Three-dimensional model for skin tumor using plasmonic nanoparticles distribution and tissue optical clearing

“…We emphasize that the model was simplified due to the uniform distribution of particles in the tumor volume that contributed to a high absorption coefficient of tumor tissue at a wavelength of 808 nm. This simplification is widely used by many authors to simulate the propagation of laser radiation and heat in similar tasks [22, 65–68]. Our results agree with previous simulations [68–70], demonstrating stronger skin heating than a tumor without additional absorbers in the form of plasmonic nanoparticles or dyes.…”

Monitoring of optical properties of tumors during laser plasmon photothermal therapy

“…We emphasize that the model was simplified due to the uniform distribution of particles in the tumor volume that contributed to a high absorption coefficient of tumor tissue at a wavelength of 808 nm. This simplification is widely used by many authors to simulate the propagation of laser radiation and heat in similar tasks [22, 65–68]. Our results agree with previous simulations [68–70], demonstrating stronger skin heating than a tumor without additional absorbers in the form of plasmonic nanoparticles or dyes.…”

Monitoring of optical properties of tumors during laser plasmon photothermal therapy