Please use this identifier to cite or link to this item: http://repositorio.ufc.br/handle/riufc/73347
Type: Artigo de Periódico
Title: Internet of medical things-based on deep learning techniques for segmentation of lung and stroke regions in ct scans
Authors: Han, Tan
Nunes, Virgínia Xavier
Souza, Luís Fabrício de Freitas
Marques, Adriell Gomes
Silva, Iágson Carlos Lima
Ferreira Junior, Marcos Aurélio Araujo
Sun, Jinghua
Rebouças Filho, Pedro Pedrosa
Keywords: Health of things;Classification and segmentation;Transfer learning;Saúde das coisas;Classificação e segmentação;Transferência de aprendizagem
Issue Date: 2020
Publisher: IEEE Access
Citation: HAN, Tan; NUNES, Virgínia Xavier; SOUZA, Luís Fabrício de Freitas; MARQUES, Adriell Gomes; SILVA, Iágson Carlos Lima; FERREIRA JÚNIOR, Marcos Aurélio Araujo; SUN, Jinghua; REBOUÇAS FILHO, Pedro Pedrosa. Internet of medical things-based on deep learning techniques for segmentation of lung and stroke regions in ct scans. IEEE Access, [s.l.], v. 8, p. 71117 - 71135, 2020.
Abstract: The classification and segmentation of pathologies through intelligent systems is a significant challenge for medical image analysis and computer vision systems. Diseases, such as lung problems and strokes, have a serious effect on human health worldwide. Lung diseases are among the leading causes of death worldwide, lagging behind strokes that in 2016 became the second leading cause of death from illnesses. Computed tomography (CT) is one of the main clinical diagnostic exams, linked to Computerized Diagnostic Assistance Systems (CAD), which are becoming solutions for health technologies. In this work, we propose a method based on the health of things for the classification and segmentation of CT images of the lung and hemorrhagic stroke. The system called HTSCS - Medical Images: Health-of-Things System for the Classification and Segmentation of Medical Images, uses transfer learning between models based on deep learning combined with classical methods for fine-tuning. The proposed method obtained excellent results for the classification of hemorrhagic stroke and pulmonary regions, with values of up to 100% accuracy. The models also achieved outstanding performances for segmentation, with Accuracy above 99 % and Dice coefficient above 97% in the best cases with an average segmentation time between 0.095 and 1.7 seconds. To validate our approach, we compared our best models for the segmentation of lung and hemorrhagic stroke in CTs, with related works found in state of the art. Our method brings an innovative approach to classification and segmentation through the use of the Health of Things for different types of medical images with promising results for medical image analysis and computer vision fields
URI: http://www.repositorio.ufc.br/handle/riufc/73347
ISSN: 2169-3536
Access Rights: Acesso Aberto
Appears in Collections:DEEL - Artigos publicados em revista científica

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