Melanoma is the deadliest form of skin cancer. Early diagnosis of malignant lesions is crucial for reducing mortality. The use of deep learning techniques on dermoscopic images can help in keeping track of the change over time in the appearance of the lesion, which is an important factor for detecting malignant lesions. In this paper, we present a deep learning architecture called Attention Squeeze U-Net for skin lesion area segmentation specifically designed for embedded devices. The main goal is to increase the patient empowerment through the adoption of deep learning algorithms that can run locally on smartphones or low cost embedded devices. This can be the basis to (1) create a history of the lesion, (2) reduce patient visits to the hospital, and (3) protect the privacy of the users. Quantitative results on publicly available data demonstrate that it is possible to achieve good segmentation results even with a compact model.
Skin Lesion Area Segmentation Using Attention Squeeze U-Net for Embedded Devices / Pennisi, Andrea; Bloisi, Domenico D; Suriani, Vincenzo; Nardi, Daniele; Facchiano, Antonio; Giampetruzzi, Anna Rita. - In: JOURNAL OF DIGITAL IMAGING. - ISSN 0897-1889. - 35:5(2022), pp. 1217-1230. [10.1007/s10278-022-00634-7]
Skin Lesion Area Segmentation Using Attention Squeeze U-Net for Embedded Devices
Pennisi, Andrea;Bloisi, Domenico D;Suriani, Vincenzo;Nardi, Daniele;
2022
Abstract
Melanoma is the deadliest form of skin cancer. Early diagnosis of malignant lesions is crucial for reducing mortality. The use of deep learning techniques on dermoscopic images can help in keeping track of the change over time in the appearance of the lesion, which is an important factor for detecting malignant lesions. In this paper, we present a deep learning architecture called Attention Squeeze U-Net for skin lesion area segmentation specifically designed for embedded devices. The main goal is to increase the patient empowerment through the adoption of deep learning algorithms that can run locally on smartphones or low cost embedded devices. This can be the basis to (1) create a history of the lesion, (2) reduce patient visits to the hospital, and (3) protect the privacy of the users. Quantitative results on publicly available data demonstrate that it is possible to achieve good segmentation results even with a compact model.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
