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Sickle Cell Disease Severity Prediction from Percoll Gradient Images using Graph Convolutional Networks
- Source :
- Domain Adaptation and Representation Transfer, and Affordable Healthcare and AI for Resource Diverse Global Health ISBN: 9783030877217, DART/FAIR@MICCAI
- Publication Year :
- 2021
-
Abstract
- Sickle cell disease (SCD) is a severe genetic hemoglobin disorder that results in premature destruction of red blood cells. Assessment of the severity of the disease is a challenging task in clinical routine since the causes of broad variance in SCD manifestation despite the common genetic cause remain unclear. Identification of the biomarkers that would predict the severity grade is of importance for prognosis and assessment of responsiveness of patients to therapy. Detection of the changes in red blood cell (RBC) density through separation of Percoll density gradient could be such marker as it allows to resolve intercellular differences and follow the most damaged dense cells prone to destruction and vaso-occlusion. Quantification of the images obtained from the distribution of RBCs in Percoll gradient and interpretation of the obtained is an important prerequisite for establishment of this approach. Here, we propose a novel approach combining a graph convolutional network, a convolutional neural network, fast Fourier transform, and recursive feature elimination to predict the severity of SCD directly from a Percoll image. Two important but expensive laboratory blood test parameters measurements are used for training the graph convolutional network. To make the model independent from such tests during prediction, the two parameters are estimated by a neural network from the Percoll image directly. On a cohort of 216 subjects, we achieve a prediction performance that is only slightly below an approach where the groundtruth laboratory measurements are used. Our proposed method is the first computational approach for the difficult task of SCD severity prediction. The two-step approach relies solely on inexpensive and simple blood analysis tools and can have a significant impact on the patients' survival in underdeveloped countries where access to medical instruments and doctors is limited<br />Accepted for publication at MICCAI 2021 workshop on aFfordable healthcare and AI for Resource diverse global health (FAIR)
- Subjects :
- FOS: Computer and information sciences
Computer science
Low resource
Computer Vision and Pattern Recognition (cs.CV)
Computer Science - Computer Vision and Pattern Recognition
Convolutional neural network
Disease severity
FOS: Electrical engineering, electronic engineering, information engineering
medicine
Blood test
1700 General Computer Science
2614 Theoretical Computer Science
medicine.diagnostic_test
Artificial neural network
business.industry
Image and Video Processing (eess.IV)
Pattern recognition
Electrical Engineering and Systems Science - Image and Video Processing
10081 Institute of Veterinary Physiology
Feature (computer vision)
10076 Center for Integrative Human Physiology
570 Life sciences
biology
Graph (abstract data type)
Artificial intelligence
business
Percoll
Subjects
Details
- Language :
- English
- ISBN :
- 978-3-030-87721-7
- ISBNs :
- 9783030877217
- Database :
- OpenAIRE
- Journal :
- Domain Adaptation and Representation Transfer, and Affordable Healthcare and AI for Resource Diverse Global Health ISBN: 9783030877217, DART/FAIR@MICCAI
- Accession number :
- edsair.doi.dedup.....76e4425d97760ab5e64650f4730875dd