An optofluidic platform for cell-counting applications

Cell-counting is critical for a wide range of applications, e.g., life sciences, medicine, or pharmacology. Hemocytometry is a classical method that requires manual counting of cells under a microscope. This methodology is low-cost but manual counting is slow, and the test accuracy is limited by the operator experience. Accuracy and throughput of such application could be improved with the use of automated cell-counting devices. Possessing the ability of recording and processing cell images, devices employing these technologies could dramatically improve the accuracy of the counting results. However, accuracy of these devices still requires further improvement as the counting results rely only on 100-200 cells. Furthermore, the test cost of these devices increases due to the need for a counting chamber or consumables compatible with their hardware settings. Herein, in order to address these drawbacks, we introduced an optofluidic cell-counting platform that could scan more than 2000 cells, which dramatically improves the test accuracy. Our technology could yield an error rate below 1% for cell viability, and below 5% for cell concentration. The platform could deliver the count results within only similar to 1 minute, including sample loading, autofocusing, recording images, and image processing. The presented platform also benefits from a built-in fluidic component that eliminates the need for an external counting chamber, and allows fully automated sample loading and self-cleaning modality compatible with any solutions that are typically used for cell-counting tests. Providing an easy-to-use and rapid feature from sample loading to image analyses, our optofluidic platform could be a critical asset for accurate and low cost cell-counting applications.

Automated summary

Cell-counting is crucial for various applications in life sciences, medicine, and pharmacology, but manual counting under a microscope is slow and limited by operator experience. Automated cell-counting devices with image recording and processing capabilities can improve accuracy and throughput. However, these devices still need further improvement in accuracy, and the test cost increases due to the need for compatible consumables. To address these drawbacks, we introduced an optofluidic cell-counting platform that can scan over 2000 cells, significantly improving test accuracy. The platform delivers count results in about 1 minute and eliminates the need for an external counting chamber.