Nanofabrication and Characterization Platform for Novel NanoBiological Architectures

新型纳米生物结构的纳米制造和表征平台

• 批准号: RGPIN-2018-03947
• 负责人: Stepanova, Maria
• 金额: $ 4.08万
• 依托单位: University of Alberta
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2022
• 资助国家: 加拿大
• 起止时间: 2022-01-01 至 2023-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=752279
• 关键词: Nanofabrication; Characterization; Platform; Novel; NanoBiological

Bioelectronic engineering is a rapidly advancing interdisciplinary field of research and innovation. Novel emerging technologies allowing integrating biological polymers, such as proteins and DNA molecules, with surfaces of solid-state electronic devices are expected to revolutionize biological diagnostics, medical instrumentation, food and water safety testing techniques, as well as green energy harvesting, to name just a few applications. Particularly important, but also challenging, is to fabricate devices that involve nanoscale-sized structures on the device's surface conjugated with biological polymers in such a way that their function could be both directed and monitored. My research at the University of Alberta pursues a development of methods that allow efficiently fabricating, as well as characterizing, novel conjugate architectures interfacing stimuli-responsive polymers with surfaces designed in such a way that they may very efficiently harvest energy from light, and convert this energy in other forms. Such surfaces, also known as plasmonic substrates, involve tiny metallic features with nanoscale dimensions. Due to their ability to convert energy of light in different forms, plasmonic substrates can influence chemical changes in biological materials on their surface. These activities build upon the unique instrumentation infrastructure of the University of Alberta, and also rely strongly on our earlier achievements in several relevant disciplines, including fabrication of surface nanostructures with dimensions down to 10-20 nm, immobilization of biological polymers on such nanostructures, and predicting whether biological molecules would remain stable when required. In this project, we develop and test conjugate architectures with more functionalities than has been available previously. This involves immobilizing biological polymers on plasmonic substrates of carefully optimized size and shape; monitoring the immobilized biopolymers with a highly sensitive spectroscopy technique known as the surface-enhanced Raman scattering (SERS); and combining this with photocatalytic and electrical stimulation. The development and proof-of-concept demonstration of such addressable, conjugate nano-biological architectures while maintaining the biopolymers in their near-native environment, would allow for novel techniques of detecting as well as manipulating surface-immobilized biopolymers. Such capabilities are basic for numerous biolelectronic and bioelectrochemical devices of the future, and our work will provide the community with a powerfully enhanced capacity to develop them.

生物电子工程是一个快速发展的跨学科研究和创新领域。允许将生物聚合物（例如蛋白质和DNA分子）与固态电子装置的表面整合的新兴技术预期将使生物诊断、医疗仪器、食品和水安全测试技术以及绿色能量收集（仅举几个应用）发生革命性变化。特别重要但也具有挑战性的是，制造涉及与生物聚合物结合的器件表面上的纳米级结构的器件，其功能可以被引导和监测。我在阿尔伯塔大学的研究追求的方法，允许有效地制造，以及表征，新的共轭体系结构接口刺激响应聚合物与表面设计的方式，他们可以非常有效地从光中收获能量，并将这种能量转换为其他形式。这样的表面，也被称为等离子体基片，涉及具有纳米尺度的微小金属特征。由于它们能够以不同形式转换光能，等离子体基片可以影响其表面上生物材料的化学变化。这些活动建立在阿尔伯塔大学独特的仪器基础设施之上，也强烈依赖于我们在几个相关学科的早期成就，包括制造尺寸低至10-20 nm的表面纳米结构，将生物聚合物固定在这种纳米结构上，以及预测生物分子是否在需要时保持稳定。在这个项目中，我们开发和测试共轭体系结构，具有比以前更多的功能。这涉及将生物聚合物固定在精心优化尺寸和形状的等离子体基片上;用称为表面增强拉曼散射（Sers）的高灵敏度光谱技术监测固定的生物聚合物;并将其与光催化和电刺激相结合。这种可寻址的共轭纳米生物结构的开发和概念验证演示，同时将生物聚合物保持在其接近天然的环境中，将允许检测和操纵表面固定的生物聚合物的新技术。这种能力是未来许多生物电子和生物电化学设备的基础，我们的工作将为社区提供一个强大的增强能力来开发它们。