Angiogenic Bioengineered Systems to Optimize Post-Infarction Myocardial Recovery

血管生成生物工程系统优化梗死后心肌恢复

• 批准号: 9887268
• 负责人: Y Joseph Woo
• 金额: $ 62.02万
• 依托单位: STANFORD UNIVERSITY
• 依托单位国家: 美国
• 财政年份: 2008
• 资助国家: 美国
• 起止时间: 2008-03-15 至 2024-02-29
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/9887268
• 关键词: 3-Dimensional; Ablation; Affect; Amino Acid Substitution; Animal Experiments; Animal Model; Animals; Arteries; Attenuated; Biocompatible Materials; Biomechanics; Biomedical Engineering; Blood; Blood Vessels; Bypass; CXCR4 Receptors; Cardiac; Cardiac Myocytes; Cardiovascular system; Cause of Death; Cell Hypoxia; Cells; Characteristics; Clinical; Clinical Trials; Coronary Arteriosclerosis; Coronary Artery Bypass; Coronary Vessels; Development; Elements; Encapsulated; Endothelium; Engineering; Funding; Health; Heart; Heart failure; Human; Hydrogels; Impairment; In Vitro; Injury; Knowledge; Mediating; Modality; Modeling; Molecular; Molecular Conformation; Molecular Structure; Myocardial; Myocardial Infarction; Myocardial Ischemia; Myocardial Revascularization; Myocardial perfusion; Myocardial tissue; Natural regeneration; Nutrient; Operative Surgical Procedures; Oxygen; Pathway interactions; Patients; Peptides; Performance; Perfusion; Pharmacologic Substance; Pharmacology; Phase; Population; Pre-Clinical Model; Process; Property; Prunella vulgaris; Receptor Activation; Recovery; Recovery of Function; Research; Science; Signal Pathway; Signal Transduction; Stromal Cell-Derived Factor 1; Stromal Cells; Surgical Models; System; Techniques; Testing; Therapeutic; Therapeutic Effect; Therapeutic Studies; Thinness; Tissue Engineering; Tissues; Transgenic Mice; Translating; Translations; Treatment Efficacy; United States; Ventricular; Ventricular Function; Ventricular Remodeling; Work; analog; angiogenesis; base; biomaterial compatibility; chemokine; clinical efficacy; clinical translation; cytokine; cytokine therapy; design; design and construction; engineered stem cells; experimental study; genetic manipulation; global health; heart function; improved; in vivo; innovation; minimally invasive; mortality; mouse model; myogenesis; novel; novel strategies; overexpression; pre-clinical; preservation; progenitor; reconstruction; repaired; restoration; stem cells; success; targeted treatment; therapeutic angiogenesis; therapeutic target

PROJECT SUMMARY Ischemic heart disease affects over 150 million people worldwide and remains a leading cause of death for mankind. While overall mortality after myocardial infarction has improved, many patients ultimately succumb to heart failure despite pharmacologic, revascularization, and reconstructive therapies due to microvascular perfusion deficits which remain unaddressed. Targeted therapies such as cytokine, stem cell, and tissue- engineering approaches to myocardial revascularization, repair, and regeneration have had varied success, likely due to limitations in mechanistic understanding and suboptimal delivery systems. Thus, novel approaches to microrevascularization are greatly needed. In the recent funding period, we further elucidated the native signaling mechanisms of the angiogenic cytokine stromal cell-derived factor 1 (SDF) with its target, endothelial progenitor stem cells, to better harness its therapeutic effect during post-infarction myocardial repair. Furthermore, we synthesized a supra-efficient engineered SDF analog (ESA) and delivered it via a novel biomaterial for prolonged therapeutic effect. These strategies revealed robust angiogenesis, improved cardiomyocyte survival, preserved myocardial tissue biomechanics, reduced adverse post-injury remodeling, and enhanced cardiac functional recovery. We also designed and constructed a tissue-engineered bilayer cell sheet and demonstrated its ability to improve angiogenesis and ventricular remodeling. Finally, we have translated elements of our work into pre-clinical large animal models to evaluate the potential of these therapies to reach human clinical trials. This renewal application proposes to further define the mechanisms underlying the therapeutic effects of SDF, and to optimize cytokine delivery platforms for large animal and eventual human clinical translation. Aim 1 seeks to delineate SDF/ESA molecular structure to guide synthesis of novel analogs with enhanced efficacy, genetically manipulate SDF signaling to identify therapeutic targeting opportunities, and study the effects of microrevascularization on cellular perfusion, tissue biomechanics, and ventricular function. Aim 2 proposes the development of two innovative bioengineered cytokine delivery platforms for treating myocardial ischemia. One encompasses a novel shear-thinning hydrogel with dual cytokine release modalities and the capacity for percutaneous transcatheter delivery. Another involves fabricating a tissue-engineered SDF-eluting vascular conduit to enable simultaneous macro- and microrevascularization. Aim 3 strives to scale these innovative strategies to large animal pre-clinical models of percutaneous transcatheter therapeutics and minimally invasive coronary artery bypass grafting with synthesized bioconduits. The proposed experiments will yield important knowledge on potential clinical therapies for coronary artery disease, myocardial infarction, and heart failure.

项目总结 缺血性心脏病影响着全球超过1.5亿人，仍然是导致 人类。虽然心肌梗死后的总死亡率有所改善，但许多患者最终死于 尽管进行了药物治疗、血运重建和微血管重建治疗，但仍有心力衰竭 仍未解决的血流灌注缺陷。靶向治疗，如细胞因子、干细胞和组织- 心肌血运重建、修复和再生的工程方法已经取得了各种成功， 很可能是由于机械性理解的局限性和次优的交付系统。因此，新的方法 到微血管重建术是非常必要的。在最近的资助期间，我们进一步阐明了本地化 血管生成细胞因子基质细胞衍生因子1及其靶点内皮细胞信号转导机制 祖细胞干细胞，以更好地利用其在梗死后心肌修复中的治疗效果。 此外，我们合成了一种超高效的工程化SDF类似物(ESA)，并通过一种新颖的 延长疗效的生物材料。这些策略显示了强大的血管生成，改善了 心肌细胞存活，保存心肌组织生物力学，减少损伤后不良重塑， 促进心功能恢复。我们还设计并构建了组织工程化双层细胞。 并证明了其改善血管生成和心室重塑的能力。最后，我们有 将我们的工作内容转化为临床前的大型动物模型，以评估这些疗法的潜力 以达到人体临床试验。 该更新申请建议进一步定义SDF治疗效果的潜在机制， 并优化用于大型动物和最终人类临床翻译的细胞因子传递平台。目标1寻求 描述SDF/ESA的分子结构以指导从基因上合成具有增强疗效的新型类似物 操纵SDF信号以确定治疗靶向机会，并研究 微血管重建术对细胞灌流、组织生物力学和心功能的影响。目标2提出了 用于治疗心肌缺血的两种创新型生物工程细胞因子递送平台的开发。一 包含一种新的剪切变稀水凝胶，具有双重细胞因子释放方式和能力 经皮经导管给药。另一项涉及构建组织工程化SDF洗脱血管 能够同时进行宏观和微观血运重建的管道。Aim 3致力于扩展这些创新 经皮经导管微创治疗大动物临床前模型的策略 人工合成生物管道冠状动脉旁路移植术。拟议中的实验将产生重要的 了解冠心病、心肌梗死和心力衰竭的潜在临床治疗方法。