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Fluorescent Glucose Sensors from Polyion Microshells

Polyion 微壳荧光葡萄糖传感器

基本信息

批准号：
6665023
负责人：
Mike McShane
金额：
$ 25.92万
依托单位：
LOUISIANA TECH UNIVERSITY
依托单位国家：
美国
项目类别：
财政年份：
2002
资助国家：
美国
起止时间：
2002-09-30 至 2007-08-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/6665023
关键词：
bioengineering /biomedical engineering biomaterial compatibility biosensor device blood glucose enzyme activity fluorescent dye /probe implant laboratory rat medical implant science microcapsule nanotechnology noninvasive diagnosis patient monitoring device technology /technique development

项目摘要

DESCRIPTION (provided by applicant): Non-invasive glucose monitoring is desired to reduce the pain of blood sampling, which is an important step toward improved control of blood glucose for diabetics. Poor control results in debilitating complications, but the bother associated with testing typically leads to low patient compliance with recommended monitoring frequencies. The concept of implantable fluorescent sensors that can be monitored transdermally would be an attractive solution to the problem, but many obstacles to practical use have been identified. This work aims to use polyelectrolyte microcapsules to overcome drawbacks of previously proposed systems. Methods for fabricating these structures have been developed over the past few years, with precision control over mechanical and chemical properties, thus, "tuning" of the structures to fit different applications may be possible. Recent work has produced fundamental knowledge on the properties of these nanostructured capsules, yet there has been little reported by way of practical application. Since biomedical applications have not been pursued, no work has been done to assess the biocompatibility of the materials used. An interdisciplinary research team will evaluate the potential for polyelectrolyte microcapsules to function as carriers for fluorescence sensing chemistry using an integrative approach to sensor design that considers material, chemical, optical, and biological properties. The work will clarify basic questions regarding the process of encapsulation, then use these data to engineer sensor properties that will possess clinically relevant response characteristics. The stability of the structures will be assessed over time in increasingly physiological conditions, and methods to overcome problems with fouling and enzyme degradation will be identified to allow progress to continue. Finally, the biocompatibility of the materials used will be studied from molecule to device level, in vitro and in vivo, to determine baseline host response and risk factors for device failure.

描述（由申请人提供）：需要无创血糖监测来减少采血的痛苦，这是改善糖尿病患者血糖控制的重要一步。控制不良会导致使人衰弱的并发症，但与测试相关的麻烦通常会导致患者对推荐监测频率的依从性较低。可经皮监测的植入式荧光传感器的概念将是解决该问题的一个有吸引力的解决方案，但已发现实际应用中存在许多障碍。这项工作旨在使用聚电解质微胶囊来克服先前提出的系统的缺点。在过去的几年里，制造这些结构的方法已经被开发出来，并且可以精确控制机械和化学性能，因此，“调整”结构以适应不同的应用是可能的。最近的工作已经产生了有关这些纳米结构胶囊特性的基础知识，但实际应用的报道却很少。由于尚未进行生物医学应用，因此尚未开展评估所用材料的生物相容性的工作。一个跨学科研究小组将使用考虑材料、化学、光学和生物特性的综合传感器设计方法，评估聚电解质微胶囊作为荧光传感化学载体的潜力。这项工作将澄清有关封装过程的基本问题，然后使用这些数据来设计具有临床相关响应特性的传感器特性。随着时间的推移，将在日益增加的生理条件下评估结构的稳定性，并将确定克服污垢和酶降解问题的方法，以便继续取得进展。最后，将从分子到设备水平、体外和体内研究所用材料的生物相容性，以确定基线宿主反应和设备故障的风险因素。