A Method to Study Tissue Microenvironments at Single-Cell Resolution
Spatial transcriptomics is a rapidly evolving field aiming to capture transcriptomic features and spatial relationships of cells within tissues.
A High-Throughput Sample Processing Pipeline with a 28-color Flow Cytometry Panel
The complexity of the immune system entails the simultaneous analysis of several parameters to gather meaningful insights. The advancements in flow cytometry instrumentation and the availability of reagents in recent years have facilitated high-dimensional analysis of immune cells to a tremendous extent.
Using Flow Cytometry and Single-Cell Multiomics for Analyzing COVID-19 Immune Responses
The human immune system exerts coordinated responses capable of overcoming a broad spectrum of pathogenic challenges, including viral infections. Understanding the nature and sequence of these responses paves the way for targeting specific cells for further translational research.
High-parameter flow cytometry for deep immune profiling of COVID-19 patients
The SARS-CoV-2 virus infection presents a range of clinical manifestations, ranging from mild or no symptoms to moderate to severe respiratory illnesses, such as ARDS (acute respiratory-distress syndrome) and multiorgan failure, to death. The innate immune defense mounted by the body involves pattern recognition receptors (PAR), which activate an array of transcription factors through a signal transduction pathway, ultimately resulting in the secretion of different interferons and chemokines.
Immunotyping of natural killer (NK) cells in COVID-19 patients using high-parameter flow cytometry
SARS-CoV-2 infection elicits a spectrum of immune responses, activating both the innate and adaptive immune systems. Whether these immune responses are targeted and controlled or misdirected and uncontrolled could determine the outcome of the disease. Recent studies using deep immunoprofiling have indicated that the nature of immune responses can also determine the severity of the disease.
