📝 SummarXiv

Abstract

Large particle sorters have potential applications in sorting microplastics and large biomaterials (>50 micrometer), such as tissues, spheroids, organoids, and embryos. Though great advancements have been made in image-based sorting of cells and particles (<50 micrometer), their translation for high-throughput sorting of larger biomaterials and particles (>50 micrometer) has been more limited. An image-based detection technique is highly desirable due to richness of the data (including size, shape, color, morphology, and optical density) that can be extracted from live images of individualized biomaterials or particles. Such a detection technique is label-free and can be integrated with a contact-free actuation mechanism such as one based on traveling surface acoustic waves (TSAWs). Recent advances in using TSAWs for sorting cells and particles (<50 micrometer) have demonstrated short response times (<1 ms), high biocompatibility, and reduced energy requirements to actuate. Additionally, TSAW-based devices are miniaturized and easier to integrate with an image-based detection technique. In this work, a high-throughput image-detection based large particle microfluidic sorting technique is implemented. The technique is used to separate binary mixtures of small and large polyethylene particles (ranging between ~45-180 micrometer in size). All particles in flow were first optically interrogated for size, followed by actuations using momentum transfer from TSAW pulses, if they satisfied the size cutoff criterion. The effect of control parameters such as duration and power of TSAW actuation pulse, inlet flow rates, and sample dilution on sorting efficiency and throughput was observed. At the chosen conditions, this sorting technique can sort on average ~4.9-34.3 particles/s (perform ~2-3 actuations/s), depending on the initial sample composition and concentration.