Abstract
Objective To identify, characterize, and automatically classify hypoperfusion-related changes in the blood oxygenation level dependent (BOLD) signal in acute stroke using spatial independent component analysis of resting-state functional MRI data.
Methods We applied spatial independent component analysis to resting-state functional MRI data of 37 stroke patients scanned within 24 hours of symptom onset, 17 of whom received follow-up scans the next day. All patients also received dynamic susceptibility contrast MRI. After denoising and manually classifying the components, we extracted a set of temporal and spatial features from each independent component and used a generalized linear model to automatically identify components related to tissue hypoperfusion.
Results Our analysis revealed “Hypoperfusion spatially-Independent Components” (HICs) whose BOLD signal spatial patterns resembled regions of delayed perfusion depicted by dynamic susceptibility contrast MRI. These HICs were detected even in the presence of excessive patient motion, and disappeared following successful tissue reperfusion. The unique spatial and temporal features of HICs allowed them to be distinguished with high accuracy from other components in a user-independent manner (AUC = 0.95, accuracy = 0.96, sensitivity = 1.00, specificity = 0.96).
Interpretation Our study presents a new, non-invasive method for assessing blood flow in acute stroke that minimizes interpretative subjectivity and is robust to severe patient motion.
Introduction
Imaging blood flow in acute ischemic stroke is important in directing treatment decisions. In clinical practice, MRI-based blood flow imaging is typically performed using dynamic susceptibility contrast MRI (DSC-MRI). This method is well-established and correlates well with the in-vivo perfusion imaging gold-standard, 15O-water positron emission tomography (PET) 1–2. However, it requires the use of intravenously administered contrast agents, which are contraindicated in patients with kidney impairment 3 and can accumulate in tissues with repeated use 4.
BOLD functional MRI has been proposed as an alternative to DSC-MRI. At rest, BOLD signal oscillations reflect a combination of different signal sources, including the hemodynamic response to spontaneous neural activity (neurovascular coupling), peripheral physiology (respiratory and cardiac function), fluctuations in blood carbon dioxide 5,6, and head motion 7. Disturbed cerebral blood flow is associated with changes in BOLD signal fluctuations in multiple ways. One of the best studied perfusion-related changes in the BOLD signal is BOLD delay 8–17, which utilizes relative phase lags in low frequency oscillations (LFOs) of the BOLD signal originating from outside the brain (systemic LFOs) in underperfused brain regions 18. Disturbed perfusion is known to affect other BOLD signal features, including a shift to lower LFO frequencies 19–21 and a decrease in LFO amplitude 22. These findings suggest that regions of disturbed perfusion may have a unique set of BOLD signal characteristics that distinguish them from normally perfused tissue. Using this BOLD “signature” to rapidly and reliably identify abnormally perfused tissue would be of great diagnostic and prognostic utility.
Spatial independent component analysis (spatial ICA) is a data-driven method for decomposing complex signals into statistically-independent subcomponents 23. In fMRI, it has been used to remove non-neuronal signal contributions such as head motion, large vessel pulsations, and scanner instabilities 24. Using spatial ICA, researchers can isolate functionally distinct resting-state networks (RSNs) such as visual cortical areas and the sensory-motor cortex 25.
Considering spatial ICA’s ability to separate statistically-independent sources of variance in the BOLD signal, we investigated whether spatial ICA would detect hypoperfusion-related changes in the BOLD signal in acute stroke patients. Specifically, we aimed 1) to identify spatial ICA components corresponding to tissue hypoperfusion, 2) to characterize the temporal and spatial properties of these “Hypoperfusion spatially-Independent Components” (HICs), and 3) to determine whether HICs can be identified in a fully automated manner.
Methods
Patients
This study analyzes data from a subset of ischemic stroke patients from 1000Plus26 (clinicaltrials.gov identifier: NCT00715533) and LOBI-BBB (clinicaltrials.gov identifier: NCT02077582), two prospective cohort imaging studies conducted at Charité Universitätsmedizin Campus Benjamin Franklin (Berlin, Germany) between January 2009 and March 2016.
The patients included in this study had a clinical and radiological diagnosis of acute supratentorial ischemic stroke, and had received both dynamic susceptibility contrast magnetic resonance imaging (DSC-MRI) and resting-state functional MRI (rs-fMRI) scans within 24 hours of symptom onset as part of a standard stroke imaging protocol 26. All patients showed perfusion deficits on their time-to-maximum (Tmax) maps at baseline. Where available, follow-up scans from the same patients, acquired approximately 24 hours after the baseline scans, were also included in the analysis. Exclusion criteria were any contraindications to MRI or gadolinium contrast agent. Patients provided written informed consent prior to participation, and all procedures were approved by the local ethics committee and were performed according to the Declaration of Helsinki.
Thirty-seven acute ischemic stroke patients who met our inclusion criteria were included in this study. The baseline scans of twenty-two of these patients were previously analyzed in a comparison between time shift analysis of rs-fMRI data (BOLD delay) and DSC-MRI9 and twelve patients (and their follow-up scans) from the current study were previously investigated in a study of the longitudinal evolution of perfusion deficits detected using BOLD delay10.
Imaging
Acquisition
All imaging was performed on a Siemens (Erlangen, Germany) Tim Trio 3 Tesla MRI scanner. The sequence parameters were as follows, rs-fMRI; repetition time (TR) = 2300 ms, echo time (TE) = 30 ms, flip angle (FA) = 90°, matrix = 64 x 64, voxel dimensions = 3 x 3 x 3 mm3, 1 mm slice gap, 33 slices and 150 volumes (acquisition time=5 min. and 50 s). The rs-fMRI scan was performed prior to the administration of the contrast agent and patients were requested to relax, lie still, and close their eyes for the duration of the scan.
DSC-MRI was performed after injection of a bolus of 5ml Gadovist® (Gadobutrol, 1M, Bayer Schering Pharma AG, Berlin, Germany) followed by a saline flush at a flow rate of 5ml/s. The sequence parameters were: TR = 1390 ms, TE = 29 ms, FA = 60, matrix = 128 x 128, voxel dimensions = 1.8 x 1.8 x 5 mm, 0.5 mm slice gap, 21 slices and 80 volumes (acquisition time = 1 min and 58 s).
Other imaging included diffusion-weighted imaging (DWI), time-of-flight MR angiography, and fluid-attenuated inversion recovery (FLAIR) scans, as described previously 26.
Dynamic susceptibility contrast MRI
Maps of time-to-maximum of the tissue residue function (Tmax) were generated from the DSC-MRI data using Stroketool (version 2.8; Digital Image Solutions – H.J. Wittsack) after deconvolution of the concentration-time curve through block-circulant singular value decomposition 27. The arterial input function (AIF) was selected from 5-10 voxels in the distal branches of the middle cerebral artery on the hemisphere contralateral to the acute infarct 28. Artifacts in the cerebrospinal fluid (CSF) were automatically removed from the Tmax maps using CSF masks derived from T2-weighted B0 images.
Resting-state functional MRI
Preprocessing
Preprocessing of the resting-state data was performed using tools from Analysis of Functional NeuroImages (AFNI) and the FMRIB Software Library (FSL). The first four volumes of each time series were discarded for signal equilibration. After correcting for slice-timing effects, the remaining volumes were skull-stripped, realigned to the mean functional image of each individual, and linear and quadratic trends were removed. Images were spatially smoothed (Gaussian kernel of full-width-at-half-maximum = 6 mm), but left temporally unfiltered to include the full range of signal frequencies for spatial independent component analysis.
ICA decomposition
Spatial ICA is a data-driven approach for multivariate data analysis and representation. It was implemented in this study using FSL’s Multivariate Exploratory Linear Optimized Decomposition into Independent Components - MELODIC 23. Spatial ICA models four-dimensional fMRI data as a linear combination of unknown source signals (referred to as “independent components”), each described by a spatial map and an associated time course. It dissects out the different source signals by assuming their mutual, statistical independence and non-Gaussianity 23. In this study, spatial ICA was implemented using MELODIC’s default Bayesian dimensionality estimation, which estimates the number of source signals within the data automatically 23. This means that the number of independent components outputted by MELODIC can differ between patients and scanning sessions in this study.
Manual classification of independent components
For a subset of the data (20 out of 37 baseline scans; the FIX training dataset, see below), independent components from MELODIC were manually classified by consensus of two raters (A.A.K and J-Y.H.) into the following classes: resting-state networks (RSNs), likely hypoperfusion independent components (HICs), noise (including head motion and scanner noise), or “unknown” if the independent component could not be clearly identified. Manual classification of the RSNs, noise, and unknown components was carried out according to published guidelines 29 by inspecting the thresholded spatial maps (|Z| > 2.33), the power spectrum, and the time courses. HICs were identified as components that were unilateral and corresponded roughly to the location of the patient’s infarct on DWI.
A total of 896 independent components were generated using MELODIC from the subjects in the FIX training dataset. The median number of independent components per subject was 45 (IQR = 43 – 47). The mean (± SD) contribution of each component class (% out of the total number of components) for subjects in the FIX-training dataset are as follows: noise (79.8% ± 9.4%), resting-state networks (9.2% ± 5.9%), and likely hypoperfusion independent component(s) (HIC; 2.6% ± 1.5%). “Other” components that could not be unambiguously classified into any of the other three categories formed 8.4% ± 4.8% of the training dataset. Of the 20 subjects in the FIX training dataset, 14 had a single HIC, 3 had two HICs, 1 had three HICs, and 2 had no HICs.
Data denoising
To reduce the number of components by removing non-signal independent components, we used FMRIB’s ICA-based X-noiseifier (FIX), a machine-learning algorithm that automatically classifies signal and artifact components in rs-fMRI data using 186 spatial and temporal features 30. Minor modifications were made to FIX to accommodate our data: we substituted T1-weighted magnetization-prepared rapid gradient-echo (MPRAGE) scans used in calculations of FIX features with B0 images (T2-weighted spin-echo EPI), as MPRAGEs are not routinely acquired as part of our acute stroke MR imaging protocol 26. Tissue segmentation maps needed for these features were generated from these images using FSL’s FMRIB Automated Segmentation Tool (FAST). All segmentations were visually assessed for quality.
FIX was trained on the FIX training dataset. The accuracy of FIX for separating signal from noise in the FIX training dataset was investigated using leave-one-out cross-validation. An optimal threshold of 20 was selected for the classification of independent components in our training data, as this was the highest threshold at which no HICs were incorrectly classified by FIX as noise. At this threshold, FIX achieved a mean true positive rate (TPR; percent of true signal independent components correctly classified) of 90.9%, and a mean true negative rate (TNR; percent of true noise independent components correctly classified) of 84.6%. The output of FIX denoising was a “shortlist” of components classified by FIX as being “non-noise”. After training, FIX was applied to the full dataset (n = 2337 independent components from 51 subjects). FIX reduced the number of independent components to a list of likely-signal independent components by 77.4% (total, n = 528 independent components from 51 subjects).
Image registration
All images (including Tmax maps, resting-state data, and spatial ICA maps) were registered to a custom echo planar imaging (EPI) template in MNI 152 standard space using a rigid body spatial transformation (3 rotations and 3 translations, implemented using FSL FLIRT) for further processing. This template was derived from the EPI scans of 103 stroke patients and details of how it was generated can be found in the Supplementary Materials of 9.
Feature extraction
We extracted a set of relevant spatial and temporal features from the shortlisted independent components (i.e. after data denoising by FIX) to examine how HICs may differ from other signal components. The following features were extracted:
Temporal delay to a reference signal: Temporally delayed BOLD signals, calculated using time shift analysis 8, have been found to correspond to hypoperfused brain regions. We thus explored whether the temporal delay between the mean time courses of the independent components and a reference time course was different between HICs and independent components representing normally perfused tissue. We used two different reference time courses: the whole brain (global) signal 8,11 and the signal from within the major venous sinuses 9,12,31, the latter of which was automatically extracted using a venous sinus template in MNI space (details described in the Supplementary Materials of 9). Positive delay values indicate the component’s BOLD signal time course followed the reference time course, while negative delay values indicate the component’s BOLD signal time course preceded the reference time course.
Power in frequency bands: Ischemia shifts BOLD signal oscillations towards lower frequencies 19–21. For each independent component, we calculated the percentage of total spectral power in six different frequency ranges (0 – 0.01 Hz, 0.01 – 0.025 Hz, 0.025 – 0.05 Hz, 0.05 – 0.1 Hz, 0.1 – 0.15 Hz, 0.15 – 0.20 Hz) after fast Fourier transform of the time courses 30.
Percent restriction to a single vascular territory: Ischemic stroke-related hypoperfusion is most commonly restricted to a vascular territory supplied by a single major artery. This makes the percent restriction of an independent component’s spatial map to a single vascular territory a potential feature of interest. We thus calculated the percentage of each independent component’s volume that exists within a single vascular territory. For this analysis, only independent components with >50% of their volume within a single vascular territory were considered. The vascular territories were defined according to a custom vascular territory atlas in MNI template space, described in further detail in the Supplementary Materials of 9.
Mean Tmax delay: To compare the results of the spatial ICA with the level of perfusion revealed by DSC-MRI in the area covered by each independent component, we calculated the mean Tmax delay of all voxels in the Tmax map overlapped by the independent component’s spatial map.
Automated identification of HICs
Model training
We used a Generalized Linear Model (GLM) on the extracted features to estimate the probability that a given independent component is a HIC. To mitigate multicollinearity effects we selected an elastic net regularized GLM 32.
Disregarding components classified as noise, HICs form about 10% of the components per dataset. To address this problem of extreme class imbalance 33, which can bias GLM results, we first sub-sampled our dataset to contain 50% HICs (number of components = 57), and 50% non-HICs (number of components = 57). From this model dataset, which undersamples the majority (non-HIC) class, we randomly selected 80% of the independent components to be the training dataset (containing 43 HICs and 48 non-HICs).
For the model training, components were classified as HICs if their model probabilities were above a probability threshold determined by Youden’s index, which gives equal weight to sensitivity and specificity. The shrinkage parameter lambda was estimated using leave-one-out cross-validation on the training dataset.
Model testing
The test dataset contained all the HICs (number of components = 14) and non-HICs (number of components = 414) remaining after selection of the training dataset. From this, we randomly subsampled 5 HICs and a set of non-HICs according to the mean ratio between HICs and non-HICs in individual MELODIC outputs in the FIX shortlist (about 1:10). This random selection was repeated 50 times and the model’s performance is reported as the median of these iterations (see below for metrics of model performance).
Statistical analysis
Radar plots were created using the “radarchart” function from the fmsb R package 34 to visualize feature values. Raincloud plots, which combine dot plots, box plots, and violin plots, are used to visualize the distribution of continuous variables 35.
The elastic net regularized GLM used in this study was implemented using the “cv.glmnet” function from the glmnet R package 36.
Model performance is reported using the following metrics:
Area-under-the-curve of the receiver operating ROC curve (AUC): The probability that the model will assign a higher probability of being a HIC to a randomly chosen HIC than to a randomly chosen non-HIC. ROC curves were visualized and their AUCs were calculated using the pROC R package 37
Accuracy: The proportion of true positives and true negatives, or the proportion correctly classified by the model
Sensitivity: The true positive rate, or the proportion of HICs correctly classified by the model as being HICs
Specificity: The true negative rate, or the proportion of non-HICs correctly classified by the model as being non-HICs
Cohen’s kappa: The agreement between the model’s classification and the “true”/”reference” classification, beyond that expected due to random chance. This was calculated using the irr R package 38.
The GLM coefficients were converted into Odds ratios (Odds ratio = ecoefficient). Since elastic net, like all penalized regression models, provides biased estimators, no meaningful standard errors can be calculated 39 and therefore p-values are not reported in this analysis. Instead, the model produces penalized coefficients through bootstrapped cross-validation. Variables whose contribution to the outcome is negligible have penalized coefficients of zero (i.e. Odds ratios of 1).
Data availability
The data and code for the training and testing of the model can be found at https://github.com/ahmedaak/spatial_ICA_stroke.
Results
Patients
The study sample consisted of 17 women and 20 men (mean age = 71 years, SD = 14 years). Their median NIHSS was 7 (IQR 3 - 14) and the median time from symptom onset to MRI was 7 hours (IQR 2 - 16 h). Intravenous thrombolysis was administered to 19 (51%) patients. Fourteen patients received follow-up scans on the second day following stroke onset, resulting in a total of 51 scans. Tissue reperfusion was successful in 3 of the 14 patients with follow-up scans, as demonstrated by the complete resolution of time-to-maximum (Tmax) lesions observed on their baseline scans.
Twelve out of the 51 rsfMRI scans exhibited severe head motion, defined according to previous studies on the use of rsfMRI for assessing cerebral hemodynamics as a mean framewise displacement of >0.4 mm across the scan or a maximum framewise displacement of >3 mm9,10. Head motion was quantified using framewise displacement (FD), which is the sum of the absolute value of individual subjects’ six translational and rotational realignment parameters40. Median FD (mean across all scan volumes) in the sample was 0.23 mm (IQR: 0.15 mm) for rs-fMRI, and 0.29 mm (IQR: 0.19 – 0.47 mm) for DSC-MRI. Median FD (maximum across all scan volumes) were 1.28 mm (IQR: 0.61 – 2.86 mm) and 0.82 (IQR: 0.49 – 1.89 mm) for rs-fMRI and DSC-MRI scans, respectively.
Hypoperfusion independent components reflect tissue hypoperfusion
Of the 37 baseline scans, 34 showed at least one HIC (6 scans showed 2 HICs, 2 scans showed 3 HICs). Fig 1 shows the DWI, Tmax, and HIC of three example patients. Maps for the other 31 patients may be found at http://dx.doi.org/10.6084/m9.figshare.12612809. Together, these figures reveal the striking spatial similarities between HICs and perfusion deficits on Tmax maps.
In addition, 10 out of the 14 follow-up scans showed HICs. Fig 2 illustrates the relationship between the spatial ICA results and vessel status (recanalization or persistent vessel occlusion) in two patients with follow-up scans. In patient A, we observe the resolution of HICs following vessel recanalization and tissue reperfusion, while in patient B, HICs persist with continued vessel occlusion and tissue hypoperfusion. This finding suggests that HICs dynamically respond to changes in vessel status and perfusion dynamics over time.
HICs were identified in most subjects with high head motion during their rs-fMRI scans, as shown in an example patient in Fig 3. HICs were identified in 10 out of the 12 patients with high head motion. Overall, there were 4 false negative cases, in which no HIC was visible despite the presence of a perfusion deficit on Tmax maps (http://dx.doi.org/10.6084/m9.figshare.12612809). In two of the false negative cases, extremely severe motion was present in the rs-fMRI data, exceeding 20 mm maximum framewise displacement. In the other two false negative cases, motion during the rs-fMRI scan was much lower (mean FD = 0.25 and 0.14 mm, max FD = 0.56 and 0.44 mm).
HICs identified multiple perfusion deficits located in different vascular territories within the same patient (Fig 4). The fact that multiple, spatially remote areas of hypoperfusion within an individual patient are captured in a single independent component suggests that these areas share a BOLD signal signature that sets them apart from other components.
HICs show unique characteristics
Table 1 shows the feature values (mean across patients) extracted from the independent components.
For each patient, min-max normalization was applied to the values of the features extracted from each of the independent components using the following equation: where z is the normalized feature value, x is the original feature value, i refers to the independent component in question, and S refers to the feature values of the entire set of independent components from a single patient.
The mean of the normalized feature values across patients is shown on the radar plot in Fig 5. HICs have a unique feature signature compared to non-HICs, characterized by delayed low frequency oscillations compared to the whole-brain and venous sinus references, greater restriction to a single vascular territory, larger overlap with areas of hypoperfusion (as assessed using Tmax), and more power in the lowest frequency bands (0 - 0.025 Hz).
Hypoperfusion independent components can be automatically identified
Elastic net regularized GLM was applied to the FIX-shortlisted independent components (i.e. the independent components that were classified by FIX as being non-noise) to determine the predictive power of a set of features on HIC classification. The model discriminated HICs from non-HICs with a median accuracy of 0.96, sensitivity of 1.00, and specificity of 0.96. The median Cohen’s kappa for agreement between the model’s classification and the reference classification was 0.78 and the median AUC was 0.95. Fig 6 shows the distribution of these performance metrics across 50 iterations of the model, using different combinations of HICs and non-HICs.
A useful feature of elastic net regularized GLM is that it performs implicit variable selection, and thus enhances model interpretability by allowing the assessment of each feature’s relative importance for the classification 32. Table 2 shows that 7 out of the 9 extracted features were used by the model to distinguish HICs from non-HICs (i.e. have an Odds ratio ≠ 0). These features included a larger delay in the low frequency oscillations of the HIC relative to the whole-brain and venous sinus signals, a larger restriction to a single vascular territory by the HICs, a higher power in the 0 - 0.001 Hz and 0.015 - 0.02 Hz frequency bands in the HICs, and a higher power in the 0.0025 - 0.005 Hz and 0.01 - 0.015 Hz frequency bands in the non-HICs.
Discussion
In this study, we present a novel approach for identifying areas of disturbed perfusion in ischemic stroke without the use of contrast agents. We demonstrate that, using this method, areas of hypoperfusion can be extracted from resting-state fMRI data in a manner that is user-independent and robust to patient motion. The results of this study have important implications from both an application and methodological perspective.
We provide several lines of evidence that certain independent components isolated from rs-fMRI data using spatial ICA reflect regions of hypoperfused brain tissue. Firstly, there is high visual similarity between the spatial maps of HICs and the Tmax maps of individual patients. This is noticeable even when patients had multiple perfusion deficits within (Fig 3) and across (Fig 4) vascular territories. Secondly, HICs were present in areas of much higher Tmax delay than other independent components (Fig 5). Thirdly, HICs observed at baseline disappeared at follow-up in patients with successful recanalization and reperfusion, paralleling the reversal of the patients’ DSC-MRI Tmax lesions (Fig 2). Finally, HICs show BOLD signal characteristics that are consistent with those previously described in hypoperfused tissue 8,19–21.
These spatial and temporal features of HICs help distinguish them from resting-state connectivity networks (Fig 5). BOLD oscillations associated with HICs were more temporally delayed in relation to the global and venous sinus signals than oscillations associated with resting-state networks. Although temporal delays in BOLD LFOs have been shown to occur under physiological conditions 31 and differ between resting-state networks 41, the largest delays are seen in areas of pathologically reduced perfusion 9,10.
Additionally, HICs showed more signal power in very low frequency ranges (0 - 0.025 Hz) and less signal power in the 0.025 - 0.05 Hz range than resting-state networks. This finding is consistent with studies showing that the signal power increases in the <0.01 Hz range in hypoperfused tissue 19–21. Our study adds to this in our finding that oscillations associated with resting-state networks exist largely towards the higher end of the low frequency range than oscillations associated with disturbed perfusion.
One disadvantage of spatial ICA is that it outputs potentially dozens of components, and browsing through them to visually identify those likely reflecting hypoperfusion can be time-consuming, require expertise, and be subject to bias. We therefore combined the aforementioned component features with the degree of restriction of the component’s spatial map to a single vascular territory and used this set of features to train an algorithm to automatically distinguish HICs from resting-state networks. The algorithm did this with high (>95%) accuracy, sensitivity and specificity, showing that HICs can be automatically extracted from the rest of the components of spatial ICA.
Spatial ICA has certain advantages over existing methods for assessing perfusion using rs-fMRI. Instead of assessing the individual characteristics of hypoperfusion-related signals separately, spatial ICA extracts components that reflect a combination of changes in frequency, amplitude, and temporal delay. In addition, while methods based on cross-correlation, such as time shift analysis 8, are sensitive to small, motion-related changes in the BOLD signal, spatial ICA is capable of identifying perfusion deficits even in the presence of severe patient motion (Fig 3). Finally, unlike time shift analysis, spatial ICA does not require the specification of a reference signal, the choice of which is not trivial 9,12,17.
This study’s findings have two major implications. From a clinical perspective, it introduces a new method for assessing blood flow in acute stroke patients that may be relevant for informing decision-making regarding recanalization and reperfusion therapies. This method is safer, as it does not require the use of exogenous contrast agents, which are particularly problematic in this patient population, who are generally older and have a higher prevalence of chronic kidney disease 42. The acquisition of the rs-fMRI data, upon which this method is based, is simple and widely available on clinical scanners. Although the rs-fMRI data acquisition took substantially longer than DSC-MRI in this study (about six minutes vs two minutes), recent evidence suggests that extracting perfusion-related information from rs-fMRI can be achieved with much shorter acquisitions43. The method is also user-independent, which avoids the subjective assessment of perfusion maps that often leads to inconsistencies between and within experts44 and allows it to be seamlessly integrated in routine clinical practice. Finally, the robustness of the method to head motion is a substantial practical advantage, as patients scanned during acute illnesses tend to exhibit a lot of motion, which diminishes scan quality and interpretability 45.
From a methodological perspective, this study underscores the importance of accounting for disturbed perfusion as a potential source of confounding in rs-fMRI studies, particularly in patients with cerebrovascular diseases. Studies investigating functional connectivity in patients with potentially abnormal cerebral perfusion should therefore attempt to disentangle the effects of disturbed perfusion on the BOLD signal (e.g. due to vessel pathology) from components of the BOLD signal that reflect neuronal activity via local neurovascular coupling. So far, suggestions on how to do this have included regressing out the time delays (relative to a reference) from the rs-fMRI data 46 and temporally realigning the BOLD signal time courses according to each voxel’s time delay value 47.
While the spatial distribution of physiological vascular processes overlap with, and are often indistinguishable from, the spatial distribution of resting-state networks 41,48,49, we show that the influence of disturbed perfusion on the BOLD signal in stroke patients can be readily disentangled from other components of the BOLD signal using spatial ICA. There are two potential explanations for this. The first is that, in stroke, hypoperfusion is spatially restricted to either a vascular territory or part of a vascular territory. On the other hand, physiological vascular processes are spatially distributed in a manner similar to resting-state networks 41,48,49, which may make their separation using spatial ICA less likely. The second explanation has to do with the large difference in the temporal BOLD signal characteristics between hypoperfused and normally perfused tissue, which may also facilitate their separation by spatial ICA. In stroke, disturbed perfusion tends to be severe compared to the physiological delays in perfusion across different brain regions, and this leads to relatively large changes in the temporal characteristics of the BOLD signal in hypoperfused regions 9,10,19–21.
As the first study to describe this method for assessing perfusion, the study has some limitations. The study sample is relatively small, owing to the fact that it includes an established, albeit relatively invasive, reference standard for assessing perfusion (DSC-MRI) as a comparison. Future studies should test the algorithm we developed on larger cohorts with different MR sequence parameters and more heterogeneous patient cohorts. Larger cohorts would also allow the investigation of the clinical relevance of perfusion assessed using this method, in terms of how it relates to clinical and imaging outcomes and how it potentially influences clinical decision-making in acute stroke patients50.
In summary, spatial independent component analysis is a novel approach for identifying hypoperfused tissue in ischemic stroke. It does not require the use of exogenous contrast agents, its data can be analyzed without user input, and its results are robust to patient motion. It therefore presents a convenient and promising new alternative to existing perfusion imaging methods in acute stroke.
Author contributions
Jiun-Yiing Hu: conceptualization, methodology, software, formal analysis, visualization, data curation, writing - original draft, writing - review & editing
Evgeniya Kirilina: methodology, writing - review & editing
Till Nierhaus: methodology, writing - review & editing
Smadar Ovadia-Caro: visualization, writing - original draft, writing - review & editing
Michelle Livne: methodology, formal analysis, writing - review & editing
Kersten Villringer: project administration, investigation, writing - review & editing
Daniel Margulies: methodology, writing - review & editing
Jochen B. Fiebach: resources, project administration, supervision, writing - review & editing
Arno Villringer: resources, supervision, writing - review & editing
Ahmed A. Khalil: conceptualization, methodology, software, formal analysis, visualization, data curation, supervision, writing - original draft, writing - review & editing
Competing interests
J-Y.H., A.A.K., K.V., and J.B.F. are co-inventors of a method for automatically delineating perfusion lesions on perfusion MRI data (European Patent application 17179320.01-1906), distinct from the method described in this study, which is now in the public domain. J.B.F. reports grants from European Union 7th Framework Program and personal fees from Bioclinica, Artemida, Cerevast, Brainomix, BMS, Merck, Eisai, Biogen, Guerbet, and Nicolab outside the submitted work.
Acknowledgments
The authors thank Prof. Dr. med. Andreas Meisel for providing feedback on the manuscript. A.A.K. received funding from the NeuroCure Cluster of Excellence and the Berlin Institute of Health Junior Clinician-Scientist Programme.