Comet Assay Measurements of DNA Damage in Cells by Laser Microbeams and Trapping Beams with Wavelengths Spanning a Range of 308 nm to 1064 nm

Abstract Mohanty, S. K., Rapp, A., Monajembashi, S., Gupta, P. K. and Greulich, K. O. Comet Assay Measurements of DNA Damage in Cells by Laser Microbeams and Trapping Beams with Wavelengths Spanning a Range of 308 nm to 1064 nm. Radiat. Res. 157, 378–385 (2002). DNA damage induced in NC37 lymphoblasts by optical tweezers with a continuous-wave Ti:sapphire laser and a continuous-wave Nd:YAG laser (60–240 mW; 10–50 TJ/m2; 30–120 s irradiation) was studied with the comet assay, a single-cell technique used to detect DNA fragmentation in genomes. Over the wavelength range of 750–1064 nm, the amount of damage in DNA peaks at around 760 nm, with the fraction of DNA damage within the range of 750–780 nm being a factor of two larger than the fraction of DNA damage within the range of 800–1064 nm. The variation in DNA damage was not significant over the range of 800–1064 nm. When the logarithm of damage thresholds measured in the present work, as well as values reported previously in the UV range, was plotted as a function of wavelength, a dramatic wavelength dependence became apparent. The damage threshold values can be fitted on two straight lines, one for continuous-wave sources and the other for pulsed sources, irrespective of the type of source used (e.g. classical lamp or laser). The damage threshold around 760 nm falls on the line extrapolated from values for UV-radiation-induced damage, while the data for 800–1064 nm fall on a line that has a different slope. The change in the slope between 320 and 340 nm observed earlier is consistent with a well-known change in DNA-damaging mechanisms. The change observed around 780 nm is therefore suggestive of a further change in the mechanism(s). The data from this work together with our previous measurements provide, to the best of our knowledge, the most comprehensive view available of the DNA damage produced by microfocused light.

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