Middermal Wound Healing: A Comparison Between Dermatomal Excision and Pulsed Carbon Dioxide Laser Ablation

Howard A. Green, Elizabeth Burd, Norman S. Nishioka, Ulrich Brüggemann, Carolyn C. Compton

Research output: Contribution to journalArticlepeer-review

80 Scopus citations


Background.— Continuous-wave carbon dioxide lasers are not widely used for the surgical removal of most skin lesions because it is difficult to control laser ablation and the extensive laser-induced thermal damage slows healing. Pulsed lasers provide means to reduce thermal damage produced during laser ablation and permit precise control of tissue removed during ablation. Using a swine model, we compared on a gross and microscopic level the healing of middermal wounds of similar depth and area created by a dermatome and a focused pulsed CO2 laser. Results.— Pulsed CO2 laser ablation removed skin precisely and bloodlessly with 85 ±15 μm (mean ±SD)of residual thermal damage covering the surface of the wound. Compared with the dermatome, tissue reepithelialization was delayed in the laser wounds at day 3. By day 7, epithelial coverage of the laser-created wounds was not significantly different from the dermatome-created wounds. No significant difference in the appearance of the two wounds was noted at 42 days. Conclusions.— We conclude that the focused pulsed CO2 laser is capable of precisely and bloodlessly ablating skin with conservation of residual subjacent adnexal elements, minimal early interference with epibolic epithelial outgrowth, and no pathologic effects on the wound healing process. Pulsed CO2 lasers may be a valuable instrument for the conservative ablation of skin and skin lesions.

Original languageEnglish (US)
Pages (from-to)639-645
Number of pages7
JournalArchives of Dermatology
Issue number5
StatePublished - May 1992
Externally publishedYes

ASJC Scopus subject areas

  • Dermatology


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