基于塑料的声流控装置用于高通量、生物相容性的血小板分离。
Plastic-based acoustofluidic devices for high-throughput, biocompatible platelet separation.
机构信息
Department of Mechanical Engineering and Material Science, Duke University, Durham, NC 27707, USA.
出版信息
Lab Chip. 2019 Jan 29;19(3):394-402. doi: 10.1039/c8lc00527c.
Abstract
Platelet separation is a crucial step for both blood donation and treatment of essential thrombocytosis. Here we present an acoustofluidic device that is capable of performing high-throughput, biocompatible platelet separation using sound waves. The device is entirely made of plastic material, which renders the device disposable and more suitable for clinical use. We used this device to process undiluted human whole blood, and we demonstrate a sample throughput of 20 mL min-1, a platelet recovery rate of 87.3%, and a red/white blood cell removal rate of 88.9%. We preserved better platelet function and integrity for isolated platelets than those which are isolated using established methods. Our device features advantages such as rapid fabrication, high throughput, and biocompatibility, so it is a promising alternative to existing platelet separation approaches.
摘要
血小板分离对于献血和治疗原发性血小板增多症都至关重要。在这里,我们提出了一种声流控装置,它可以使用声波进行高通量、生物相容性的血小板分离。该装置完全由塑料材料制成,这使得装置一次性使用,更适合临床应用。我们使用该装置处理未稀释的人类全血,并证明了 20 毫升/分钟的样品通量、87.3%的血小板回收率和 88.9%的红细胞/白细胞去除率。与使用既定方法分离的血小板相比,我们分离得到的血小板具有更好的功能和完整性。我们的装置具有快速制造、高通量和生物相容性等优点,因此是现有血小板分离方法的一种有前途的替代方法。
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