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Radiological features of brain hemorrhage through automated segmentation from computed tomography in stroke and traumatic brain injury

MacIntosh, Bradley J. ; Liu, Qinghui ; Schellhorn, Till ; Beyer, Mona K. ; Groote, Inge Rasmus ; Morberg, Pål C. ; Poulin, Joshua M. ; Selseth, Maiken N. ; Bakke, Ragnhild C. and Naqvi, Aina , et al. (2023) In Frontiers in Neurology 14.
Abstract

Introduction: Radiological assessment is necessary to diagnose spontaneous intracerebral hemorrhage (ICH) and traumatic brain injury intracranial hemorrhage (TBI-bleed). Artificial intelligence (AI) deep learning tools provide a means for decision support. This study evaluates the hemorrhage segmentations produced from three-dimensional deep learning AI model that was developed using non-contrast computed tomography (CT) imaging data external to the current study. Methods: Non-contrast CT imaging data from 1263 patients were accessed across seven data sources (referred to as sites) in Norway and Sweden. Patients were included based on ICH, TBI-bleed, or mild TBI diagnosis. Initial non-contrast CT images were available for all... (More)

Introduction: Radiological assessment is necessary to diagnose spontaneous intracerebral hemorrhage (ICH) and traumatic brain injury intracranial hemorrhage (TBI-bleed). Artificial intelligence (AI) deep learning tools provide a means for decision support. This study evaluates the hemorrhage segmentations produced from three-dimensional deep learning AI model that was developed using non-contrast computed tomography (CT) imaging data external to the current study. Methods: Non-contrast CT imaging data from 1263 patients were accessed across seven data sources (referred to as sites) in Norway and Sweden. Patients were included based on ICH, TBI-bleed, or mild TBI diagnosis. Initial non-contrast CT images were available for all participants. Hemorrhage location frequency maps were generated. The number of estimated haematoma clusters was correlated with the total haematoma volume. Ground truth expert annotations were available for one ICH site; hence, a comparison was made with the estimated haematoma volumes. Segmentation volume estimates were used in a receiver operator characteristics (ROC) analysis for all samples (i.e., bleed detected) and then specifically for one site with few TBI-bleed cases. Results: The hemorrhage frequency maps showed spatial patterns of estimated lesions consistent with ICH or TBI-bleed presentations. There was a positive correlation between the estimated number of clusters and total haematoma volume for each site (correlation range: 0.45–0.74; each p-value < 0.01) and evidence of ICH between-site differences. Relative to hand-drawn annotations for one ICH site, the VIOLA-AI segmentation mask achieved a median Dice Similarity Coefficient of 0.82 (interquartile range: 0.78 and 0.83), resulting in a small overestimate in the haematoma volume by a median of 0.47 mL (interquartile range: 0.04 and 1.75 mL). The bleed detection ROC analysis for the whole sample gave a high area-under-the-curve (AUC) of 0.92 (with sensitivity and specificity of 83.28% and 95.41%); however, when considering only the mild head injury site, the TBI-bleed detection gave an AUC of 0.70. Discussion: An open-source segmentation tool was used to visualize hemorrhage locations across multiple data sources and revealed quantitative hemorrhage site differences. The automated total hemorrhage volume estimate correlated with a per-participant hemorrhage cluster count. ROC results were moderate-to-high. The VIOLA-AI tool had promising results and might be useful for various types of intracranial hemorrhage.

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publication status
published
subject
keywords
computed tomography, deep learning, intracerebral hemorrhage, segmentation, stroke, traumatic brain injury
in
Frontiers in Neurology
volume
14
article number
1244672
publisher
Frontiers Media S. A.
external identifiers
  • pmid:37840934
  • scopus:85173652184
ISSN
1664-2295
DOI
10.3389/fneur.2023.1244672
language
English
LU publication?
yes
id
c95102ae-3e9f-45c7-ae07-393cdc3c3b16
date added to LUP
2023-12-20 11:15:16
date last changed
2024-04-18 20:53:28
@article{c95102ae-3e9f-45c7-ae07-393cdc3c3b16,
  abstract     = {{<p>Introduction: Radiological assessment is necessary to diagnose spontaneous intracerebral hemorrhage (ICH) and traumatic brain injury intracranial hemorrhage (TBI-bleed). Artificial intelligence (AI) deep learning tools provide a means for decision support. This study evaluates the hemorrhage segmentations produced from three-dimensional deep learning AI model that was developed using non-contrast computed tomography (CT) imaging data external to the current study. Methods: Non-contrast CT imaging data from 1263 patients were accessed across seven data sources (referred to as sites) in Norway and Sweden. Patients were included based on ICH, TBI-bleed, or mild TBI diagnosis. Initial non-contrast CT images were available for all participants. Hemorrhage location frequency maps were generated. The number of estimated haematoma clusters was correlated with the total haematoma volume. Ground truth expert annotations were available for one ICH site; hence, a comparison was made with the estimated haematoma volumes. Segmentation volume estimates were used in a receiver operator characteristics (ROC) analysis for all samples (i.e., bleed detected) and then specifically for one site with few TBI-bleed cases. Results: The hemorrhage frequency maps showed spatial patterns of estimated lesions consistent with ICH or TBI-bleed presentations. There was a positive correlation between the estimated number of clusters and total haematoma volume for each site (correlation range: 0.45–0.74; each p-value &lt; 0.01) and evidence of ICH between-site differences. Relative to hand-drawn annotations for one ICH site, the VIOLA-AI segmentation mask achieved a median Dice Similarity Coefficient of 0.82 (interquartile range: 0.78 and 0.83), resulting in a small overestimate in the haematoma volume by a median of 0.47 mL (interquartile range: 0.04 and 1.75 mL). The bleed detection ROC analysis for the whole sample gave a high area-under-the-curve (AUC) of 0.92 (with sensitivity and specificity of 83.28% and 95.41%); however, when considering only the mild head injury site, the TBI-bleed detection gave an AUC of 0.70. Discussion: An open-source segmentation tool was used to visualize hemorrhage locations across multiple data sources and revealed quantitative hemorrhage site differences. The automated total hemorrhage volume estimate correlated with a per-participant hemorrhage cluster count. ROC results were moderate-to-high. The VIOLA-AI tool had promising results and might be useful for various types of intracranial hemorrhage.</p>}},
  author       = {{MacIntosh, Bradley J. and Liu, Qinghui and Schellhorn, Till and Beyer, Mona K. and Groote, Inge Rasmus and Morberg, Pål C. and Poulin, Joshua M. and Selseth, Maiken N. and Bakke, Ragnhild C. and Naqvi, Aina and Hillal, Amir and Ullberg, Teresa and Wassélius, Johan and Rønning, Ole M. and Selnes, Per and Kristoffersen, Espen S. and Emblem, Kyrre Eeg and Skogen, Karoline and Sandset, Else C. and Bjørnerud, Atle}},
  issn         = {{1664-2295}},
  keywords     = {{computed tomography; deep learning; intracerebral hemorrhage; segmentation; stroke; traumatic brain injury}},
  language     = {{eng}},
  publisher    = {{Frontiers Media S. A.}},
  series       = {{Frontiers in Neurology}},
  title        = {{Radiological features of brain hemorrhage through automated segmentation from computed tomography in stroke and traumatic brain injury}},
  url          = {{http://dx.doi.org/10.3389/fneur.2023.1244672}},
  doi          = {{10.3389/fneur.2023.1244672}},
  volume       = {{14}},
  year         = {{2023}},
}