CODAIT / deep-histopath

A deep learning approach to predicting breast tumor proliferation scores for the TUPAC16 challenge
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cancer-research deep-learning machine-learning medical-imaging medicine

Predicting Breast Cancer Proliferation Scores with TensorFlow, Keras, and Apache Spark

Note: This project is still a work in progress. There is also an experimental branch with additional files and experiments.

Overview

The Tumor Proliferation Assessment Challenge 2016 (TUPAC16) is a "Grand Challenge" that was created for the 2016 Medical Image Computing and Computer Assisted Intervention (MICCAI 2016) conference. In this challenge, the goal is to develop state-of-the-art algorithms for automatic prediction of tumor proliferation scores from whole-slide histopathology images of breast tumors.

Background

Breast cancer is the leading cause of cancerous death in women in less-developed countries, and is the second leading cause of cancerous deaths in developed countries, accounting for 29% of all cancers in women within the U.S. [1]. Survival rates increase as early detection increases, giving incentive for pathologists and the medical world at large to develop improved methods for even earlier detection [2]. There are many forms of breast cancer including Ductal Carcinoma in Situ (DCIS), Invasive Ductal Carcinoma (IDC), Tubular Carcinoma of the Breast, Medullary Carcinoma of the Breast, Invasive Lobular Carcinoma, Inflammatory Breast Cancer and several others [3]. Within all of these forms of breast cancer, the rate in which breast cancer cells grow (proliferation), is a strong indicator of a patient’s prognosis. Although there are many means of determining the presence of breast cancer, tumor proliferation speed has been proven to help pathologists determine the best treatment for the patient. The most common technique for determining the proliferation speed is through mitotic count (mitotic index) estimates, in which a pathologist counts the dividing cell nuclei in hematoxylin and eosin (H&E) stained slide preparations to determine the number of mitotic bodies. Given this, the pathologist produces a proliferation score of either 1, 2, or 3, ranging from better to worse prognosis [4]. Unfortunately, this approach is known to have reproducibility problems due to the variability in counting, as well as the difficulty in distinguishing between different grades.

References:
[1] http://emedicine.medscape.com/article/1947145-overview#a3
[2] http://emedicine.medscape.com/article/1947145-overview#a7
[3] http://emedicine.medscape.com/article/1954658-overview
[4] http://emedicine.medscape.com/article/1947145-workup#c12

Goal & Approach

In an effort to automate the process of classification, this project aims to develop a large-scale deep learning approach for predicting tumor scores directly from the pixels of whole-slide histopathology images (WSI). Our proposed approach is based on a recent research paper from Stanford [1]. Starting with 500 extremely high-resolution tumor slide images [2] with accompanying score labels, we aim to make use of Apache Spark in a preprocessing step to cut and filter the images into smaller square samples, generating 4.7 million samples for a total of ~7TB of data [3]. We then utilize TensorFlow and Keras to train a deep convolutional neural network on these samples, making use of transfer learning by fine-tuning a modified ResNet50 model [4]. Our model takes as input the pixel values of the individual samples, and is trained to predict the correct tumor score classification for each one. We also explore an alternative approach of first training a mitosis detection model [5] on an auxiliary mitosis dataset, and then applying it to the WSIs, based on an approach from Paeng et al. [6]. Ultimately, we aim to develop a model that is sufficiently stronger than existing approaches for the task of breast cancer tumor proliferation score classification.

References:
[1] https://web.stanford.edu/group/rubinlab/pubs/2243353.pdf
[2] http://tupac.tue-image.nl/node/3
[3] preprocess.py, breastcancer/preprocessing.py
[4] MachineLearning-Keras-ResNet50.ipynb
[5] preprocess_mitoses.py, train_mitoses.py
[6] https://arxiv.org/abs/1612.07180

Approach


Setup (All nodes unless other specified):

Create a Histopath slide “lab” to view the slides (just driver):