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Your search keyword '"Lv Rui"' showing total 6 results
Start Over Author "Lv Rui" Topic vulnerable plaque
6 results on '"Lv Rui"'

3. Human Coronary Plaque Optical Coherence Tomography Image Repairing, Multilayer Segmentation and Impact on Plaque Stress/Strain Calculations.

Author

Huang, Mengde, Maehara, Akiko, Tang, Dalin, Zhu, Jian, Wang, Liang, Lv, Rui, Zhu, Yanwen, Zhang, Xiaoguo, Matsumura, Mitsuaki, Chen, Lijuan, Ma, Genshan, and Mintz, Gary S.

Subjects
INTRAVASCULAR ultrasonography, CORONARY arteries, INSTITUTIONAL review boards, OPTICAL coherence tomography, GEOMETRIC modeling
Abstract

Coronary vessel layer structure may have a considerable impact on plaque stress/strain calculations. Most current plaque models use single-layer vessel structures due to the lack of available multilayer segmentation techniques. In this paper, an automatic multilayer segmentation and repair method was developed to segment coronary optical coherence tomography (OCT) images to obtain multilayer vessel geometries for biomechanical model construction. Intravascular OCT data were acquired from six patients (one male; mean age: 70.0) using a protocol approved by the local institutional review board with informed consent obtained. A total of 436 OCT slices were selected in this study. Manually segmented data were used as the gold standard for method development and validation. The edge detection method and cubic spline surface fitting were applied to detect and repair the internal elastic membrane (IEM), external elastic membrane (EEM) and adventitia–periadventitia interface (ADV). The mean errors of automatic contours compared to manually segmented contours were 1.40%, 4.34% and 6.97%, respectively. The single-layer mean plaque stress value from lumen was 117.91 kPa, 10.79% lower than that from three-layer models (132.33 kPa). On the adventitia, the single-layer mean plaque stress value was 50.46 kPa, 156.28% higher than that from three-layer models (19.74 kPa). The proposed segmentation technique may have wide applications in vulnerable plaque research. [ABSTRACT FROM AUTHOR]

Published
2022
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4. Image-based biomechanical modeling for coronary atherosclerotic plaque progression and vulnerability prediction.

Author

Lv, Rui, Wang, Liang, Maehara, Akiko, Guo, Xiaoya, Zheng, Jie, Samady, Habib, Giddens, Don P., Mintz, Gary S., Stone, Gregg W., and Tang, Dalin

Subjects
*ATHEROSCLEROTIC plaque, *MYOCARDIAL infarction, *CARDIOVASCULAR development, *PREDICTION models
Abstract

Atherosclerotic plaque progression and rupture play an important role in cardiovascular disease development and the final drastic events such as heart attack and stroke. Medical imaging and image-based computational modeling methods advanced considerably in recent years to quantify plaque morphology and biomechanical conditions and gain a better understanding of plaque evolution and rupture process. This article first briefly reviewed clinical imaging techniques for coronary thin-cap fibroatheroma (TCFA) plaques used in image-based computational modeling. This was followed by a summary of different types of biomechanical models for coronary plaques. Plaque progression and vulnerability prediction studies based on image-based computational modeling were reviewed and compared. Much progress has been made and a reasonable high prediction accuracy has been achieved. However, there are still some inconsistencies in existing literature on the impact of biomechanical and morphological factors on future plaque behavior, and it is very difficult to perform direct comparison analysis as differences like image modality, biomechanical factors selection, predictive models, and progression/vulnerability measures exist among these studies. Encouraging data and model sharing across the research community would partially resolve these differences, and possibly lead to clearer assertive conclusions. In vivo image-based computational modeling could be used as a powerful tool for quantitative assessment of coronary plaque vulnerability for potential clinical applications. • Review current progress in effectively predicting future coronary plaque behavior • Predictive framework that combines medical imaging and biomechanical modeling • Vast differences in image data, methods exist across published studies. [ABSTRACT FROM AUTHOR]

Published
2022
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5. Quantifying Patient-Specific in vivo Coronary Plaque Material Properties for Accurate Stress/Strain Calculations: An IVUS-Based Multi-Patient Study.

Author

Wang, Liang, Zhu, Jian, Maehara, Akiko, Lv, Rui, Qu, Yangyang, Zhang, Xiaoguo, Guo, Xiaoya, Billiar, Kristen L., Chen, Lijuan, Ma, Genshan, Mintz, Gary S., and Tang, Dalin

Subjects
MECHANICAL properties of condensed matter, INTRAVASCULAR ultrasonography, YOUNG'S modulus, ATHEROSCLEROTIC plaque
Abstract

Introduction: Mechanical forces are closely associated with plaque progression and rupture. Precise quantifications of biomechanical conditions using in vivo image-based computational models depend heavily on the accurate estimation of patient-specific plaque mechanical properties. Currently, mechanical experiments are commonly performed on ex vivo cardiovascular tissues to determine plaque material properties. Patient-specific in vivo coronary material properties are scarce in the existing literature. Methods: In vivo Cine intravascular ultrasound and virtual histology intravascular ultrasound (IVUS) slices were acquired at 20 plaque sites from 13 patients. A three-dimensional thin-slice structure-only model was constructed for each slice to obtain patient-specific in vivo material parameter values following an iterative scheme. Effective Young's modulus (YM) was calculated to indicate plaque stiffness for easy comparison purposes. IVUS-based 3D thin-slice models using in vivo and ex vivo material properties were constructed to investigate their impacts on plaque wall stress/strain (PWS/PWSn) calculations. Results: The average YM values in the axial and circumferential directions for the 20 plaque slices were 599.5 and 1,042.8 kPa, respectively, 36.1% lower than those from published ex vivo data. The YM values in the circumferential direction of the softest and stiffest plaques were 103.4 and 2,317.3 kPa, respectively. The relative difference of mean PWSn on lumen using the in vivo and ex vivo material properties could be as high as 431%, while the relative difference of mean PWS was much lower, about 3.07% on average. Conclusion: There is a large inter-patient and intra-patient variability in the in vivo plaque material properties. In vivo material properties have a great impact on plaque stress/strain calculations. In vivo plaque material properties have a greater impact on strain calculations. Large-scale-patient studies are needed to further verify our findings. [ABSTRACT FROM AUTHOR]

Published
2021
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6. Quantification of patient-specific coronary material properties and their correlations with plaque morphological characteristics: An in vivo IVUS study.

Author

Wang, Liang, Maehara, Akiko, Zhang, Xiaoguo, Lv, Rui, Qu, Yangyang, Guo, Xiaoya, Zhu, Jian, Wu, Zheyang, Billiar, Kristen L., Zheng, Jie, Chen, Lijuan, Ma, Genshan, Mintz, Gary S., and Tang, Dalin

Subjects
*YOUNG'S modulus, *IN vivo studies, *CORONARY artery disease, *BONFERRONI correction, *KRUSKAL-Wallis Test
Abstract

A method using in vivo Cine IVUS and VH-IVUS data has been proposed to quantify material properties of coronary plaques. However, correlations between plaque morphological characteristics and mechanical properties have not been studied in vivo. Method: In vivo Cine IVUS and VH-IVUS data were acquired at 32 plaque cross-sections from 19 patients. Six morphological factors were extracted for each plaque. These samples were categorized into healthy vessel, fibrous plaque, lipid-rich plaque and calcified plaque for comparisons. Three-dimensional thin-slice models were constructed using VH-IVUS data to quantify in vivo plaque material properties following a finite element updating approach by matching Cine IVUS data. Effective Young's moduli were calculated to represent plaque stiffness for easy comparison. Spearman's rank correlation analysis was performed to identify correlations between plaque stiffness and morphological factor. Kruskal-Wallis test with Bonferroni correction was used to determine whether significant differences in plaque stiffness exist among four plaque groups. Our results show that lumen circumference change has a significantly negative correlation with plaque stiffness (r = −0.7807, p = 0.0001). Plaque burden and calcification percent also had significant positive correlations with plaque stiffness (r = 0.5105, p < 0.0272 and r = 0.5312, p < 0.0193) respectively. Among the four categorized groups, calcified plaques had highest stiffness while healthy segments had the lowest. There is a close link between plaque morphological characteristics and mechanical properties in vivo. Plaque stiffness tends to be higher as coronary atherosclerosis advances, indicating the potential to assess plaque mechanical properties in vivo based on plaque compositions. • Strong correlations between coronary plaque morphological characteristics and mechanical properties were found in vivo. • Several morphological factors had the potential to assess in vivo plaque stiffness due to their significant correlations. • Plaque components had a great influence on the plaque stiffness. Among four plaque groups, calcified plaque had highest stiffness while healthy vessel had the lowest. And fibrous and lipid-rich plaques had intermediate plaque stiffness. [ABSTRACT FROM AUTHOR]

Published
2023
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