Multiplexed Viability Assays for High-Throughput Screening of Spheroids of Multiple Sizes.

Abstract

High-throughput (HT) drug screening is in high demand for successful drug discovery and personalized medicine. Spheroids act as a promising preclinical model for HT drug screening, which may decrease drug failures in clinical trials. Numerous spheroid-forming technological platforms are currently under development, which include synchronous, jumbo-sized, hanging drop, rotary, and nonadherent surface spheroid growth. Initial cell seeding concentration and time of culture play a vital role for spheroids to mimic the extracellular microenvironment of natural tissue, especially for HT preclinical evaluation. Hence microfluidic platforms become a potential technology to provide a confined space for the oxygen and nutrient gradients within the tissues while controlling the cell count and spheroid size in an HT manner. We describe here a microfluidic platform capable of generating spheroids of multiple sizes in a controlled manner with a predefined cell concentration for HT drug screening. Ovarian cancer spheroids grown on this microfluidic platform were evaluated for viability using a confocal microscope and flow cytometer. In addition, screening of the HT chemotherapeutic drug carboplatin was carried out on-chip to evaluate the impact of spheroid size on drug toxicity. This chapter summarizes a detailed protocol on microfluidic platform fabrication for spheroid growth, on-chip multi-sized spheroid analysis, and chemotherapeutic drug screening.