生物医学应用海藻酸钠微球的一代
Summary
在下面的章节中,我们概括为海藻酸钠微球在生物医学应用的准备程序。我们特意说明了创建多层海藻酸钠微球作为潜在的治疗1型糖尿病的细胞和蛋白质封装的双重目的的技术。
Abstract
海藻酸钠基材料已收到相当重视医学领域的应用,由于其亲水性,生物相容性和物理结构。应用范围包括细胞封装,药物输送,干细胞培养,组织工程支架。事实上,目前正在临床试验中的小岛是封装在巴解组织涂层海藻酸钠微球作为I型糖尿病的治疗进行。然而,需要大量的胰岛由于穷人生存以下移植的疗效。局部刺激包裹细胞周围的微血管网络形成的能力,通过改善运输氧气,葡萄糖和其他重要的营养物质,可能会增加其可行性。成纤维细胞生长因子(FGF-1)是一种自然产生的生长因子是能刺激血管形成,改善缺血组织中的氧含量。 FGF-1的疗效SUST交付时,它是在增强ained时尚,而不是单一的大丸的管理。当地长期从胰岛封装系统的生长因子的释放,可以直接刺激血管的生长,对移植的细胞,有可能改善功能移植结果。在这篇文章中,我们概括为海藻酸钠微球在生物医学应用的准备程序。此外,我们描述的方法,我们生成多层海藻酸钠微球的发展。细胞可以被封装在海藻酸钠的内在核心,在血管生成的蛋白质外海藻酸钠层。从这个外层蛋白的释放会直接刺激当地的微血管网络的形成,对胰岛移植。
Protocol
Discussion
海藻酸钠是一种天然,从海藻中提取的酸性多糖和1,4'-β-D-甘露糖醛酸(M)和α-L-古洛糖醛酸(G)的2,3单元组成。简单的凝胶发生时,二价阳离子,如Ca 2 +的Sr 2 +,或BA 2 +形成离子桥相邻海藻酸钠链的G-单体交互。海藻酸钠微球已被用来提供多种蛋白质,其中包括成纤维细胞生长因子(FGF-1),神经生长因子,白血病抑制因子,血管内皮生长因子(VEGF),包括软…
Disclosures
The authors have nothing to disclose.
Acknowledgements
这项研究是由美国退伍军人事务部(华盛顿),补助0852048,0731201,0854430从国家科学基金会(阿灵顿,弗吉尼亚州),并从国家卫生研究院授予RO1的DK080897(马里兰州贝塞斯达的支持) 。康纳先生收到从来自比尔和梅林达·盖茨基金会(西雅图)先生爱德华·罗斯和莫妮卡莫亚博士的慷慨捐赠支持。
Materials
| Name of the reagent | Company | Catalogue number | Comments (optional) |
| Pronova Ultrapure LVG alginate | Nova-Matrix | 4200006 | A variety of alginate formulations are available. The choice of alginate influences the end properties of the microbeads, including size, mechanical properties, and transport. The composition used should be optimized for a given application. |
| Pronova Ultrapure LVM alginate | Nova-Matrix | 4200206 | A variety of alginate formulations are available. The choice of alginate influences the end properties of the microbeads, including size, mechanical properties, and transport. The composition used should be optimized for a given application. |
| Poly-L-ornithine hydrochloride | Sigma-Aldrich | P2533 |
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