Novel Transfer Learning Approach for Medical Imaging with Limited Labeled Data.

Laith Alzubaidi,Omran Al-Shamma,J Santamaría,Ye Duan,Amjad J Humaidi,Ahmed Al-Asadi,Muthana Al-Amidie,Jinglan Zhang,Mohammed A Fadhel

doi:10.3390/cancers13071590

Abstract

Deep learning requires a large amount of data to perform well. However, the field of medical image analysis suffers from a lack of sufficient data for training deep learning models. Moreover, medical images require manual labeling, usually provided by human annotators coming from various backgrounds. More importantly, the annotation process is time-consuming, expensive, and prone to errors. Transfer learning was introduced to reduce the need for the annotation process by transferring the deep learning models with knowledge from a previous task and then by fine-tuning them on a relatively small dataset of the current task. Most of the methods of medical image classification employ transfer learning from pretrained models, e.g., ImageNet, which has been proven to be ineffective. This is due to the mismatch in learned features between the natural image, e.g., ImageNet, and medical images. Additionally, it results in the utilization of deeply elaborated models. In this paper, we propose a novel transfer learning approach to overcome the previous drawbacks by means of training the deep learning model on large unlabeled medical image datasets and by next transferring the knowledge to train the deep learning model on the small amount of labeled medical images. Additionally, we propose a new deep convolutional neural network (DCNN) model that combines recent advancements in the field. We conducted several experiments on two challenging medical imaging scenarios dealing with skin and breast cancer classification tasks. According to the reported results, it has been empirically proven that the proposed approach can significantly improve the performance of both classification scenarios. In terms of skin cancer, the proposed model achieved an F1-score value of 89.09% when trained from scratch and 98.53% with the proposed approach. Secondly, it achieved an accuracy value of 85.29% and 97.51%, respectively, when trained from scratch and using the proposed approach in the case of the breast cancer scenario. Finally, we concluded that our method can possibly be applied to many medical imaging problems in which a substantial amount of unlabeled image data is available and the labeled image data is limited. Moreover, it can be utilized to improve the performance of medical imaging tasks in the same domain. To do so, we used the pretrained skin cancer model to train on feet skin to classify them into two classes—either normal or abnormal (diabetic foot ulcer (DFU)). It achieved an F1-score value of 86.0% when trained from scratch, 96.25% using transfer learning, and 99.25% using double-transfer learning.

Highlights

The deep learning (DL) computing paradigm has been deemed the gold standard in the medical image analysis field
We can conclude by highlighting six major points in this paper. (i) We proposed a novel approach of transfer learning (TL) to tackle the issue of the lack of training data in medical imaging tasks
The approach is based on training the DL models on a large number of unlabeled images of a specific task and fine-tuning the model to train on a small number of labeled images for the same task. (ii) We designed a hybrid deep convolutional neural network (DCNN) model based on several ideas, including parallel convolutional layers and residual connections along with global average pooling. (iii) We empirically proved the effectiveness of the proposed approach and model by applying them in two challenging tasks, skin and breast cancer. (iv) We utilized more than 200,000 unlabeled images of skin cancer to train the model, and we fine-tuned the model for a small dataset of labeled skin cancer to classify them into two classes, namely benign and malignant

Summary

Introduction

The deep learning (DL) computing paradigm has been deemed the gold standard in the medical image analysis field. It has been exhibiting excellent performance in several medical imaging areas, such as pathology [1], dermatology [2], radiology [3,4], and ophthalmology [5,6], which are the most competitive fields requiring human specialists. The recent approaches within DL being adapted to the direction of clinical alteration commonly depend on a large volume of highly reliable annotated images. Low-resource settings generate different issues, such as gathering highly reliable data, which turn out to be the bottleneck for advancing deep learning applications. Transfer learning (TL) has been proposed in this paper to overcome this challenging issue

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