The effect of laser beam profile on brain cancer treatment through photothermal therapy

Q4 Physics and Astronomy Iranian Journal of Physics Research Pub Date : 2023-06-01 DOI:10.47176/ijpr.23.1.11603
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Abstract

Brain cancer has the lowest survival percentage among different cancers and it has caused the death of people under 40 more than others. Therefore, in this paper, the treatment of brain cancer with non-invasive photothermal therapy is investigated and the effect of various treatment factors including laser power full width at half maximum (FWHM) of the laser beam profile on the success of the treatment is evaluated. The simulations are performed by solving the three-dimensional Pennes bioheat transfer equation, Beer–Lambert law, and by considering the presence of gold nanorods, the Gaussian laser profile, as well as the initial and boundary conditions with the finite element method (FEM). The results of the investigations demonstrate that the laser power and radius of the laser spot are two important quantities in the success of the treatment. These two quantities affect the dose of thermal energy received by the cancerous tissue and control the temperature and fraction of tumour and tissue damage in different positions. Also, smaller and larger radii of laser spot than 1.1R (R is the radius of the brain tumour) lead to more and less temperature differences, respectively, in different parts of the tumour. However, the highest temperature and temperature rate can be obtained at the upper center point of the cancerous tissue in all treatment conditions. In addition, increasing the laser power from 0.5 to 1 W causes an increase in the temperature in different points of the tumour and irreversible destruction continues even after turning off the laser due to the tumor temperature in a different position beeing higher than 42 °C, as well as heat transfer due to conduction and convection.
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激光束轮廓对光热治疗脑癌的影响
在各种癌症中,脑癌的存活率最低,40岁以下的人死于脑癌的人数多于其他癌症。因此,本文对无创光热治疗脑癌进行了研究,并评价了包括激光功率半最大全宽(FWHM)在内的各种治疗因素对治疗成功的影响。通过求解三维Pennes生物传热方程、Beer-Lambert定律,并考虑金纳米棒的存在、高斯激光轮廓以及初始条件和边界条件,采用有限元法进行了模拟。研究结果表明,激光功率和激光光斑半径是影响治疗成功的两个重要因素。这两个量影响癌组织接受的热能剂量,并控制不同位置肿瘤和组织损伤的温度和比例。此外,激光光斑半径小于1.1R (R为脑肿瘤半径)和大于1.1R会导致肿瘤不同部位的温差增大和减小。然而,在所有治疗条件下,在癌组织的上中心点均可获得最高温度和温度速率。此外,将激光功率从0.5 W增加到1 W,由于不同位置的肿瘤温度高于42°C,以及传导和对流的传热,导致肿瘤不同位置的温度升高,即使在关闭激光后也会继续不可逆破坏。
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来源期刊
Iranian Journal of Physics Research
Iranian Journal of Physics Research Physics and Astronomy-Physics and Astronomy (all)
CiteScore
0.20
自引率
0.00%
发文量
0
审稿时长
30 weeks
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