Neural network can determine lung cancer severity

Neural network can determine lung cancer severity
Visualization of LungNet predictions in two dimensional space showed that patients in the high-risk group are clustered away from those in the low-risk group. Lesions of low-risk patients were characterized by regular and uniform shaped nodules. Nodules of patients in the high-risk group had sharp and irregular margins. Credit: Mukherjee, et al., Nature Machine Intelligence, May-2020

Computed tomography (CT) is a major diagnostic tool for assessment of lung cancer in patients. Now NIBIB-funded researchers at Stanford University have created an artificial neural network that analyzes lung CT scans to provide information about lung cancer severity that can guide treatment options.

CT imaging is an important diagnostic tool to measure the location, extent, size, and shape of lesions used to guide therapeutic decisions for patients with lung —the most common fatal malignancy in adults worldwide. However, analysis of CT images is limited to what is visible to the human eye, and reader variability results in differences in clinical care across different oncology centers.

A multidisciplinary group of experts in , radiology, data science, , and radiation oncology have teamed up to create a machine learning neural network called LungNet designed to obtain consistent, fast, and accurate information from lung CT scans from patients. The group worked with scans from adults with non-small cell lung cancer (NSCLC), which accounts for 85% of lung cancer diagnoses.

"LungNet demonstrates the benefits of designing and training machine learning tools directly on from patients," said Qi Duan, Ph.D., director of the NIBIB Program in Image Processing, Visual Perception and Display. "This is an outstanding example of how machine learning technology can be a cost-effective approach to advance disease detection, diagnosis, and treatment."

The research group was led by Olivier Gevaert, Assistant Professor of Medicine in Biomedical Informatics Research, at Stanford who specializes in the development of machine learning methods for biomedical decision support using multi-scale biomedical data.

"Quantitative image analysis has demonstrated that radiological images, such as CT scans of patients with lung cancer, contain more minable information than what is observed by radiologists," explained Gevaert. "Using CT image datasets from several different oncology clinics, we set out to determine whether our neural network could be trained to accurately and reproducibly analyze the scans and deliver consistent, useful clinical information."

The called LungNet was trained and evaluated on four independent cohorts of patients with NSCLC from four medical centers, with each center averaging several hundred patients. The LungNet analysis accurately predicted overall survival in all four patient groups. LungNet also accurately classified benign versus malignant nodules and was able to further stratify nodules regarding cancer progression.

The research team expects LungNet to be extremely valuable for not only classifying benign versus malignant tumors but also for stratifying patients into low, medium, and high risk groups. This allows for intensified treatment for patients in the high-risk group as well as reducing unnecessary treatments for patients in the low-risk group.

The results were published in the journal Nature Machine Intelligence.

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More information: Pritam Mukherjee et al. A shallow convolutional neural network predicts prognosis of lung cancer patients in multi-institutional computed tomography image datasets, Nature Machine Intelligence (2020). DOI: 10.1038/s42256-020-0173-6
Journal information: Nature Machine Intelligence

Citation: Neural network can determine lung cancer severity (2020, June 25) retrieved 24 February 2021 from
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