Using Block Copolymers to Control Cell Behavior

使用嵌段共聚物控制细胞行为

基本信息

批准号：
7624212
负责人：
SCOTT R SCHRICKER
金额：
$ 13.56万
依托单位：
OHIO STATE UNIVERSITY
依托单位国家：
美国
项目类别：
财政年份：
2005
资助国家：
美国
起止时间：
2005-06-01 至 2010-05-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/7624212
关键词：
Acrylamides Acrylates Adhesions Adsorption Affect Area Attention Behavior Behavior Control Biocompatible Materials Biological Biological Assay Biological Sciences Cell Culture Techniques Cell Differentiation process Cell Line Cell Proliferation Cells Cellular Morphology Cellular biology Chemicals Chemistry Controlled Study Data Development Ethylene Glycols Exhibits Family Fibronectins Free Radicals Future Goals Individual Label Lead Life Measures Mentors Methacrylates Modeling Molecular Conformation Molecular Weight Monoclonal Antibodies Morphology Osteoblasts Pattern Phase Phenotype Play Polymers Proteins Relative (related person)Research Research Personnel Research Project Grants Role Scientist Surface System Techniques Testing Tissue Engineering Tissues Training acrylic acid biocompatible polymer cell behavior copolymer design ethylene glycol extracellular improved in vivo mineralization monomer nanoscale poly(lactic acid)polymerization response scaffold

项目摘要

DESCRIPTION (provided by applicant): The goal of this proposal is to train the principle investigator to become an independent scientist in the field of tissue engineering. The first two years of the proposal will involve didactic training in the area of cell biology and the biological sciences. The next three years will involve executing a mentor guided research project. This project involves studying controlling the cellular response of a pre-osteoblast cell line using block copolymers. Using living or controlled free radical polymerization well-defined block copolymers from the acrylate and methacrylate families of monomer can be readily synthesized. These monomers are known to yield polymers that are biocompatible and used widely in biomaterials. The resulting morphologies from the phase segregated block copolymers can be controlled by the block size and spatial arrangement. It is expected that these morphologies can control the behavior of the cell lines. In most polymer systems, either the morphology or the surface chemistry is varied to control cell response. In the proposed system, both the morphology and surface chemistry will be varied in a controlled fashion and the effect of each on a given cellular response can be determined. This will lead to a better understanding of cell-material interaction and to the design of improved tissue engineering scaffolds. Fibronectin assays will be employed to measure the adhesion and conformation on the polymer surface. Proteins adsorbed to a polymer surface play a large role in regulating the behavior and phenotype of the cell. The adhesion and conformation data is expected to correlate to the cell responses of a MC3T3-E1cell line. Several cell responses will be measured as part of this proposal, cell proliferation and activity, cell morphology and adhesion and cell differentiation. Understanding the interaction of a systematically modulated polymer surface with a cell line will lead to the development of improved scaffold materials.

描述（由申请人提供）：该提案的目的是培训主要研究者，成为组织工程领域的独立科学家。该提案的前两年将涉及细胞生物学和生物科学领域的教学培训。接下来的三年将涉及执行导师指导研究项目。该项目涉及研究使用块共聚物控制骨细胞细胞系的细胞反应。使用来自丙烯酸酯和丙烯酸酯家族的生存或受控的自由基聚合定义明确定义的块共聚物，可以很容易地合成。已知这些单体会产生具有生物相容性并广泛用于生物材料的聚合物。从相隔离的块共聚物中产生的形态可以通过块大小和空间排列来控制。预计这些形态可以控制细胞系的行为。在大多数聚合物系统中，形态或表面化学因素在控制细胞反应方面各不相同。在提出的系统中，形态和表面化学的影响都将以控制的方式变化，并且可以确定每个系统对给定细胞反应的影响。这将使人们更好地了解细胞材料的相互作用以及改进的组织工程支架的设计。纤连蛋白测定将用于测量聚合物表面上的粘附和构象。吸附到聚合物表面的蛋白质在调节细胞的行为和表型中起着重要作用。预计粘附和构象数据与MC3T3-E1CELL线的细胞反应相关。将测量几个细胞反应，作为该建议的一部分，细胞增殖和活性，细胞形态和粘附和细胞分化。了解系统调制的聚合物表面与细胞系的相互作用将导致改进的脚手架材料的发展。