Unlock Cellular Insights with MTS Reagent
Accurately measure cell health and response with our advanced MTS Reagent.
Get a Quote & SampleMTS Reagent: Your Key to Cellular Health Assessment
MTS Reagent
MTS Reagent is a sophisticated biochemical tool designed for precise measurement of cell viability and cytotoxicity. Its ability to react with intracellular reducing agents, like glutathione, to form a soluble formazan dye makes it ideal for quantitative analysis of cellular metabolic activity.
- Accurately quantify cell proliferation rates by leveraging the MTS reagent's ability to link metabolic activity to a measurable signal.
- Evaluate the cytotoxic effects of various compounds with confidence, enabling robust cytotoxicity testing in your experiments.
- Understand cellular responses in functional genomics studies by correlating gene expression changes with cell viability metrics.
- Monitor cellular health in cutting-edge tissue engineering applications, supporting the development of advanced biomaterials.
Advantages of Using MTS Reagent
Simplicity and Sensitivity
Experience straightforward experimental design and highly sensitive detection of cellular metabolic activity, making your research more efficient.
Low Cellular Toxicity
Ensure cell integrity and enable multiple measurements from the same cell culture with MTS reagent's minimal impact on cell health.
High-Throughput Compatibility
Streamline large-scale screening processes, as MTS reagent is well-suited for automated platforms and high-throughput experimental setups.
Key Applications
Cell Proliferation Assays
Quantify cell growth and replication dynamics, a core aspect of understanding cellular behavior under various conditions.
Cytotoxicity Testing
Assess the toxicological impact of drugs, chemicals, and nanoparticles on cultured cells, crucial for safety evaluations.
Functional Genomics Studies
Investigate the effects of gene knockouts or knockdowns on cell viability and metabolic function, shedding light on genetic pathways.
Tissue Engineering
Monitor cellular viability and metabolic activity within 3D scaffolds, vital for developing effective tissue grafts.