Discover the Latest in Biomedical Research Innovation

Perform the wound healing assay with this detailed step-by-step protocol. Learn the materials, methods, and procedures for seeding cells, creating a consistent scratch, imaging cell migration over time using microscopy, and analyzing wound closure rates. Includes tips for optimization and controlling proliferation. Essential technique for studying in vitro cell motility, cancer research, and drug screening. This guide provides the technical details needed for reproducible res

Unlock the future of healthcare with the top 7 biomedical research tools revolutionizing science—CRISPR, NGS, AI, 3D bioprinting, and more. From gene editing to wearable sensors, discover how cutting-edge technologies are transforming diagnostics, treatments, and lab innovation. Dive into the tools driving next-gen biomedical engineering breakthroughs and shaping the future of life science research.

The U.S. biomedical research system stands at a turning point. A new Health Affairs article outlines four key reforms to boost innovation, equity, and sustainability—supporting early-career scientists, modernizing incentives, promoting diversity, and strengthening infrastructure. With smarter NIH funding and bold policy shifts, the future of life-saving research and public health breakthroughs is within reach. Now is the time for strategic, lasting change.

CellCut is a high-throughput, precision-engineered device for generating consistent wounds in in vitro scratch assays. Designed to replace manual pipette-tip methods, CellCut delivers uniform scratch width, reduced variability, and improved reproducibility across 96-well and 48-well plates. Ideal for cell migration, wound healing, and drug screening studies, CellCut enhances data quality and streamlines imaging workflows in both academic and industrial labs.