3D NICHE ENGINEERING FOR REGULATION OF STEM CELL FATE DECISIONS

调控干细胞命运决定的 3D 利基工程

• 批准号: RGPIN-2019-06349
• 负责人: Sachlos, Eleftherios
• 金额: $ 2.04万
• 依托单位: York University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2021
• 资助国家: 加拿大
• 起止时间: 2021-01-01 至 2022-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=738859
• 关键词: 3D; NICHE; ENGINEERING; REGULATION; STEM

Bone marrow houses hematopoietic stem cells (HSC) that are responsible for continuously regenerating blood tissue throughout one's lifetime. Bone marrow transplants, also called HSC transplants (HSCT), are life-saving procedures used to treat leukemia patients and more recently, autoimmune diseases like multiple sclerosis, which can lead to durable disease-free remission. However, HSCT are plagued by limited supply, tissue mismatching complications and high mortality rates (up to 10% of patients do not survive the transplant). Many more patients could benefit from safer HSCT if the number of HSC in each donor sample could be augmented. For this advancement to be engineered a more detailed understanding of the interplay between HSC and their native 3D bone marrow environment, or niche, is required. When removed from their native bone marrow niche and placed in culture, HSC and progenitor (HSPC) cells very quickly lose their stem cell function  (24-72h). Mounting evidence suggests that the bone marrow extracellular matrix (ECM) is a critical, yet underappreciated, component of the niche that may be instructive to stem cell regulation. In order for HSPCs to be expanded ex vivo, culture conditions that recapitulate the native ECM environment need to be developed. This program aims to develop technology that discovers ex vivo stem cell niche conditions and apply this knowledge to elucidate stem cell-ECM interactions. Combinatorial chemistry methods that systematically assemble and test individual, and combinations of ECM components will be employed with the intent of elucidating the contribution of each component to HSPC function. These findings will further be implemented in a novel 3D screening assay using "off-patent" drugs able to identify molecular targets that regulate stem cell function. Finally, 3D Printing technology will be developed to create a vascular system with the ECM and support HSPC survival in thick 3D constructs. This program leads to the development of tissue-matched engineered bone marrow tissue for personalized HSCT medicine. Canadian leukemia and autoimmune disease patients stand to benefit the most with shorter waiting times and safer procedures. Canadian healthcare savings can also be realized by accelerating patient treatment and recovery, thereby reducing healthcare costs of managing sick and deteriorating patients. Furthermore, this research can be applied to test new drugs that unintentionally cause myelosuppression toxicity, a potentially lethal side-effect, before approving investigational new drugs. This additional test for regulatory approval can reduce animal testing and promote safer news drugs. Within the program's first 5 years, a total of 3 PhDs, 3 MASc and 10 undergraduate research assistants will be will be trained in stem cells and tissue engineering and position them for academic or industry employment opportunities in high-impact areas such as regenerative medicine and biotechnology.

骨髓容纳造血干细胞（HSC），负责在人的一生中不断再生血液组织。骨髓移植，也称为HSC移植（HSCT），是用于治疗白血病患者的挽救生命的程序，最近，自身免疫性疾病，如多发性硬化症，可导致持久的无病缓解。然而，HSCT受到供应有限、组织错配并发症和高死亡率（高达10%的患者无法在移植后存活）的困扰。如果每个供体样本中的HSC数量可以增加，更多的患者可以从更安全的HSCT中受益。为了实现这一进展，需要更详细地了解HSC与其天然3D骨髓环境或生态位之间的相互作用。 当从其天然骨髓龛中取出并置于培养物中时，HSC和祖细胞（HSPC）细胞非常迅速地失去其干细胞功能（24- 72小时）。越来越多的证据表明，骨髓细胞外基质（ECM）是一个关键的，但未得到充分重视，组成部分的生态位，可能是有益的干细胞调控。为了使HSPC离体扩增，需要开发重现天然ECM环境的培养条件。该计划旨在开发发现离体干细胞生态位条件的技术，并应用这些知识来阐明干细胞-ECM相互作用。将采用系统组装和测试ECM组分的单个和组合的组合化学方法，旨在阐明每种组分对HSPC功能的贡献。这些发现将进一步在一种新型的3D筛选试验中实施，该试验使用能够识别调节干细胞功能的分子靶点的“非专利”药物。最后，将开发3D打印技术，以创建具有ECM的血管系统，并支持HSPC在厚3D结构中存活。 该计划导致开发组织匹配的工程骨髓组织用于个性化HSCT药物。加拿大白血病和自身免疫性疾病患者将受益最多，等待时间更短，手术更安全。加拿大的医疗保健储蓄也可以通过加速患者治疗和康复来实现，从而降低管理生病和病情恶化患者的医疗保健成本。此外，这项研究可用于在批准研究性新药之前测试无意中引起骨髓抑制毒性的新药，这是一种潜在的致命副作用。这种额外的监管批准测试可以减少动物试验，促进更安全的新药物。 在该计划的前5年内，共有3名博士，3名硕士和10名本科生研究助理将接受干细胞和组织工程方面的培训，并将他们定位为再生医学和生物技术等高影响力领域的学术或行业就业机会。