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Key Features
- Contains applied case studies and full color images that support concept illustration
- Features a diverse range of chapters that cover the fundamentals of nuclear mechanics and genome regulation, including physico-chemical constraints in DNA
- Introduces advanced biophysical methods, bio-imaging methods, and new molecular biology tools for studying nuclear structures
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About the Book
Introduction to Nuclear Mechanics and Genome Regulation provides a detailed discussion of the biophysical principles underlying nuclear organization and their role in determining tissue function, cell differentiation and homeostasis, and disease expression and management. Applied case studies and full cover images support concept illustration across a diverse range of chapters covering physico-chemical constraints in DNA, 3D organization of chromosomes and functional gene clusters, spatial dimensions of DNA transcription, replication, damage and repair, and more. With its practical approach and foundational focus, this book will be an invaluable reference for students, researchers and clinicians looking to understand this area of cutting-edge study.
Readership
Advanced undergraduate, graduate, and postdocs in biomedical research, molecular biology, and biomedical engineering; PhD and MD level researchers in biomedical research, life sciences, human genetics, and bioengineering; clinical and translational drug discovery researchers in academics and pharmaceutical industry
Content
View Table of Contents
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