Biophysical signals, biomaterial surface characteristics and hMSC differentiation

生物物理信号、生物材料表面特征和 hMSC 分化

• 批准号: 7847285
• 负责人: Henry J Donahue
• 金额: $ 6.51万
• 依托单位: PENNSYLVANIA STATE UNIV HERSHEY MED CTR
• 依托单位国家: 美国
• 财政年份: 2009
• 资助国家: 美国
• 起止时间: 2009-06-10 至 2012-05-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7847285
• 关键词: Actins; Adhesions; Affect; Age; Aging; Allografting; Animal Model; Atomic Force Microscopy; Autologous Transplantation; Biocompatible; Biocompatible Materials; Bone Regeneration; Bone Tissue; Bone Transplantation; Calcineurin; Calcium; Cell Adhesion; Cell Culture Techniques; Cell Proliferation; Cells; Characteristics; Cytoskeleton; Defect; Disease; Environment; Exposure to; Extracellular Matrix; Focal Adhesion Kinase 1; Genetic Engineering; Goals; Histologic; Human; Human Characteristics; Hydroxyapatites; Immune; Implant; In Vitro; Injury; Integrins; Lead; Mesenchymal Stem Cells; Mitogen-Activated Protein Kinase 3; Molds; Morbidity - disease rate; Mus; Musculoskeletal; Nanotechnology; Nanotopography; Operative Surgical Procedures; Orthopedics; Osteogenesis; Pathology; Pathway interactions; Phenotype; Phospholipase C; Polymers; Polystyrenes; Population; Protocols documentation; Regulation; Signal Pathway; Signal Transduction; Signal Transduction Pathway; Site; Source; Staging; Surface; Therapeutic; Tissue Engineering; Transgenic Animals; adult stem cell; aged; bone; bone loss; electron beam lithography; fluid flow; in vivo; inhibitor/antagonist; insight; nanoscale; novel; novel strategies; novel therapeutic intervention; osteogenic; polybromo; public health relevance; research study; response; scaffold; shear stress; stem cell differentiation; surface coating; tricalcium phosphate; wasting

DESCRIPTION (provided by applicant): The need for bone grafts to repair bone defects is rapidly accelerating as our population ages. Bone defects have been successfully treated using autografts and allografts. However, these are less than ideal approaches since autograft availability is limited and can result in donor-site morbidity while allografts can be immunologically rejected and have the potential to transmit disease. The use of putative human mesenchymal stem cells (hMSC) combined with biocompatible scaffolds has great potential for treating bone defects, which would otherwise be treated with autografts or allografts. Unfortunately, the expansion of hMSC in vitro, which could increase the therapeutic potential of hMSC, reduces their osteogenic potential. The ability to expand hMSC in vitro while maintaining, or even enhancing, their osteogenic potential, could greatly enhance their therapeutic potential. Therefore, the goal of this project is to identify specific biomaterial surface characteristics and biophysical signals that interact synergistically in optimizing hMSC differentiation toward the osteoblastic lineage. Our overall hypothesis is that biomaterial surface characteristics, specifically nanoscale topography, sensitize cells to fluid flow thus increasing the effect of fluid flow on expansion of hMSC while also enhancing the osteogenic potential of hMSC. Using unique fluid flow protocols, novel biomaterial surface characteristics, atomic force microscopy, genetic engineering and transgenic animal models we will identify an environment that optimizes differentiation of hMSC towards the osteoblastic lineage and the signal transduction pathways involved in this mechanism. We will then examine whether these pre-treated hMSC are more osteogenic in vivo than non pre-treated hMSC. We will accomplish this through the completion, over a 5 year period, of 4 aims: Aim 1, Examine the effect of surface topography on adhesion, proliferation and differentiation of hMSC, in the presence and absence of inhibitors of specific signaling pathways; Aim 2, Determine stiffness and mechanosensitivity of hMSC on surfaces with varying nanoscale topographies; Aim 3, Examine the effect of fluid flow, in the presence and absence of inhibitors of the PLC/calcineurin and PLC/ERK signaling pathways, on hMSC proliferation and differentiation; and Aim 4, Examine in vivo osteogenesis of hMSC seeded onto HA/TCP scaffolds. By completing these aims we will not only develop novel strategies for bone tissue engineering but also provide mechanistic insight into the regulation of hMSC proliferation and differentiation. PUBLIC HEALTH RELEVANCE: As the aged population increases the need for novel therapeutic approaches to musculoskeletal pathology will also increase. Tissue engineering exploiting adult stem cells is one such approach. This project will develop novel musculoskeletal tissue engineering protocols combining nanotechnology, adult stem cells and biophysical forces that will lead to strategies to replace bone loss to disease, injury and aging.

描述（由申请人提供）：随着人口老龄化，对骨移植物修复骨缺损的需求正在迅速加速。骨缺损已成功地治疗使用自体移植和同种异体移植。然而，这些都不是理想的方法，因为自体移植物的可用性是有限的，并可能导致供体部位的发病率，而同种异体移植物可以被免疫排斥，并有可能传播疾病。使用假定的人间充质干细胞（hMSC）与生物相容性支架组合具有治疗骨缺损的巨大潜力，否则将用自体移植物或同种异体移植物治疗。不幸的是，hMSC在体外的扩增，这可能会增加hMSC的治疗潜力，降低其成骨潜力。在体外扩增hMSC的同时保持甚至增强其成骨潜力的能力可以极大地增强其治疗潜力。因此，本项目的目标是确定特定的生物材料表面特征和生物物理信号，协同作用，优化hMSC分化成骨细胞谱系。我们的总体假设是，生物材料的表面特征，特别是纳米级形貌，使细胞对流体流动敏感，从而增加了流体流动对hMSC扩增的影响，同时也增强了hMSC的成骨潜力。使用独特的流体流动协议，新的生物材料表面特性，原子力显微镜，基因工程和转基因动物模型，我们将确定一个环境，优化分化的hMSC向成骨细胞谱系和信号转导通路参与这一机制。然后，我们将检查这些预处理的hMSC是否比未预处理的hMSC在体内更具成骨性。我们将通过在5年内完成4个目标来实现这一目标：目标1，在存在和不存在特定信号传导通路抑制剂的情况下，检查表面形貌对hMSC粘附、增殖和分化的影响;目标2，确定hMSC在具有不同纳米级形貌的表面上的刚度和机械敏感性;目的3，检查在存在和不存在PLC/钙调磷酸酶和PLC/ERK信号传导途径的抑制剂的情况下，流体流动对hMSC增殖和分化的影响;以及目的4，检查接种到HA/TCP支架上的hMSC的体内成骨。通过完成这些目标，我们不仅将开发新的策略，骨组织工程，但也提供了机制的洞察hMSC的增殖和分化的调节。公共卫生相关性：随着老年人口的增加，对肌肉骨骼病理学新治疗方法的需求也将增加。利用成体干细胞的组织工程就是这样一种方法。该项目将开发新的肌肉骨骼组织工程方案，结合纳米技术，成人干细胞和生物物理力量，将导致替代疾病，损伤和衰老导致的骨丢失的策略。