Abstract: Bioassays are provided for detecting and analyzing responses from single cells and cell pairs suspended in micro-scale droplets (80-200 ?m diameter) generated in microfluidic devices. Cell responses to various stimuli are analyzed. The stimuli are delivered by homotypic or heterotypic cells, small molecule drugs, and therapeutic agents including immunotherapeutics. The bioassays can be used to describe heterogeneity in any given cell population, and can be used in a clinical setting, such as profiling of patient-derived cells, designing personalized treatment strategies, and optimizing drug combinations for immunotherapy of tumors.

Abstract: A microfluidic device provides high throughput generation and analysis of defined three-dimensional cell spheroids with controlled geometry, size, and cell composition. The cell spheroids of the invention mimic tumor microenvironments, including pathophysiological gradients, cell composition, and heterogeneity of the tumor mass mimicking the resistance to drug penetration providing more realistic drug response. The device is used to test the effects of antitumor agents.

Abstract: Platform technology involving aqueous microdroplet reaction vessels created, arrayed, and characterized by imaging microscopy in a microfluidic device are applied to a wide variety of bioassays involving the detection and phenotypic characterization of single cells. The bioassays include the rapid and automated detection of microbial pathogens and their antibiotic sensitivity from patient samples as well as the characterization of immune responses using a patient's own cells, including the killing of tumor cells.

Abstract: Platform technology involving aqueous microdroplet reaction vessels created, arrayed, and characterized by imaging microscopy in a microfluidic device are applied to a wide variety of bioassays involving the detection and phenotypic characterization of single cells. The bioassays include the rapid and automated detection of microbial pathogens and their antibiotic sensitivity from patient samples as well as the characterization of immune responses using a patient's own cells, including the killing of tumor cells.

Abstract: Platform technology involving aqueous microdroplet reaction vessels created, arrayed, and characterized by imaging microscopy in a microfluidic device are applied to a wide variety of bioassays involving the detection and phenotypic characterization of single cells. The bioassays include the rapid and automated detection of microbial pathogens and their antibiotic sensitivity from patient samples as well as the characterization of immune responses using a patient's own cells, including the killing of tumor cells.

Abstract: Bioassays are provided for detecting and analyzing responses from single cells and cell pairs suspended in micro-scale droplets (80-200 ?m diameter) generated in microfluidic devices. Cell responses to various stimuli are analyzed. The stimuli are delivered by homotypic or heterotypic cells, small molecule drugs, and therapeutic agents including immunotherapeutics. The bioassays can be used to describe heterogeneity in any given cell population, and can be used in a clinical setting, such as profiling of patient-derived cells, designing personalized treatment strategies, and optimizing drug combinations for immunotherapy of tumors.

Abstract: Platform technology involving aqueous microdroplet reaction vessels created, arrayed, and characterized by imaging microscopy in a microfluidic device are applied to a wide variety of bioassays involving the detection and phenotypic characterization of single cells. The bioassays include the rapid and automated detection of microbial pathogens and their antibiotic sensitivity from patient samples as well as the characterization of immune responses using a patient's own cells, including the killing of tumor cells.

Abstract: A microfluidic device provides high throughput generation and analysis of defined three-dimensional cell spheroids with controlled geometry, size, and cell composition. The cell spheroids of the invention mimic tumor microenvironments, including pathophysiological gradients, cell composition, and heterogeneity of the tumor mass mimicking the resistance to drug penetration providing more realistic drug response. The device is used to test the effects of antitumor agents.