Comparative biophysics of intermediate filament based materials

中间丝基材料的比较生物物理学

• 批准号: 327352-2011
• 负责人: Fudge, Douglas
• 金额: $ 3.42万
• 依托单位: University of Guelph
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2014
• 资助国家: 加拿大
• 起止时间: 2014-01-01 至 2015-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=549058
• 关键词: Comparative; biophysics; intermediate; filament; based

The work described in this proposal will continue the work in the field of biomaterials and biomimetics that my lab has carried out for the last five years with funding from NSERC. Biomaterials are materials and structures that are made by organisms, and we study them in order to understand how organisms use them for their own purposes, and to gain insights that could help humans produce materials with improved performance and/or environmental sustainability. The research proposed in this application will focus on two materials, hagfish slime and whale baleen. We are interested in hagfish slime in part because of the remarkable fibres that reinforce this unique biomaterial. Hagfish slime is reinforced with tens of thousands of protein threads that resemble spider silks in their dimensions and mechanical properties. They are produced within specialized cells that somehow manufacture a single, continuous thread within their cytoplasm that is about 15 cm long. One aim of this research is to understand how these cells achieve this. We expect that lessons learned from studying thread development in these cells will yield novel insights that will aid in efforts to produce sustainable materials using nanotechnology. We will also investigate the mechanisms by which the mucus component of the slime is deployed when the slime exudate comes in contact with seawater. We expect that this research will reveal the presence of novel ion and water channels in membranes of mucus vesicles, some of which may have value as therapeutic agents. We will also investigate the biomechanics of whale baleen and attempt to understand the process by which this unique keratin material wears away on the edge facing the tongue to form a mat of fibres used to strain prey from seawater in these animals. We will also study the mechanical design of the spacer tissue between baleen plates, which we suspect is a unique type of keratin that is adapted for damping baleen plate oscillations that occur during filter feeding in baleen whales. This research could lead to novel strategies for the design of filtration systems or unique low-resilience, energy-dissipating materials.

这项提案中描述的工作将继续我的实验室在过去五年中在NSERC的资助下在生物材料和仿生领域开展的工作。生物材料是由有机体制造的材料和结构，我们研究它们是为了了解生物体如何将它们用于自己的目的，并获得有助于人类生产性能和/或环境可持续性提高的材料的见解。这项申请中提出的研究将集中在两种材料上，八目鳗泥和鲸鱼须。我们之所以对鳗鱼粘液感兴趣，部分原因是因为这种独特的生物材料中含有增强这种独特生物材料的非凡纤维。鳗鱼粘液由成千上万条在尺寸和机械性能上与蜘蛛丝相似的蛋白线加固。它们是在专门的细胞中产生的，这些细胞以某种方式在细胞质中制造出一根大约15厘米长的单一、连续的丝线。这项研究的目的之一是了解这些细胞是如何做到这一点的。我们预计，从研究这些细胞中的丝线发展中吸取的经验教训将产生新的见解，这将有助于利用纳米技术生产可持续材料。我们还将研究当粘液渗出物与海水接触时粘液成分被展开的机制。我们预计这项研究将揭示粘液泡膜上存在新的离子和水通道，其中一些可能具有治疗价值。我们还将研究鲸须的生物力学，并试图了解这种独特的角蛋白材料在面对舌头的边缘磨损的过程，以形成一层纤维垫，用于从这些动物的海水中过滤猎物。我们还将研究须板之间的间隔物组织的机械设计，我们怀疑这是一种独特的角蛋白类型，适用于抑制须鲸过滤进食期间发生的须板振荡。这项研究可能会为过滤系统或独特的低弹性、能量消耗材料的设计带来新的策略。