Mechanisms for treating ischemic wounds with human adipocyte derived stem cell exosomes

人脂肪细胞来源的干细胞外泌体治疗缺血性伤口的机制

基本信息

批准号：
9898296
负责人：
DENISE Ratzlaff COOPER
金额：
--
依托单位：
JAMES A. HALEY VA MEDICAL CENTER
依托单位国家：
美国
项目类别：
财政年份：
2017
资助国家：
美国
起止时间：
2017-04-01 至 2022-03-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/9898296
关键词：
Accident and Emergency department Address Adipocytes Adipose tissue Adult Aging Arginine Binding Biological Biological Assay Burn injury CRISPR/Cas technology Cell Cycle Cell physiology Cells Ceramides Chronically Ill Clinical Collagen Collection Deposition Dermal Diabetes Mellitus Endocytosis Pathway Engineering Environment Face Fibroblasts Freezing Gene Expression Genes Goals Home environment Homeostasis Hospitals Human Hypoxia Impaired wound healing In Vitro Inflammation Inflammatory Response Injury Innovative Therapy Knock-out Lipids Liver MALAT1 gene Mediating Mediator of activation protein Methods MicroRNAs Modeling Nuclear Ontology Patients Phagocytosis Population Populations at Risk Porifera Preparation Proteins Proteomics RNA Rattus Regenerative Medicine Research Rodent Model Role Serine Site Soldier Source Spinal cord injury Standardization Stem Cell Factor Stem Cell Research Supporting Cell Testing Therapeutic Time Topical application Traumatic injury Untranslated RNA Veterans Work Wound models acrosome stabilizing factor angiogenesis bone cell motility chronic ulcer chronic wound cohort cold temperature derepression diabetic patient exosome experience extracellular healing immunoregulation improved in vitro Assay in vivo inhibitor/antagonist injury and repair intercellular communication interest migration nanovesicle novel therapeutics older patient overexpression paracrine pre-clinical programs protein expression regenerative relating to nervous system repaired skin wound stem cells tissue regeneration transcriptome sequencing uptake wound wound bed wound care wound closure wound healing

项目摘要

This research will develop an innovative therapy to promote tissue regeneration and reverse the consequences of recalcitrant wound healing. It is particularly relevant to our Veteran population that suffers the consequences of injury and aging. The $5 billion global market for “advanced wound care” is anticipated to triple in the next ten years. We have a rapidly growing cohort of older veterans with diabetes, a new cohort of wounded warriors with injuries that include non-healing ulcers from spinal cord injury, multiple traumatic injuries and burns. Hence Veteran populations are at risk for a staggering number of chronic wounds. We propose to use a secreted nanovesicle from adipose derived stem cells (human ADSC). Adipose tissue is an abundant and renewable source of stem cells. Human ADSC release trophic factors that stimulate endogenous repair mechanisms in wounds, and they have immunomodulatory effects, responding to the microenvironment. They have been shown to heal wounds. However, hADSC research is flawed by the lack of standardization and delivery methods. Our goal is to harness the promise of stem cell regenerative secreted factors to heal wounds. We have identified a wound healing treatment using conditioned media (CM) collected from hADSC in culture. We recognize that CM contains exosomes secreted by hADSC, and the factors within the exosomes act in a paracrine manner. In addition to lipids and proteins, exosomes contain various species of RNA. One type, long non- coding RNA, is of particular interest in that it is only secreted by stem cells. Once cells start to differentiate to lineages such as bone and adipocytes, it is retained for a nuclear function. The secreted long non-coding RNA that we find in exosomes is MALAT1. It functions in wound healing, and we predict that exosomes rich in MALAT1 will be able to heal a variety of wounds. We hypothesize that MALAT probably derepresses genes for migration, proliferation, and angiogenesis via its interaction with microRNAs. We will examine how exosomes function in vitro in a human dermal fibroblast wound healing assay. We will use a rat ischemic wound model for examining how exosomes function in vivo. Both of these models will let us optimize the number and concentrations of exosomes that allow for wound closure and modulation of angiogenesis. We propose improvements to hADSC that will allow for collection of more exosomes. Exosomes are more stable than stem cells for wound applications. They can be stored in low temperatures, applied topically and be made available to wounds in emergency rooms and for home use. This project is the first step in making hADSC exosomes a clinical reality for wound repair and tissue regeneration.

这项研究将开发一种创新疗法来促进组织再生并逆转伤口难以愈合的后果与我们的退伍军人群体尤其相关。 50 亿美元的全球“先进市场”正遭受着受伤和衰老的后果。预计未来十年，“伤口护理”的数量将增加两倍。我们的老年人群体正在迅速增长。患有糖尿病的退伍军人，这是一群新的受伤战士，他们的伤势包括无法治愈脊髓损伤、多处外伤和烧伤引起的溃疡。面临数量惊人的慢性伤口的风险，我们建议使用分泌的纳米囊泡。来自脂肪干细胞（人类 ADSC）的脂肪组织是丰富且可再生的。人类 ADSC 释放刺激内源修复的营养因子。伤口机制，并且它们具有免疫调节作用，对然而，hADSC 研究存在缺陷。由于缺乏标准化和交付方法，我们的目标是利用干的承诺。细胞再生分泌因子来治愈伤口我们已经确定了一种伤口愈合治疗方法。使用从培养物中的 hADSC 收集的条件培养基 (CM) 我们认识到 CM 含有。外泌体由 hADSC 分泌，外泌体内的因子以旁分泌方式发挥作用。除了脂质和蛋白质外，外泌体还含有多种类型的RNA，长非。编码RNA的蛋白质特别令人感兴趣，因为它仅在细胞开始分泌时才被分泌。分化为骨细胞和脂肪细胞等谱系，保留核功能。我们在外泌体中发现的分泌性长非编码RNA是MALAT1，它在伤口中发挥作用。我们预测富含 MALAT1 的外泌体将能够治愈各种伤口。我们寻找 MALAT 可能去抑制迁移、增殖和我们将研究外泌体如何在体外发挥作用。我们将使用大鼠缺血性伤口模型进行人真皮成纤维细胞伤口愈合测定。检查外泌体在体内的功能将让我们优化数量。以及允许伤口闭合和调节血管生成的外泌体浓度。对 hADSC 的改进将允许收集更多的外泌体。它们比伤口应用中的干细胞更稳定，可以在低温下保存，局部使用，可用于急诊室和家庭的伤口。该项目是使 hADSC 外泌体成为伤口修复和组织临床现实的第一步再生。