Histological and modeling study of skin thermal injury to 2.0 microm laser irradiation.

Background And Objective: Qualitative and quantitative gross histopathologic studies of skin damage were performed at 48 hours after irradiation with a 2.0 microm thulium CW laser to determine the mechanisms of laser effects in the skin under various exposure conditions.

Study Design/materials And Methods: Pig skin lesions were created at, below and beyond the threshold irradiation conditions for grossly apparent thermal lesions.

Corneal minimal visible lesion thresholds for 2.0 microm laser radiation.

To support refinement of the ANSI Maximum Permissible Exposure safety limits, a series of experiments were conducted in vivo on Dutch Belted rabbit corneas to determine corneal minimum visible lesion thresholds for 2.0 microm continuous-wave laser irradiation. Single pulse radiant exposures were made at specified pulse durations of 0.

Effect of pigmentation density upon 2.0 microm laser irradiation thermal response.

Yucatan mini-pigs with predominantly dark skin have been used to determine skin safety standards for infrared (IR) wavelength irradiation due to its anatomical similarity to all human skin. It has generally been argued that water is the principle absorber in the IR-B band and melanin has relatively low absorbance. To accept dark pigmented damage thresholds for skin with various melanin densities, it is necessary to investigate the potential role of melanin in producing skin injury as characterized by an erythermal response.

Modeling thermal damage in skin from 2000-nm laser irradiation.

An optical-thermal-damage model of the skin under laser irradiation is developed by using finite-element modeling software (FEMLAB 3.1, Comsol, Incorporated, Burlington, Massachusetts). The general model simulates light propagation, heat generation, transient temperature response, and thermal damage produced by a radically symmetric laser beam of normal incidence.

Porcine skin ED50 damage thresholds for 2,000 nm laser irradiation.

Background And Objectives: To gain refinement in safe-exposure limits, indicated by the maximum permissible exposure (MPE) limits, the minimum visible lesion thresholds for three spot sizes (5-15 mm) and four exposure durations (0.25-2.5 seconds) were determined for the skin at 2,000 nm continuous wave laser irradiation.

Effects of cryogen spray cooling and high radiant exposures on selective vascular injury during laser irradiation of human skin.

Background: Increasing radiant exposure offers a means to increase treatment efficacy during laser-mediated treatment of vascular lesions, such as port-wine stains; however, excessive radiant exposure decreases selective vascular injury due to increased heat generation within the epidermis and collateral damage to perivascular collagen.

Objective: To determine if cryogen spray cooling could be used to maintain selective vascular injury (ie, prevent epidermal and perivascular collagen damage) when using high radiant exposures (16-30 J/cm2).

Design: Observational study.