Description

Breast cancer, a widespread and potentially fatal illness, emphasizes the urgent requirement for early and precise detection to enhance patient outcomes. The current diagnostic framework, characterized by manual histopathological examination, exhibits inherent drawbacks such as subjectivity and limited throughput. In response, our research aims to transform breast cancer diagnostics by leveraging advanced computational techniques, particularly deep learning. Breast cancer can be classified into two main subtypes: invasive and noninvasive.

Noninvasive breast cancer, often termed in situ breast cancer, is characterized by abnormal cells confined within the milk ducts (ductal carcinoma in situ or DCIS) or lobules (lobular carcinoma in situ or LCIS) without invading surrounding tissues. This type is considered an early stage and typically not life-threatening on its own. Invasive breast cancers are those that spread from the original site (either the milk ducts or the lobules) into the surrounding breast tissue. These constitute approximately 70% of all breast cancer cases and generally have a poorer prognosis compared to the in-situ subtypes.

Medical imaging of breasts can be acquired through various techniques, such as MRI scans, mammography, ultrasound, thermography, computed tomography scans, and histopathology. Among these approaches, the histopathology test serves as the gold standard for the clinical diagnosis of cancer.

The proposed AI model aims to streamline and enhance the analysis of histopathological images for the classification of invasive and noninvasive breast cancer, surpassing conventional methods and providing a reliable means of identifying cancerous regions. This promises to significantly improve the accuracy and efficiency of breast cancer diagnostics, meeting the urgent need for dependable and scalable solutions. By automating the complex process of breast cancer histopathological image analysis, our goal is to democratize screening, making it more accessible and reaching underserved populations. Moreover, our model goes beyond technological innovation; it addresses broader issues of accessibility and scalability, particularly in low-income settings. The research's focus on domain adaptation is crucial, ensuring the model's accuracy and reliability across various health facilities. This involves accommodating differences in resources, equipment, and demographic factors, making it a versatile and adaptable solution for diverse contexts.

In summary, our research not only aims to advance the technological frontier in breast cancer diagnostics but also seeks to drive a transformative change in accessibility, efficiency, and reliability. By developing an AI model that tackles the specific challenges of traditional methods, we aim to make a meaningful impact on breast cancer screening, ultimately leading to early detection, tailored treatment, and improved outcomes for patients worldwide.