Bayesian-Edge system for classification and segmentation of skin lesions in Internet of Medical Things

被引:2
作者
Naseem, Shahid [1 ]
Anwar, Muhammad [1 ]
Faheem, Muhammad [2 ]
Fayyaz, Muhammad [3 ]
Malik, Muhammad Sheraz Arshad [4 ]
机构
[1] Univ Educ, Dept Informat Sci, Div Sci & Technol, Lahore, Pakistan
[2] Univ Vaasa, Sch Technol & Innovat, Vaasa, Finland
[3] FAST Natl Univ Comp & Emerging Sci, Dept Comp Sci, Chiniot Faisalabad Campus, Islamabad, Pakistan
[4] Univ Faisalabad, Govt Coll, Dept Software Engn, Faisalabad, Pakistan
关键词
auto-immune pathogenic traits; Bayesian inference; edge intelligence; internet of things; malignance; psoriasis; skin lesions; DERMOSCOPY IMAGES; DISEASE;
D O I
10.1111/srt.13878
中图分类号
R75 [皮肤病学与性病学];
学科分类号
100206 ;
摘要
BackgroundSkin diseases are severe diseases. Identification of these severe diseases depends upon the abstraction of atypical skin regions. The segmentation of these skin diseases is essential to rheumatologists in risk impost and for valuable and vital decision-making. Skin lesion segmentation from images is a crucial step toward achieving this goal-timely exposure of malignancy in psoriasis expressively intensifies the persistence ratio. Defies occur when people presume skin diseases they have without accurately and precisely incepted. However, analyzing malignancy at runtime is a big challenge due to the truncated distinction of the visual similarity between malignance and non-malignance lesions. However, images' different shapes, contrast, and vibrations make skin lesion segmentation challenging. Recently, various researchers have explored the applicability of deep learning models to skin lesion segmentation.Materials and methodsThis paper introduces a skin lesions segmentation model that integrates two intelligent methodologies: Bayesian inference and edge intelligence. In the segmentation model, we deal with edge intelligence to utilize the texture features for the segmentation of skin lesions. In contrast, Bayesian inference enhances skin lesion segmentation's accuracy and efficiency.ResultsWe analyze our work along several dimensions, including input data (datasets, preprocessing, and synthetic data generation), model design (architecture, modules), and evaluation aspects (data annotation requirements and segmentation performance). We discuss these dimensions from seminal works and a systematic viewpoint and examine how these dimensions have influenced current trends.ConclusionWe summarize our work with previously used techniques in a comprehensive table to facilitate comparisons. Our experimental results show that Bayesian-Edge networks can boost the diagnostic performance of skin lesions by up to 87.80% without incurring additional parameters of heavy computation.
引用
收藏
页数:14
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