Thomas Hopfes, Radin Tahvildari, Koen de Wijs, Chi Dang, Jelle Fondu, Liesbet Lagae and Sarah Libbrecht
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In this work, we present a new version of the sorter chip that emphasizes durability and continuous sorting operation. To characterize the sorter, we first focus on the technical performance and show a sorter lifetime that repeatedly exceeds 80 million actuation cycles. In addition, we show continuous operation at high firing rates, but also discuss limitations due to heat buildup. In a second step, we present continuous sorting runs of millions of beads and CD3 positive T cells at rates surpassing 1000 sorting events per second, while maintaining high purity (>90%) and recovery (>85%). Dedicated viability tests show that the gentle sorting process maintains cell viability in this closed, aerosol-free device. The remarkable combination of high lifetime, sorting rate, and sorting efficiency, along with the potential for on-chip parallelization show the promise of this technology to meet the growing demand for large-scale sample isolation in drug and immunotherapy development.</p>","PeriodicalId":64,"journal":{"name":"Analytical Methods","volume":null,"pages":null},"PeriodicalIF":2.7000,"publicationDate":"2024-08-19","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Durability of the bubble-jet sorter enables high performance bio sample isolation†\",\"authors\":\"Thomas Hopfes, Radin Tahvildari, Koen de Wijs, Chi Dang, Jelle Fondu, Liesbet Lagae and Sarah Libbrecht\",\"doi\":\"10.1039/D4AY01168F\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p >Sorting cells while maintaining their viability for further processing or analysis is an essential step in a variety of biological processes ranging from early diagnostics to cell therapy. 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引用次数: 0
摘要
在保持细胞活力的同时对细胞进行分拣,以便进一步处理或分析,是从早期诊断到细胞治疗等各种生物过程中必不可少的一步。荧光激活细胞分拣(FACS)等分拣技术已经有了长足的发展,并提供了标准的分拣方法。然而,由于成本、细胞活力和生物安全性等方面的挑战,人们仍在继续寻找紧凑、集成、高效和高通量的微流控分选平台。在我们之前的工作中,我们介绍了一种有可能成为这种平台的技术:气泡喷射分拣机。这是一种硅基分拣芯片,依靠微气泡形成的细胞偏转。在这项工作中,我们提出了一种新版本的分拣芯片,强调耐用性和连续分拣操作。为了描述分拣机的特性,我们首先关注技术性能,并展示了分拣机的使用寿命,多次超过 8000 万次启动周期。此外,我们还展示了高发射率下的连续运行,但也讨论了由于热量积聚造成的限制。第二步,我们展示了数百万个珠子和 CD3 阳性 T 细胞的连续分拣运行,分拣速度超过每秒 1000 次,同时保持高纯度(>90%)和高回收率(>85%)。专门的存活率测试表明,在这种封闭、无气溶胶的设备中,温和的分拣过程保持了细胞的存活率。高寿命、分拣率和分拣效率的显著组合,以及片上并行化的潜力,都表明这项技术有望满足药物和免疫疗法开发中对大规模样本分离日益增长的需求。
Durability of the bubble-jet sorter enables high performance bio sample isolation†
Sorting cells while maintaining their viability for further processing or analysis is an essential step in a variety of biological processes ranging from early diagnostics to cell therapy. Sorting techniques such as fluorescence-activated cell sorting (FACS) have evolved considerably and provide standard ways of sorting. Nevertheless, the search for compact, integrated, efficient, and high throughput microfluidic sorting platforms continues due to challenges such as cost, cell viability, and biosafety. In our previous work, we introduced a technology with the potential to become such a platform: the bubble-jet sorter. It is a silicon-based sorter chip relying on cell deflection through micro vapor bubble formation. In this work, we present a new version of the sorter chip that emphasizes durability and continuous sorting operation. To characterize the sorter, we first focus on the technical performance and show a sorter lifetime that repeatedly exceeds 80 million actuation cycles. In addition, we show continuous operation at high firing rates, but also discuss limitations due to heat buildup. In a second step, we present continuous sorting runs of millions of beads and CD3 positive T cells at rates surpassing 1000 sorting events per second, while maintaining high purity (>90%) and recovery (>85%). Dedicated viability tests show that the gentle sorting process maintains cell viability in this closed, aerosol-free device. The remarkable combination of high lifetime, sorting rate, and sorting efficiency, along with the potential for on-chip parallelization show the promise of this technology to meet the growing demand for large-scale sample isolation in drug and immunotherapy development.