Automated quantification of cerebral edema following hemispheric infarction: Application of a machine-learning algorithm to evaluate CSF shifts on serial head CTs
- Authors
- Chen, Yasheng; Dhar, Rajat; Heitsch, Laura; Ford, Andria; Fernandez-Cadenas, Israel; Carrera, Caty; Montaner, Joan; Lin, Weili; Shen, Dinggang; An, Hongyu; Lee, Jin-Moo
- Issue Date
- 2016
- Publisher
- ELSEVIER SCI LTD
- Keywords
- Active contour; Cerebral edema; CSF segmentation; Ischemic stroke CT; Mass effect; Random forest
- Citation
- NEUROIMAGE-CLINICAL, v.12, pp.673 - 680
- Indexed
- SCIE
SCOPUS
- Journal Title
- NEUROIMAGE-CLINICAL
- Volume
- 12
- Start Page
- 673
- End Page
- 680
- URI
- https://scholar.korea.ac.kr/handle/2021.sw.korea/90421
- DOI
- 10.1016/j.nicl.2016.09.018
- ISSN
- 2213-1582
- Abstract
- Although cerebral edema is a major cause of death and deterioration following hemispheric stroke, there remains no validated biomarker that captures the full spectrum of this critical complication. We recently demonstrated that reduction in intracranial cerebrospinal fluid (CSF) volume (Delta CSF) on serial computed tomography (CT) scans provides an accurate measure of cerebral edema severity, which may aid in early triaging of stroke patients for craniectomy. However, application of such a volumetric approach would be too cumbersometo performmanually on serial scans in a real-world setting. We developed and validated an automated technique for CSF segmentation via integration of random forest (RF) based machine learning with geodesic active contour (GAC) segmentation. The proposed RF + GAC approach was compared to conventional Hounsfield Unit (HU) thresholding and RF segmentation methods using Dice similarity coefficient (DSC) and the correlation of volumetric measurements, with manual delineation serving as the ground truth. CSF spaces were outlined on scans performed at baseline (<6 h after stroke onset) and early follow-up (FU) (closest to 24 h) in 38 acute ischemic stroke patients. RF performed significantly better than optimized HU thresholding (p < 10(-4) in baseline and p < 10(-5) in FU) and RF + GAC performed significantly better than RF (p < 10(-3) in baseline and p < 10(-5) in FU). Pearson correlation coefficients between the automatically detected Delta CSF and the ground truth were r = 0.178 (p = 0.285), r= 0.876 (p < 10(-6)) and r= 0.879 (p < 10(-6)) for thresholding, RF and RF + GAC, respectively, with a slope closer to the line of identity in RF+ GAC. When we applied the algorithm trained from images of one stroke center to segment CTs from another center, similar findings held. In conclusion, we have developed and validated an accurate automated approach to segment CSF and calculate its shifts on serial CT scans. This algorithm will allow us to efficiently and accurately measure the evolution of cerebral edema in future studies including large multi-site patient populations. (C) 2016 The Authors. Published by Elsevier Inc.
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