Intracranial drug-delivery scaffolds: biocompatibility evaluation of sucrose acetate isobutyrate gels.

INTRODUCTION: Sucrose acetate isobutyrate (SAIB) is a water insoluble, biodegradable gel used for controlled-release oral and subcutaneous drug delivery. We investigated SAIB compatibility in the rat central nervous system (CNS) by implanting solutions of SAIB in adult and in neonatal brains. METHODS: 10-15 microL solutions of SAIB gels in 0-30% ethanol were injected into the cerebral cortex of adult Fischer 344 rats. Control animals were implanted with a 10 mg biodegradable poly anhydride copolymer of poly [bis (p-carboxyphenoxy) propane] anhydride and sebacic acid (PCPP:SA). Adult rats were evaluated for signs of pain and distress, including changes in posture, facial signs, and grooming behavior. 1-2 microL solutions of SAIB gels in 15% ethanol were injected into brains of 12-24 h-old rats. Neonatal rats were evaluated for survival. Adult and neonatal brains were examined by histopathology 3-48 days after implant. RESULTS: Gel implants produced elliptical compression of cortical tissue, cell loss, and inflammation. Cell loss appeared to be confined to the implantation wound and associated neuronal fields. In adult rats, neurophil compression, inflammation, and cell loss appeared similar with the 10-mg PCPP:SA implants and the 10-mg SAIB implants. There was no clinical evidence of pain or distress from SAIB implants. 1-2 microL implants of SAIB-15% ethanol had no effect on survival of neonatal animals. CONCLUSION: Brain implants of SAIB induce a mild to moderate inflammatory response and associated neuronal cell damage. The implants appeared to be biocompatible in adult and neonatal animals. These results suggest that further studies of SAIB as an injectable drug-delivery scaffold for CNS therapeutic agents are warranted.

A surgical technique for safely placing a drug delivery catheter into the pons of primates: preliminary results of carboplatin infusion.

OBJECTIVE: We sought to develop a neurosurgical procedure to access the pons with a drug delivery device for chronic therapy and collect preliminary data on the toxicity of direct infusions of carboplatin in primates. METHODS: We made midline incisions on five cynomolgus monkeys, identified the inion, made a burr hole 2.5 cm below the inion, and inserted a catheter through the cerebellum into the roof of the pons. Pumps that infused saline for 90 days or carboplatin solutions for 30 to 35 days at 10 microl/d were placed subcutaneously in the low cervical/high thoracic region. Monkeys were assessed by computed tomography and magnetic resonance imaging, laboratory studies, daily neurological observation, postmortem examinations, and histopathology. RESULTS: Monkeys infused with saline and 82 microg of carboplatin remained neurologically intact throughout the infusion periods. Serial imaging showed that the catheter tip was in the pons and revealed no evidence of hemorrhage, edema, or migration. Two monkeys infused with up to 850 microg of carboplatin showed hyperintense magnetic resonance imaging signals at Days 15 and 18 and neurological deficits at approximately Week 3. Platinum levels greater than 10 ng/mg tissue were detected over a distance of 1 cm in tissue slices. Histopathology demonstrated significant tissue necrosis around the tip of the catheter. CONCLUSION: The pons of monkeys is safely accessed with a catheter for drug delivery by using a posterior midline approach. Clinical observations, radiographic imaging, and laboratory tests of animals infused with saline for 3 months or 0.26 mg/ml of carboplatin for 1 month were unremarkable. Neurotoxicity was seen with dose levels of 2.6 mg/ml of drug for 1 month. This procedure offers opportunities for examining the toxicity of brainstem antitumor therapy in primates.