Development of Functional Polymers and Surfaces as Bioactive Biomaterials

作为生物活性生物材料的功能聚合物和表面的开发

• 批准号: RGPIN-2018-03828
• 负责人: Kizhakkedathu, Jayachandran
• 金额: $ 6.7万
• 依托单位: University of British Columbia
• 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=761960
• 关键词: Development; Functional; Polymers; Surfaces; Bioactive

The advancement in biomaterials has enormous impact on modern medicine. The design and development of novel therapeutics, novel materials for organs and tissue replacement influenced the health of millions of people. Synthetic polymers have played critical roles in the success of many biomedical applications and are widely used in devices, implants, contact lenses, vascular grafts and stents, dental materials and in drug delivery. Easy access to smart and degradable materials is critical to the development of new drug delivery systems and smart devices. Although synthetic materials helped to treat many medical conditions, significant problems exist in terms of their biocompatibility, functionality and biodegradation as most of these materials are not specifically designed for its intended medical use. In this research program, we are addressing these challenges by generating novel polymeric structures and surfaces for biomedical use, and how these new synthetic structures interact with the biological system. The long term objective of my research program is to develop tool kits to address unmet clinical needs utilizing polymer chemistry and polymeric materials.Primary Objectives of this Program are:1. Investigation on branched polyketals and polyglycerols with defined degradation and biocompatibility.2. Development of novel heparin neutralizing agents and heparin sensors.3. Development of novel polymers and surface structures for immunomodulation applications.4. Development of cell-adhesive biomaterials via a novel interaction mechanism.The connecting theme is the development and understanding of advanced polymers for its use as biomaterials and devices. We anticipate that the chemistry and materials proposed here will provide new directions in the design of biodegradable polymers, drug delivery systems and biomedical devices.Training Potential: I am currently training 8 PhD and 4 M.Sc students from the Departments of Chemistry and Pathology. The proposed research is ideal for training students from Chemistry, Engineering and Materials background. Thus I am requesting the support for 3 PhD students and 1 M.Sc student for the next five years to train them in a highly collaborative environment. The proposed projects provide rich training opportunities to understand macromolecular properties, and the interaction of synthetic materials with biological systems.Significance and Impact: There is a worldwide need for novel biodegradable polymers and novel materials for biomedical and device applications. The developed knowledge and technologies in this project will have wide applications in smart devices, drug delivery, implants and tissue- engineering. We anticipate that the described program will generate new directions in polymeric biomaterials, especially development of novel biomaterials and applications related to blood contacting biomaterials.

生物材料的进步对现代医学产生了巨大影响。新型疗法、器官和组织替代新材料的设计和开发影响了数百万人的健康。合成聚合物在许多生物医学应用的成功中发挥了关键作用，并广泛应用于设备、植入物、隐形眼镜、血管移植物和支架、牙科材料以及药物输送。轻松获取智能和可降解材料对于开发新型药物输送系统和智能设备至关重要。尽管合成材料有助于治疗许多医疗状况，但在其生物相容性、功能性和生物降解性方面存在重大问题，因为大多数这些材料并不是专门为其预期医疗用途而设计的。在这个研究项目中，我们通过生成用于生物医学用途的新型聚合物结构和表面以及这些新的合成结构如何与生物系统相互作用来应对这些挑战。我的研究计划的长期目标是开发工具包，利用高分子化学和聚合物材料来解决未满足的临床需求。该计划的主要目标是：1。具有明确降解性和生物相容性的支化聚缩酮和聚甘油的研究。 2．新型肝素中和剂及肝素传感器的研制。 3．开发用于免疫调节应用的新型聚合物和表面结构。4．通过新颖的相互作用机制开发细胞粘附生物材料。连接主题是开发和理解先进聚合物作为生物材料和设备的用途。我们预计这里提出的化学和材料将为可生物降解聚合物、药物输送系统和生物医学设备的设计提供新的方向。 培训潜力：我目前正在培训来自化学和病理学系的 8 名博士生和 4 名硕士生。拟议的研究非常适合培养化学、工程和材料背景的学生。因此，我请求在未来五年内为 3 名博士生和 1 名硕士生提供支持，以便在高度协作的环境中对他们进行培训。拟议的项目提供了丰富的培训机会，以了解大分子特性以及合成材料与生物系统的相互作用。意义和影响：全球范围内都需要用于生物医学和设备应用的新型可生物降解聚合物和新型材料。该项目所开发的知识和技术将在智能设备、药物输送、植入和组织工程领域得到广泛应用。我们预计所描述的计划将产生聚合生物材料的新方向，特别是新型生物材料的开发以及与血液接触生物材料相关的应用。