Collaborative Research: Long Term Spatiotemporal Control to Investigate Dynamics in Xenopus Laevis Embryonic Development

合作研究：长期时空控制研究非洲爪蟾胚胎发育的动态

• 批准号: 1100430
• 负责人: Philip LeDuc
• 金额: $ 33.53万
• 依托单位: Carnegie-Mellon University
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2011
• 资助国家: 美国
• 起止时间: 2011-09-01 至 2015-08-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1100430&HistoricalAwards=false
• 关键词: Collaborative; Research; Long; Term; Spatiotemporal

This collaborative research project will develop a system for investigating embryonic development. Specifically the team will develop a system for controlling the chemical environment of nearly microscopic (~1/20th of an inch) samples of embryonic tissues, such as from the African clawed frog, Xenopus laevis, frequently used by biologists. By controlling the region of the tissue that is exposed to different chemicals, and the time for which it is exposed, the research team can gain unprecedented insight into the embryonic development process. Our system will employ sophisticated independent control of five inlet-ports supplying three different fluidic streams. This system will have a wide range of applications for manipulation of the complex chemical environment of engineered tissues. Deliverables include (1) the development of micro-fluidic systems and control systems capable of regulating complex 2D and 3D flow patterns, (2) a novel control algorithm design methodology for dealing with uncertain dynamics, and (3) fluorescent biosensor tools for evaluating control over the microfluidic environment of embryonic tissues. This project will provide tools for tissue engineers to precisely control chemical stimulation that may be useful for creating new tissues for long term future clinical application. The work will combine techniques that previously have been successfully implemented in microfabrication and automatic control of disk drives. These tools may be used to create complex patterns of chemical stimulation to growing cells for manufacturing of engineered tissues. Dissemination of our results will also lead to new devices with increased accuracies, reliability, and functionality for commercial and basic science applications. In addition, this project will train undergraduate and graduate students to become leaders in science and industry in transdisciplinary fields including dynamic systems/controls, biology, microtechnology, and engineering. The team will also reach out to underrepresented K-12 students in academically challenged neighborhoods to build their knowledge and their interest in STEM.

该合作研究项目将开发一个研究胚胎发育的系统。 具体来说，该团队将开发一种系统，用于控制胚胎组织的近微观（约1/20英寸）样本的化学环境，例如生物学家经常使用的非洲爪蛙（Xenopus laevis）。 通过控制暴露于不同化学物质的组织区域以及暴露时间，研究团队可以对胚胎发育过程获得前所未有的洞察力。我们的系统将采用先进的独立控制的五个入口端口提供三种不同的流体流。 该系统将具有广泛的应用范围，用于操纵工程组织的复杂化学环境。可实现的目标包括：（1）能够调节复杂的2D和3D流动模式的微流体系统和控制系统的开发，（2）用于处理不确定动力学的新型控制算法设计方法，以及（3）用于评估胚胎组织微流体环境控制的荧光生物传感器工具。该项目将为组织工程师提供工具，以精确控制化学刺激，这可能有助于创造新的组织，用于长期的未来临床应用。这项工作将结合联合收割机技术，以前已成功地实施了微型制造和自动控制的磁盘驱动器。这些工具可用于产生对生长细胞的化学刺激的复杂模式，用于制造工程组织。我们的研究结果的传播也将导致新的设备具有更高的准确性，可靠性和商业和基础科学应用的功能。 此外，该项目将培养本科生和研究生成为跨学科领域的科学和工业领导者，包括动态系统/控制，生物学，微技术和工程。该团队还将接触到在学术挑战社区代表性不足的K-12学生，以建立他们的知识和他们对STEM的兴趣。