Synergistic Development of Biochips and Cell Preservation Methodologies: A Tale of Converging Technologies.

IF 2.3 Q4 CELL & TISSUE ENGINEERING

Current Stem Cell Reports Pub Date : 2017-03-01 Epub Date: 2017-01-21 DOI:10.1007/s40778-017-0074-8

Shangping Wang, Gloria D Elliott

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引用次数: 4

Abstract

Purpose of the review: Over the past several decades, cryopreservation has been widely used to preserve cells during long term storage, but advances in stem cell therapies, regenerative medicine, and miniaturized cell-based diagnostics and sensors are providing new targets of opportunity for advancing preservation methodologies. The advent of microfluidics-based devices is an interesting case in which the technology has been used to improve preservation processing, but as the devices have evolved to also include cells, tissues, and simulated organs as part of the architecture, the biochip itself is a desirable target for preservation. In this review, we will focus on the synergistic co-development of preservation methods and biochip technologies, while identifying where the challenges and opportunities lie in developing methods to place on-chip biologics on the shelf, ready for use.

Recent findings: Emerging studies are demonstrating that the cost of some biochips have been reduced to the extent that they will have high utility in point-of-care settings, especially in low resource environments where diagnostic capabilities are limited. Ice-free low temperature vitrification and anhydrous vitrification technologies will likely emerge as the preferred strategy for long-term preservation of bio-chips.

Summary: The development of preservation methodologies for partially or fully assembled biochips would enable the widespread distribution of these technologies and enhance their application.

Abstract Image

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生物芯片和细胞保存方法的协同发展:融合技术的故事。

综述的目的:在过去的几十年里，冷冻保存被广泛用于长期保存细胞，但干细胞治疗、再生医学和小型化细胞诊断和传感器的进步为推进保存方法提供了新的目标。基于微流体的设备的出现是一个有趣的案例，该技术已被用于改善保存处理，但随着设备已经发展到还包括细胞，组织和模拟器官作为架构的一部分，生物芯片本身是保存的理想目标。在这篇综述中，我们将重点关注保存方法和生物芯片技术的协同开发，同时确定开发将芯片上的生物制剂放在货架上准备使用的方法所面临的挑战和机遇。最新发现:新出现的研究表明，一些生物芯片的成本已经降低到一定程度，它们将在护理点环境中具有很高的效用，特别是在诊断能力有限的资源匮乏环境中。无冰低温玻璃化和无水玻璃化技术将可能成为长期保存生物芯片的首选策略。摘要:部分或全部组装的生物芯片保存方法的发展将使这些技术的广泛分布和增强其应用。

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来源期刊

Current Stem Cell Reports Biochemistry, Genetics and Molecular Biology-Genetics

CiteScore

3.30

自引率

0.00%

发文量

期刊介绍： The goal of this journal is to publish cutting-edge reviews on subjects pertinent to all aspects of stem cell research, therapy, ethics, commercialization, and policy. We aim to provide incisive, insightful, and balanced contributions from leading experts in each relevant domain that will be of immediate interest to a wide readership of clinicians, basic scientists, and translational investigators. We accomplish this aim by appointing major authorities to serve as Section Editors in key subject areas across the discipline. Section Editors select topics to be reviewed by leading experts who emphasize recent developments and highlight important papers published over the past year on their topics, in a crisp and readable format. We also provide commentaries from well-known figures in the field, and an Editorial Board of internationally diverse members suggests topics of special interest to their country/region and ensures that topics are current and include emerging research.