{"title":"癌症乳房模型的热分析","authors":"Arjun Chanmugam, Rajeev Hatwar, Cila Herman","doi":"10.1115/IMECE2012-88244","DOIUrl":null,"url":null,"abstract":"<p><p>Breast cancer is one of the most common and dangerous cancers. Subsurface breast cancer lesions generate more heat and have increased blood supply when compared to healthy tissue, and this temperature rise is mirrored in the skin surface temperature. The rise in temperature on the skin surface, caused by the cancerous lesion, can be measured noninvasively using infrared thermography, which can be used as a diagnostic tool to detect the presence of a lesion. However, its diagnostic ability is limited when image interpretation relies on qualitative principles. In this study, we present a quantitative thermal analysis of breast cancer using a 3D computational model of the breast. The COMSOL FEM software was used to carry out the analysis. The effect of various parameters (tumor size, location, metabolic heat generation and blood perfusion rate) on the surface temperature distribution (which can be measured with infrared thermography) has been analyzed. Key defining features of the surface temperature profile have been identified, which can be used to estimate the size and location of the tumor based on (measured) surface temperature data. In addition, we employed a dynamic cooling process, to analyze surface temperature distributions during cooling and thermal recovery as a function of time. In this study, the effect of the cooling temperature on the enhancement of the temperature differences between normal tissue and cancerous lesions is evaluated. This study demonstrates that a quantification of temperature distributions by computational modeling, combined with thermographic imaging and dynamic cooling can be an important tool in the early detection of breast cancer.</p>","PeriodicalId":73488,"journal":{"name":"International Mechanical Engineering Congress and Exposition : [proceedings]. International Mechanical Engineering Congress and Exposition","volume":"2012 ","pages":"134-143"},"PeriodicalIF":0.0000,"publicationDate":"2012-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4199207/pdf/nihms-468671.pdf","citationCount":"0","resultStr":"{\"title\":\"Thermal analysis of cancerous breast model.\",\"authors\":\"Arjun Chanmugam, Rajeev Hatwar, Cila Herman\",\"doi\":\"10.1115/IMECE2012-88244\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><p>Breast cancer is one of the most common and dangerous cancers. Subsurface breast cancer lesions generate more heat and have increased blood supply when compared to healthy tissue, and this temperature rise is mirrored in the skin surface temperature. The rise in temperature on the skin surface, caused by the cancerous lesion, can be measured noninvasively using infrared thermography, which can be used as a diagnostic tool to detect the presence of a lesion. However, its diagnostic ability is limited when image interpretation relies on qualitative principles. In this study, we present a quantitative thermal analysis of breast cancer using a 3D computational model of the breast. The COMSOL FEM software was used to carry out the analysis. The effect of various parameters (tumor size, location, metabolic heat generation and blood perfusion rate) on the surface temperature distribution (which can be measured with infrared thermography) has been analyzed. Key defining features of the surface temperature profile have been identified, which can be used to estimate the size and location of the tumor based on (measured) surface temperature data. In addition, we employed a dynamic cooling process, to analyze surface temperature distributions during cooling and thermal recovery as a function of time. In this study, the effect of the cooling temperature on the enhancement of the temperature differences between normal tissue and cancerous lesions is evaluated. This study demonstrates that a quantification of temperature distributions by computational modeling, combined with thermographic imaging and dynamic cooling can be an important tool in the early detection of breast cancer.</p>\",\"PeriodicalId\":73488,\"journal\":{\"name\":\"International Mechanical Engineering Congress and Exposition : [proceedings]. 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引用次数: 0
摘要
乳腺癌是最常见、最危险的癌症之一。与健康组织相比,乳腺癌的表皮下病灶会产生更多的热量,血液供应也会增加,这种温度升高会反映在皮肤表面温度上。癌症病灶引起的皮肤表面温度升高可以通过红外热成像技术进行无创测量,该技术可用作检测病灶是否存在的诊断工具。然而,如果图像解读依赖于定性原则,其诊断能力就会受到限制。在本研究中,我们利用乳房的三维计算模型对乳腺癌进行了定量热分析。分析使用了 COMSOL FEM 软件。分析了各种参数(肿瘤大小、位置、代谢产热和血液灌注率)对表面温度分布(可通过红外热成像测量)的影响。我们确定了表面温度分布的关键定义特征,这些特征可用于根据(测量到的)表面温度数据估计肿瘤的大小和位置。此外,我们还采用了动态冷却过程,分析冷却过程中的表面温度分布以及热恢复与时间的函数关系。在这项研究中,我们评估了冷却温度对增强正常组织和癌症病灶之间温度差异的影响。这项研究表明,通过计算建模对温度分布进行量化,并结合热成像和动态冷却,可以成为乳腺癌早期检测的重要工具。
Breast cancer is one of the most common and dangerous cancers. Subsurface breast cancer lesions generate more heat and have increased blood supply when compared to healthy tissue, and this temperature rise is mirrored in the skin surface temperature. The rise in temperature on the skin surface, caused by the cancerous lesion, can be measured noninvasively using infrared thermography, which can be used as a diagnostic tool to detect the presence of a lesion. However, its diagnostic ability is limited when image interpretation relies on qualitative principles. In this study, we present a quantitative thermal analysis of breast cancer using a 3D computational model of the breast. The COMSOL FEM software was used to carry out the analysis. The effect of various parameters (tumor size, location, metabolic heat generation and blood perfusion rate) on the surface temperature distribution (which can be measured with infrared thermography) has been analyzed. Key defining features of the surface temperature profile have been identified, which can be used to estimate the size and location of the tumor based on (measured) surface temperature data. In addition, we employed a dynamic cooling process, to analyze surface temperature distributions during cooling and thermal recovery as a function of time. In this study, the effect of the cooling temperature on the enhancement of the temperature differences between normal tissue and cancerous lesions is evaluated. This study demonstrates that a quantification of temperature distributions by computational modeling, combined with thermographic imaging and dynamic cooling can be an important tool in the early detection of breast cancer.