Breast Cancer Screening Using Inverse Modeling of Surface Temperatures and Steady-State Thermal Imaging

Cancer is characterized by increased metabolic activity and vascularity, leading to temperature changes in cancerous tissues compared to normal cells. This study focused on patients with abnormal mammogram findings or a clinical suspicion of breast cancer, exclusively those confirmed by biopsy. Util...

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Veröffentlicht in:	Cancers 2024-06, Vol.16 (12), p.2264
Hauptverfasser:	Sritharan, Nithya, Gutierrez, Carlos, Perez-Raya, Isaac, Gonzalez-Hernandez, Jose-Luis, Owens, Alyssa, Dabydeen, Donnette, Medeiros, Lori, Kandlikar, Satish, Phatak, Pradyumna
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Sprache:	eng
Schlagworte:	Algorithms Biopsy Breast cancer Cancer screening Heat detection Heat transfer Magnetic resonance imaging Mammography Medical screening Metabolism Patients Population studies Prediction models Radiation Sensitivity analysis Software Temperature Tumors Ultrahigh temperature Womens health
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container_issue	12
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container_title	Cancers
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creator	Sritharan, Nithya Gutierrez, Carlos Perez-Raya, Isaac Gonzalez-Hernandez, Jose-Luis Owens, Alyssa Dabydeen, Donnette Medeiros, Lori Kandlikar, Satish Phatak, Pradyumna
description	Cancer is characterized by increased metabolic activity and vascularity, leading to temperature changes in cancerous tissues compared to normal cells. This study focused on patients with abnormal mammogram findings or a clinical suspicion of breast cancer, exclusively those confirmed by biopsy. Utilizing an ultra-high sensitivity thermal camera and prone patient positioning, we measured surface temperatures integrated with an inverse modeling technique based on heat transfer principles to predict malignant breast lesions. Involving 25 breast tumors, our technique accurately predicted all tumors, with maximum errors below 5 mm in size and less than 1 cm in tumor location. Predictive efficacy was unaffected by tumor size, location, or breast density, with no aberrant predictions in the contralateral normal breast. Infrared temperature profiles and inverse modeling using both techniques successfully predicted breast cancer, highlighting its potential in breast cancer screening.
doi_str_mv	10.3390/cancers16122264
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subjects	Algorithms Biopsy Breast cancer Cancer screening Heat detection Heat transfer Magnetic resonance imaging Mammography Medical screening Metabolism Patients Population studies Prediction models Radiation Sensitivity analysis Software Temperature Tumors Ultrahigh temperature Womens health
title	Breast Cancer Screening Using Inverse Modeling of Surface Temperatures and Steady-State Thermal Imaging
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