Abstract
Background: Short pulse duration (∼0.1–5 milliseconds) CO2 lasers are perceived as excellent tools for vaporization of craters arrays in fractional skin resurfacing. Objectives: To present a thermo-mechanical ablation technology, which affects tissue identically to fractional CO2 lasers, however at a fraction of the size and cost of a laser. Material and methods: The new technology is based on heating an oscillating array of thin metallic rods to a temperature of 400°C and advancing the rods into tissue down to a precise pre-selected depth for a duration of 0.1–5 milliseconds. As a result, an array of crater is vaporized with identical properties of those produced by CO2 lasers. An ex vivo test was performed with a thermo- metallic rod array prototype. Results: Arrays of 10 × 10 vaporized micro-craters of 350 micron diameter, 200 micron depth have been produced with lateral thermal damage of 80 micron while thermal damage below craters was 80–250 micron. Conclusions: A resonating thermo-mechanical array of high temperature (350–400°C) rods is capable of producing an array of craters identical to those produced with pulsed CO2 lasers.
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Declaration of interest: Michael Slatkine is cofounder of NovaB and its chief scientist. All other authors will be compensated in the future (in the form of payments/stock options) for running the multicentre clinical trial and for serving in the medical advisory board of NovaB.