Deep Transfer Learning with Enhanced Feature Fusion for Detection of Abnormalities in X-ray Images

Alammar, Zaenab; Alzubaidi, Laith; Zhang, Jinglan; Li, Yuefeng; Lafta, Waail; Gu, Yuantong

doi:10.3390/cancers15154007

Cited by 16 publications

(2 citation statements)

References 65 publications

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“…In this study, we introduce LeishFuNet, a deep learning model designed for the detection of Leishmania patients from their microscopic images. Leveraging transfer learning, specifically employing a feature fusion technique known to be beneficial for models trained on small-sized datasets [ 31 – 33 ], our model demonstrates promising capabilities in this domain. The key contributions of our research are as follows:…”

Section: Introductionmentioning

confidence: 99%

A deep learning-based model for detecting Leishmania amastigotes in microscopic slides: a new approach to telemedicine

Sadeghi,

Fakhar

et al. 2024

BMC Infect Dis

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Background Leishmaniasis, an illness caused by protozoa, accounts for a substantial number of human fatalities globally, thereby emerging as one of the most fatal parasitic diseases. The conventional methods employed for detecting the Leishmania parasite through microscopy are not only time-consuming but also susceptible to errors. Therefore, the main objective of this study is to develop a model based on deep learning, a subfield of artificial intelligence, that could facilitate automated diagnosis of leishmaniasis. Methods In this research, we introduce LeishFuNet, a deep learning framework designed for detecting Leishmania parasites in microscopic images. To enhance the performance of our model through same-domain transfer learning, we initially train four distinct models: VGG19, ResNet50, MobileNetV2, and DenseNet 169 on a dataset related to another infectious disease, COVID-19. These trained models are then utilized as new pre-trained models and fine-tuned on a set of 292 self-collected high-resolution microscopic images, consisting of 138 positive cases and 154 negative cases. The final prediction is generated through the fusion of information analyzed by these pre-trained models. Grad-CAM, an explainable artificial intelligence technique, is implemented to demonstrate the model’s interpretability. Results The final results of utilizing our model for detecting amastigotes in microscopic images are as follows: accuracy of 98.95 1.4%, specificity of 98 2.67%, sensitivity of 100%, precision of 97.91 2.77%, F1-score of 98.92 1.43%, and Area Under Receiver Operating Characteristic Curve of 99 1.33. Conclusion The newly devised system is precise, swift, user-friendly, and economical, thus indicating the potential of deep learning as a substitute for the prevailing leishmanial diagnostic techniques.

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Section: Introductionmentioning

confidence: 99%

A deep learning-based model for detecting Leishmania amastigotes in microscopic slides: a new approach to telemedicine

Sadeghi,

Fakhar

et al. 2024

BMC Infect Dis

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“…Deep learning has demonstrated remarkable achievements across diverse tasks, including image processing, speech recognition, and more [9]. Particularly in medical imaging, deep learning has emerged as the leading approach, exhibiting state-of-the-art performance in tasks such as image classification and segmentation [10]. For example, Chen et al [11] have shown great success with the task of cerebrovascular segmentation from time-of-flight MRI data.…”

Section: Introductionmentioning

confidence: 99%

Deep-Learning-Based Multitask Ultrasound Beamforming

Dahan,

Cohen

2023

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In this paper, we present a new method for multitask learning applied to ultrasound beamforming. Beamforming is a critical component in the ultrasound image formation pipeline. Ultrasound images are constructed using sensor readings from multiple transducer elements, with each element typically capturing multiple acquisitions per frame. Hence, the beamformer is crucial for framerate performance and overall image quality. Furthermore, post-processing, such as image denoising, is usually applied to the beamformed image to achieve high clarity for diagnosis. This work shows a fully convolutional neural network that can learn different tasks by applying a new weight normalization scheme. We adapt our model to both high frame rate requirements by fitting weight normalization parameters for the sub-sampling task and image denoising by optimizing the normalization parameters for the speckle reduction task. Our model outperforms single-angle delay and sum on pixel-level measures for speckle noise reduction, subsampling, and single-angle reconstruction.

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Artificial intelligence and multimodal data fusion for smart healthcare: topic modeling and bibliometrics

Chen,

Xie,

Tao

et al. 2024

Artif Intell Rev

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Advancements in artificial intelligence (AI) have driven extensive research into developing diverse multimodal data analysis approaches for smart healthcare. There is a scarcity of large-scale analysis of literature in this field based on quantitative approaches. This study performed a bibliometric and topic modeling examination on 683 articles from 2002 to 2022, focusing on research topics and trends, journals, countries/regions, institutions, authors, and scientific collaborations. Results showed that, firstly, the number of articles has grown from 1 in 2002 to 220 in 2022, with a majority being published in interdisciplinary journals that link healthcare and medical research and information technology and AI. Secondly, the significant rise in the quantity of research articles can be attributed to the increasing contribution of scholars from non-English speaking countries/regions and the noteworthy contributions made by authors in the USA and India. Thirdly, researchers show a high interest in diverse research issues, especially, cross-modality magnetic resonance imaging (MRI) for brain tumor analysis, cancer prognosis through multi-dimensional data analysis, and AI-assisted diagnostics and personalization in healthcare, with each topic experiencing a significant increase in research interest. There is an emerging trend towards issues such as applying generative adversarial networks and contrastive learning for multimodal medical image fusion and synthesis and utilizing the combined spatiotemporal resolution of functional MRI and electroencephalogram in a data-centric manner. This study is valuable in enhancing researchers’ and practitioners’ understanding of the present focal points and upcoming trajectories in AI-powered smart healthcare based on multimodal data analysis.

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Deep Transfer Learning with Enhanced Feature Fusion for Detection of Abnormalities in X-ray Images

Cited by 16 publications

References 65 publications

A deep learning-based model for detecting Leishmania amastigotes in microscopic slides: a new approach to telemedicine

A deep learning-based model for detecting Leishmania amastigotes in microscopic slides: a new approach to telemedicine

Deep-Learning-Based Multitask Ultrasound Beamforming

Artificial intelligence and multimodal data fusion for smart healthcare: topic modeling and bibliometrics

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