Howard A. Green scite author profile

Pulsed lasers produce efficient and precise tissue ablation with limited residual thermal damage. In this study, the efficiency of pulsed CO2 laser ablation of burned and normal swine skin was studied in vitro with a mass loss technique. The heats of ablation for normal and burned skin were 2,706 and 2,416 J/cm3 of tissue ablated, respectively. The mean threshold radiant exposures for ablating normal skin and eschar were 2.6 J/cm2 and 3.0 J/cm2, respectively. Radiant exposures greater than 19 J/cm2 produced a plasma, which decreased the efficiency of laser ablation. Thus the radiant exposures for efficient ablation range from 4 to 19 J/cm2, and within this radiant exposure range 20-40 microns of tissue are ablated per pulse. We also examined, on a gross and histopathologic basis, in vivo burn eschar excision with a pulsed CO2 laser. The laser allowed bloodless excisions of full thickness burns on the backs of male hairless rats. The zone of thermal damage was approximately 85 microns over the subjacent fascia. The pulsed CO2 laser can ablate burn eschar efficiently, precisely, and bloodlessly and may prove valuable for the excision of burned and necrotic tissue.

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Skin Graft Take and Healing Following 193-nm Excimer, Continuous-Wave Carbon Dioxide (CO2), Pulsed CO2, or Pulsed Holmium:YAG Laser Ablation of the Graft Bed

Green

Burd

Nishioka

et al. 1993

Arch Dermatol

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Burn Depth Estimation Using Indocyanine Green Fluorescence

Green

Bua²,

Anderson³

et al. 1992

Arch Dermatol

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Expedient primary excision of deep dermal and full-thickness burn wounds with subsequent skin grafting is the standard of care in most burn institutions, but differentiating full-thickness from partial-thickness burns is often difficult. Because accurate early assessment of burn depth may improve care, a variety of technical methods have attempted to measure burn depth but these methods have had limited success. We describe a new technique to determine burn depth that uses infrared (840- to 850-nm) fluorescence emission from intravenously administered indocyanine green following excitation with infrared (780 nm) and UV light (369 nm). Full-thickness and partial-thickness burns in hairless rat skin were distinguished based on the infrared-induced and UV-induced fluorescence intensity ratios relative to normal, unburned skin immediately after the burn and on post-burn days 1 through 3 and 7. Dual-wavelength excitation of indocyanine green infrared fluorescence can delineate full-thickness from partial-thickness burns at an early date, allowing prognosis, surgical planning, and early primary excision and grafting.

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Howard A. Green

Pulsed carbon dioxide laser ablation of burned skin: In vitro and in vivo analysis

Skin Graft Take and Healing Following 193-nm Excimer, Continuous-Wave Carbon Dioxide (CO2), Pulsed CO2, or Pulsed Holmium:YAG Laser Ablation of the Graft Bed

Burn Depth Estimation Using Indocyanine Green Fluorescence

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