MODELING THE IMPACT OF LASER IRRADIATION ON TEMPERATURE CHANGES IN BIOLOGICAL TISSUES

Abstract

Modeling the impact of laser irradiation (MILI) on biological tissues plays a crucial role in research and the development of laser technologies in biology and medicine. MILI opens a wide spectrum of knowledge for scientists and medical professionals, providing insights into how laser radiation interacts with different types of tissues and organs and determining optimal parameters to achieve the desired outcome. Models can account for various physical processes occurring during irradiation, such as energy absorption, heat propagation, changes in tissue structure, and functions. This enables the prediction of tissue responses to different laser exposure regimes, including intensity, wavelength, and exposure time. In medicine, modeling is used to determine optimal laser exposure parameters for specific diseases or procedures. For example, MILI helps identify the optimal radiation dose during laser therapy or surgical interventions. Additionally, modeling allows for the assessment of potential risks associated with laser radiation, such as tissue overheating or side effects. This, in turn, enhances the development of safer and more effective laser application methods. Moreover, optimizing laser irradiation parameters is relevant for minimizing the risk of damage to surrounding tissues. MILI can be used to develop new laser technologies and devices aimed at improving the outcomes of laser applications in medicine. It also facilitates the faster and more efficient implementation of new methods and technologies into clinical practice. Thus, modeling the impact of laser irradiation on temperature changes in biological tissues plays a vital role in enhancing understanding of processes in biological tissues and contributes to the development of new methods and technologies, as well as the optimization of laser application for achieving effective treatment outcomes and patient safety.