The Benefits of Stem Cell Biology and Tissue Engineering in Low-Earth Orbit.

Stem cells and development Pub Date : 2024-03-01 Epub Date: 2024-02-26 DOI:10.1089/scd.2023.0291
Madelyn Arzt, Maedeh Mozneb, Sean Escopete, Jemima Moses, Arun Sharma
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Abstract

Over the past 15 years, there has been a significant shift in biomedical research toward a major focus on stem cell research. Although stem cells and their derivatives exhibit potential in modeling and mitigating human diseases, the ongoing objective is to enhance their utilization and translational potential. Stem cells are increasingly employed in both academic and commercial settings for a variety of in vitro and in vivo applications in regenerative medicine. Notably, accessibility to stem cell research in low-Earth orbit (LEO) has expanded, driven by the unique properties of space, such as microgravity, which cannot exactly be replicated on Earth. As private enterprises continue to grow and launch low-orbit payloads alongside government-funded spaceflight, space has evolved into a more viable destination for scientific exploration. This review underscores the potential benefits of microgravity on fundamental stem cell properties, highlighting the adaptability of cells to their environment and emphasizing physical stimuli as a key factor influencing cultured cells. Previous studies suggest that stimuli such as magnetic fields, shear stress, or gravity impact not only cell kinetics, including differentiation and proliferation, but also therapeutic effects such as cells with improved immunosuppressive capabilities or the ability to identify novel targets to refine disease treatments. With the rapid progress and sustained advocacy for space research, we propose that the advantageous properties of LEO create novel opportunities in biomanufacturing for regenerative medicine, spanning disease modeling, the development of stem cell-derived products, and biofabrication.

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低地轨道干细胞生物学和组织工程学的益处。
在过去的15年里,生物医学研究发生了重大转变,重点转向干细胞研究。虽然干细胞及其衍生物在模拟和缓解人类疾病方面具有潜力,但目前的目标是提高其利用率和转化潜力。学术界和商业界越来越多地将干细胞用于再生医学的各种体外和体内应用。值得注意的是,在低地轨道(LEO)上进行干细胞研究的可能性已经扩大,这是由于太空的独特特性(如微重力)所驱动的,而微重力在地球上是无法完全复制的。随着私营企业不断发展壮大,与政府资助的太空飞行一起发射低轨道有效载荷,太空已发展成为科学探索更可行的目的地。这篇综述强调了微重力对干细胞基本特性的潜在益处,突出了细胞对环境的适应性,并强调物理刺激是影响培养细胞的关键因素。以往的研究表明,磁场、剪切应力或重力等刺激不仅影响细胞动力学,包括分化和增殖,还影响治疗效果,如细胞具有更好的免疫抑制能力,或能够识别新的靶点以完善疾病治疗。随着太空研究的快速发展和持续倡导,我们建议利用低地轨道的优势特性为再生医学的生物制造创造新的机遇,包括疾病建模、干细胞衍生产品的开发和生物制造。
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