Skip to content

NCBI-Codeathons/A-DEEP-CONVOLUTIONAL-NEURAL-NETWORK-FOR-IDENTIFYING-THYROID-CANCER

Folders and files

NameName
Last commit message
Last commit date

Latest commit

 

History

7 Commits
 
 
 
 
 
 
 
 
 
 
 
 

Repository files navigation

A DEEP CONVOLUTIONAL NEURAL NETWORK FOR IDENTIFYING THYROID CANCER

The Problem

Differentiating benign thyroid nodules from cancer is a significant health challenge, as thyroid nodules are present by ultrasound (US) in a staggering 19 – 35% of the general adult population (approximately 130 million people). Most of these nodules are benign, however the diagnostic process is costly, inefficient, and leads to unnecessary surgery and morbidity.

Our Proposal

We propose to develop a more accurate system for identifying thyroid cancer by applying a deep convolutional neural network (DCNN) algorithm to data from our thyroid cancer database, which includes a large number patients who have been followed clinically for several years. We propose to develop a new risk prediction and prognosis tool to predict the individualized risk of death and recurrence from thyroid cancer. We envision two modes of analysis:

  1. exploratory analysis, and
  2. clinical performance optimization

Exploratory Analysis

In the exploratory mode we will leverage advanced unsupervised machine learning techniques such as manifold learning and dimension reduction (DR) to visualize multi-modal, integrated, high-dimensional data (as a point cloud). We hope to build an interactive, GUI-based data visualization dashboard to allow rapid traversal of this complex data by scientists and clinicians alike. Additionally, we will incorporate and overlay the proposed predictive models as they are developed and refined, and provide the ability to annotate data/models on the fly for subsequent use with other models.

Performance Optimization

In the second mode, performance optimization, we will build on the recognition patterns discovered in the augmented data exploration, and then refine and optimize specific candidate predictive models emphasizing those with high potential for clinical impact/utility. The most high-performing predictive models will then be validated retrospectively and prospectively.

Targeted Outcome

At the conclusion of this project, we will have a deep learning tool that has improved ability to detect thyroid cancer in patients with thyroid nodules. We also anticipate that we will have a risk prediction tool that accurately identifies the risk of recurrence and death after initial treatment of thyroid cancer. Through this process, we will have established one of the first comprehensive annotated databases of thyroid ultrasound images that will allow development and validation of a deep learning algorithm to accurately differentiate benign from malignant thyroid nodules.

Team

Team Lead: Dr. Fiemu Nwariaku, MD, Surgery, https://www.utsouthwestern.edu/labs/nwariaku/

Technical Facilitators: Dr. Andrew Jamieson

  • Dr. Hanieh Mazloom Farsibaf
  • Dr. Stephan Daetwyler
  • Michael Holcomb
  • Kishan Kolur
  • Jesus Vega
  • Meyer Zinn
  • James Singhal

Releases

No releases published

Packages

No packages published