Advancing Medical Imaging Informatics by Deep Learning-Based Domain Adaptation

Choudhary, Anirudh; Li, Tong; Zhu, Yuanda; Wang, May D.

doi:10.1055/s-0040-1702009

Cited by 65 publications

(32 citation statements)

References 76 publications

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“…As stated in [24] , using the target dataset is vital for training a model, as using a different source dataset from other hospitals/clinics to train the model might yield poor test performance in the target dataset. Such distribution mismatch among different data sources is a frequent short-coming of deep learning solutions in the context of medical imaging.…”

Section: Discussionmentioning

confidence: 99%

“…Furthermore, given the different patient ethnicity’s and characteristics, along with varying imaging protocols, using a model trained with data from another set of hospitals or clinics (from possibly different countries) might yield a distribution mismatch between the training and test datasets. This possibly would yield a very low performance [23] , [24] . Therefore, training the model with data from the specific clinic/hospital where the model is intended to be used (target data), is an urgent task, which faces the challenge of dealing with very limited labelled datasets [23] , [24] , [25] .…”

Section: Introductionmentioning

confidence: 99%

“…This possibly would yield a very low performance [23] , [24] . Therefore, training the model with data from the specific clinic/hospital where the model is intended to be used (target data), is an urgent task, which faces the challenge of dealing with very limited labelled datasets [23] , [24] , [25] .…”

Section: Introductionmentioning

confidence: 99%

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Correcting data imbalance for semi-supervised COVID-19 detection using X-ray chest images

Calderón-Ramírez

Yang

Moemeni

et al. 2021

Applied Soft Computing

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A key factor in the fight against viral diseases such as the coronavirus (COVID-19) is the identification of virus carriers as early and quickly as possible, in a cheap and efficient manner. The application of deep learning for image classification of chest X-ray images of COVID-19 patients could become a useful pre-diagnostic detection methodology. However, deep learning architectures require large labelled datasets. This is often a limitation when the subject of research is relatively new as in the case of the virus outbreak, where dealing with small labelled datasets is a challenge. Moreover, in such context, the datasets are also highly imbalanced, with few observations from positive cases of the new disease. In this work we evaluate the performance of the semi-supervised deep learning architecture known as MixMatch with a very limited number of labelled observations and highly imbalanced labelled datasets. We demonstrate the critical impact of data imbalance to the model’s accuracy. Therefore, we propose a simple approach for correcting data imbalance, by re-weighting each observation in the loss function, giving a higher weight to the observations corresponding to the under-represented class. For unlabelled observations, we use the pseudo and augmented labels calculated by MixMatch to choose the appropriate weight. The proposed method improved classification accuracy by up to 18%, with respect to the non balanced MixMatch algorithm. We tested our proposed approach with several available datasets using 10, 15 and 20 labelled observations, for binary classification (COVID-19 positive and normal cases). For multi-class classification (COVID-19 positive, pneumonia and normal cases), we tested 30, 50, 70 and 90 labelled observations. Additionally, a new dataset is included among the tested datasets, composed of chest X-ray images of Costa Rican adult patients.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Correcting data imbalance for semi-supervised COVID-19 detection using X-ray chest images

Calderón-Ramírez

Yang

Moemeni

et al. 2021

Applied Soft Computing

View full text Add to dashboard Cite

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“…Domain adaptation has been proposed as one of the methods to solve the domain shift problem and is being actively studied [172,[176][177][178][179][180][181][182][183][184][185][186][187]. Domain adaptation is a type of transfer learning in which knowledge obtained from a domain with sufficient labeled training data (source domain) is applied to a target domain that lacks sufficient information (target domain) to learn things such as discriminators that work with high accuracy in the target domain (here, a domain is a collection of data).…”

Section: Discrepancies Among Facilities Especially In Medical Imaginmentioning

confidence: 99%

Application of Artificial Intelligence Technology in Oncology: Towards the Establishment of Precision Medicine

Hamamoto

Suvarna

Yamada³

et al. 2020

Cancers

116

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In recent years, advances in artificial intelligence (AI) technology have led to the rapid clinical implementation of devices with AI technology in the medical field. More than 60 AI-equipped medical devices have already been approved by the Food and Drug Administration (FDA) in the United States, and the active introduction of AI technology is considered to be an inevitable trend in the future of medicine. In the field of oncology, clinical applications of medical devices using AI technology are already underway, mainly in radiology, and AI technology is expected to be positioned as an important core technology. In particular, “precision medicine,” a medical treatment that selects the most appropriate treatment for each patient based on a vast amount of medical data such as genome information, has become a worldwide trend; AI technology is expected to be utilized in the process of extracting truly useful information from a large amount of medical data and applying it to diagnosis and treatment. In this review, we would like to introduce the history of AI technology and the current state of medical AI, especially in the oncology field, as well as discuss the possibilities and challenges of AI technology in the medical field.

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“…For these reasons, the medical imaging literature has had an increasing number of publications, whose goal is to compensate for the lack of expert annotations [8]. While some methods leverage partly-annotated data sets [9], others use domain adaptation strategies to compensate for small training data sets [10]. Some other approaches artificially increase the number of annotated data with generative adversarial networks (GANs) [11,12], while others use third-party neural networks to help experts annotate images more rapidly [13].…”

Section: Introductionmentioning

confidence: 99%

Deep Learning Based Cardiac MRI Segmentation: Do We Need Experts?

2021

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Deep learning methods are the de facto solutions to a multitude of medical image analysis tasks. Cardiac MRI segmentation is one such application, which, like many others, requires a large number of annotated data so that a trained network can generalize well. Unfortunately, the process of having a large number of manually curated images by medical experts is both slow and utterly expensive. In this paper, we set out to explore whether expert knowledge is a strict requirement for the creation of annotated data sets on which machine learning can successfully be trained. To do so, we gauged the performance of three segmentation models, namely U-Net, Attention U-Net, and ENet, trained with different loss functions on expert and non-expert ground truth for cardiac cine–MRI segmentation. Evaluation was done with classic segmentation metrics (Dice index and Hausdorff distance) as well as clinical measurements, such as the ventricular ejection fractions and the myocardial mass. The results reveal that generalization performances of a segmentation neural network trained on non-expert ground truth data is, to all practical purposes, as good as that trained on expert ground truth data, particularly when the non-expert receives a decent level of training, highlighting an opportunity for the efficient and cost-effective creation of annotations for cardiac data sets.

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Advancing Medical Imaging Informatics by Deep Learning-Based Domain Adaptation

Cited by 65 publications

References 76 publications

Correcting data imbalance for semi-supervised COVID-19 detection using X-ray chest images

Correcting data imbalance for semi-supervised COVID-19 detection using X-ray chest images

Application of Artificial Intelligence Technology in Oncology: Towards the Establishment of Precision Medicine

Deep Learning Based Cardiac MRI Segmentation: Do We Need Experts?

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