EarlyTox Cardiotoxicity Kit
The EarlyTox™ Cardiotoxicity Kit provides a fast, simple, and reliable fluorescence-based method for identifying cardiotoxic compounds in a biorelevant assay using stem-cell derived cardiomyocytes. Leveraging our proprietary masking technology with our novel calcium sensitive indicator, researchers can:• Eliminate cardiotoxic compounds and identify potential drug candidates• Measure 384 samples in minutes rather than h…
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The EarlyTox™ Cardiotoxicity Kit provides a fast, simple, and reliable fluorescence-based method for identifying cardiotoxic compounds in a biorelevant assay using stem-cell derived cardiomyocytes. Leveraging our proprietary masking technology with our novel calcium sensitive indicator, researchers can:• Eliminate cardiotoxic compounds and identify potential drug candidates• Measure 384 samples in minutes rather than hours• Minimize non-specific effect of dye on beat characteristics• Reduce well-to-well variation and improve data quality• Largest signal dynamic range available• Benchmark against three reference compounds: isoproterenol, sotalol and propranolol
Optimized plate reader assays for breakthrough drug discovery research
Biology research has been greatly simplified by the availability of standardized assay kits, instruments, and assay protocols from commercial manufacturers. However, assay optimization remains an essential and often time-consuming step to ensure the desired sensitivity and specificity to the target of interest. Molecular Devices presents its range of easy-to-use, robust assay kits for protein, DNA, and cell-based assays. Discover how these assay kits are optimized for the highest data quality on Molecular Devices instruments, including compatible software to streamline your workflow.
Calcium Flux Assay for In Vitro Neurotoxicity Studies and Drug Screening
Neurons are electrically excitable cells in the central and peripheral nervous system that process and transmit information through electrical and chemical signals. These signals occur via synapses that allow neurons connecting to each other to form neuronal networks.
