Discover the Latest in Biomedical Research Innovation

Unlock the full potential of your scratch assays! Are you confident in your cell migration results? This definitive guide reveals why positive and negative controls are non-negotiable for robust, publishable data. Learn to select the best controls—from EGF and serum to cytochalasin D—and integrate them seamlessly into your workflow. We provide step-by-step instructions and pro-tips to help you eliminate ambiguity, troubleshoot with precision, and make confident claims about y

Unlock crystal-clear, high-contrast views of cell migration with Live/Dead staining! This powerful technique vividly stains live cells green and dead cells red, enabling precise quantification of wound healing and providing crucial insights into cell viability. Elevate your research from basic observation to high-content analysis with this simple, 30-minute protocol. Discover how to get sharper data and more compelling visuals for your regenerative medicine, drug testing, or

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.

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.