So you are predicting failure to recover. What survivor wants to hear that? Damn it all; create research that gets these strokes to 100% recovery. Until that research occurs and is implemented it is your responsibility not to have this type of stroke.
The coronal plane maximum diameter of deep intracerebral hemorrhage predicts functional outcome more accurately than hematoma volume
Stefan P Haiderhttps://orcid.org/0000-0002-7640-36451,2, Adnan I Qureshi3, Abhi Jain1, Hishan Tharmaseelan1, Elisa R Berson1, Shahram Majidi4, Christopher G Filippi5, Adrian Mak1,6, David J Werring7, Julian N Acosta8, Ajay Malhotrahttps://orcid.org/0000-0001-9223-66401, Jennifer A Kim8, Lauren H Sansing8, Guido J Falcone8, Kevin N Sheth8, and Seyedmehdi Payabvash1
BackgroundAmong prognostic imaging variables, the hematoma volume on admission computed tomography (CT) has long been considered the strongest predictor of outcome and mortality in intracerebral hemorrhage.
Aims
BackgroundAmong prognostic imaging variables, the hematoma volume on admission computed tomography (CT) has long been considered the strongest predictor of outcome and mortality in intracerebral hemorrhage.
Aims
To examine whether different features of hematoma shape are associated with functional outcome in deep intracerebral hemorrhage.
Methods
Methods
We analyzed 790 patients from the ATACH-2 trial, and 14 shape features were quantified. We calculated Spearman’s Rho to assess the correlation between shape features and three-month modified Rankin scale (mRS) score, and the area under the receiver operating characteristic curve (AUC) to quantify the association between shape features and poor outcome defined as mRS>2 as well as mRS > 3.
Results
Results
Among 14 shape features, the maximum intracerebral hemorrhage diameter in the coronal plane was the strongest predictor of functional outcome, with a maximum coronal diameter >∼3.5 cm indicating higher three-month mRS scores. The maximum coronal diameter versus hematoma volume yielded a Rho of 0.40 versus 0.35 (p = 0.006), an AUC[mRS>2] of 0.71 versus 0.68 (p = 0.004), and an AUC[mRS>3] of 0.71 versus 0.69 (p = 0.029). In multiple regression analysis adjusted for known outcome predictors, the maximum coronal diameter was independently associated with three-month mRS (p < 0.001).
Conclusions
Conclusions
A coronal-plane maximum diameter measurement offers greater prognostic value in deep intracerebral hemorrhage than hematoma volume. This simple shape metric may expedite assessment of admission head CTs, offer a potential biomarker for hematoma size eligibility criteria in clinical trials, and may substitute volume in prognostic intracerebral hemorrhage scoring systems.
Keywords
Intracerebral hemorrhage, hematoma, volume, shape feature, outcome, computed tomography, CT
1Department of Radiology and Biomedical Imaging, Yale School of Medicine, New Haven, CT, USA
2Department of Otorhinolaryngology, University Hospital of Ludwig Maximilians Universität München, Munich, Germany
3Zeenat Qureshi Stroke Institute and Department of Neurology, University of Missouri, Columbia, MO, USA
4Department of Neurosurgery, Icahn School of Medicine at Mount Sinai, New York, NY, USA
5Department of Radiology, Tufts University School of Medicine, Boston, MA, USA
6Charité Lab for Artificial Intelligence in Medicine (CLAIM), Charité – Universitätsmedizin Berlin, Berlin, Germany
7Stroke Research Centre, University College London, Queen Square Institute of Neurology, London, UK
8Department of Neurology, Yale School of Medicine, New Haven, CT, USA
*Dr. Sheth and Dr. Payabvash contributed equally to this work.
Corresponding author(s):
Seyedmehdi Payabavsh, Department of Radiology, Yale School of Medicine, 789 Howard Ave, PO Box 208042, New Haven, CT 06519, USA. Email: sam.payabvash@yale.edu
Hematoma volume thresholds are common enrollment criteria for clinical trials,3-5 highlighting the importance of rapid hematoma volume estimation at admission. Many clinical trials adopted the “ABC/2” method as a tool for rapid hematoma volume estimation and as an inclusion criterion for intervention.3,4 Multiple studies demonstrated that the ABC/2 formula can provide accurate and quick estimation of smaller, ellipsoid hematoma volumes, while perhaps underestimating the size of larger, complex-shaped ICH.6 While the majority of prior studies focused on evaluating the concordance of ABC/2 volume estimates with hematoma volume, a comprehensive analysis of the prognostic utility of ICH shape features has been lacking.
Aims
We analyzed data from the Antihypertensive Treatment of Acute Cerebral Hemorrhage II (ATACH-2) trial5 to investigate the association of 14 hematoma shape features—including volume—with functional outcome in deep ICH patients.
Methods
Data acquisition and allocation
The admission CT scans and corresponding clinical information utilized in this study originate from the ATACH-2 trial5: a multicentric, randomized, clinical trial of “intensive” blood pressure lowering treatment (target systolic blood pressure of 110–139 mmHg within 2 h) versus “standard” treatment (target systolic blood pressure of 140–179 mmHg within 2 h) in patients with primary supratentorial ICH.5 In total, 1000 patients with a baseline ICH volume <60 mL and elevated admission systolic blood pressure >180 mmHg were enrolled.5 For the current study, we excluded subjects with (1) CT artifacts impeding ICH segmentation, (2) corrupted CT data, (3) absent admission CT scans, (4) missing clinical data, and (5) lobar or infratentorial ICH (i.e., ICH not located in the basal ganglia or thalamus, hereafter referred to as deep ICH; Figure 1). Institutional review board approval was obtained in participating centers, and all trial participants or their legal proxy provided informed consent for inclusion.5
Figure 1. Flowchart depicting patient inclusion criteria.
Hematoma shape feature quantification
To enable quantification of ICH shape features, we defined three-dimensional masks (i.e., volumes of interest, VOIs) enclosing the hematoma on admission non-contrast head CT scans.7–10 Using 3D-Slicer version 4.10.1,11 the “paint” and “erase” tools in the “segment editor” module were employed to delineate intracerebral hematoma contours on each axial slice resulting in three-dimensional VOIs. A neuroradiologist (SP) with greater than nine years of dedicated experience reviewed and adjusted all VOI masks. Subsequently, radiomics software (Pyradiomics version 2.1.2)12,13 was used to automatically extract 14 shape features from ICH masks.7-10 To mitigate the impact of CT data heterogeneity on the analysis, we adopted voxel dimension resampling of ICH masks and CT images to an isotropic voxel spacing of 1 × 1 × 1 mm using B-spline interpolation prior to shape feature quantification.7-10,12-14 Figure 2 visualizes the segmentation workflow and ICH shape features. A list of all shape features is provided in Table 1.
Figure 2. Segmentation (upper panel) involved delineating hematoma contours “slice-by-slice” on axial CT slices to generate 3D-VOIs; ICH shape features (lower panel) quantify different hematoma shape characteristics (Table 1).
Association of ICH shape features with clinical outcome
We calculated Spearman’s rank correlation coefficient (Rho) to investigate the association of ICH shape features with three-month modified Rankin Scale (mRS) score. In we performed receiver operating characteristic (ROC) analysis and calculated the area under the ROC curve (AUC) to determine the performance of ICH shape features in predicting poor functional outcome defined as three-month mRS > 2, as well as mRS > 3. The accuracy, sensitivity and specificity were calculated for both definitions of poor outcome, whereby the cutoff minimizing the absolute difference between sensitivity and specificity was determined to binarize ICH features.
The ICH shape feature demonstrating the strongest association with three-month mRS score was selected: we compared Spearman’s correlation between the selected shape feature and mRS score with the correlation between ICH volume and mRS score; the corresponding AUC scores were also compared. We utilized R.R. Wilcox' percentile bootstrap method15 and DeLong’s method16 to compare Rho and AUC scores, respectively.
In secondary analysis, we investigated the association of the selected shape feature and of the ICH volume with death; the resulting AUC scores were compared.
Statistical analysis was performed in R version 3.6.0.17 The “Sphericity” and “Surface Area to Volume Ratio” features were negated prior to analysis to obtain positive correlations. Two-sided p values <0.05 ascertained statistical significance.
Reproducibility and inter-rater reliability in direct manual measurement of hematomas
To test whether automatically extracted select shape features could be reproduced in direct manual measurement of hematoma lesions, two independent readers measured all ICH lesions in a randomly selected sample of 100 patients (50 from each treatment subgroup). We utilized a “two-way random effects, absolute agreement, single rater/measurement intraclass correlation coefficient” (ICC) to assess the degree of reproducibility.18 We calculated the ICC for each reader against the automatically extracted select shape feature as well as between the two readers’ measurements to additionally assess the inter-rater reliability.
Finally, to investigate the prognostic significance of an established manual hematoma volume estimation technique, the ABC/2 method was applied in the same subsample of 100 patients by the same two readers.6 We determined the association of ABC/2 volume with three-month mRS score as well as poor outcome and compared its predictive value with that of select shape features as described above.
Multiple regression analysis to identify independent predictors of outcome
In multivariate analysis of three-month mRS score, we applied ordinal logistic regression adjusted for established predictors of functional outcome19,20 and treatment (standard vs. intensive) to investigate if select shape features were independently associated with mRS score.
Results
Patients’ characteristics
In total, 790 subjects were included in this study, of whom 379 had received standard and 411 had received intensive treatment. Relevant patients’ characteristics are provided in Supplemental Table 1.
Hematoma shape features predictive of clinical outcome
Figure 3 summarizes the association of ICH shape features with three-month mRS score (quantified by Spearman’s Rho) and poor clinical outcome (quantified by the AUC and defined as mRS > 2 or mRS > 3). Individual features demonstrated varying predictive ability, with Rho and AUC scores ranging from Rho = 0 and AUC∼0.50 (“Elongation” feature) to Rho = 0.40 and AUC = 0.71 (“Maximum 2D Diameter – Coronal” feature). The “Maximum 2D Diameter – Coronal” feature quantifies the maximum hematoma diameter in the coronal plane; overall, it exhibited the strongest association with three-month mRS, attaining Rho = 0.40, AUC[mRS>2] = 0.71 and AUC[mRS>3] = 0.71. Based on this feature, the optimized maximum diameter cutoffs for differentiation of poor from favorable outcome are 34.93 [mRS > 2] and 36.14 mm [mRS > 3] (Figure 3). Among complex shape features, “Elongation” and “Flatness” had weaker associations with clinical outcome reflected in lower Rho and AUC scores; whereas the “Maximum 3D Diameter”, “Sphericity”, “Surface Area”, and “Surface Area to Volume Ratio” features demonstrated stronger associations (Figure 3).
Figure 3. Heatmap depicting the association of deep ICH shape features with three-month clinical outcome. Spearman’s Rho quantifies the association of shape features with mRS score, whereas the AUC, accuracy, sensitivity and specificity quantify the association with poor outcome defined as mRS > 2 as well as mRS > 3.
Comparison of maximum coronal diameter and hematoma volume for outcome prediction
The “Maximum 2D Diameter – Coronal” shape feature demonstrated the strongest association with three-month mRS score and poor outcome (Figure 3), and was significantly associated with clinical outcome (Rho = 0.40, p < 0.001; AUC[mRS >2] = 0.71; AUC[mRS > 3] = 0.71, Table 2). ICH volume was significantly associated with outcome as well (p < 0.001, Table 2). However, all “Maximum 2D Diameter – Coronal” Rho and AUC scores were significantly higher than corresponding ICH volume Rho and AUC scores (pRho = 0.006, p[mRS>2] = 0.004, p[mRS>3] = 0.029, Table 2).
Mortality analysis revealed an association between the “Maximum 2D Diameter – Coronal” shape feature and death (AUC[Death] = 0.60), which was not significantly different from the association between ICH volume and death (p[Death] = 0.37, Supplemental Table 2).
Reproducibility and inter-rater reliability in direct manual measurement of hematomas
Two independent readers measured the maximum hematoma diameter in the coronal plane in a subsample of 100 patients. The ICC (95% confidence interval, CI) for the manually measured maximum hematoma diameter versus the automatically extracted “Maximum 2D Diameter – Coronal” feature was 0.94 (0.91–0.96) for reader #1 and 0.92 (0.85–0.95) for reader #2. In addition, the manual measurements yielded an inter-rater ICC (95% CI) of 0.92 (0.86–0.95).
The manually measured maximum coronal diameter, the automatically measured ICH volume, and the manual ABC/2 volume were significantly associated with three-month mRS score in the subsample of 100 patients (all p < 0.001, Table 3). There was no significant difference in the strength of association of the manually measured maximum coronal diameter and of hematoma volume with three-month mRS score (Table 3). The general tendency, however, was retained, with all maximum coronal diameter Rho and AUC scores numerically higher than the corresponding hematoma volume scores. Additionally, all ABC/2 volume Rho and AUC scores were not significantly different from corresponding maximum coronal diameter scores (Table 3).
Independent predictors of outcome in multiple regression analysis
In a multiple ordinal logistic regression model, the “Maximum 2D Diameter – Coronal” feature was an independent predictor of three-month mRS score (p < 0.001) while controlling for admission GCS score (p = 0.004), admission NIHSS score (p < 0.001), presence of intraventricular hemorrhage on baseline CT (p < 0.001), patients’ age (p < 0.001), and intensive treatment (p = 0.59; variance inflation factor, VIF of all covariates <5; Supplemental Table 3). All significant covariates remained significant when the model was additionally adjusted for ICH volume, including the maximum coronal diameter (p = 0.006), while ICH volume did not attain significance (p = 0.56; VIF of all covariates <5).
Discussion
In this study, we reanalyzed the ATACH-2 trial data to examine whether different features of hematoma shape on admission CT are associated with functional outcome in deep ICH patients. We found that a single-plane measurement of the maximum hematoma diameter provides greater prognostic value compared to the baseline hematoma volume, the most powerful imaging predictor of outcome described thus far for this disease (Table 2).1,2 Specifically, in deep ICH patients, the maximum hematoma diameter in the coronal plane had the highest prognostic performance, with the optimized threshold for prediction of poor outcome defined as three-month mRS > 2 and mRS > 3 being 3.5 and 3.6 cm, respectively (Figure 3). For prediction of death, we demonstrated the maximum coronal diameter offered similar prognostic value compared to ICH volume (Supplemental Table 2). In a randomly selected subsample, we confirmed the reliability of manual maximum coronal diameter measurements based on inter-rater agreement analysis between two independent readers as well as between manual measurements from individual readers versus the automatically extracted feature values. In addition, the readers determined the ABC/2 volume in the randomly selected subsample, which was found to be a similarly accurate outcome predictor compared to the maximum coronal diameter and ICH volume (Table 3). However, the distinctive advantage of the coronal diameter measurement lies in more rapid estimation of disease severity compared to ABC/2 while retaining good prognostic accuracy. Finally, we showed the maximum coronal diameter was independently associated with functional outcome in multiple regression adjusted for established outcome predictors. These findings suggest a single-plane measurement of the maximum hematoma diameter may facilitate speedy prognostication in ICH patients at the time of admission, may substitute whole volume thresholds as enrollment criteria in future clinical trials, and may replace hematoma volume in prognostic ICH scoring systems while potentially improving their prognostic accuracy.
The ICH location affects the 30-day mortality rate and functional outcome.1,22 Deep ICH—which is located in the basal ganglia or thalamus—is often related to hypertension, whereas lobar ICH—located in the cortex and subcortical white matter—usually occurs in association with cerebral amyloid angiopathy.1 Given that only patients with elevated admission systolic blood pressure >180 mmHg were eligible for enrollment in the ATACH-2 trial, the majority of patients (879/988) had deep ICH, and our study accordingly focused on this subgroup.5 Of note, deep ICHs represent almost two thirds of primary ICH incidents.23 A systematic review of 37 studies concluded that patients with lobar ICH had better short- and medium-term outcomes compared to those with deep hematomas, highlighting the significance of speedy risk-stratification for patients with deep ICH at the time of admission.22
Our study is founded on a large and prospectively collected sample of supratentorial ICH patients enrolled in a multicentric clinical trial. Additional strengths lie in the comprehensive assessment of shape features, which is based on correlation analysis with mRS score, as well as binarized functional outcome analyses relying on widely accepted definitions of poor outcome (three-month mRS > 2, mRS > 3 and death [mRS = 6]). Our study is, however, inherently limited by the ATACH-2 enrollment criteria, restricting all analyses to patients with spontaneous supratentorial ICH with an elevated admission systolic blood pressure >180 mmHg and a baseline hematoma volume <60 mL.5 While our study determined ICH shape feature correlates for functional outcome at three months, future research may investigate the clinical significance of features beyond functional outcome. The small number of patients with lobar ICH in our dataset (n = 104) precludes statistically powerful analysis, and follow-up studies are needed to evaluate the application of single-plane maximum diameter measurements for prognostication of lobar ICH.
Conclusions
In a comprehensive assessment of 14 features of deep ICH shape, a single-plane maximum diameter measurement offered greater prognostic accuracy than hematoma volume with respect to three-month functional outcome. We confirmed the reliability of manual coronal diameter measurements across independent readers and showed that this parameter is independently associated with outcome. Our findings indicate the maximum coronal plane diameter measurement may expedite prognostic assessment of admission head CTs in ICH, offer a potential biomarker for hematoma size eligibility criteria in future clinical trials, and may replace hematoma volume in prognostic ICH scoring systems.
Keywords
Intracerebral hemorrhage, hematoma, volume, shape feature, outcome, computed tomography, CT
1Department of Radiology and Biomedical Imaging, Yale School of Medicine, New Haven, CT, USA
2Department of Otorhinolaryngology, University Hospital of Ludwig Maximilians Universität München, Munich, Germany
3Zeenat Qureshi Stroke Institute and Department of Neurology, University of Missouri, Columbia, MO, USA
4Department of Neurosurgery, Icahn School of Medicine at Mount Sinai, New York, NY, USA
5Department of Radiology, Tufts University School of Medicine, Boston, MA, USA
6Charité Lab for Artificial Intelligence in Medicine (CLAIM), Charité – Universitätsmedizin Berlin, Berlin, Germany
7Stroke Research Centre, University College London, Queen Square Institute of Neurology, London, UK
8Department of Neurology, Yale School of Medicine, New Haven, CT, USA
*Dr. Sheth and Dr. Payabvash contributed equally to this work.
Corresponding author(s):
Seyedmehdi Payabavsh, Department of Radiology, Yale School of Medicine, 789 Howard Ave, PO Box 208042, New Haven, CT 06519, USA. Email: sam.payabvash@yale.edu
Introduction
Currently, fewer than 40% of intracerebral hemorrhage (ICH) patients ever reach long-term functional independence, and the mortality rate is approximately 40% at one-month post presentation.1 Given the high morbidity and mortality rates, clinical and imaging predictors of functional outcome are of paramount importance to guide clinicians and researcher alike. Among prognostic admission imaging variables, the hematoma volume on baseline computed tomography (CT) has long been considered the strongest predictor of functional outcome and mortality.1,2 The admission hematoma volume affects early treatment decisions (such as surgical intervention, vs. conservative treatment, or palliation), as well as inclusion in clinical trials.3,4Hematoma volume thresholds are common enrollment criteria for clinical trials,3-5 highlighting the importance of rapid hematoma volume estimation at admission. Many clinical trials adopted the “ABC/2” method as a tool for rapid hematoma volume estimation and as an inclusion criterion for intervention.3,4 Multiple studies demonstrated that the ABC/2 formula can provide accurate and quick estimation of smaller, ellipsoid hematoma volumes, while perhaps underestimating the size of larger, complex-shaped ICH.6 While the majority of prior studies focused on evaluating the concordance of ABC/2 volume estimates with hematoma volume, a comprehensive analysis of the prognostic utility of ICH shape features has been lacking.
Aims
We analyzed data from the Antihypertensive Treatment of Acute Cerebral Hemorrhage II (ATACH-2) trial5 to investigate the association of 14 hematoma shape features—including volume—with functional outcome in deep ICH patients.
Methods
Data acquisition and allocation
The admission CT scans and corresponding clinical information utilized in this study originate from the ATACH-2 trial5: a multicentric, randomized, clinical trial of “intensive” blood pressure lowering treatment (target systolic blood pressure of 110–139 mmHg within 2 h) versus “standard” treatment (target systolic blood pressure of 140–179 mmHg within 2 h) in patients with primary supratentorial ICH.5 In total, 1000 patients with a baseline ICH volume <60 mL and elevated admission systolic blood pressure >180 mmHg were enrolled.5 For the current study, we excluded subjects with (1) CT artifacts impeding ICH segmentation, (2) corrupted CT data, (3) absent admission CT scans, (4) missing clinical data, and (5) lobar or infratentorial ICH (i.e., ICH not located in the basal ganglia or thalamus, hereafter referred to as deep ICH; Figure 1). Institutional review board approval was obtained in participating centers, and all trial participants or their legal proxy provided informed consent for inclusion.5
Figure 1. Flowchart depicting patient inclusion criteria.
Hematoma shape feature quantification
To enable quantification of ICH shape features, we defined three-dimensional masks (i.e., volumes of interest, VOIs) enclosing the hematoma on admission non-contrast head CT scans.7–10 Using 3D-Slicer version 4.10.1,11 the “paint” and “erase” tools in the “segment editor” module were employed to delineate intracerebral hematoma contours on each axial slice resulting in three-dimensional VOIs. A neuroradiologist (SP) with greater than nine years of dedicated experience reviewed and adjusted all VOI masks. Subsequently, radiomics software (Pyradiomics version 2.1.2)12,13 was used to automatically extract 14 shape features from ICH masks.7-10 To mitigate the impact of CT data heterogeneity on the analysis, we adopted voxel dimension resampling of ICH masks and CT images to an isotropic voxel spacing of 1 × 1 × 1 mm using B-spline interpolation prior to shape feature quantification.7-10,12-14 Figure 2 visualizes the segmentation workflow and ICH shape features. A list of all shape features is provided in Table 1.
Figure 2. Segmentation (upper panel) involved delineating hematoma contours “slice-by-slice” on axial CT slices to generate 3D-VOIs; ICH shape features (lower panel) quantify different hematoma shape characteristics (Table 1).
Association of ICH shape features with clinical outcome
We calculated Spearman’s rank correlation coefficient (Rho) to investigate the association of ICH shape features with three-month modified Rankin Scale (mRS) score. In we performed receiver operating characteristic (ROC) analysis and calculated the area under the ROC curve (AUC) to determine the performance of ICH shape features in predicting poor functional outcome defined as three-month mRS > 2, as well as mRS > 3. The accuracy, sensitivity and specificity were calculated for both definitions of poor outcome, whereby the cutoff minimizing the absolute difference between sensitivity and specificity was determined to binarize ICH features.
The ICH shape feature demonstrating the strongest association with three-month mRS score was selected: we compared Spearman’s correlation between the selected shape feature and mRS score with the correlation between ICH volume and mRS score; the corresponding AUC scores were also compared. We utilized R.R. Wilcox' percentile bootstrap method15 and DeLong’s method16 to compare Rho and AUC scores, respectively.
In secondary analysis, we investigated the association of the selected shape feature and of the ICH volume with death; the resulting AUC scores were compared.
Statistical analysis was performed in R version 3.6.0.17 The “Sphericity” and “Surface Area to Volume Ratio” features were negated prior to analysis to obtain positive correlations. Two-sided p values <0.05 ascertained statistical significance.
Reproducibility and inter-rater reliability in direct manual measurement of hematomas
To test whether automatically extracted select shape features could be reproduced in direct manual measurement of hematoma lesions, two independent readers measured all ICH lesions in a randomly selected sample of 100 patients (50 from each treatment subgroup). We utilized a “two-way random effects, absolute agreement, single rater/measurement intraclass correlation coefficient” (ICC) to assess the degree of reproducibility.18 We calculated the ICC for each reader against the automatically extracted select shape feature as well as between the two readers’ measurements to additionally assess the inter-rater reliability.
Finally, to investigate the prognostic significance of an established manual hematoma volume estimation technique, the ABC/2 method was applied in the same subsample of 100 patients by the same two readers.6 We determined the association of ABC/2 volume with three-month mRS score as well as poor outcome and compared its predictive value with that of select shape features as described above.
Multiple regression analysis to identify independent predictors of outcome
In multivariate analysis of three-month mRS score, we applied ordinal logistic regression adjusted for established predictors of functional outcome19,20 and treatment (standard vs. intensive) to investigate if select shape features were independently associated with mRS score.
Results
Patients’ characteristics
In total, 790 subjects were included in this study, of whom 379 had received standard and 411 had received intensive treatment. Relevant patients’ characteristics are provided in Supplemental Table 1.
Hematoma shape features predictive of clinical outcome
Figure 3 summarizes the association of ICH shape features with three-month mRS score (quantified by Spearman’s Rho) and poor clinical outcome (quantified by the AUC and defined as mRS > 2 or mRS > 3). Individual features demonstrated varying predictive ability, with Rho and AUC scores ranging from Rho = 0 and AUC∼0.50 (“Elongation” feature) to Rho = 0.40 and AUC = 0.71 (“Maximum 2D Diameter – Coronal” feature). The “Maximum 2D Diameter – Coronal” feature quantifies the maximum hematoma diameter in the coronal plane; overall, it exhibited the strongest association with three-month mRS, attaining Rho = 0.40, AUC[mRS>2] = 0.71 and AUC[mRS>3] = 0.71. Based on this feature, the optimized maximum diameter cutoffs for differentiation of poor from favorable outcome are 34.93 [mRS > 2] and 36.14 mm [mRS > 3] (Figure 3). Among complex shape features, “Elongation” and “Flatness” had weaker associations with clinical outcome reflected in lower Rho and AUC scores; whereas the “Maximum 3D Diameter”, “Sphericity”, “Surface Area”, and “Surface Area to Volume Ratio” features demonstrated stronger associations (Figure 3).
Figure 3. Heatmap depicting the association of deep ICH shape features with three-month clinical outcome. Spearman’s Rho quantifies the association of shape features with mRS score, whereas the AUC, accuracy, sensitivity and specificity quantify the association with poor outcome defined as mRS > 2 as well as mRS > 3.
Comparison of maximum coronal diameter and hematoma volume for outcome prediction
The “Maximum 2D Diameter – Coronal” shape feature demonstrated the strongest association with three-month mRS score and poor outcome (Figure 3), and was significantly associated with clinical outcome (Rho = 0.40, p < 0.001; AUC[mRS >2] = 0.71; AUC[mRS > 3] = 0.71, Table 2). ICH volume was significantly associated with outcome as well (p < 0.001, Table 2). However, all “Maximum 2D Diameter – Coronal” Rho and AUC scores were significantly higher than corresponding ICH volume Rho and AUC scores (pRho = 0.006, p[mRS>2] = 0.004, p[mRS>3] = 0.029, Table 2).
Mortality analysis revealed an association between the “Maximum 2D Diameter – Coronal” shape feature and death (AUC[Death] = 0.60), which was not significantly different from the association between ICH volume and death (p[Death] = 0.37, Supplemental Table 2).
Reproducibility and inter-rater reliability in direct manual measurement of hematomas
Two independent readers measured the maximum hematoma diameter in the coronal plane in a subsample of 100 patients. The ICC (95% confidence interval, CI) for the manually measured maximum hematoma diameter versus the automatically extracted “Maximum 2D Diameter – Coronal” feature was 0.94 (0.91–0.96) for reader #1 and 0.92 (0.85–0.95) for reader #2. In addition, the manual measurements yielded an inter-rater ICC (95% CI) of 0.92 (0.86–0.95).
The manually measured maximum coronal diameter, the automatically measured ICH volume, and the manual ABC/2 volume were significantly associated with three-month mRS score in the subsample of 100 patients (all p < 0.001, Table 3). There was no significant difference in the strength of association of the manually measured maximum coronal diameter and of hematoma volume with three-month mRS score (Table 3). The general tendency, however, was retained, with all maximum coronal diameter Rho and AUC scores numerically higher than the corresponding hematoma volume scores. Additionally, all ABC/2 volume Rho and AUC scores were not significantly different from corresponding maximum coronal diameter scores (Table 3).
Independent predictors of outcome in multiple regression analysis
In a multiple ordinal logistic regression model, the “Maximum 2D Diameter – Coronal” feature was an independent predictor of three-month mRS score (p < 0.001) while controlling for admission GCS score (p = 0.004), admission NIHSS score (p < 0.001), presence of intraventricular hemorrhage on baseline CT (p < 0.001), patients’ age (p < 0.001), and intensive treatment (p = 0.59; variance inflation factor, VIF of all covariates <5; Supplemental Table 3). All significant covariates remained significant when the model was additionally adjusted for ICH volume, including the maximum coronal diameter (p = 0.006), while ICH volume did not attain significance (p = 0.56; VIF of all covariates <5).
Discussion
In this study, we reanalyzed the ATACH-2 trial data to examine whether different features of hematoma shape on admission CT are associated with functional outcome in deep ICH patients. We found that a single-plane measurement of the maximum hematoma diameter provides greater prognostic value compared to the baseline hematoma volume, the most powerful imaging predictor of outcome described thus far for this disease (Table 2).1,2 Specifically, in deep ICH patients, the maximum hematoma diameter in the coronal plane had the highest prognostic performance, with the optimized threshold for prediction of poor outcome defined as three-month mRS > 2 and mRS > 3 being 3.5 and 3.6 cm, respectively (Figure 3). For prediction of death, we demonstrated the maximum coronal diameter offered similar prognostic value compared to ICH volume (Supplemental Table 2). In a randomly selected subsample, we confirmed the reliability of manual maximum coronal diameter measurements based on inter-rater agreement analysis between two independent readers as well as between manual measurements from individual readers versus the automatically extracted feature values. In addition, the readers determined the ABC/2 volume in the randomly selected subsample, which was found to be a similarly accurate outcome predictor compared to the maximum coronal diameter and ICH volume (Table 3). However, the distinctive advantage of the coronal diameter measurement lies in more rapid estimation of disease severity compared to ABC/2 while retaining good prognostic accuracy. Finally, we showed the maximum coronal diameter was independently associated with functional outcome in multiple regression adjusted for established outcome predictors. These findings suggest a single-plane measurement of the maximum hematoma diameter may facilitate speedy prognostication in ICH patients at the time of admission, may substitute whole volume thresholds as enrollment criteria in future clinical trials, and may replace hematoma volume in prognostic ICH scoring systems while potentially improving their prognostic accuracy.
The ICH location affects the 30-day mortality rate and functional outcome.1,22 Deep ICH—which is located in the basal ganglia or thalamus—is often related to hypertension, whereas lobar ICH—located in the cortex and subcortical white matter—usually occurs in association with cerebral amyloid angiopathy.1 Given that only patients with elevated admission systolic blood pressure >180 mmHg were eligible for enrollment in the ATACH-2 trial, the majority of patients (879/988) had deep ICH, and our study accordingly focused on this subgroup.5 Of note, deep ICHs represent almost two thirds of primary ICH incidents.23 A systematic review of 37 studies concluded that patients with lobar ICH had better short- and medium-term outcomes compared to those with deep hematomas, highlighting the significance of speedy risk-stratification for patients with deep ICH at the time of admission.22
Our study is founded on a large and prospectively collected sample of supratentorial ICH patients enrolled in a multicentric clinical trial. Additional strengths lie in the comprehensive assessment of shape features, which is based on correlation analysis with mRS score, as well as binarized functional outcome analyses relying on widely accepted definitions of poor outcome (three-month mRS > 2, mRS > 3 and death [mRS = 6]). Our study is, however, inherently limited by the ATACH-2 enrollment criteria, restricting all analyses to patients with spontaneous supratentorial ICH with an elevated admission systolic blood pressure >180 mmHg and a baseline hematoma volume <60 mL.5 While our study determined ICH shape feature correlates for functional outcome at three months, future research may investigate the clinical significance of features beyond functional outcome. The small number of patients with lobar ICH in our dataset (n = 104) precludes statistically powerful analysis, and follow-up studies are needed to evaluate the application of single-plane maximum diameter measurements for prognostication of lobar ICH.
Conclusions
In a comprehensive assessment of 14 features of deep ICH shape, a single-plane maximum diameter measurement offered greater prognostic accuracy than hematoma volume with respect to three-month functional outcome. We confirmed the reliability of manual coronal diameter measurements across independent readers and showed that this parameter is independently associated with outcome. Our findings indicate the maximum coronal plane diameter measurement may expedite prognostic assessment of admission head CTs in ICH, offer a potential biomarker for hematoma size eligibility criteria in future clinical trials, and may replace hematoma volume in prognostic ICH scoring systems.
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