Bioactive Polymers of Effective Islet Delivery System

有效胰岛输送系统的生物活性聚合物

• 批准号: 6895764
• 负责人: You Han Bae
• 金额: $ 22.43万
• 依托单位: UNIVERSITY OF UTAH
• 依托单位国家: 美国
• 财政年份: 2000
• 资助国家: 美国
• 起止时间: 2000-03-01 至 2008-05-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/6895764
• 关键词: BCL2 gene /protein; binding proteins; biomaterial development /preparation; biomaterial evaluation; biotechnology; cell proliferation; chemical conjugate; crosslink; cytokine; cytoprotection; diabetes mellitus therapy; drug delivery systems; gene delivery system; hemoglobin; high performance liquid chromatography; hybrid cells; incretin hormone; insulin; insulin dependent diabetes mellitus; laboratory rat; longevity; oxygen transport; packaging material; pancreatic islet function; pancreatic islet transplantation; polymers; transfection

This proposal is for competing renewal application of R01 DK56884 supported for 4 years. Bioactive polymers have been designed and tested for improved oxygen transport to the encapsulated islets by hemoglobin crosslinked with poly(ethylene glycol) (Hb-C) and for islet stimulation by water-soluble polymer conjugates of sulfonylurea (SU) and glucagon-like peptide-1 (GLP-1). The experimental results demonstrated that the polymers are effective in promoting the functioning and prolonging the life-span of encapsulated islets. In this proposal, the stabilization and expansion of the functionality of the bioactive polymers derived from Hb and GLP-1 intended for a longer duration will be pursued. Tetrameric Hb is prone to oxidation (metHb production), dissociation and denaturation. GLP-1 is also subject to destabilization and denaturation in physiological environment. The central research theme in this aspect will be placed on the stabilization of Hb and GLP-1 based bioactive polymers. For Hb-C, by using intramolecularly crosslinked and/or pyridoxalated Hb and introducing antioxidant enzymes to Hb-C, the stability of Hb-C could be promoted. In addition, the oxygen binding property will be optimized for improved oxygen supply to islets with a detailed mechanistic study of facilitated oxygen transport by directly measuring the profile of oxygen partial _ressure and Hb-C diffusivity in islet capsules. For GLP-1 conjugate, zinc-induced crystallization or precipitation approach will be employed. The precipitate will then be allowed to equilibrate with bioactive soluble GLP-1 conjugates and will be the source of continuous supply of GLP-1 conjugate in islet capsules. A new subject in this research is centered on the construction of effective polymeric gene carriers to pancreatic islets for the transfer of anti-apoptotic Bcl-2 gene. The protection of encapsulated islets from early cytokine assault when transplanted by Bcl-2 expression is an additional critical factor for determining islet survival. This challenge relies on our observation that SU-conjugate was actively internalized into the cells (islets and insulinoma cell line) that express SU receptors. Because the bioactive polymers designed were based on different mechanisms for the same goals of improved islet functionality and prolonged life-span, the combined effects of the bioactive polymers will be evaluated to verify if there is synergistic, summing up or one-component dominant effect.

此提案是针对R01 DK56884的竞争性续期申请，支持4年。生物活性聚合物已被设计和测试，用于通过与聚乙二醇交联的血红蛋白（Hb-C）改善氧输送到被包裹的胰岛，以及通过磺酰脲（SU）和胰高血糖素样肽-1 （GLP-1）的水溶性聚合物偶联物刺激胰岛。实验结果表明，该聚合物能有效地促进被封装胰岛的功能，延长胰岛的寿命。在本提案中，将追求Hb和GLP-1衍生的生物活性聚合物的稳定性和功能扩展，并延长其持续时间。四聚体Hb易于氧化（甲氧基乙），解离和变性。GLP-1也容易失稳和