Human female breast is composed of skin, fibrous tissue, breast glands and fat. Breast cancer is a malignant tumor that occurs in the epithelial tissue of breast glands. The breast is not an important organ for maintaining human life. Breast cancer in situ is not fatal; however, because breast cancer cells lose the characteristics of normal cells, the connections between cells are loose and easy to fall off. Once the cancer cells fall off, the free cancer cells can spread throughout the body with the blood or lymph fluid, forming metastases, and endangering life. Breast cancer has become a common tumor threatening women's physical and mental health. Therefore, studying the interaction between laser and breast tissue and breast tumors has important theoretical and practical significance for the treatment of breast cancer. To this end, this research uses the commercial finite element simulation software COMSOL Multiphysics to develop a two-dimensional numerical simulation model based on finite element, which studies the propagation and heat transfer of light in the breast of breast cancer patients. In this study, the model consists of four parts: 1) water layer; 2) breast; 3) breast tumor; 4) short pulse laser source (wavelength is 840nm). The laser point source is located in the middle of the water layer above the breast tissue to irradiate the breast and tumor. Simulate the propagation of light in the breast and tumor by solving the diffusion equation. The temperature changes of breast tissue and breast tumors are obtained by solving the biological heat transfer equation. This research helps to understand the spread of light in human breasts and breast tumors and the interaction between the two, and has certain theoretical guiding significance for the research and treatment of breast cancer.
The study of the interaction between laser and mouse brain tissue has important theoretical and practical significance for brain imaging. A two-dimensional simulation model that studies the propagation of light and heat transfer in brain tissue based on finite element has been developed by using the commercial finite element simulation software COMSOL Multiphysics. In this study, the model consists of three parts of 1) a layer of water on the surface of the brain, 2) brain tissue and 3) short pulsed laser source (the wavelength is 840nm). The laser point source is located in the middle of the layer of water above the brain tissue and irradiates the brain tissue. The propagation of light in brain tissue was simulated by solving the diffusion equation. And the temperature changes of gray matter and blood vessels were achieved by solving the biological heat transfer equation. The simulation results show that the light energy in the brain tissue decreases exponentially with the increase of penetration depth. Since the cerebral blood vessels have a stronger absorption on light compared with the surrounding tissues, the remaining light energy of the blood vessel in the cerebral cortex is ~ 74.86 % of the remaining light energy in the surrounding gray matter. In the process of biological heat transfer, due to more light deposition in blood vessels, the temperature of blood vessels is 0.65 K higher than that of gray matter, and the temperature of gray matter hardly changes. This research is helpful to understand the propagation of light in the brain and the interaction between them, and has certain theoretical guiding for the optical imaging of the brain.
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