Toward Tissue Engineering of the Knee Meniscus

膝关节半月板组织工程

• 批准号: 6827416
• 负责人: Kyriacos A Athanasiou
• 金额: $ 27.27万
• 依托单位: RICE UNIVERSITY
• 依托单位国家: 美国
• 财政年份: 2002
• 资助国家: 美国
• 起止时间: 2002-12-10 至 2007-11-30
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/6827416
• 关键词: Toward; Tissue; Engineering; Knee; Meniscus

EXCEED THE SPACE PROVIDED. The application's long-term objective is to use a cogent and comprehensive tissue engineering approach to successfully address meniscus regeneration, which remains one of the most elusive problems in musculoskeletal medicine. The study's main hypothesis is that the meniscus can be regenerated by a series of steps that involve the use of a scaffold with bioactive agents, cells, a bioreactor, mechanical stimuli, and an animal model. To test this hypothesis, we propose the following specific aims: 1) To design, fabricate, and characterize meniscus-specific biodegradable scaffolds. 2) To engineer the meniscus. 3) To test the meniscus in an animal model. The methodology involves an analysis and a synthesis phase: In the analysis phase, topographical and spatial properties of the meniscus will be identified using biomechanics, biochemistry, ultrastructural methods, and cell culture. The objective is to define 'gold standard' properties against which the properties of the regenerated meniscus will be compared. In the synthesis phase, fibrochondrocytes will be seeded onto meniscus-specific scaffolds and exposed to mechanical forces. The scaffolds, made of poly(propylene fumarate-co-ethylene glycol), are designed to be bioabsorbable, biocompatible, have mechanical integrity, allow for directed attachment of cells through the use of the GRGD peptide, and provide biosynthetic signals through the use of a growth factor. A hydrodynamic focusing bioreactor, operating in a low-shear environment, will then be used to enhance nutrient transport and to modulate mechanical signals. Furthermore, the effects of hydrostatic pressure and direct compression/tension will also be examined using custom-made instruments. At various time points, the properties of the engineered constructs will be quantified and compared to native tissue properties. The tissue engineered constructs will then be implanted in rabbits to evaluate the in vivo functional characteristics of the new meniscus. The clinical significance of the approach described in this proposal is enormous, since meniscal problems continue to be some of the most vexing in orthopaedics. PERFORMANCE SITE ========================================Section End===========================================

超出所提供的空间。该应用的长期目标是使用令人信服且全面的组织工程方法来成功解决半月板再生问题，这仍然是肌肉骨骼医学中最难以捉摸的问题之一。该研究的主要假设是，半月板可以通过一系列步骤再生，包括使用含有生物活性剂的支架、细胞、生物反应器、机械刺激和动物模型。为了检验这一假设，我们提出以下具体目标：1）设计、制造和表征半月板特异性可生物降解支架。 2) 设计弯液面。 3) 在动物模型中测试半月板。该方法涉及分析和合成阶段：在分析阶段，将使用生物力学、生物化学、超微结构方法和细胞培养来识别半月板的地形和空间特性。目的是定义“黄金标准”特性，并与再生弯液面的特性进行比较。在合成阶段，纤维软骨细胞将被接种到半月板特异性支架上并暴露于机械力。该支架由聚（富马酸丙烯酯-乙二醇）制成，具有生物可吸收性、生物相容性、机械完整性，允许通过使用 GRGD 肽直接附着细胞，并通过使用生长因子提供生物合成信号。然后，在低剪切环境下运行的水动力聚焦生物反应器将用于增强营养物运输并调节机械信号。此外，还将使用定制仪器检查静水压力和直接压缩/拉伸的影响。在不同的时间点，工程构建体的特性将被量化并与天然组织特性进行比较。然后将组织工程构建体植入兔子体内，以评估新半月板的体内功能特征。该提案中描述的方法具有巨大的临床意义，因为半月板问题仍然是骨科中最令人烦恼的问题之一。表演网站==========================================章节结束===============================================