1. Introduction
Perivascular spaces (PVSs), also known as Virchow-Robin spaces, are the pial-lined and fluid-filled cavities surrounding the walls of arteries, arterioles, veins, and venules in the brain [
1]. PVSs have a significant role in the glymphatic system and waste clearance process [
2,
3] and are key to regulating immunological responses [
4]. Several studies on enlarged perivascular spaces (EPVS) in the brain indicate that their presence is an indication of neuronal dysfunctions and that they could serve as a biomarker to diagnose brain diseases such as dementia [
5,
6,
7], multiple sclerosis [
8], stroke [
9,
10,
11,
12,
13], Parkinson’s [
14], and small vessel diseases [
15,
16,
17,
18,
19]. Due to its soft tissue contrast and high-resolution features, magnetic resonance imaging (MRI) is the most often utilized imaging tool in the assessment of EPVS. In MRI scans, PVSs are observed as well-defined oval/rounded/tubular structures with smooth margins. However, quantification of EPVS is challenging due to the difficulty of discriminating them from lacunes (both lacunes and EPVS have a cerebrospinal fluid (CSF)-like intensity on T1-weighted and T2-weighted MRI and are observed as hyperintensities on T2-weighted MRI and hypo-intensities on T1-weighted MRI scans [
20,
21]).
In general, clinical studies manually count the number of EPVS presented in a region of interest [
20,
22,
23,
24] (basal ganglia, hippocampus, midbrain, and centrum semiovale) and rate the presence of EPVS on a five-point scale [
20]. However, there is an intra- and inter-reader variability of detecting EPVS due to their tiny structures and morphological ambiguity [
20]. In brain disease diagnosis, the manual assessment of EPVS is the key step but is challenging and time consuming due to (i) the difficulty in discriminating the EPVS from brain lesions with similar appearances and (ii) the existence of multiple EPVS in single scans.
Several studies have developed automatic and semi-automatic methods for EPVS segmentation. For instance: an automated EPVS segmentation method based on Haar-like features was proposed in [
25]. The authors of [
26] proposed an interactive segmentation method based on intensity thresholding, while those of [
27] used a Frangi filter to enhance EPVS area and performed segmentation of individual EPVS. Recent studies have begun to apply deep learning to EPVS quantification as the popularity of deep learning algorithms have grown due to their superior performance. For example, [
28] proposed a multi-channel and multi-scale strategy approach for segmenting EPVS using 7 Tesla MRI scans, while [
29] proposed a GP-Unet model for segmenting EPVS using 1.5 Tesla MRI scans. However, most of these methods focus on the segmentation and the detection of the EPVS, and as a result they often lead to inaccurate EPVS rating scores due to their low segmentation performance (existing segmentation methods do not satisfy the performance parameters). Further, the production of the training dataset for deep learning-based segmentation requires the medical experts to manually label EPVS as masks—a time-consuming and laborious process. This is because as many as 20–50 EPVSs can be contained in a single slice.
In contrast, counting the EPVS as a rating score is significantly simpler. The development of methods for directly rating the EPVS could overcome the mentioned drawbacks in existing segmentation methods. In particular, since clinical decisions are made based on the rating score of EPVS, the direct measure of the EPVS rating score is a more convenient way—it bypasses the labor-intensive segmentation practice. Therefore, to deal with the above problems, we propose the direct estimation model of EPVS rating without segmentation or detection.
Currently, only one study reports a successful segmentation-free quantification of EPVS using a 3D regressive convolutional neural network (CNN) [
30]. However, this study used 7.0 Tesla MRI scans for its evaluation. There is a big difference in image quality between 3T and 7T, where the EPVS are much more clearly seen in 7T. To our knowledge, our study makes the first attempt to estimate the rating of EPVS without detection or segmentation using a 2D image-based deep learning model trained on 3.0 Tesla MRI scans. In this paper, we present a method for directly rating the EPVS in the basal ganglia using T2-weighted MRI. To do this, we first apply the preprocessing procedure containing Haar-transformation to the MRI to enhance EPVS visibility. Then, a CNN model is used with manual rating as training labels to estimate the EPVS rating. The rating of EVPS was formulated as a multi-class classification problem.
2. Materials and Methods
2.1. Subjects Information
A total of 96 subjects’ MRI data were collected from two hospitals, Konkuk University Medical Center and Hanyang University Seoul Hospital (July 2018 to August 2019). 76 subsets who reported memory complaints (in either subjective or objective form) were categorized as ‘patients’. The remaining 20 individuals—who were younger than 45 and had not shown clinical evidence of neurological or psychiatric symptoms—were categorized as ‘normal’. The demographic information of all subjects is as described in
Table 1. Information such as diagnosis, age, gender, clinical dementia rating (CDR), CDR (SB), and mini-mental status examination (MMSE) of all the subjects are detailed in
Table 1. Neuro psychiatric examination scores of MMSE, CDR, and neuropsychiatric battery test were used to diagnose mild cognitive impairment (MCI) and Alzheimer’s dementia (AD) based on the criteria suggested in [
31]. Based on these criteria, all 96 subjects were classified as: 8—AD, 4—other dementia, 47—MCI, 17—subjective memory impairment (SMI), and 20 control subjects. In this study, the SMI subjects were considered the ‘normal’ category, and AD and other dementia subjects were considered the ‘dementia’ category.
2.2. Data
All subjects’ MRIs were acquired using SIEMENS 3.0T Skyra (20-channel coil). The protocol includes 3D T1-weighted MRI, 3D/2D FLAIR MRI, and 3D SWI. Data of 76 patients consist of T1, T2, and FLAIR images. Data of 20 normal subjects include T2 and FLAIR images. For T1-weighted images, magnetization prepared rapid gradient echo (MPRAGE) sequence was used with repetition time (TR)/echo time (TE) = 2300 ms/2.98 ms; inversion time = 900; matrix size 256 × 256 in-plane resolution = 1 × 1 mm; slice thickness = 1 mm; number of slices = 192; and Grappa factor = 2. For T2-weighted images, an axial turbo spin-echo sequence was used with repetition time (TR)/echo time (TE) = 4450 ms/81 ms; flip angle = 150 degree; matrix size = 384 × 384; in-plane resolution = 0.573 × 0.573 mm; slice thickness = 5 mm; number of slices = 28. For FLAIR images, the 3D sequences were obtained using repetition time (TR)/echo time (TE) = 5000 ms/393 ms; inversion time = 1800 ms; matrix size = 256 × 256; in-plane resolution = 1 × 1 mm; slice thickness = 1 mm; and number of slices = 196. Parameters used to obtain the 2D FLAIR images include: repetition time (TR)/echo time (TE) = 9000 ms/95 ms; inversion time = 1800 ms; matrix size = 320 × 320; in-plane resolution = 0.688 × 0.688 mm; slice thickness = 5 mm; and number of slices = 28.
2.3. Manual Assessment of EPVS
This study defines EPVS as small, sharply delineated structures of less than 3 mm following the movement of the perforating vessel [
23] and containing CSF intensity (or near-CSF intensity). Visual assessment of EPVS rating was carried out manually by two neuroradiologists (one with 22 years of experience and the other with 8 years of experience) who were blinded to the clinical diagnosis one month prior to the visual assessment session. The two raters conducted their own analyses and reached a consensus on the final decision. All images (T1-weighted, T2-weighted MRI, and FLAIR) were considered for manual visual assessment. To begin, EPVS is evaluated using T2-weighted MRI. In FLAIR images, even if surrounding hyperintensity is present, it is regarded as EPVS if it exists inside white matter [
23]. EPVS is evaluated based on the three slices that contain the basal ganglia, which is above anterior commissure area. As suggested in [
20,
22], EPVS evaluation also includes sub-insular white matter originating from perforating artery of the insular cortex as the basal ganglia.
Both the size and shapes are critical in assessing the EPVS. When the exact count is difficult to obtain, general impression of imaging features can aid the EPVS rating [
20,
22]. Thus, the general impression of each rater is also recorded to grade EPVS. Finally, we recorded the counts of EPVS on both brains (three slices) of basal ganglia area independently and selected the highest count for rating. In cases of asymmetrical distribution in each anatomical region, the higher count from the two regions is selected for rating the EPVS. The rating (five point scale [
20]) was made based on the EPVS counts (
Table 2). Along with the rating score of the EPVS, the manual ratings of the dataset for all 576 images (96 subjects) are also presented in
Table 2. Agreement between the two raters (evaluated via intraclass correlation coefficient (ICC) using the healthy controls’ T2 images) were 88.0% (95% confidence interval: 0.761–0.942) and 90.1% (95% confidence interval: 0.800–0.952).
2.4. Deep Learning Model for EPVS Rating Estimation
The objective of this study is to directly estimate the rating of EPVS. The proposed framework of EPVS rating estimation comprised two steps and is as illustrated in
Figure 1. The first step, denoted by the highlighted box in
Figure 1, involves preprocessing the MRI to emphasize the EPVS region for better visibility and resizing it to accommodate the input of the deep neural network. In step 2, which is also indicated by the highlighted box in
Figure 1, we estimate the EPVS rating using a convolutional neural network (CNN). We describe the preprocessing methods used in this study and proposed deep neural network for direct rating estimation of EPVS in the sections that follow.
2.4.1. Preprocessing
During the preprocessing step, first the signal intensities of MRI were normalized in the range 0–1 by dividing the maximum value for each MRI scan. Then, in three selected MRI slices of the left and right brain, basal ganglia regions were cropped. Cropping the basal ganglia regions was necessary because EPVS ratings were estimated solely based on the basal ganglia region. Overall, a total of 576 images (6 images × 96 subject) were obtained and used as a dataset. Finally, the cropped images were enhanced using a Haar-transform-based approach [
32]. The application of Haar-transform to the cropped images resulted in emphasized images with clear visibility of EPVS. For illustration purposes, the cropped image before and after applying Haar-transform to the selected subject is shown in
Figure 2. In
Figure 2 (circled with red color), we can clearly observe that the EPVS of the basal ganglia region has better visibility. Finally, the pre-processed images were resized to 112 × 86 before feeding to the deep neural network.
2.4.2. Deep Neural Network
As illustrated in
Figure 1, the proposed deep neural network for directly estimating the EPVS rating consists of five convolutional layers, an average pooling layer, two fully connected layers, and a classification softmax layer. The final layer, for classification, is composed of five nodes, representing the EPVS’ five-point rating scale. The pre-processed image size is provided as an input for the network. Since EPVS have thin and tiny structures, average pooling over the max pooling layer is selected after several convolutions to maximally preserve the EPVS features.
Training: The proposed network was trained in an image-by-image manner. We divided the 576 images from 96 subjects into 462 training images from 77 subjects and 114 test images from 19 subjects for training and testing purposes. We used cross-entropy loss function for loss function. Additionally, for another loss function, we trained our model with mean square error (MSE). Adam optimizer with the learning rate of 0.001 was used. The network was trained for 300 epochs. To increase the diversity of the data and for better generalization of the trained network, data augmentation was performed using 2D rotation and flipping (each axis was rotated −30 and 30 degrees). The proposed method was implemented on TensorFlow 1.14 using a PC equipped with four GPUs (NVIDIA Geforce RTX 2080Ti).
Testing: During the testing phase, six images per subject were fed into the model and we obtained six EPVS ratings (EPVS rating score at image level). Finally, the highest score among the six images was selected for the EPVS rating estimation.
2.5. Evaluation for Deep Learning Model
We assessed our model’s accuracy at the image and subject levels. In terms of methodology, since we trained our deep learning model in a slice-by-slice manner, we reported the accuracy of our model at the image level. However, because one subject was evaluated using several MRI slices in a clinical setting, we used majority voting to report the accuracy of our model at the subject-level.
The training and testing data were carefully selected to evenly include all groups, i.e., dementia (AD and other dementia), MCI, and normal (SMI, healthy) subjects. Using five-fold cross validation, the average estimation score is reported as the model accuracy. Furthermore, the performance of the model for individual groups (dementia, MCI, and normal) was also analyzed and reported. Finally, the correlation between the model estimation and ground truth results (both image level and subject level) were analyzed using Spearman’s correlation coefficient.
3. Results
Using the data split as described previously, the proposed model was trained with 77 subjects and tested with 19 subjects.
Table 3 summarizes the model’s performance at the image and subject levels. A training accuracy of 88.1% at image level and 83.6% at subject level was observed. Overall, an accuracy of 87.7% at image level and an accuracy of 80.2% at subject level were achieved. The performance of the model for individual groups are also tabulated in
Table 3. In the case of dementia, the model achieved an accuracy of 91.7% at both image and subject level. In case of MCI, we obtained an accuracy of 83.0% at image level and 80.9% at subject level. For healthy subjects, we observed an accuracy of 92.3% at image level and 75.7% at subject level.
Spearman’s correlation coefficient between the estimated rating and ground truths at both image level and subject level were evaluated and are as shown in
Figure 3. A correlation coefficient of 0.9169 (
p-value < 0.0001) at subject level and 0.9335 (
p-value < 0.0001) at image level shows the reliability of the estimated values. Subject wise prediction of all subjects considered in this study are also analyzed and the results are as shown in
Figure 4. In
Figure 4, the estimated rating score of each subject, along with the ground truth, is presented.
Figure 4a depicts all subjects who were correctly predicted and
Figure 4b depicts all subjects who were incorrectly predicted. In the case of correctly predicted subjects, the prediction was correct despite the differences presented in the image-wise predictions. In the case of incorrectly predicted subjects, the prediction scores of most of the subjects were lower than the manual score (ground truth). This is because the numbers of EPVS were close to the critical numbers of the decision boundaries (for instance, when the number of EPVS is 11 or 21, the model tends to estimate the EPVS rating score as 1 or 2 instead of 2 or 3).
Table 4 summarizes the findings of an ablation study (an experiment with and without the pre-processing step). In pre-processing, the Haar transformation-based approach was applied to enhance the EPVS in MRI images. When the pre-processing step is included, estimation performances are increased by 10% at the subject level and 11% at the image level. This experiment result demonstrates that pre-processing for EPVS enhancement results in a more robust estimation model.
We compared our model to the automatic method of EPVS quantification using Haar-like features and random forest as a baseline approach (see [
25]). The compared method is a traditional approach that is one of the most represented techniques for the quantification of EPVS. We trained and tested the baseline method with the same dataset used in our estimation model. Compared to the other study, our estimation model has ~17% increased accuracy at both image and subject level (the baseline approach showed 69.73 ± 0.5% accuracy at image level and 63.02 ± 1.4% accuracy at subject level for our dataset).
4. Discussion
In this study, we proposed a framework to directly estimate the EPVS rating from T2-weighted MRI without using either detection or segmentation of EVPS. The overall accuracy of 87.7% at image level and 80.2% at subject level with the proposed method shows that the EPVS rating can be directly estimated from T2-weighted MRI images. We implemented our method following the same procedure as radiologists do. In clinical practice, radiologists choose the EVPS score based on the highest number of EPVS across multiple slices of MRI. As a result, we implemented this decision process as a majority vote using the results of image-level predictions. Since we used majority voting in the subject level prediction, the performance of the model at subject level was less accurate when compared to its performance at image level. We observed this decrease in performance because the correct prediction at the image-level in the presence of a low EPVS score could not be considered at the subject-level prediction.
Individual analyses of each subject’s EPVS rating prediction reveals that for incorrectly predicted subjects the prediction score was lower than the manual score in most subjects (15 out of 19). One possible explanation is that the number of subjects presented in the range of [0, 2] is higher than the number of subjects presented in the range of [3, 4]. Another reason may be that many of the EPVS numbers were close to the critical number of the decision boundary and may have caused under-rating.
We can see from the result analysis of each group that the predictions of all groups at image level are like the predictions at subject level, except for normal subjects (92.3% at image-level, and 75.7% at subject-level). This discrepancy was caused by the strict criteria of rating at zero level (zero means that there are no EPVS in any of the images corresponding to a particular subject. Additionally, we used majority voting from the six images and predicted the score at the subject level). More sophisticated methods of voting could nullify this gap between subject level and image level.
This study has a limitation for comparison with other state-of-the-art methods due to its different labeling scheme. We labeled the EPVS as the score (weak labeling), but for comparison with segmentation networks we must label the EPVS as masks of MRI slices (strong labeling), in which there are 20–50 EVPS (About 50% or more of the total data) in one slice. Moreover, one existing method for EPVS quantification is 3D modeling, but in our case we used a 2D model. We followed Potter et al.’s method [
20] for making the labeling as widely applicable to clinical practice as possible and this means using 2D slice-based measurements of portions of the basal ganglia region in MRI images. The existing 3D models use the whole basal ganglia region of MRI images. Therefore, we simply compared our model with the traditional method as a baseline approach and of the two our model gave significantly better performance.
While doing manual ratings of EPVS, we first identified EPVS on T2-weighted MRI images and then confirmed this with T1-weighted MRI and FLAIR scans. However, the study includes only the T2-weighted MRI in the analysis. This is due to the variations in the acquisition parameters such as direction of acquisition, image matrix, FOV, and slice thickness. Though the T1-weighted MRI and FLAIR could provide additional features and improve the accuracy further, it is not convenient to apply the image registration between T1-weighted, T2-weighted, and FLAIR images. Thus, although T2-weighted MRI alone is used to directly predict the rating of EVPS, we obtained comparable accuracy to state-of-the-art methods at both image- and subject-level.
Direct grading of the EPVS rather than detection or segmentation is more convenient and efficient in clinical practice. Since the model estimates the rating directly from T2-weighted MRI without either detection or segmentation of EPVS, the proposed framework has great potential for use as a disease risk indicator. However, before the proposed framework can be used in clinical practice, the EPVS rating estimation model must be further improved with sufficient data training. In the future, we intend to continue collecting data in order to develop an efficient model for estimating the EPVS rating accurately.
5. Conclusions
In this paper we proposed a deep learning model for directly estimating the EPVS rating from T2-weighted MRI images without requiring detection or segmentation. The proposed model is trained in an image-by-image manner and validated at the subject-level via the majority voting method. Since the proposed model followed the same procedure as a radiologist does and estimates the EPVS rating directly from T2-weighted MRI images without either detection or segmentation, it is convenient and efficient for clinical use. Our results demonstrate that the proposed method can be used as a disease risk indicator, assisting in the early detection of dementia. This paper may be of interest to readers who are interested in neurology and its applications.
Author Contributions
Conceptualization, J.-H.K. and E.Y.; methodology, E.Y.; software, E.Y.; validation, E.Y., M.P.; formal analysis, E.Y., J.-H.K. and W.-J.M.; investigation, E.Y., V.G. and W.-J.M.; resources, E.Y., V.G. and J.-H.K.; data curation, W.-J.M., Y.M. and H.-J.K.; writing—original draft preparation, E.Y.; writing—review and editing, V.G. and J.-H.K.; visualization, E.Y. and V.G.; supervision, J.-H.K.; project administration, J.-H.K.; funding acquisition, J.-H.K. and W.-J.M. All authors have read and agreed to the published version of the manuscript.
Funding
This research was supported by a grant from the Korea Health Technology R&D Project through the Korea Health Industry Development Institute (KHIDI), which is funded by the Ministry of Health & Welfare, Republic of Korea (grant number: HI18C1038 and HU21C0222).
Institutional Review Board Statement
The study was approved by the Institutional Review Board (or Ethics Committee) of Konkuk University Medical Center (CRIS registration number KCT000318, date of approval: 2018.07.15.).
Informed Consent Statement
Informed consent was obtained from all subjects involved in the study.
Conflicts of Interest
The authors declare no conflict of interest.
References
- Zhang, E.T.; Inman, C.B.; Weller, R.O. Interrelationships of the pia mater and the perivascular (Virchow-Robin) spaces in the human cerebrum. J. Anat. 1990, 170, 111–123. [Google Scholar]
- Iliff, J.J.; Wang, M.; Zeppenfeld, D.M.; Venkataraman, A.; Plog, B.A.; Liao, Y.; Deane, R.; Nedergaard, M. Cerebral Arterial Pulsation Drives Paravascular CSF-Interstitial Fluid Exchange in the Murine Brain. J. Neurosci. 2013, 33, 18190–18199. [Google Scholar] [CrossRef] [PubMed] [Green Version]
- Kress, B.T.; Iliff, J.J.; Xia, M.; Wang, M.; Wei, H.S.; Zeppenfeld, D.; Xie, L.; Kang, H.; Xu, Q.; Liew, J.A.; et al. Impairment of paravascular clearance pathways in the aging brain. Ann. Neurol. 2014, 76, 845–861. [Google Scholar] [CrossRef] [PubMed]
- Wuerfel, J.; Haertle, M.; Waiczies, H.; Tysiak, E.; Bechmann, I.; Wernecke, K.D.; Zipp, F.; Paul, F. Perivascular spaces--MRI marker of inflammatory activity in the brain? Brain 2008, 131, 2332–2340. [Google Scholar] [CrossRef] [PubMed] [Green Version]
- Chen, H.; Dou, Q.; Yu, L.; Qin, J.; Heng, P.A. VoxResNet: Deep voxelwise residual networks for brain segmentation from 3D MR images. NeuroImage 2018, 170, 446–455. [Google Scholar] [CrossRef]
- Smeijer, D.; Ikram, M.K.; Hilal, S. Enlarged Perivascular Spaces and Dementia: A Systematic Review. J. Alzheimer’s Dis. 2019, 72, 247–256. [Google Scholar] [CrossRef] [Green Version]
- Gertje, E.C.; van Westen, D.; Panizo, C.; Mattsson-Carlgren, N.; Hansson, O. Association of enlarged perivascular spaces and measures of small vessel and Alzheimers disease. Neurology 2020, 96, e193–e202. [Google Scholar] [CrossRef]
- Etemadifar, M.; Hekmatnia, A.; Tayari, N.; Kazemi, M.; Ghazavi, A.; Akbari, M.; Maghzi, A.-H. Features of Virchow-Robin spaces in newly diagnosed multiple sclerosis patients. Eur. J. Radiol. 2011, 80, e104–e108. [Google Scholar] [CrossRef]
- Duperron, M.-G.; Tzourio, C.; Schilling, S.; Zhu, Y.-C.; Soumaré, A.; Mazoyer, B.; Debette, S. High dilated perivascular space burden: A new MRI marker for risk of intracerebral hemorrhage. Neurobiol. Aging 2019, 84, 158–165. [Google Scholar] [CrossRef]
- Mikami, T.; Tamada, T.; Suzuki, H.; Ukai, R.; Wanibuchi, M.; Mikuni, N. Influence of hemodynamics on enlarged perivascular spaces in atherosclerotic large vessel disease. Neurol. Res. 2018, 40, 1021–1027. [Google Scholar] [CrossRef]
- Liang, Y.; Deng, M.; Chen, Y.-K.; Mok, V.; Wang, D.-F.; Ungvari, G.S.; Chu, C.-W.W.; Berge, E.; Tang, W.-K. Enlarged perivascular spaces are associated with health-related quality of life in patients with acute ischemic stroke. CNS Neurosci. Ther. 2017, 23, 973–979. [Google Scholar] [CrossRef] [Green Version]
- Uchiyama, Y.; Kunieda, T.; Asano, T.; Kato, H.; Hara, T.; Kanematsu, M.; Iwama, T.; Hoshi, H.; Kinosada, Y.; Fujita, H. Computer-aided diagnosis scheme for classification of lacunar infarcts and enlarged Virchow-Robin spaces in brain MR images. In Proceedings of the 2008 30th Annual International Conference of the IEEE Engineering in Medicine and Biology Society, Vancouver, BC, Canada, 20–24 August 2008; pp. 3908–3911. [Google Scholar]
- Hosoki, S.; Tanaka, T.; Ihara, M. Diagnostic and prognostic blood biomarkers in vascular dementia: From the viewpoint of ischemic stroke. Neurochem. Int. 2021, 146, 105015. [Google Scholar] [CrossRef]
- Fang, Y.; Gu, L.-Y.; Tian, J.; Dai, S.-B.; Chen, Y.; Zheng, R.; Si, X.-L.; Jin, C.-Y.; Song, Z.; Yan, Y.-P.; et al. MRI-visible perivascular spaces are associated with cerebrospinal fluid biomarkers in Parkinson’s disease. Aging 2020, 12, 25805–25818. [Google Scholar] [CrossRef]
- Zhu, Y.-C.; Tzourio, C.; Soumaré, A.; Mazoyer, B.; Dufouil, C.; Chabriat, H.J.S. Severity of dilated Virchow-Robin spaces is associated with age, blood pressure, and MRI markers of small vessel disease: A population-based study. Stroke 2010, 41, 2483–2490. [Google Scholar] [CrossRef] [Green Version]
- Descombes, X.; Kruggel, F.; Wollny, G.; Gertz, H. An Object-Based Approach for Detecting Small Brain Lesions: Application to Virchow-Robin Spaces. IEEE Trans. Med. Imaging 2004, 23, 246–255. [Google Scholar] [CrossRef] [PubMed]
- Zhao, L.; Lee, A.; Fan, Y.-H.; Mok, V.C.; Shi, L. Magnetic resonance imaging manifestations of cerebral small vessel disease: Automated quantification and clinical application. Chin. Med. J. 2021, 134, 151–160. [Google Scholar] [CrossRef] [PubMed]
- Lyndon, D.; Davagnanam, I.; Wilson, D.; Jichi, F.; Merwick, A.; Bolsover, F.; Jager, H.R.; Cipolotti, L.; Wheeler-Kingshott, C.; Hughes, D.; et al. MRI-visible perivascular spaces as an imaging biomarker in Fabry disease. J. Neurol. 2021, 268, 872–878. [Google Scholar] [CrossRef]
- Huang, P.; Zhu, Z.; Zhang, R.; Wu, X.; Jiaerken, Y.; Wang, S.; Yu, W.; Hong, H.; Lian, C.; Li, K.; et al. Factors Associated with the Dilation of Perivascular Space in Healthy Elderly Subjects. Front. Aging Neurosci. 2021, 13, 125. [Google Scholar] [CrossRef] [PubMed]
- Potter, G.M.; Chappell, F.M.; Morris, Z.; Wardlaw, J.M. Cerebral Perivascular Spaces Visible on Magnetic Resonance Imaging: Development of a Qualitative Rating Scale and its Observer Reliability. Cerebrovasc. Dis. 2015, 39, 224–231. [Google Scholar] [CrossRef]
- Huang, P.; Zhang, R.; Jiaerken, Y.; Wang, S.; Yu, W.; Hong, H.; Lian, C.; Li, K.; Zeng, Q.; Luo, X.; et al. Deep white matter hyperintensity is associated with the dilation of perivascular space. Br. J. Pharmacol. 2021, 41, 2370–2380. [Google Scholar] [CrossRef]
- Potter, G.M.; Doubal, F.N.; Jackson, C.A.; Chappell, F.M.; Sudlow, C.L.; Dennis, M.S.; Wardlaw, J.M. Enlarged Perivascular Spaces and Cerebral Small Vessel Disease. Int. J. Stroke 2015, 10, 376–381. [Google Scholar] [CrossRef] [PubMed] [Green Version]
- Wardlaw, J.M.; Smith, E.; Biessels, G.J.; Cordonnier, C.; Fazekas, F.; Frayne, R.; Lindley, R.; O’Brien, J.; Barkhof, F.; Benavente, O.R.; et al. Neuroimaging standards for research into small vessel disease and its contribution to ageing and neurodegeneration. Lancet Neurol. 2013, 12, 822–838. [Google Scholar] [CrossRef] [Green Version]
- Dubost, F.; Yilmaz, P.; Adams, H.; Bortsova, G.; Ikram, M.A.; Niessen, W.; Vernooij, M.; de Bruijne, M. Enlarged perivascular spaces in brain MRI: Automated quantification in four regions. NeuroImage 2019, 185, 534–544. [Google Scholar] [CrossRef]
- Park, S.H.; Zong, X.; Gao, Y.; Lin, W.; Shen, D. Segmentation of perivascular spaces in 7 T MR image using auto-context model with orientation-normalized features. NeuroImage 2016, 134, 223–235. [Google Scholar] [CrossRef] [PubMed] [Green Version]
- Ramirez, J.; Berezuk, C.; McNeely, A.A.; Scott, C.J.; Gao, F.; Black, S.E. Visible Virchow-Robin spaces on magnetic resonance imaging of Alzheimer’s disease patients and normal elderly from the Sunnybrook Dementia Study. J. Alzheimer’s Dis. 2015, 43, 415–424. [Google Scholar] [CrossRef]
- Ballerini, L.; Lovreglio, R.; Hernández, M.D.C.V.; Gonzalez-Castro, V.; Maniega, S.M.; Pellegrini, E.; Bastin, M.E.; Deary, I.J.; Wardlaw, J.M. Application of the Ordered Logit Model to Optimising Frangi Filter Parameters for Segmentation of Perivascular Spaces. Procedia Comput. Sci. 2016, 90, 61–67. [Google Scholar] [CrossRef] [Green Version]
- Lian, C.; Zhang, J.; Liu, M.; Zong, X.; Hung, S.-C.; Lin, W.; Shen, D. Multi-channel multi-scale fully convolutional network for 3D perivascular spaces segmentation in 7T MR images. Med. Image Anal. 2018, 46, 106–117. [Google Scholar] [CrossRef]
- Dubost, F.; Bortsova, G.; Adams, H.; Ikram, A.; Niessen, W.J.; Vernooij, M.; De Bruijne, M. GP-Unet: Lesion Detection from Weak Labels with a 3D Regression Network. In Proceedings of the International Conference on Medical Image Computing and Computer-Assisted Intervention, Quebec City, QC, Canada, 11–13 September 2017; pp. 214–221. [Google Scholar]
- Dubost, F.; Adams, H.; Bortsova, G.; Ikram, M.A.; Niessen, W.; Vernooij, M.; De Bruijne, M. 3D regression neural network for the quantification of enlarged perivascular spaces in brain MRI. Med. Image Anal. 2019, 51, 89–100. [Google Scholar] [CrossRef] [Green Version]
- Ahn, H.-J.; Chin, J.; Park, A.; Lee, B.H.; Suh, M.K.; Seo, S.W.; Na, D.L. Seoul Neuropsychological Screening Battery-Dementia Version (SNSB-D): A Useful Tool for Assessing and Monitoring Cognitive Impairments in Dementia Patients. J. Korean Med. Sci. 2010, 25, 1071–1076. [Google Scholar] [CrossRef] [Green Version]
- Hou, Y.; Park, S.H.; Wang, Q.; Zhang, J.; Zong, X.; Lin, W.; Shen, D. Enhancement of Perivascular Spaces in 7 T MR Image using Haar Transform of Non-local Cubes and Block-matching Filtering. Sci. Rep. 2017, 7, 1–12. [Google Scholar] [CrossRef]
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