Monolithic triglyceride matrices: a controlled-release system for proteins.

Matrices made of glyceryl trimyristate as a bioerodible and biocompatible material were manufactured by compression in dimensions that would still allow an application via injection. Pyranine, as a low molecular hydrophilic compound with a low detection limit, and tetramethylrhodamine labeled bovine serum albumin (TAMRA-BSA), as a high molecular weight (66 kDa) protein compound, served as model drugs for release investigations. In vitro studies with pyranine revealed that release depends substantially on the gelatin content of the matrices, which proved to be a useful tool as a release modifier. The duration of the drug release period can be adjusted to a desired time interval ranging from days to weeks by choosing the right gelatin content. Moreover, results illustrated the importance of the molecular weight and the nature of the compound to be incorporated into such matrices, since investigations with TAMRA-BSA showed a more pronounced burst release and altered release profiles and periods. Experiments with hyaluronidase, which served as a model enzyme to assess the problem of protein integrity in such matrices, suggested that proteins may display sufficient stability during the manufacturing procedure of the cylinders or while in contact with the triglyceride matrices. In addition to in vitro investigations, a study in mice revealed that after 15 days of subcutaneous implantation the matrices showed a good in vivo stability. The main conclusion that could be drawn from these results was that triglycerides are a promising alternative to biodegradable polymers for the development of parenteral release systems for protein and peptide drugs.

Monolithic glyceryl trimyristate matrices for parenteral drug release applications.

Monolithic lipid matrices were developed that allow parenteral drug release for days, weeks or even months. The cylindrical matrices consist of triglycerides or triglyceride/cholesterol mixtures and allow, due to their small dimensions, an application via injection. Pure triglyceride matrices showed less than 3%, triglyceride matrices containing 70% and more cholesterol less than 10% water uptake over 30 weeks. This swelling behavior would allow the use of such matrices even for sophisticated applications such as interstitial drug delivery to the brain where excessive swelling is highly undesirable. The drug release kinetics were found to depend strongly on the fatty acid chain length of the triglyceride and the cholesterol content of the matrices. Increasing the chain length from C(12) to C(18) allowed an increase in the release of pyranine, a low molecular weight model compound, from approx. 60 days to more than 120 days. Adding cholesterol to glyceryl trimyristate matrices made it possible to adjust the release within a time span varying from days to weeks. While matrices containing 50% cholesterol released pyranine within 8 days, cholesterol contents of 90% allowed a release of the dye for more than 3 weeks.

Efficacy of BCNU and paclitaxel loaded subcutaneous implants in the interstitial chemotherapy of U-87 MG human glioblastoma xenografts.

Nude mice were challenged with human U-87 MG glioblastoma tumors to assess the efficacy of different cytostatics and different application protocols. While the intraperitoneal application of BCNU solutions (3 times 20 mg BCNU/kg) had no effect on tumor growth, the application of polymer matrices made of a physical mixture of poly(1,3-bis[carboxyphenoxpropane]-co-sebacic acid) 20:80 with poly(D,L-lactic-co-glycolic acid) loaded with 0.25 mg BCNU, slowed down the growth of tumors significantly. When the animals were treated with implants carrying 0.25 mg BCNU they responded to the treatment whether the tumor had been inoculated recently (9 days ago) or whether it was fully established (after 20 days). After its sensitivity was proven, the xenograft model was used to further investigate the efficacy of anticancer drugs and some treatment regimens using polymer implants. Thus the tumor model allowed to discriminate between the efficacy of different doses of BCNU. Only implants loaded with 0.75 or 1 mg of BCNU led to a substantial suppression of tumor growth over approximately 2 months. While BCNU was only able to suppress the growth of the tumor, the combination of BCNU with paclitaxel led to a complete remission in some animals. These preliminary results suggest that combinations of cytostatics might improve local chemotherapy of malignant glioma substantially. Based on our data it will be worthwhile to investigate implants that release drugs such as BCNU and paclitaxel closer. Amongst other factors we will try to elucidate the effect of repetitive doses of drugs using programmable implants.

Programmable biodegradable implants.

Pulsatile release implants were developed that release substances up to 58 days post implantation. With a cylindrical size of 2 mm diameter and 1.8 mm height the matrices can carry as much as 1 mg of drug and allow even for intracranial implantation into a rodent model. The matrices are made of materials that have been used for parenteral applications in humans before such as surface eroding polyanhydrides and bulk eroding poly(D,L-lactic acid) or poly(D,L-lactic acid-co-glycolic acid). The onset of drug release is controlled by the degradation of bulk eroding polymers which are known to exhibit a certain stability over a defined period of time and which start eroding after they reach a critical degree of degradation. The time of drug release onset was found to depend on the molecular weight and the chemical state of the carboxylic acid end of the polymer chain. For testing the onset of release in vivo a nude mouse model was developed where the release of Evan's blue could be observed visually after subcutaneous application. By combining individual matrices with different release onset, a therapeutic system can be composed that releases drugs after implantation at predetermined time points in a preprogrammed way. Potential applications for such matrices is vaccination and local tumor therapy.