We a good story
Quick delivery in the UK

Revealing Uncharted Biology With Single Cell Multiplex Proteomic Technologies

About Revealing Uncharted Biology With Single Cell Multiplex Proteomic Technologies

Revealing Uncharted Biology with Single Cell Multiplex Proteomic Technologies: Applications Healthy tissues and organs rely on the precise coordination of diverse cell types, each responding to external and internal signals. Disease disrupts this coordination. Since proteins drive cellular function, analyzing their abundance and activation states in single cells helps identify key cell populations in health and disease. Bulk protein analyses mask critical differences between individual cells. Additionally, the arrangement of cells into neighborhoods through cell-cell interactions is essential for tissue function. Over the last decade, single-cell proteomic phenotyping combined with positional information has become crucial for understanding biology in health and disease. This has led to the development of multiple technology platforms, profoundly impacting fields including developmental biology, cancer biology, immunology, neuroscience, and drug discovery. This book focuses on the application of single-cell multiplex proteomic platforms to various biological systems. These platforms have proved to be essential in biomedical research, advancing our understanding of complex biological systems at the cellular level. Compelling studies where authors use these technologies to answer previously unanswerable questions are featured. Exploring this "Uncharted Biology" opens new avenues for scientific inquiry and clinical translation, covering areas including oncology, immunology, metabolomics, stem cell research, preclinical models, and translational research. The initial chapters discuss incorporating these technologies into core facilities and consortia, providing access for multiple users and integrating datasets from other omics technologies. The following chapters cover applications in diverse areas such as muscle stem cell function in skeletal muscle regeneration, metabolic regulome profiling, translational studies, developing predictive biomarkers for patients receiving immune checkpoint inhibitors, and pre-clinical studies of lung cancer. These applications demonstrate how advanced single cell proteomic technologies are reshaping our understanding of complex biological systems and enhancing clinical translation. Revealing Uncharted Biology with Single Cell Multiplex Proteomic Technologies: Applications highlights the transformative benefits of single-cell proteomics, offering insights into cellular mechanisms underlying health and disease and inspiring further exploration into "Uncharted Biology." It is an essential resource for researchers, clinicians, and students aiming to advance biomedical science and improve therapeutic outcomes.

Show more
  • Language:
  • English
  • ISBN:
  • 9780128222133
  • Binding:
  • Paperback
  • Pages:
  • 300
  • Published:
  • October 31, 2023
  • Dimensions:
  • 191x0x235 mm.
  In stock
Delivery: 3-5 business days
Expected delivery: December 5, 2024

Description of Revealing Uncharted Biology With Single Cell Multiplex Proteomic Technologies

Revealing Uncharted Biology with Single Cell Multiplex Proteomic Technologies: Applications Healthy tissues and organs rely on the precise coordination of diverse cell types, each responding to external and internal signals. Disease disrupts this coordination. Since proteins drive cellular function, analyzing their abundance and activation states in single cells helps identify key cell populations in health and disease. Bulk protein analyses mask critical differences between individual cells. Additionally, the arrangement of cells into neighborhoods through cell-cell interactions is essential for tissue function. Over the last decade, single-cell proteomic phenotyping combined with positional information has become crucial for understanding biology in health and disease. This has led to the development of multiple technology platforms, profoundly impacting fields including developmental biology, cancer biology, immunology, neuroscience, and drug discovery. This book focuses on the application of single-cell multiplex proteomic platforms to various biological systems. These platforms have proved to be essential in biomedical research, advancing our understanding of complex biological systems at the cellular level. Compelling studies where authors use these technologies to answer previously unanswerable questions are featured. Exploring this "Uncharted Biology" opens new avenues for scientific inquiry and clinical translation, covering areas including oncology, immunology, metabolomics, stem cell research, preclinical models, and translational research. The initial chapters discuss incorporating these technologies into core facilities and consortia, providing access for multiple users and integrating datasets from other omics technologies. The following chapters cover applications in diverse areas such as muscle stem cell function in skeletal muscle regeneration, metabolic regulome profiling, translational studies, developing predictive biomarkers for patients receiving immune checkpoint inhibitors, and pre-clinical studies of lung cancer. These applications demonstrate how advanced single cell proteomic technologies are reshaping our understanding of complex biological systems and enhancing clinical translation. Revealing Uncharted Biology with Single Cell Multiplex Proteomic Technologies: Applications highlights the transformative benefits of single-cell proteomics, offering insights into cellular mechanisms underlying health and disease and inspiring further exploration into "Uncharted Biology." It is an essential resource for researchers, clinicians, and students aiming to advance biomedical science and improve therapeutic outcomes.

User ratings of Revealing Uncharted Biology With Single Cell Multiplex Proteomic Technologies



Join thousands of book lovers

Sign up to our newsletter and receive discounts and inspiration for your next reading experience.