32
Pradilla, Gustavo; Wang, Paul P; Gabikian, Patrik et al. (2006) Local intracerebral administration of Paclitaxel with the paclimer delivery system: toxicity study in a canine model. J Neurooncol 76:131-8
Li, Yawen; Ho Duc, Hong Linh; Tyler, Betty et al. (2005) In vivo delivery of BCNU from a MEMS device to a tumor model. J Control Release 106:138-45
Sorg, Brian S; Peltz, Cathryn D; Klitzman, Bruce et al. (2005) Method for improved accuracy in endogenous urea recovery marker calibrations for microdialysis in tumors. J Pharmacol Toxicol Methods 52:341-9
Li, Yawen; Shawgo, Rebecca S; Tyler, Betty et al. (2004) In vivo release from a drug delivery MEMS device. J Control Release 100:211-9
Grossi, Peter M; Ochiai, Hidenobu; Archer, Gary E et al. (2003) Efficacy of intracerebral microinfusion of trastuzumab in an athymic rat model of intracerebral metastatic breast cancer. Clin Cancer Res 9:5514-20

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