top of page

Flow Cytometry Screening Applications

Indispensable Tool in the Study of Human Biology
Immunophenotyping involves identifying and characterising different cell populations based on the expression of specific surface markers. Flow cytometry is a valuable tool for immunophenotyping human cells, identifying various immune cell populations, such as T cells, B cells, and natural killer (NK) cells. This information can be used to study immune responses in various diseases, including autoimmune disorders, infectious diseases, and cancers.

Flow cytometry is a powerful technique that allows for the rapid analysis of multiple cellular characteristics simultaneously, including cell size, granularity, and the expression of specific proteins. This versatile method has revolutionised our understanding of the complexities of human biology and is increasingly being employed in various research and clinical applications. 


"As new technologies and methodologies emerge, we can expect even more exciting applications for flow cytometry in the future."


Here are some of the most exciting applications of flow cytometry using human biosamples.


Immunophenotyping

Immunophenotyping involves identifying and characterising different cell populations based on the expression of specific surface markers. Flow cytometry is a valuable tool for immunophenotyping human cells, identifying various immune cell populations, such as T cells, B cells, and natural killer (NK) cells. This information can be used to study immune responses in various diseases, including autoimmune disorders, infectious diseases, and cancers.


Hematopoietic Stem Cell Transplantation

Hematopoietic stem cells (HSCs) generate all blood cell types. Flow cytometry identifies and isolates HSCs from human biosamples, such as bone marrow and peripheral blood. These cells can then be used for hematopoietic stem cell transplantation, a life-saving treatment for patients with various blood-related disorders, including leukaemia, lymphoma, and sickle cell anaemia.


Cancer Diagnosis and Prognosis

Flow cytometry can analyse tumour cells from human biosamples, such as blood, bone marrow, and solid tumour biopsies. This analysis allows for identifying cancer-specific markers, which can be used for diagnosis, staging, and determining prognosis. Furthermore, flow cytometry can be employed to monitor minimal residual disease (MRD) after treatment, helping to predict relapse and inform clinical decision-making.


Drug Discovery and Development

Flow cytometry can be used to assess the effects of potential therapeutics on human cells, providing valuable insights into drug efficacy and toxicity. By examining changes in cell surface markers, proliferation, and apoptosis, researchers can evaluate the impact of novel compounds on specific cell types or cellular processes, accelerating drug discovery and development.


Cellular Therapy Development

Cellular therapies, such as chimeric antigen receptor (CAR) T cells, have emerged as promising treatments for various diseases, including cancer. Flow cytometry plays a critical role in developing these therapies by allowing for the characterisation and selection of modified cells and monitoring their activity in patients after administration. 



Several emerging and innovative uses for flow cytometry are anticipated to significantly contribute to the field of human biology in the coming years. Some of these promising areas include:


Single-cell Genomics

As researchers continue to delve into the complexities of the human genome, flow cytometry has emerged as a valuable tool for single-cell genomics. Flow cytometry can provide insights into the genomic and transcriptomic heterogeneity of cell populations by allowing for the isolation and analysis of individual cells. This information can help researchers better understand the underlying mechanisms of various diseases and identify potential therapeutic targets.


Multiplexed Flow Cytometry

Multiplexed flow cytometry expands the capabilities of traditional flow cytometry by enabling the simultaneous analysis of multiple parameters within a single sample. This approach can significantly enhance the depth and breadth of information from a single experiment, leading to a more comprehensive understanding of complex biological systems and processes.


Microvesicle and Extracellular Vesicle Analysis

Extracellular vesicles, including microvesicles and exosomes, have gained increasing attention recently due to their role in cell-to-cell communication and involvement in various disease processes. Flow cytometry is being adapted to analyse these vesicles, providing insights into their origin, cargo, and function, and paving the way for the development of novel diagnostic and therapeutic strategies.


High-throughput Screening and Functional Assays

Flow cytometry's capacity for high-throughput analysis makes it an ideal tool for large-scale screening and functional assays. Researchers can leverage flow cytometry to quickly assess the effects of thousands of compounds or conditions on cellular processes, facilitating the identification of promising therapeutic candidates or elucidating key regulatory mechanisms.


Spatial Cytometry

Recent advances in flow cytometry technology have enabled the development of spatial cytometry, which combines flow cytometry's high-throughput and multiparametric capabilities with spatial information derived from tissue samples. This emerging technology can provide valuable insights into the spatial organisation and interactions of cells within their native tissue environment, enhancing our understanding of tissue function and disease pathogenesis.



Flow cytometry has undoubtedly become an essential tool in human biology, offering many insights into cellular characteristics and functions. By harnessing the power of flow cytometry, researchers and clinicians can gain an in-depth understanding of various aspects of human health and disease.


The diverse applications of flow cytometry, as demonstrated through immunophenotyping, hematopoietic stem cell transplantation, cancer diagnosis and prognosis, drug discovery, and cellular therapy development, highlight the technique's versatility and emphasise its significant potential to revolutionise the field of biomedical research. Each application provides unique insights that contribute to the broader understanding of human biology and the development of novel therapeutic approaches. 


As flow cytometry technology and methodology advance, we can anticipate even more exciting and impactful applications. The technique's versatility, its capacity for high-throughput analysis, and the depth of information it provides ensure that flow cytometry will remain at the forefront of biomedical research, driving innovation and improving human health for years to come. 



Please click on the links below to inquire about the Compare Biomarket® range of clinical biospecimens and services suitable for your unique human health research needs.

Compare Biomarket Logo_edited_edited.png

Compare

Biomarket

Latest Biosamples, Services and Research Developments

Human Biospecimens for Acute Myeloid Leukaemia Research

Elucidating Molecular and Genetic Characteristics

Board-Certified Pathology Review

Ensuring FFPE Tissue Specimens are Accurately Characterized

Fresh Viable Tissue

Applications Include Biology, Medicine and Pharmacology
bottom of page