Biomimetic Materials and Bioprocesses for High-Density Cultures of Pancreatic Islets and Tissues

用于胰岛和组织高密度培养的仿生材料和生物过程

• 批准号: RGPIN-2018-06131
• 负责人: Vermette, Patrick
• 金额: $ 2.84万
• 依托单位: Université de Sherbrooke
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2018
• 资助国家: 加拿大
• 起止时间: 2018-01-01 至 2019-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=667738
• 关键词: Biomimetic; Materials; Bioprocesses; Density; Cultures

3.5 million Canadians live with diabetes, with an associated cost of $ 3.4 billion. Beta-cells (cells producing insulin) lost has been observed in both types 1 and 2 diabetes. Pancreatic islet transplantation can restore functional beta-cells to achieve normoglycemia in type 1 diabetics. Islet transplantation has encountered problems including beta-cell apoptosis. Improving the success of islet transplantation has been a target in the research community. Also, the development of therapeutic to treat diabetes has been identified by pharmaceutical companies to be hindered due to a lack of adequate pancreatic tissue models.*** Tissue engineering methods have been applied to encapsulate and culture pancreatic islets and beta-cells in three-dimensional matrices, and using bioreactors. The aim here is to expose cells/tissues to environments mimicking their native ones, so they can behave more physiologically. Encapsulating pancreatic islets could be a solution to protect transplanted islets from host responses. Development in tissue engineering enables the use of decellularized organs and tissues as scaffolds for cell therapies. However, little is known about the mechanisms governing the effects of decellularized matrices on cells.******The LONG-TERM PROGRAM OBJECTIVE is to develop the automated processes to isolate and culture endocrine pancreatic tissues and cells at high density and to adapt the process to other tissues and organs.***The SPECIFIC OBJECTIVES are:***1) To develop a perfusion bioreactor for organ/tissue decellularization and processes for cell/tissue seeding and culture. This reactor will be used to investigate pancreatic islets and beta-cells survival and function in decellularized organs and tissues under perfusion;***2) To study endocrine pancreatic islets/cells survival and function on biomimetic surfaces produced from decellularized tissues/organs;***3) To characterize the co-culture of endocrine pancreatic islets and cells with pancreatic microvessels under bioreactor perfusion.******SIGNIFICANCE AND NOVELTY: 1) Our biomimetic surfaces provide excellent low-fouling coatings allowing studying specific cell responses by eliminating non-specific ones. 2) Knowledge about how biomimetic scaffolds affect islets can support the development of better encapsulation techniques. 3) Understanding how flow conditions affect islet responses allows identifying how transplanted islets are affected by physiological conditions at an implantation site. Developing an automated process to decellularize organs/tissues will be a step to transfer manually-operated laboratory-scale methods to industrial processes for cell therapy products. 4) Finally, little is known about how to re-establish a functional vasculature in isolated islets. We have been the first to isolate pancreatic microvessels. This program will support training of highly qualified personnel.

350万加拿大人患有糖尿病，相关费用为34亿美元。在1型和2型糖尿病中都观察到β细胞（产生胰岛素的细胞）丢失。胰岛移植可恢复1型糖尿病患者的功能β细胞，达到正常血糖水平。胰岛移植遇到了包括β细胞凋亡在内的问题。提高胰岛移植的成功率一直是研究界的目标。此外，由于缺乏足够的胰腺组织模型，制药公司已经确定了治疗糖尿病的治疗方法的发展受到阻碍。***组织工程方法已被应用于在三维基质和生物反应器中封装和培养胰岛和β细胞。这里的目的是将细胞/组织暴露在模仿其原生环境的环境中，这样它们就能表现得更生理。包裹胰岛可能是保护移植胰岛免受宿主反应的一种解决方案。组织工程的发展使去细胞化的器官和组织成为细胞治疗的支架。然而，关于脱细胞基质对细胞影响的机制知之甚少。******长期计划目标是开发自动化过程，以分离和培养高密度的胰腺内分泌组织和细胞，并使该过程适应其他组织和器官。***具体目标是：***1)开发用于器官/组织脱细胞的灌注生物反应器和用于细胞/组织播种和培养的工艺。该反应器将用于研究胰岛和β细胞在灌注下去细胞化器官和组织中的存活和功能；***2)研究内分泌胰岛/细胞在脱细胞组织/器官仿生表面上的存活和功能；***3)观察生物反应器灌注下胰岛内分泌细胞与胰腺微血管的共培养情况。******意义和新颖性：1)我们的仿生表面提供了优异的低污染涂层，允许通过消除非特异性细胞反应来研究特异性细胞反应。2)了解仿生支架如何影响胰岛可以支持更好的封装技术的发展。3)了解血流条件如何影响胰岛反应，可以确定移植胰岛如何受到植入部位生理条件的影响。开发一种自动化的过程来去除器官/组织的细胞，将是将人工操作的实验室规模方法转移到细胞治疗产品的工业过程的一步。4)最后，关于如何在孤立的胰岛中重建功能性血管系统，我们所知甚少。我们是第一个分离胰腺微血管的。该计划将支持高素质人才的培训。