Karen M. McNally-Heintzelman scite author profile

Quantitative data regarding photothermal and damage processes during pulsed laser irradiation of blood are necessary to achieve a better understanding of laser treatment of cutaneous vascular lesions and improve numerical models. In this study, multiple experimental techniques were employed to quantify the effects of single-pulse KTP laser (X = 532 nm, t, = 10 ms) irradiation of whole blood in vitro: high-speed temperature measurement with a thermal camera in line-scan mode (8 kHz); optical coherence tomography (for determination of coagulum morphology); and transmission measurement with a co-aligned laser beam (X = 635 nm) Threshold radiant exposures for coagulation (4.4-5.0 J/cm2) and ablation (-12 J/cm2) were identified. Thermal camera measurements indicated threshold coagulation temperatures of 90-100 °C, and peak temperatures of up to 145 °C for sub-ablation radiant exposures. Significant changes in coagulum thickness and consistency, and a corresponding decrease in transmission, were observed with increasing radiant exposure. The Arrhenius equation was shown to produce accurate predictions of coagulation onset (using appropriate rate process coefficients). The significance of dynamic effects such as evaporative loss and dynamic changes in optical properties was indicated. Implications for numerical modeling are discussed. Most importantly, the threshold temperatures typically quoted in the literature for pulsed laser coagulation (60-70 °C) and ablation (100 °C) of blood do not match the results of this study.

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Comparison of scaffold-enhanced albumin and n-butyl-cyanoacrylate adhesives for joining of tissue in a porcine model

McNally-Heintzelman

Riley

Heintzelman³

2003

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Alternative chromophores for use in light-activated surgical adhesives: optimization of parameters for tensile strength and thermal damage profile

Hoffman

Byrd

Soller

et al. 2003

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The use of indocyanine green-doped albumin protein solders has been shown to vastly improve the anastomotic strength that can be achieved by laser tissue repair techniques, while at the same time minimizing collateral thermal tissue damage. However, the safety of the degradation products of the chromophore following laser irradiation is uncertain. Therefore, we studied the feasibility of using alternative chromophores in terms of temperature rise at the solder/tissue interface, the extent of thermal damage in the surrounding tissue, and the tensile strength of repairs. Biodegradable polymer scaffolds of controlled porosity were fabricated with poly(L-lactic-co-glycolic acid), using a solvent-casting and particulate-leaching technique. The porous scaffold acted as a carrier to the traditional protein solder composition of serum albumin and an absorbing chromophore mixed in deionized water. Two commonly used chromophores, indocyanine green and methylene blue were investigated, as well as blue and green food colorings.Temperature rise at the solder surface and at the interface between the solder and tissue were monitored by an IR temperature monitoring system and a type-K thermocouple, respectively, and the extent of thermal damage in the underlying tissue was determined using light microscopy. As expected, temperature rise at the solder/tissue interface, and consequently the degree of collateral thermal tissue damage, was directly related to the penetration depth of the laser light in the protein solder. Optimal tensile strength of repairs was achieved by selecting a chromophore concentration that resulted in a temperature of 66 ± 3 °C at the solder/tissue interface.

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