CometChip® Starter Kit


The CometChip® Starter Kit includes one CometChip® Reagent Kit and the 96-Well CometChip® System  (macrowell former).

Available Size(s): 96 Samples Catalog Number: 4260-096-CSK Category:


CometChip® in 96-Well CometChip® System



  • CometChip® for single cell capture – no overlapping comets
  • 96-Well CometChip® System – Multiple experiments on single slide
  • Parallel Processing – ease of handling saves time and reagents
  • Ready to use low melt agarose (LMAgarose) and Lysis Solution in convenient size
  • Optimized electrophoresis conditions



Material Safety Data Sheet(s)

msds_4250-010-01 Lysis Solution

msds_4250-050-02 LMAgarose

msds_4260-096-01 CometChip 30 micron

4260-096-CS Safety Data Sheets are not provided for “articles” defined as a manufactured item other than a fluid or particle.


SOT 2017 Trevigen’s CometChip® Platform for High-Through-Put DNA Damage Analysis

Catalog # 4260-096-CSK includes :
Catalog Number Description Qty
4250-010-01 CometAssay® Lysis Solution 1
4250-050-02 CometAssay® LMAgarose 1
4260-096-01 CometChip®, 30 micron 1
4260-096-CS 96-Well CometChip® System 1

Sykora, Peter et al. “Next Generation High Throughput DNA Damage Detection Platform for Genotoxic Compound Screening.” Scientific Reports 8:2771 (2018): 1-20.

Ge, Jing et al. “Micropatterned Comet Assay Enables High Throughput and Sensitive DNA Damage Quantification.” Mutagenesis 30.1 (2015): 11–19.

Li, Na et al. “Influenza Infection Induces Host DNA Damage and Dynamic DNA Damage Responses during Tissue Regeneration.” Cellular and molecular life sciences : CMLS 72.15 (2015): 2973–2988.

Ge, Jing et al. “CometChip: A High-Throughput 96-Well Platform for Measuring DNA Damage in Microarrayed Human Cells.” Journal of Visualized Experiments : JoVE 92 (2014): 50607.

Sotiriou, Georgios A. et al. “Engineering Safer-by-Design, Transparent, Silica-Coated ZnO Nanorods with Reduced DNA Damage Potential.” Environmental science. Nano 1.2 (2014): 144–153.

Watson, Christa et al. “High-Throughput Screening Platform for Engineered Nanoparticle-Mediated Genotoxicity Using CometChip Technology.” ACS Nano 8.3 (2014): 2118–2133.

Ge, Jing et al. “Standard Fluorescent Imaging of Live Cells Is Highly Genotoxic.” Cytometry. Part A : the journal of the International Society for Analytical Cytology 83.6 (2013): 552–560.

Weingeist, David M. et al. “Single-Cell Microarray Enables High-Throughput Evaluation of DNA Double-Strand Breaks and DNA Repair Inhibitors.” Cell Cycle 12.6 (2013): 907–915.

Chao, Ming-Wei et al. “Genotoxicity of 2,6- and 3,5-Dimethylaniline in Cultured Mammalian Cells: The Role of Reactive Oxygen Species.” Toxicological Sciences 130.1 (2012): 48–59.

Mutamba, James T. et al. “XRCC1 and Base Excision Repair Balance in Response to Nitric Oxide.” DNA repair 10.12 (2011): 1282–1293.

Wood, David K. et al. “Single Cell Trapping and DNA Damage Analysis Using Microwell Arrays.” Proceedings of the National Academy of Sciences of the United States of America 107.22 (2010): 10008–10013.