Generation of a Virtual Cohort of Patients for in Silico Trials of Acute Ischemic Stroke Treatments
by
, , , ,
Sara Bridio
1,
Giulia Luraghi
1,
Anna Ramella
1,
Jose Felix Rodriguez Matas
1,
Gabriele Dubini
1,
Claudio A. Luisi
2,
Michael Neidlin
2,
Praneeta Konduri
3,4,
Nerea Arrarte Terreros
3,4,
Henk A. Marquering
3,4, 
Charles B. L. M. Majoie
4 and
Francesco Migliavacca
1,* 1
Computational Biomechanics Laboratory, Laboratory of Biological Structure Mechanics (LaBS), Department of Chemistry, Materials and Chemical Engineering “Giulio Natta”, Politecnico di Milano, 20133 Milano, Italy
2
Department of Cardiovascular Engineering, Institute of Applied Medical Engineering, Medical Faculty, RWTH Aachen University, 52074 Aachen, Germany
3
Department of Biomedical Engineering and Physics, Amsterdam UMC, Location University of Amsterdam, 1105 AZ Amsterdam, The Netherlands
4
Department of Radiology and Nuclear Medicine, Amsterdam UMC, Location University of Amsterdam, 1105 AZ Amsterdam, The Netherlands
*
Author to whom correspondence should be addressed.
Appl. Sci. 2023, 13(18), 10074; https://doi.org/10.3390/app131810074
Submission received: 31 July 2023
/
Revised: 4 September 2023
/
Accepted: 5 September 2023
/
Published: 7 September 2023
(This article belongs to the Special Issue Application of Biomechanics in Cardiovascular Diseases)
Abstract
:The development of in silico trials based on high-fidelity simulations of clinical procedures requires the availability of large cohorts of three-dimensional (3D) patient-specific anatomy models, which are often hard to collect due to limited availability and/or accessibility and imaging quality. Statistical shape modeling (SSM) allows one to identify the main modes of shape variation and to generate new samples based on the variability observed in a training dataset. In this work, a method for the automatic 3D reconstruction of vascular anatomies based on SSM is used for the generation of a virtual cohort of cerebrovascular models suitable for computational simulations, useful for in silico stroke trials. Starting from 88 cerebrovascular anatomies segmented from stroke patients’ images, an SSM algorithm was developed to generate a virtual population of 100 vascular anatomies, defined by centerlines and diameters. An acceptance criterion was defined based on geometric parameters, resulting in the acceptance of 83 generated anatomies. The 3D reconstruction method was validated by reconstructing a cerebrovascular phantom lumen and comparing the result with an STL geometry obtained from a computed tomography scan. In conclusion, the final 3D models of the generated anatomies show that the proposed methodology can produce a reliable cohort of cerebral arteries.
1. Introduction
The increasing credibility of computational models and simulations of medical treatments is encouraging the exploration of the use of in silico trials to support and refine traditional clinical trials. An in silico trial consists of using computational tools to simulate the use of a new treatment, device, or drug in a cohort of virtual patients, obtaining insights on the efficacy. Credible biomechanical models have the potential of reducing the overall time and costs of the process by estimating in advance the performance of the new devices and only letting the most promising ones move forward to actual clinical trials [1].
Many clinical applications would benefit from the development of in silico trials. Among these, an in silico trial may support the development of better treatments for acute ischemic stroke (AIS), the pathology occurring when a thrombus obstructs a cerebral artery causing the development of an infarct zone in brain tissues [2]. In the case of large vessel occlusion, i.e., occurring in the internal carotid artery (ICA), the middle cerebral artery (MCA) M1 or M2 segments, or the anterior cerebral artery (ACA), which form a bifurcation called the T-junction, the most effective treatment is endovascular thrombectomy [3], a minimally invasive treatment aiming at mechanically removing the thrombus with a stent-retriever and/or aspiration catheters.
High-fidelity in silico models of the thrombectomy procedure have been recently proposed in the literature [4,5,6,7]. The stent-retriever thrombectomy simulation developed in [4], used to replicate a patient-specific case, was integrated into a framework for running the first proof-of-concept in silico trial for stroke treatments [8]. The framework was validated by replicating a real clinical trial and then employed to compare treatment outcomes in different subpopulations and with different thrombectomy devices, demonstrating the potentiality of the in silico approach to support clinical stroke trials. Knowing that anatomy does impact thrombectomy outcome [9,10,11,12,13], two aspects are important to consider when developing in silico trials for stroke treatments: (i) patient stratification based on anatomical characteristics; (ii) the generation of a large cohort of patients. The latter aspect is important for building data-driven surrogate or reduced-order models to predict in silico trial outcomes.
Normally, in patient-specific modeling, the geometry domain is obtained from diagnostic images, e.g., computed tomography (CT) and Magnetic Resonance Imaging (MRI). In the AIS context, it is possible to automatically identify the centerlines and diameters of the vessels [14], while three-dimensional (3D) reconstruction from the segmentation process provides a non-smooth voxel representation and requires additional steps to be used in models [4]. Due to the limited accessibility, consistency, and quality of clinical images, the generation of virtual cohorts of patients is helpful to run in silico clinical trials. When an in silico trial is based solely on data-driven models, the cohort of patients can be represented by a set of metadata [8]. Differently, if the in silico trial pipeline includes high-fidelity modeling (e.g., [15,16]), the cohort of patients requires the collection of 3D domains. In [17], the authors provided a review of different virtual cohorts of cardiac models. They indicated three different methodologies for developing virtual patient cohorts: mapping virtual cohorts, sampling from inferred distributions, and random sampling with acceptance criteria. In the current literature, an acceptance criterion for a virtual patient cohort can be distinguished as data-driven or clinically driven: data-driven if the acceptance criterion relies on the geometrical variability of the training samples [18]; clinically driven if the acceptance criterion is defined by a clinical requirement, for example, a specific characteristic or phenotype [19]. In [19], the authors proposed a machine learning surrogate model to predict the outcome of the acceptance criteria in a clinically driven population of aortas. The authors demonstrated that the sampling strategy and the verification of the generated cases impacted the efficiency of the process and the quality of the resulting cohort. A centerline-based statistical shape model (SSM) was presented by [20] to generate a data-driven population of aortas; 154 real patient geometries were used to train an SSM that used a principal component analysis (PCA) to capture the morphological features in order to create a large virtual population (about 3000 patients).
Within this context, this work proposes an automatic procedure to generate a data-driven virtual cohort of AIS patients’ anatomies. The objective is the creation of a tool which enables the generation of large cohorts of virtual populations of cerebrovascular anatomies suitable for high-fidelity thrombectomy modeling. This will facilitate the development of in silico trial approaches, reducing the issues related to the availability of high-quality images of stroke patients and to privacy concerns when sharing patient data between hospitals and modelers. Moreover, the availability of large populations for in silico modeling is required in general when running in silico stroke trials, and in particular to train accurate and fast surrogate models like the one used in [8]. To this aim, first, (i) an SSM approach is used to generate cerebrovascular anatomies described by their centerlines and associated diameters, starting from a cohort of 88 real AIS patients. Then, (ii) an automatic 3D reconstruction of the vessels from the centerlines and associated diameters is implemented and (iii) validated.
2. Materials and Methods
2.1. Collection of Patient-Specific Data
The clinical data of 100 patients affected by an AIS due to an occlusion in the M1 segment of the MCA were retrospectively collected from the MR CLEAN Registry, a randomized clinical trial for stroke treatments involving several intervention centers in the Netherlands [21]. Images of the patients’ cerebral vasculature were acquired with non-contrast computed tomography (NCCT) and computed tomography angiography (CTA) before treatment. The image segmentation was performed with StrokeViewer (NICO.LAB, Amsterdam, The Netherlands), and the iCAFE V1.3.0 software [22] (© 2016–2018 University of Washington. Used with permission) was used to extract the centerlines and diameters of the cerebral vessels (a diameter associated with each point of the centerline) and to label the different segments. Thanks to the labeling of the vascular tracts, only the segments of interest for this work were collected, namely the ICA, ACA, M1, and M2. For each patient, the vessels on the contralateral side with respect to the occlusion were selected to gain a complete vascular representation (since in the occluded side the imaging is available only up to the proximal end of the occlusion).
For the purpose of creating a training dataset for the generation of virtual patients, exclusion criteria were imposed to select patients with a complete set of vessels of interest. Therefore, vascular segmentations not including the ACA or either of the M2 branches were excluded, resulting in a cohort of 88 patients in the training dataset.
2.2. Generation of Virtual Patients
A statistical shape modeling (SSM) approach was used for the generation of virtual patients. SSM generally relies on the application of a principal component analysis (PCA) to a set of anatomic representations to identify a mean anatomy and a number of modes of shape variation [23].
In this work, the training dataset was made of the cerebral anatomies of 88 patients, described by the vascular centerlines and the associated lumen diameter for each point of the centerline. The whole processing of the data was performed through a developed MATLAB (Math-Works, Natick, MA, USA) code. The centerlines were first smoothed and resampled such that each vascular segment was made of the same number of points for each patient. Linear interpolation was used to associate the diameter values to the new points. Segmentation artifacts frequently occurred at the extreme points. If a diameter value at the extreme point of a centerline was more than 50% bigger or smaller than the previous diameter, it was corrected by assigning the same diameter of the previous point.
To have homogeneous anatomies, and without evidence of significant anatomic differences between the two sides of the intracranial cerebral vasculature [24,25,26,27], the left-side anatomies were mirrored to obtain a right-side cerebrovasculature for all the training data. Subsequently, rigid registration was performed to align the anatomies. A PCA was conducted on the aligned centerlines with associated diameters to identify the principal modes of shape variation. The N modes which cumulatively represented 95% of the anatomy information were selected. The description of each vascular anatomy was then reduced to the first N principal dimensions.
One hundred virtual patients were generated by randomly sampling the values of the N principal dimensions following normal distributions fitted to each principal dimension in the training dataset. The Lilliefors test was used to test normality. An acceptance criterion was defined to reject unphysiological anatomic realizations. For this purpose, the vascular anatomies were analyzed to extract geometric parameters with the method described in [9]. Briefly, each ICA was divided into 4 bends (from the T-junction: superior, anterior, posterior, and inferior), and each bend was analyzed to extract the average diameter (Dsup, Dant, Dpos, and Dinf), the curvature expressed as the radius of the fitting circle (rsup, rant, rpos, and rinf), and the tortuosity, calculated as the ratio between the bend length along the centerline and the distance between the bend extremes (tsup, tant, tpos, and tinf) (Figure 1). In addition, the three angles formed at the T-junction (αICA-ACA, αICA-M1, and αM1-ACA) and the three angles at the M1 bifurcation (αM1-M2a, αM1-M2b, and αM2a-M2b) were calculated. Finally, the average diameters of the ACA, M1, and M2 segments (DACA, DM1, and DM2) were stored. Since the inferior bend did not show significant variability among the analyzed cerebrovascular anatomies, rinf and tinf were excluded from the acceptance criteria. A total of 19 geometric parameters were calculated both for the anatomies in the training dataset to define their admissible ranges, and for the generated virtual patients, to evaluate the acceptability of the anatomy. If any of the parameters had a value outside the minimum–maximum range of the training dataset, the generated virtual patient was discarded. Finally, in order to validate the virtual cohort of patients, a comparison between cohort-level and training-population-level distributions of the geometric parameters was performed [17] by means of the Mann–Whitney U-test, where a two-sided p-value of less than 0.05 determined significance for rejecting the hypothesis that the two compared sets of data originated from distributions with equal medians.
2.3. Automatic 3D Reconstruction of Cerebral Vessels
The proposed 3D reconstruction method requires the vascular centerlines with the associated diameters of the segment of interest to generate AIS patients. The Computer-Aided Design (CAD) software Creo Parametric (PTC, Boston, MA, USA) was used. In particular, within the software, an automatic procedure was implemented by creating blended surfaces from a text file containing cross-sections discretized by points. With a Python code, the ad hoc input files with the points-sections were created, starting from the generated vessels’ centerlines and diameters. The implemented Python code first recognized and combined the ICA, M1, and one M2 as a smooth and continuous line, the ACA in the T-junction, and the second M2 in the M1 bifurcation (Figure 2A). Then, the circular section for each node of the centerline was defined by considering the specific diameter and discretized with 20 nodes (Figure 2B). Only some sections were considered in the text files, based on the local curvature of the centerline (Figure 2C). In high-curvature points, few sections were considered in order to avoid the self-penetration of sections. More details about the local curvature calculation are presented in [9]. The final 3D reconstruction of the vascular anatomy was then automatically obtained in Creo Parametric (Figure 2D).
2.4. Reconstruction Validation
The quality of the proposed 3D reconstruction method was assessed by comparing the reconstructed CAD model with the STL geometry directly obtained from the segmentation process. For this purpose, a silicone phantom of the cerebral arteries with a complete circle of Willis anatomy was used (Figure 3A). The process of creating cerebrovascular phantoms from 3D-printed vessel lumina, which are derived from CTA scans, is described in [28].
The cerebral arteries phantom was segmented from CT images in a semi-automatic way with the open-source VMTK V1.4.0 (Orobix s.r.l.) software using the threshold method. In particular, all the pixels comprised within two specified thresholds were selected to obtain the final segmented domain (Figure 3B). The segmented domain, in particular the internal lumen, was triangulated to be exported in STL format (Figure 3C). To enable the quantification of the mismatch between the two models, the reconstructed CAD model was meshed in ANSA (BETA CAE Systems, Root, Switzerland) with triangular elements of the same average element size as in the STL model, i.e., 0.35 mm. In the post-processing software META (BETA CAE Systems), the CAD and STL models were superimposed and the mismatch between the two was evaluated by calculating, for each node of the CAD model, the Euclidean distance to the closest node of the STL model. The distances were then normalized by the local diameter value of the vascular model.
3. Results
3.1. Generated Virtual Patients
Figure 4A shows the results of the PCA on the vascular anatomies in the training dataset. Fifteen modes were required to represent 95% of the variance of the anatomy shapes. Figure 4B shows as examples the distribution of the first three principal values and their fitting with normal distributions, which are subsequently used to sample new values of the principal modes for the generation of virtual anatomies. The Lilliefors test confirmed that 14 out of the 15 principal values were normally distributed. A comparison of the distributions of the 15 principal values in the training and generated datasets is shown in Appendix A.
Examples of 3D reconstructions of the generated virtual patients are shown in Figure 5. Of the 100 generated virtual anatomies, 17 were rejected due to the acceptance criteria, as one or more of the considered 19 geometric parameters were outside the range defined with the anatomies in the training dataset. Figure 6 shows the boxplots of the distributions of the geometric parameters in the training and generated dataset. The results of the Mann–Whitney U-test indicated that for 13 out of the 19 parameters, the values in the generated and training dataset could be described with distributions with equal medians (the red asterisks in Figure 6 indicate the parameters with different distributions between the generated and training dataset). More details on the calculated geometric parameters are collected in Appendix A.
3.2. Reconstruction Validation Analysis
A comparison between the STL geometry from segmentation and the corresponding 3D reconstruction geometry was carried out (Figure 7A), aiming at assessing the goodness of the developed 3D reconstruction method. In Figure 7B, the contour map of the distances normalized by the local diameter values is shown. Higher values with a maximum of 19% were detected at the T-junction and in the M1 segment with a maximum absolute distance of 0.36 mm and 0.33 mm, respectively.
4. Discussion
The availability of in silico models of patient cohorts is gaining importance due to the growing interest in the development of in silico trials for the assessment of the safety and efficacy of new medical devices and procedures. When the in silico trial is based on high-fidelity simulations of a clinical procedure, a large amount of high-quality Computerized Tomography or Magnetic Resonance Imaging data are required for the generation of patient-specific 3D anatomical domains, together with other clinical data needed as input for the procedure modeling. However, high-quality imaging is not always available, or accessible, for instance, due to patient privacy policies, and gathering a large number of such high-quality images may not be feasible in clinical practice.
In this regard, the implementation of methodologies for the generation of synthetic data, starting from a limited real patients’ dataset, can offer a solution for the creation of large virtual populations suitable for in silico trials. Statistical shape modeling is a well-established methodology [23,29,30,31] which, based on dimensionality reduction techniques and parameter sampling, allows one to identify the principal modes of shape variation of an object and to generate new samples. The SSM technique has been used in the literature for the generation of virtual cohorts of cardiac [17] and aortic [19,20] models.
This work proposed the use of the SSM approach for the generation of virtual populations of cerebrovascular anatomies, useful for the development of in silico trials for AIS treatments. In [8], the first proof-of-concept in silico stroke trial was implemented, based on a surrogate model of the thrombectomy procedure trained on a dataset of 94 high-fidelity thrombectomy simulations run in patient-specific vascular models. The methodology described in the present work would enable the creation of the desired number of virtual stroke patients for increasing the reliability of an in silico stroke trial. Moreover, this methodology also allows one to generate virtual patients with a variety of anatomic characteristics, which is important to assess the efficacy of a stroke treatment. In fact, several studies in the literature, based on the analysis of clinical data or on computational approaches, demonstrated the impact of geometric parameters, such as arterial diameters, curvatures and ICA tortuosity, on the outcome of thrombectomy procedures [9,10,11,12,13].
As a proof-of-concept of the methodology, a virtual population of 100 cerebrovascular anatomies was generated using an SSM methodology with random sampling of the principal shape modes following the normal distributions fitted to the principal values of the training dataset. The methodology allowed the generation of the centerlines of the main cerebral vessels (ICA, ACA, M1, and M2) and the associated diameters. Subsequently, an acceptance criterion was established, based on 19 geometric parameters. Of the 100 synthetic anatomies, 17 had at least one of the parameters outside the range allowed by the analysis of the data used for the training of SSM and were excluded from the final population. The comparison of the geometric parameters’ distribution (Figure 6 and Appendix A) demonstrated that the generated virtual population represents the data variability in the original training dataset well. The Mann–Whitney U-test assessed that, for 13 out of the 19 considered geometric parameters, the parameter distribution in the generated population had a median equal to the one in the training dataset, indicating that the generated population represents the characteristics observed in the training dataset well. Different sampling strategies may lead to different results on the distribution of the geometric parameters. For instance, uniform sampling of the principal values within the training set range would allow a broader coverage of the possible anatomy configurations, increasing the number of virtual anatomies with admissible geometric parameters but less represented in the training dataset.
Following the generation of vascular centerlines and diameters, a method for the automatic 3D reconstruction of the virtual anatomies was illustrated. More generally, the proposed 3D reconstruction method allows for the automatic reconstruction of patient-specific cerebral vessels starting from centerlines and diameters obtained from the segmentation of clinical images. The accuracy of the reconstruction was evaluated through a comparison with an STL model directly obtained after the segmentation of CT scans of a patient-like 3D-printed cerebrovascular phantom. The results indicated that the obtained CAD model replicates the STL model with good accuracy. Since the reconstruction method is built from the centerline and the associated diameters, circular lumen sections were assumed. In reality, non-circular and irregular sections could be observed. However, the relative distance calculated between CAD—with circular sections—and STL—with real non-circular sections—was less than 19%. The main mismatches were observed in vascular portions with critical shapes, e.g., tracts of high curvature, or at the extremes of the models, where segmentation artifacts were more frequent. In this regard, the accuracy of the vascular reconstruction was compared with the provided STL model to assess the overall agreement of the vascular shapes. Ultimately, the accuracy of the patient-specific vascular model will always depend on the resolution of the clinical imaging techniques.
5. Conclusions
This work proposed a method for automatically generating a virtual cohort of 3D cerebral arteries. The method allows one to reconstruct cerebral vessels with good accuracy and in a short time, allowing for the future generation of large cohorts of virtual patients for the in silico simulation of stroke treatments.
Supplementary Materials
The following supporting information can be downloaded at: https://www.mdpi.com/article/10.3390/app131810074/s1, INSIST Investigators, MR CLEAN Registry Investigators, and MR CLEAN Trial Investigators.
Author Contributions
Conceptualization, S.B., G.L., J.F.R.M. and F.M.; methodology, S.B. and G.L.; software, S.B. and G.L.; validation, S.B., A.R. and C.A.L.; investigation, S.B. and G.L.; data curation, P.K. and N.A.T.; writing—original draft preparation, S.B., G.L., A.R. and C.A.L.; writing—review and editing, J.F.R.M., G.D., M.N., P.K., N.A.T., H.A.M., C.B.L.M.M. and F.M.; supervision, G.D., M.N., H.A.M., C.B.L.M.M. and F.M. All authors have read and agreed to the published version of the manuscript.
Funding
This project has received funding from the European Union’s Horizon 2020 research and innovation program under grant agreement No. 777072 and from the MIUR FISR-FISR2019_03221 CECOMES. F.M. is partially supported by the MUSA—Multilayered Urban Sustainability Action—project, funded by the European Union—NextGenerationEU, under the National Recovery and Resilience Plan (NRRP) Mission 4 Component 2 Investment Line 1.5: Strengthening of research structures and creation of R&D “innovation ecosystems”, set up of “territorial leaders in R&D”.
Institutional Review Board Statement
Not applicable.
Informed Consent Statement
Not applicable.
Data Availability Statement
Data will be made available on request.
Acknowledgments
We would like to thank the INSIST, MR CLEAN Registry, and MR CLEAN trial investigators for their contributions. A list of the investigators from all three consortia is presented in the Supplementary Material. We would like to thank Parametric Design s.r.l for its contribution to the CAD reconstruction within the PON REACT-EU project.
Conflicts of Interest
The authors declare the following financial interests/personal relationships which may be considered as potential competing interests: H.A.M. reports being a co-founder and shareholder of Nico.lab, a company that focuses on the use of artificial intelligence for medical image analysis. C.B.L.M.M. received funds from the European Commission (related to this project, paid to institution) and from CVON/Dutch Heart Foundation, Stryker, TWIN Foundation, Health Evaluation Program Netherlands (unrelated; all paid to institution). C.B.L.M.M. is a shareholder of Nico.lab, a company that focuses on the use of artificial intelligence for medical imaging analysis. H.A.M., N.A.T. and P.K. are co-founders and shareholders of inSteps B.V.
Appendix A
Figure A1 shows a comparison of the distributions of the 15 principal values describing the cerebrovascular anatomies in the training and generated datasets. As expected, the distributions are similar in the two datasets. The Mann–Whitney U-test was used to assess whether the principal values in the generated and training datasets could be described by distributions with equal medians. This was confirmed for all 15 principal values.
Figure A1.
Distributions of the first 15 principal values in the generated and training datasets.
The sampled principal values were used to generate the virtual patients, whose anatomy was analyzed to extract the geometric parameters included in the acceptance criterion. Table A1 reports, for each geometric parameter, the admissible range of values, and the median and interquartile range (IQR) both in the training and the generated datasets. It also reports the results of the Mann–Whitney U-test assessing whether the generated and training datasets can be described by distributions with equal medians. Figure A2 shows a comparison of the distributions of the geometric parameters in the two datasets.
Table A1.
Admissible ranges of values of the geometric parameters, assessed in the anatomies in the training dataset, and their median and interquartile range (IQR) both in the training and the generated datasets (including only the accepted anatomies). The last column reports the results of the Mann–Whitney U-test, indicating whether the hypothesis that the compared parameter sets originate from distributions with equal median is accepted (h = 0) or rejected (h = 1) with a 5% significance level (p-value).
Table A1.
Admissible ranges of values of the geometric parameters, assessed in the anatomies in the training dataset, and their median and interquartile range (IQR) both in the training and the generated datasets (including only the accepted anatomies). The last column reports the results of the Mann–Whitney U-test, indicating whether the hypothesis that the compared parameter sets originate from distributions with equal median is accepted (h = 0) or rejected (h = 1) with a 5% significance level (p-value).
| Parameter | Admissible Min–Max Range | Median (IQR) Training Dataset | Median (IQR) Generated Dataset | h (p-Value) |
|---|---|---|---|---|
| Dsup (mm) | 2.46–6.39 | 3.95 (0.95) | 3.98 (0.56) | 0 (0.696) |
| rsup (mm) | 2.08–17.84 | 7.68 (3.92) | 8.79 (2.42) | 1 (0.001) |
| tsup (-) | 0.016–0.527 | 0.105 (0.124) | 0.066 (0.026) | 1 (~10−5) |
| Dant (mm) | 2.93–6.98 | 4.98 (1.18) | 4.79 (0.50) | 0 (0.396) |
| rant (mm) | 1.95–8.07 | 3.36 (0.87) | 2.97 (0.79) | 1 (0.003) |
| tant (-) | 0.128–2.54 | 0.901 (0.662) | 0.848 (0.351) | 0 (0.310) |
| Dpos (mm) | 2.76–7.65 | 5.39 (1.21) | 5.33 (0.77) | 0 (0.744) |
| rpos (mm) | 1.75–14.84 | 4.25 (3.17) | 4.81 (2.99) | 0 (0.376) |
| tpos (-) | 0.015–1.827 | 0.185 (0.305) | 0.149 (0.173) | 0 (0.074) |
| Dinf (mm) | 3.46–7.11 | 5.00 (1.15) | 5.17 (0.64) | 0 (0.253) |
| DACA (mm) | 1.74–4.65 | 2.62 (0.65) | 2.64 (0.53) | 0 (0.189) |
| DM1 (mm) | 1.75–5.01 | 3.10 (0.76) | 3.15 (0.48) | 0 (0.273) |
| αICA-ACA (°) | 28.57–125.63 | 54.72 (17.67) | 47.55 (9.48) | 1 (~10−4) |
| αICA-M1 (°) | 47.48–167.10 | 125.68 (30.30) | 119.89 (26.94) | 1 (0.028) |
| αM1-ACA (°) | 49.52–170.56 | 144.37 (17.92) | 136.63 (20.02) | 1 (0.038) |
| DM2 (mm) | 1.60–3.57 | 2.25 (0.60) | 2.36 (0.38) | 0 (0.232) |
| αM1-M2a (°) | 15.72–129.80 | 65.53 (44.74) | 67.22 (42.35) | 0 (0.920) |
| αM1-M2b (°) | 5.93–135.96 | 65.60 (33.71) | 62.28 (30.56) | 0 (0.433) |
| αM2a-M2b (°) | 17.18–155.02 | 78.85 (44.94) | 67.42 (53.88) | 0 (0.186) |
Figure A2.
Distributions of the geometric parameters used for the acceptance criterion in the generated and training datasets.
Figure A2.
Distributions of the geometric parameters used for the acceptance criterion in the generated and training datasets.
References
- Viceconti, M.; Henney, A.; Morley-Fletcher, E. In Silico Clinical Trials: How Computer Simulation Will Transform the Biomedical Industry. Int. J. Clin. Trials 2016, 3, 37. [Google Scholar] [CrossRef]
- Radzik, B.R.; Puttgen, H.A.; Gottesman, R.F.; Aldrich, E.M. The Role of Interventional Radiology in Cerebrovascular Disease: A Review of Cerebrovascular Anatomy and Disease. J. Radiol. Nurs. 2007, 26, 39–43. [Google Scholar] [CrossRef]
- Phipps, M.S.; Cronin, C.A. Management of Acute Ischemic Stroke. BMJ 2020, 368, l6983. [Google Scholar] [CrossRef]
- Luraghi, G.; Bridio, S.; Rodriguez Matas, J.F.; Dubini, G.; Boodt, N.; Gijsen, F.J.H.; van der Lugt, A.; Fereidoonnezhad, B.; Moerman, K.M.; McGarry, P.; et al. The First Virtual Patient-Specific Thrombectomy Procedure. J. Biomech. 2021, 126, 110622. [Google Scholar] [CrossRef]
- Luraghi, G.; Bridio, S.; Lissoni, V.; Dubini, G.; Dwivedi, A.; McCarthy, R.; Fereidoonnezhad, B.; McGarry, P.; Gijsen, F.J.H.; Rodriguez Matas, J.F.; et al. Combined Stent-Retriever and Aspiration Intra-Arterial Thrombectomy Performance for Fragmentable Blood Clots: A Proof-of-Concept Computational Study. J. Mech. Behav. Biomed. Mater. 2022, 135, 105462. [Google Scholar] [CrossRef]
- Mousavi JS, S.M.; Faghihi, D.; Sommer, K.; Bhurwani, M.M.S.; Patel, T.R.; Santo, B.; Waqas, M.; Ionita, C.; Levy, E.I.; Siddiqui, A.H.; et al. Realistic Computer Modelling of Stent Retriever Thrombectomy: A Hybrid Finite-Element Analysis-Smoothed Particle Hydrodynamics Model. J. R. Soc. Interface 2021, 18, 20210583. [Google Scholar] [CrossRef]
- Liu, R.; Jin, C.; Wang, L.; Yang, Y.; Fan, Y.; Wang, W. Simulation of Stent Retriever Thrombectomy in Acute Ischemic Stroke by Finite Element Analysis. Comput. Methods Biomech. Biomed. Eng. 2021, 25, 740–749. [Google Scholar] [CrossRef]
- Miller, C.; Konduri, P.; Bridio, S.; Luraghi, G.; Arrarte Terreros, N.; Boodt, N.; Samuels, N.; Rodriguez Matas, J.F.; Migliavacca, F.; Lingsma, H.; et al. In Silico Thrombectomy Trials for Acute Ischemic Stroke. Comput. Methods Programs Biomed. 2023, 228, 107244. [Google Scholar] [CrossRef]
- Bridio, S.; Luraghi, G.; Rodriguez Matas, J.F.; Dubini, G.; Giassi, G.G.; Maggio, G.; Kawamoto, J.N.; Moerman, K.M.; McGarry, P.; Konduri, P.R.; et al. Impact of the Internal Carotid Artery Morphology on In Silico Stent-Retriever Thrombectomy Outcome. Front. Med. Technol. 2021, 3, 719909. [Google Scholar] [CrossRef]
- Zhu, L.; Liebeskind, D.S.; Jahan, R.; Starkman, S.; Salamon, N.; Duckwiler, G.; Vinuela, F.; Tateshima, S.; Gonzalez, N.; Villablanca, P.; et al. Thrombus Branching and Vessel Curvature Are Important Determinants of Middle Cerebral Artery Trunk Recanalization with Merci Thrombectomy Devices. Stroke 2012, 43, 787–792. [Google Scholar] [CrossRef]
- Schwaiger, B.J.; Gersing, A.S.; Zimmer, C.; Prothmann, S. The Curved MCA: Influence of Vessel Anatomy on Recanalization Results of Mechanical Thrombectomy after Acute Ischemic Stroke. AJNR Am. J. Neuroradiol. 2015, 36, 971–976. [Google Scholar] [CrossRef]
- Srivatsa, S.; Duan, Y.; Sheppard, J.P.; Pahwa, S.; Pace, J.; Zhou, X.; Bambakidis, N.C. Cerebral Vessel Anatomy as a Predictor of First-Pass Effect in Mechanical Thrombectomy for Emergent Large-Vessel Occlusion. J. Neurosurg. 2021, 134, 576–584. [Google Scholar] [CrossRef] [PubMed]
- Mousavi Janbeh Sarayi, S.M.; Santo, B.A.; Waqas, M.; Monterio, A.; Veeturi, S.S.; Jenkins, T.D.; Levy, E.I.; Siddiqui, A.H.; Tutino, V.M. Vascular Cross-Section, Rather Than Tortuosity, Can Classify First-Pass Outcome of Mechanical Thrombectomy for Ischemic Stroke. Stroke Vasc. Interv. Neurol. 2023, 3, e000646. [Google Scholar] [CrossRef]
- Dutra, B.G.; Tolhuisen, M.L.; Alves, H.C.B.R.; Treurniet, K.M.; Kappelhof, M.; Yoo, A.J.; Jansen, I.G.H.; Dippel, D.W.J.; Van Zwam, W.H.; Van Oostenbrugge, R.J.; et al. Thrombus Imaging Characteristics and Outcomes in Acute Ischemic Stroke Patients Undergoing Endovascular Treatment. Stroke 2019, 50, 2057–2064. [Google Scholar] [CrossRef]
- Luraghi, G.; Rodriguez Matas, J.F.; Dubini, G.; Berti, F.; Bridio, S.; Duffy, S.; Dwivedi, A.; McCarthy, R.; Fereidoonnezhad, B.; McGarry, P.; et al. Applicability Assessment of a Stent-Retriever Thrombectomy Finite-Element Model. Interface Focus 2021, 11, 20190123. [Google Scholar] [CrossRef]
- Józsa, T.I.; Padmos, R.M.; Samuels, N.; El-Bouri, W.K.; Hoekstra, A.G.; Payne, S.J. A Porous Circulation Model of the Human Brain for in Silico Clinical Trials in Ischaemic Stroke: A Human Brain Model for Ischaemic Stroke. Interface Focus 2021, 11, 20190127. [Google Scholar] [CrossRef]
- Niederer, S.A.; Aboelkassem, Y.; Cantwell, C.D.; Corrado, C.; Coveney, S.; Cherry, E.M.; Delhaas, T.; Fenton, F.H.; Panfilov, A.V.; Pathmanathan, P.; et al. Creation and Application of Virtual Patient Cohorts of Heart Models: Virtual Cohorts of Heart Models. Philos. Trans. R. Soc. A Math. Phys. Eng. Sci. 2020, 378. [Google Scholar] [CrossRef]
- Rodero, C.; Strocchi, M.; Marciniak, M.; Longobardi, S.; Whitaker, J.; O’Neill, M.D.; Gillette, K.; Augustin, C.; Plank, G.; Vigmond, E.J.; et al. Linking Statistical Shape Models and Simulated Function in the Healthy Adult Human Heart. PLoS Comput. Biol. 2021, 17, e1008851. [Google Scholar] [CrossRef]
- Romero, P.; Lozano, M.; Martínez-Gil, F.; Serra, D.; Sebastián, R.; Lamata, P.; García-Fernández, I. Clinically-Driven Virtual Patient Cohorts Generation: An Application to Aorta. Front. Physiol. 2021, 12, 713118. [Google Scholar] [CrossRef]
- Thamsen, B.; Yevtushenko, P.; Gundelwein, L.; Setio, A.A.A.; Lamecker, H.; Kelm, M.; Schafstedde, M.; Heimann, T.; Kuehne, T.; Goubergrits, L. Synthetic Database of Aortic Morphometry and Hemodynamics: Overcoming Medical Imaging Data Availability. IEEE Trans. Med. Imaging 2021, 40, 1438–1449. [Google Scholar] [CrossRef]
- Jansen, I.G.H.; Mulder, M.J.H.L.; Goldhoorn, R.J.B. Endovascular Treatment for Acute Ischaemic Stroke in Routine Clinical Practice: Prospective, Observational Cohort Study (MR CLEAN Registry). BMJ 2018, 360, k949. [Google Scholar] [CrossRef]
- Chen, L.; Mossa-Basha, M.; Balu, N.; Canton, G.; Sun, J.; Pimentel, K.; Hatsukami, T.S.; Hwang, J.N.; Yuan, C. Development of a Quantitative Intracranial Vascular Features Extraction Tool on 3D MRA Using Semiautomated Open-Curve Active Contour Vessel Tracing. Magn. Reson. Med. 2018, 79, 3229–3238. [Google Scholar] [CrossRef] [PubMed]
- Heimann, T.; Meinzer, H.P. Statistical Shape Models for 3D Medical Image Segmentation: A Review. Med. Image Anal. 2009, 13, 543–563. [Google Scholar] [CrossRef]
- Rai, A.T.; Hogg, J.P.; Cline, B.; Hobbs, G. Cerebrovascular Geometry in the Anterior Circulation: An Analysis of Diameter, Length and the Vessel Taper. J. Neurointerv. Surg. 2013, 5, 371–375. [Google Scholar] [CrossRef]
- Muller, H.R.; Brunh61zl, C.; Radii, E.W.; Buser, M. Neuro—Radiology Sex and Side Differences of Cerebral Arterial Caliber. Neuroradiology 1991, 33, 212–216. [Google Scholar] [CrossRef] [PubMed]
- Mokin, M.; Waqas, M.; Chin, F.; Rai, H.; Senko, J.; Sparks, A.; Ducharme, R.W.; Springer, M.; Borlongan, C.V.; Levy, E.I.; et al. Semi-Automated Measurement of Vascular Tortuosity and Its Implications for Mechanical Thrombectomy Performance. Neuroradiology 2021, 63, 381–389. [Google Scholar] [CrossRef]
- Koskinen, S.M.; Soinne, L.; Valanne, L.; Silvennoinen, H. The Normal Internal Carotid Artery: A Computed Tomography Angiographic Study. Neuroradiology 2014, 56, 723–729. [Google Scholar] [CrossRef]
- Luisi, C.A.; Amiri, A.; Büsen, M.; Sichermann, T.; Nikoubashman, O.; Wiesmann, M.; Steinseifer, U.; Müller, M.; Neidlin, M. Investigation of Cerebral Hemodynamics during Endovascular Aspiration: Development of an Experimental and Numerical Setup. Cardiovasc. Eng. Technol. 2023, 14, 393–403. [Google Scholar] [CrossRef] [PubMed]
- Cootes, T.; Taylor, C.; Cooper, D.; Graham, J. Active Shape Models—Their Training and Application. Comput. Vis. Image Underst. 1995, 61, 38–59. [Google Scholar] [CrossRef]
- Sophocleous, F.; Biffi, B.; Milano, E.G.; Bruse, J.; Caputo, M.; Rajakaruna, C.; Schievano, S.; Emanueli, C.; Bucciarelli-Ducci, C.; Biglino, G. Aortic Morphological Variability in Patients with Bicuspid Aortic Valve and Aortic Coarctation. Eur. J. Cardio-Thorac. Surg. 2019, 55, 704–713. [Google Scholar] [CrossRef]
- Cosentino, F.; Raffa, G.M.; Gentile, G.; Agnese, V.; Bellavia, D.; Pilato, M.; Pasta, S. Statistical Shape Analysis of Ascending Thoracic Aortic Aneurysm: Correlation between Shape and Biomechanical Descriptors. J. Pers. Med. 2020, 10, 28. [Google Scholar] [CrossRef] [PubMed]
Figure 1.
(A) Centerline of the main cerebrovascular vascular arteries: internal carotid artery (ICA), anterior cerebral artery (ACA), segments M1 and M2 of the middle cerebral artery; (B) division of the ICA in four bends for the extraction of geometric parameters; (C) radius of curvature of the fitting circle of each ICA bend; (D) example of calculation of the bend tortuosity (for the anterior bend).
Figure 1.
(A) Centerline of the main cerebrovascular vascular arteries: internal carotid artery (ICA), anterior cerebral artery (ACA), segments M1 and M2 of the middle cerebral artery; (B) division of the ICA in four bends for the extraction of geometric parameters; (C) radius of curvature of the fitting circle of each ICA bend; (D) example of calculation of the bend tortuosity (for the anterior bend).
Figure 2.
(A) Centerline and label recognized by the Python code (ICA in dark red, ACA in blue, M1 in red, M2 as ICA-M1 continuation in orange and the other M2 in green); (B) examples of first sections discretized with 20 points; (C) all the considered discretized sections (based on local curvature features to avoid self-penetration); (D) final 3D representation of the vessel.
Figure 2.
(A) Centerline and label recognized by the Python code (ICA in dark red, ACA in blue, M1 in red, M2 as ICA-M1 continuation in orange and the other M2 in green); (B) examples of first sections discretized with 20 points; (C) all the considered discretized sections (based on local curvature features to avoid self-penetration); (D) final 3D representation of the vessel.
Figure 3.
(A) Silicone phantom of the intracranial arteries with complete circle of Willis anatomy and inner 3D-printed lumen; (B) segmented domain in the VMTK software; (C) segmented STL geometry of the cerebrovascular phantom with the internal lumen wall in dark gray and the thickness in light gray.
Figure 3.
(A) Silicone phantom of the intracranial arteries with complete circle of Willis anatomy and inner 3D-printed lumen; (B) segmented domain in the VMTK software; (C) segmented STL geometry of the cerebrovascular phantom with the internal lumen wall in dark gray and the thickness in light gray.
Figure 4.
(A) PCA analysis of the cerebrovascular anatomies: 15 principal components represent 95% of the variance; (B) example of the three principal values and their normal fitting (red lines).
Figure 4.
(A) PCA analysis of the cerebrovascular anatomies: 15 principal components represent 95% of the variance; (B) example of the three principal values and their normal fitting (red lines).
Figure 5.
Examples of 3D reconstructed CAD geometries generated with the proposed methodology.
Figure 6.
Boxplots of the geometric parameters’ distributions in the training and generated datasets: (A) diameters; (B) bend curvature and tortuosity; (C) angles at the bifurcations. The red asterisks indicate distributions with different medians (Mann–Whitney U-test).
Figure 6.
Boxplots of the geometric parameters’ distributions in the training and generated datasets: (A) diameters; (B) bend curvature and tortuosity; (C) angles at the bifurcations. The red asterisks indicate distributions with different medians (Mann–Whitney U-test).
Figure 7.
(A) Segmented STL geometry of the phantom lumen (gray) superimposed on the reconstructed CAD geometry (red); (B) contour map of the absolute distance between STL and CAD geometry normalized with the local diameters plotted on the CAD geometry.
Figure 7.
(A) Segmented STL geometry of the phantom lumen (gray) superimposed on the reconstructed CAD geometry (red); (B) contour map of the absolute distance between STL and CAD geometry normalized with the local diameters plotted on the CAD geometry.
Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content. |
© 2023 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).
Share and Cite
MDPI and ACS Style
Bridio, S.; Luraghi, G.; Ramella, A.; Rodriguez Matas, J.F.; Dubini, G.; Luisi, C.A.; Neidlin, M.; Konduri, P.; Arrarte Terreros, N.; Marquering, H.A.; et al. Generation of a Virtual Cohort of Patients for in Silico Trials of Acute Ischemic Stroke Treatments. Appl. Sci. 2023, 13, 10074. https://doi.org/10.3390/app131810074
AMA Style
Bridio S, Luraghi G, Ramella A, Rodriguez Matas JF, Dubini G, Luisi CA, Neidlin M, Konduri P, Arrarte Terreros N, Marquering HA, et al. Generation of a Virtual Cohort of Patients for in Silico Trials of Acute Ischemic Stroke Treatments. Applied Sciences. 2023; 13(18):10074. https://doi.org/10.3390/app131810074
Chicago/Turabian StyleBridio, Sara, Giulia Luraghi, Anna Ramella, Jose Felix Rodriguez Matas, Gabriele Dubini, Claudio A. Luisi, Michael Neidlin, Praneeta Konduri, Nerea Arrarte Terreros, Henk A. Marquering, and et al. 2023. "Generation of a Virtual Cohort of Patients for in Silico Trials of Acute Ischemic Stroke Treatments" Applied Sciences 13, no. 18: 10074. https://doi.org/10.3390/app131810074
Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.
