ORCID Profile
0000-0002-0706-3835
Current Organisation
Abu Dhabi University
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Publisher: JMIR Publications Inc.
Date: 09-11-2021
Abstract: he most common dermatological complication of insulin therapy is lipohypertrophy. s a proof of concept, we built and tested an automated model using a convolutional neural network (CNN) to detect the presence of lipohypertrophy in ultrasound images. ltrasound images were obtained in a blinded fashion using a portable GE LOGIQ i e /i machine with an L8-18I-D probe (5-18 MHz GE Healthcare). The data were split into train, validation, and test splits of 70%, 15%, and 15%, respectively. Given the small size of the data set, image augmentation techniques were used to expand the size of the training set and improve the model’s generalizability. To compare the performance of the different architectures, the team considered the accuracy and recall of the models when tested on our test set. he DenseNet CNN architecture was found to have the highest accuracy (76%) and recall (76%) in detecting lipohypertrophy in ultrasound images compared to other CNN architectures. Additional work showed that the YOLOv5m object detection model could be used to help detect the approximate location of lipohypertrophy in ultrasound images identified as containing lipohypertrophy by the DenseNet CNN. e were able to demonstrate the ability of machine learning approaches to automate the process of detecting and locating lipohypertrophy.
Publisher: IEEE
Date: 06-2019
Publisher: JMIR Publications Inc.
Date: 06-05-2022
DOI: 10.2196/34830
Abstract: The most common dermatological complication of insulin therapy is lipohypertrophy. As a proof of concept, we built and tested an automated model using a convolutional neural network (CNN) to detect the presence of lipohypertrophy in ultrasound images. Ultrasound images were obtained in a blinded fashion using a portable GE LOGIQ e machine with an L8-18I-D probe (5-18 MHz GE Healthcare). The data were split into train, validation, and test splits of 70%, 15%, and 15%, respectively. Given the small size of the data set, image augmentation techniques were used to expand the size of the training set and improve the model’s generalizability. To compare the performance of the different architectures, the team considered the accuracy and recall of the models when tested on our test set. The DenseNet CNN architecture was found to have the highest accuracy (76%) and recall (76%) in detecting lipohypertrophy in ultrasound images compared to other CNN architectures. Additional work showed that the YOLOv5m object detection model could be used to help detect the approximate location of lipohypertrophy in ultrasound images identified as containing lipohypertrophy by the DenseNet CNN. We were able to demonstrate the ability of machine learning approaches to automate the process of detecting and locating lipohypertrophy.
No related grants have been discovered for Anas Al Tarabsheh.