Discover the Latest in Biomedical Research Innovation

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.

Unlocking the future of medicine starts with the right tools. Biomedical research tools—like cell lines, chemical probes, and data platforms—are essential for turning scientific discoveries into real treatments. Validated and widely shared, these tools power breakthroughs in disease understanding and drug development. Learn how they bridge the gap between lab research and patient care, accelerating medical progress for everyone.

A strong NIH is the backbone of biomedical research and innovation, funding discoveries that drive medical breakthroughs, improve public health, and fuel the U.S. economy. From heart disease to regenerative medicine, NIH-supported research powers scientific progress and global leadership. Continued investment in NIH ensures a thriving future for medical research, fostering innovation that transforms lives and keeps America at the forefront of scientific discovery.

Tired of inconsistent scratch assays with pipette tips? Meet CellCut by CLYTE—the game-changing device that delivers fast, reproducible in vitro scratches across 96-well plates in seconds. Designed for cell migration and wound healing studies, CellCut ensures precision, boosts throughput, and eliminates human error. Whether you're studying cancer, tissue regeneration, or drug responses, CellCut sets a new standard in high-quality, high-impact research.

Unlock cell movement secrets! Discover the in vitro scratch assay, a key, low-cost method to study cell migration. Learn how this technique mimics wound healing and analyzes cell-cell/cell-matrix interactions using basic lab tools & microscopy. We cover its power, versatility with transfected cells, and crucial considerations like standardization for understanding cell behavior in vitro. Essential reading for cell biology insights!

Struggling with messy scratch assay data? Traditional cell migration quantification often falls short. Explore this summary article on Monolayer Edge Velocimetry – a powerful quantification method offering accurate migration rate analysis by precisely measuring leading edge velocity. Revolutionize your in vitro results!

Picture wound healing as a city emergency: cellular crews race to repair damage. Studying this 'traffic' with old scratch assays? It's like using inconsistent maps! This variability stalls research. Learn why a standardized cell migration assay, offering precision & reproducibility, is crucial to understand & potentially speed up the body's natural repair process.

Over 50% of biomedical research is irreproducible, costing $28B+ yearly. Learn the causes, impact, and solutions to fix science!

Wound healing process explained in simplest terms! Meet the emergency responders, clean-up crew, builders & architects repairing your body.

Operator errors cause up to 30% cell culture contamination, impacting research, sustainability, and patient care—automation offers solution.