Your search keyword '"Kim, Justin N."' showing total 22 results

1. Deep learning segmentation of fibrous cap in intravascular optical coherence tomography images

Author

Lee, Juhwan, Kim, Justin N., Dallan, Luis A. P., Zimin, Vladislav N., Hoori, Ammar, Hassani, Neda S., Makhlouf, Mohamed H. E., Guagliumi, Giulio, Bezerra, Hiram G., and Wilson, David L.

Subjects

Electrical Engineering and Systems Science - Image and Video Processing

Abstract

Thin-cap fibroatheroma (TCFA) is a prominent risk factor for plaque rupture. Intravascular optical coherence tomography (IVOCT) enables identification of fibrous cap (FC), measurement of FC thicknesses, and assessment of plaque vulnerability. We developed a fully-automated deep learning method for FC segmentation. This study included 32,531 images across 227 pullbacks from two registries. Images were semi-automatically labeled using our OCTOPUS with expert editing using established guidelines. We employed preprocessing including guidewire shadow detection, lumen segmentation, pixel-shifting, and Gaussian filtering on raw IVOCT (r,theta) images. Data were augmented in a natural way by changing theta in spiral acquisitions and by changing intensity and noise values. We used a modified SegResNet and comparison networks to segment FCs. We employed transfer learning from our existing much larger, fully-labeled calcification IVOCT dataset to reduce deep-learning training. Overall, our method consistently delivered better FC segmentation results (Dice: 0.837+/-0.012) than other deep-learning methods. Transfer learning reduced training time by 84% and reduced the need for more training samples. Our method showed a high level of generalizability, evidenced by highly-consistent segmentations across five-fold cross-validation (sensitivity: 85.0+/-0.3%, Dice: 0.846+/-0.011) and the held-out test (sensitivity: 84.9%, Dice: 0.816) sets. In addition, we found excellent agreement of FC thickness with ground truth (2.95+/-20.73 um), giving clinically insignificant bias. There was excellent reproducibility in pre- and post-stenting pullbacks (average FC angle: 200.9+/-128.0 deg / 202.0+/-121.1 deg). Our method will be useful for multiple research purposes and potentially for planning stent deployments that avoid placing a stent edge over an FC., Comment: 24 pages, 9 figures, 2 tables, 2 supplementary figures, 3 supplementary tables

Published

2023

2. Automated segmentation of microvessels in intravascular OCT images using deep learning

Author

Lee, Juhwan, Kim, Justin N., Gomez-Perez, Lia, Gharaibeh, Yazan, Motairek, Issam, Pereira, Ga-briel T. R., Zimin, Vladislav N., Dallan, Luis A. P., Hoori, Ammar, Al-Kindi, Sadeer, Guagliumi, Giulio, Bezerra, Hiram G., and Wilson, David L.

Subjects

Electrical Engineering and Systems Science - Image and Video Processing, Computer Science - Computer Vision and Pattern Recognition, Computer Science - Machine Learning

Abstract

To analyze this characteristic of vulnerability, we developed an automated deep learning method for detecting microvessels in intravascular optical coherence tomography (IVOCT) images. A total of 8,403 IVOCT image frames from 85 lesions and 37 normal segments were analyzed. Manual annotation was done using a dedicated software (OCTOPUS) previously developed by our group. Data augmentation in the polar (r,{\theta}) domain was applied to raw IVOCT images to ensure that microvessels appear at all possible angles. Pre-processing methods included guidewire/shadow detection, lumen segmentation, pixel shifting, and noise reduction. DeepLab v3+ was used to segment microvessel candidates. A bounding box on each candidate was classified as either microvessel or non-microvessel using a shallow convolutional neural network. For better classification, we used data augmentation (i.e., angle rotation) on bounding boxes with a microvessel during network training. Data augmentation and pre-processing steps improved microvessel segmentation performance significantly, yielding a method with Dice of 0.71+/-0.10 and pixel-wise sensitivity/specificity of 87.7+/-6.6%/99.8+/-0.1%. The network for classifying microvessels from candidates performed exceptionally well, with sensitivity of 99.5+/-0.3%, specificity of 98.8+/-1.0%, and accuracy of 99.1+/-0.5%. The classification step eliminated the majority of residual false positives, and the Dice coefficient increased from 0.71 to 0.73. In addition, our method produced 698 image frames with microvessels present, compared to 730 from manual analysis, representing a 4.4% difference. When compared to the manual method, the automated method improved microvessel continuity, implying improved segmentation performance. The method will be useful for research purposes as well as potential future treatment planning., Comment: 21 pages, 9 figures, 3 tables

Published

2022

3. Prediction of stent under-expansion in calcified coronary arteries using machine-learning on intravascular optical coherence tomography

Author

Gharaibeh, Yazan, Lee, Juhwan, Zimin, Vladislav N., Kolluru, Chaitanya, Dallan, Luis A. P., Pereira, Gabriel T. R., Vergara-Martel, Armando, Kim, Justin N., Hoori, Ammar, Dong, Pengfei, Gamage, Peshala T., Gu, Linxia, Bezerra, Hiram G., Al-Kindi, Sadeer, and Wilson, David L.

Subjects

Electrical Engineering and Systems Science - Image and Video Processing, Computer Science - Computer Vision and Pattern Recognition, Computer Science - Machine Learning

Abstract

BACKGROUND Careful evaluation of the risk of stent under-expansions before the intervention will aid treatment planning, including the application of a pre-stent plaque modification strategy. OBJECTIVES It remains challenging to achieve a proper stent expansion in the presence of severely calcified coronary lesions. Building on our work in deep learning segmentation, we created an automated machine learning approach that uses lesion attributes to predict stent under-expansion from pre-stent images, suggesting the need for plaque modification. METHODS Pre- and post-stent intravascular optical coherence tomography image data were obtained from 110 coronary lesions. Lumen and calcifications in pre-stent images were segmented using deep learning, and numerous features per lesion were extracted. We analyzed stent expansion along the lesion, enabling frame, segmental, and whole-lesion analyses. We trained regression models to predict the poststent lumen area and then to compute the stent expansion index (SEI). Stents with an SEI < or >/= 80% were classified as "under-expanded" and "well-expanded," respectively. RESULTS Best performance (root-mean-square-error = 0.04+/-0.02 mm2, r = 0.94+/-0.04, p < 0.0001) was achieved when we used features from both the lumen and calcification to train a Gaussian regression model for a segmental analysis over a segment length of 31 frames. Under-expansion classification results (AUC=0.85+/-0.02) were significantly improved over other approaches. CONCLUSIONS We used calcifications and lumen features to identify lesions at risk of stent under-expansion. Results suggest that the use of pre-stent images can inform physicians of the need to apply plaque modification approaches., Comment: 25 pages, 7 figures, 1 table, 6 supplemental figures, 3 supplemental tables

Published

2022

4. OCTOPUS -- optical coherence tomography plaque and stent analysis software

Author

Lee, Juhwan, Kim, Justin N., Gharaibeh, Yazan, Zimin, Vladislav N., Dallan, Luis A. P., Pereira, Gabriel T. R., Vergara-Martel, Armando, Kolluru, Chaitanya, Hoori, Ammar, Bezerra, Hiram G., and Wilson, David L.

Subjects

Electrical Engineering and Systems Science - Image and Video Processing, Computer Science - Computer Vision and Pattern Recognition, Computer Science - Machine Learning

Abstract

Compared with other imaging modalities, intravascular optical coherence tomography (IVOCT) has significant advantages for guiding percutaneous coronary interventions. To aid IVOCT research studies, we developed the Optical Coherence TOmography PlaqUe and Stent (OCTOPUS) analysis software. To automate image analysis results, the software includes several important algorithmic steps: pre-processing, deep learning plaque segmentation, machine learning identification of stent struts, and registration of pullbacks. Interactive visualization and manual editing of segmentations were included in the software. Quantifications include stent deployment characteristics (e.g., stent strut malapposition), strut level analysis, calcium angle, and calcium thickness measurements. Interactive visualizations include (x,y) anatomical, en face, and longitudinal views with optional overlays. Underlying plaque segmentation algorithm yielded excellent pixel-wise results (86.2% sensitivity and 0.781 F1 score). Using OCTOPUS on 34 new pullbacks, we determined that following automated segmentation, only 13% and 23% of frames needed any manual touch up for detailed lumen and calcification labeling, respectively. Only up to 3.8% of plaque pixels were modified, leading to an average editing time of only 7.5 seconds/frame, an approximately 80% reduction compared to manual analysis. Regarding stent analysis, sensitivity and precision were both greater than 90%, and each strut was successfully classified as either covered or uncovered with high sensitivity (94%) and specificity (90%). We introduced and evaluated the clinical application of a highly automated software package, OCTOPUS, for quantitative plaque and stent analysis in IVOCT images. The software is currently used as an offline tool for research purposes; however, the software's embedded algorithms may also be useful for real-time treatment planning., Comment: 16 pages, 8 figures

Published

2022

5. Automated analysis of fibrous cap in intravascular optical coherence tomography images of coronary arteries

Author

Lee, Juhwan, Pereira, Gabriel T. R., Gharaibeh, Yazan, Kolluru, Chaitanya, Zimin, Vladislav N., Dallan, Luis A. P., Kim, Justin N., Hoori, Ammar, Al-Kindi, Sadeer G., Guagliumi, Giulio, Bezerra, Hiram G., and Wilson, David L.

Subjects

Computer Science - Machine Learning, Computer Science - Computer Vision and Pattern Recognition

Abstract

Thin-cap fibroatheroma (TCFA) and plaque rupture have been recognized as the most frequent risk factor for thrombosis and acute coronary syndrome. Intravascular optical coherence tomography (IVOCT) can identify TCFA and assess cap thickness, which provides an opportunity to assess plaque vulnerability. We developed an automated method that can detect lipidous plaque and assess fibrous cap thickness in IVOCT images. This study analyzed a total of 4,360 IVOCT image frames of 77 lesions among 41 patients. To improve segmentation performance, preprocessing included lumen segmentation, pixel-shifting, and noise filtering on the raw polar (r, theta) IVOCT images. We used the DeepLab-v3 plus deep learning model to classify lipidous plaque pixels. After lipid detection, we automatically detected the outer border of the fibrous cap using a special dynamic programming algorithm and assessed the cap thickness. Our method provided excellent discriminability of lipid plaque with a sensitivity of 85.8% and A-line Dice coefficient of 0.837. By comparing lipid angle measurements between two analysts following editing of our automated software, we found good agreement by Bland-Altman analysis (difference 6.7+/-17 degree; mean 196 degree). Our method accurately detected the fibrous cap from the detected lipid plaque. Automated analysis required a significant modification for only 5.5% frames. Furthermore, our method showed a good agreement of fibrous cap thickness between two analysts with Bland-Altman analysis (4.2+/-14.6 micron; mean 175 micron), indicating little bias between users and good reproducibility of the measurement. We developed a fully automated method for fibrous cap quantification in IVOCT images, resulting in good agreement with determinations by analysts. The method has great potential to enable highly automated, repeatable, and comprehensive evaluations of TCFAs., Comment: 18 pages, 9 figures

Published

2022

6. Prediction of stent under-expansion in calcified coronary arteries using machine learning on intravascular optical coherence tomography images

Author

Gharaibeh, Yazan, Lee, Juhwan, Zimin, Vladislav N., Kolluru, Chaitanya, Dallan, Luis A. P., Pereira, Gabriel T. R., Vergara-Martel, Armando, Kim, Justin N., Hoori, Ammar, Dong, Pengfei, Gamage, Peshala T., Gu, Linxia, Bezerra, Hiram G., Al-Kindi, Sadeer, and Wilson, David L.

Published

2023

7. OCTOPUS – Optical coherence tomography plaque and stent analysis software

Author

Lee, Juhwan, Kim, Justin N., Gharaibeh, Yazan, Zimin, Vladislav N., Dallan, Luis A.P., Pereira, Gabriel T.R., Vergara-Martel, Armando, Kolluru, Chaitanya, Hoori, Ammar, Bezerra, Hiram G., and Wilson, David L.

Published

2023

8. Data-efficient segmentation of coronary arteries for pericoronary adipose tissue analysis on coronary CT angiography using self-supervised learning

Author

Kim, Justin N., primary, Lee, Juhwan, additional, Song, Yingnan, additional, Subramaniam, Ananya, additional, Wu, Hao, additional, Joseph, Naomi M., additional, Makhlouf, Mohamed H. E., additional, Shafiabadi, Neda, additional, Al-Kindi, Sadeer, additional, and Wilson, David L., additional

Published

2024

9. Plaque Characteristics Derived from Intravascular Optical Coherence Tomography That Predict Cardiovascular Death.

Author

Lee, Juhwan, Gharaibeh, Yazan, Zimin, Vladislav N., Kim, Justin N., Hassani, Neda S., Dallan, Luis A. P., Pereira, Gabriel T. R., Makhlouf, Mohamed H. E., Hoori, Ammar, and Wilson, David L.

Subjects

INTRAVASCULAR ultrasonography, CARDIOVASCULAR disease related mortality, OPTICAL coherence tomography, PERCUTANEOUS coronary intervention, SURFACE area, MULTIVARIATE analysis, LOGISTIC regression analysis

Abstract

This study aimed to investigate whether plaque characteristics derived from intravascular optical coherence tomography (IVOCT) could predict a long-term cardiovascular (CV) death. This study was a single-center, retrospective study on 104 patients who had undergone IVOCT-guided percutaneous coronary intervention. Plaque characterization was performed using Optical Coherence TOmography PlaqUe and Stent (OCTOPUS) software developed by our group. A total of 31 plaque features, including lesion length, lumen, calcium, fibrous cap (FC), and vulnerable plaque features (e.g., microchannel), were computed from the baseline IVOCT images. The discriminatory power for predicting CV death was determined using univariate/multivariate logistic regressions. Of 104 patients, CV death was identified in 24 patients (23.1%). Univariate logistic regression revealed that lesion length, calcium angle, calcium thickness, FC angle, FC area, and FC surface area were significantly associated with CV death (p < 0.05). In the multivariate logistic analysis, only the FC surface area (OR 2.38, CI 0.98–5.83, p < 0.05) was identified as a significant determinant for CV death, highlighting the importance of the 3D lesion analysis. The AUC of FC surface area for predicting CV death was 0.851 (95% CI 0.800–0.927, p < 0.05). Patients with CV death had distinct plaque characteristics (i.e., large FC surface area) in IVOCT. Studies such as this one might someday lead to recommendations for pharmaceutical and interventional approaches. [ABSTRACT FROM AUTHOR]

Published

2024

10. Data-efficient segmentation of coronary arteries for pericoronary adipose tissue analysis on coronary CT angiography using self-supervised learning

Author

Gimi, Barjor S., Krol, Andrzej, Kim, Justin N., Lee, Juhwan, Subramaniam, Ananya, Song, Yingnan, Wu, Hao, Makhlouf, Mohamed H. E., Shafiabadi, Neda, Al-Kindi, Sadeer, and Wilson, David

Published

2024

11. Pericoronary Adipose Tissue Radiomics from Coronary Computed Tomography Angiography Identifies Vulnerable Plaques

Author

Kim, Justin N., primary, Gomez-Perez, Lia, additional, Zimin, Vladislav N., additional, Makhlouf, Mohamed H. E., additional, Al-Kindi, Sadeer, additional, Wilson, David L., additional, and Lee, Juhwan, additional

Published

2023

12. Pericoronary adipose tissue radiomics from coronary CT angiography identifies vulnerable plaques characteristics in intravascular OCT

Author

Kim, Justin N., primary, Gomez-Perez, Lia, additional, Zimin, Vladislav N., additional, Makhlouf, Mohamed H. E., additional, Al-Kindi, Sadeer, additional, Wilson, David L., additional, and Lee, Juhwan, additional

Published

2023

13. Neoatherosclerosis prediction using plaque markers in intravascular optical coherence tomography images

Author

Lee, Juhwan, primary, Pereira, Gabriel T. R., additional, Motairek, Issam, additional, Kim, Justin N., additional, Zimin, Vladislav N., additional, Dallan, Luis A. P., additional, Hoori, Ammar, additional, Al-Kindi, Sadeer, additional, Guagliumi, Giulio, additional, and Wilson, David L., additional

Published

2022

14. Automated analysis of fibrous cap in intravascular optical coherence tomography images of coronary arteries

Author

Lee, Juhwan, primary, Pereira, Gabriel T. R., additional, Gharaibeh, Yazan, additional, Kolluru, Chaitanya, additional, Zimin, Vladislav N., additional, Dallan, Luis A. P., additional, Kim, Justin N., additional, Hoori, Ammar, additional, Al-Kindi, Sadeer G., additional, Guagliumi, Giulio, additional, Bezerra, Hiram G., additional, and Wilson, David L., additional

Published

2022

15. Automated Segmentation of Microvessels in Intravascular OCT Images Using Deep Learning

Author

Lee, Juhwan, primary, Kim, Justin N., additional, Gomez-Perez, Lia, additional, Gharaibeh, Yazan, additional, Motairek, Issam, additional, Pereira, Gabriel T. R., additional, Zimin, Vladislav N., additional, Dallan, Luis A. P., additional, Hoori, Ammar, additional, Al-Kindi, Sadeer, additional, Guagliumi, Giulio, additional, Bezerra, Hiram G., additional, and Wilson, David L., additional

Published

2022

16. Prediction of stent under-expansion in calcified coronary arteries using machine learning on intervascular optical coherence tomography images

Author

Gharaibeh, Yazan, primary, Lee, Juhwan, additional, Zimin, Vladislav N., additional, Kolluru, Chaitanya, additional, Dallan, Luis A. P., additional, Pereira, Gabriel T. R., additional, Vergara-Martel, Armando, additional, Kim, Justin N., additional, Hoori, Ammar, additional, Dong, Pengfei, additional, Gamage, Peshala T., additional, Gu, Linxia, additional, Bezerra, Hiram G., additional, Al-Kindi, Sadeer, additional, and Wilson, David L., additional

Published

2022

17. Assessment of Post-Dilatation Strategies for Optimal Stent Expansion in Calcified Coronary Lesions: Ex Vivo Analysis With Optical Coherence Tomography

Author

Dallan, Luis A.P., primary, Zimin, Vladislav N., additional, Lee, Juhwan, additional, Gharaibeh, Yazan, additional, Kim, Justin N., additional, Pereira, Gabriel T.R., additional, Vergara-Martel, Armando, additional, Dong, Pengfei, additional, Gu, Linxia, additional, Wilson, David L., additional, and Bezerra, Hiram G., additional

Published

2022

18. Automatic microchannel detection using deep learning in intravascular optical coherence tomography images

Author

Lee, Juhwan, primary, Kim, Justin N., additional, Pereira, Gabriel T. R., additional, Gharaibeh, Yazan, additional, Kolluru, Chaitanya, additional, Zimin, Vladislav N., additional, Dallan, Luis A. P., additional, Motairek, Issam K., additional, Hoori, Ammar, additional, Guagliumi, Giulio, additional, Bezerra, Hiram G., additional, and Wilson, David L., additional

Published

2022

19. Automatic microchannel detection using deep learning in intravascular optical coherence tomography images

Author

Linte, Cristian A., Siewerdsen, Jeffrey H., Lee, Juhwan, Kim, Justin N., Pereira, Gabriel T. R., Gharaibeh, Yazan, Kolluru, Chaitanya, Zimin, Vladislav N., Dallan, Luis A. P., Motairek, Issam K., Hoori, Ammar, Guagliumi, Giulio, Bezerra, Hiram G., and Wilson, David L.

Published

2022

20. Automatic microchannel detection using deep learning in intravascular optical coherence tomography images.

Author

Lee, Juhwan, Kim, Justin N., Pereira, Gabriel T. R., Gharaibeh, Yazan, Kolluru, Chaitanya, Zimin, Vladislav N., Dallan, Luis A. P., Motairek, Issam K., Hoori, Ammar, Guagliumi, Giulio, Bezerra, Hiram G., and Wilson, David L.

Published

2022

21. Deep learning segmentation of fibrous cap in intravascular optical coherence tomography images.

Author

Lee J, Kim JN, Dallan LAP, Zimin VN, Hoori A, Hassani NS, Makhlouf MHE, Guagliumi G, Bezerra HG, and Wilson DL

Subjects

Humans, Tomography, Optical Coherence methods, Reproducibility of Results, Coronary Vessels pathology, Fibrosis, Deep Learning, Plaque, Atherosclerotic diagnostic imaging, Plaque, Atherosclerotic pathology

Abstract

Thin-cap fibroatheroma (TCFA) is a prominent risk factor for plaque rupture. Intravascular optical coherence tomography (IVOCT) enables identification of fibrous cap (FC), measurement of FC thicknesses, and assessment of plaque vulnerability. We developed a fully-automated deep learning method for FC segmentation. This study included 32,531 images across 227 pullbacks from two registries (TRANSFORM-OCT and UHCMC). Images were semi-automatically labeled using our OCTOPUS with expert editing using established guidelines. We employed preprocessing including guidewire shadow detection, lumen segmentation, pixel-shifting, and Gaussian filtering on raw IVOCT (r,θ) images. Data were augmented in a natural way by changing θ in spiral acquisitions and by changing intensity and noise values. We used a modified SegResNet and comparison networks to segment FCs. We employed transfer learning from our existing much larger, fully-labeled calcification IVOCT dataset to reduce deep-learning training. Postprocessing with a morphological operation enhanced segmentation performance. Overall, our method consistently delivered better FC segmentation results (Dice: 0.837 ± 0.012) than other deep-learning methods. Transfer learning reduced training time by 84% and reduced the need for more training samples. Our method showed a high level of generalizability, evidenced by highly-consistent segmentations across five-fold cross-validation (sensitivity: 85.0 ± 0.3%, Dice: 0.846 ± 0.011) and the held-out test (sensitivity: 84.9%, Dice: 0.816) sets. In addition, we found excellent agreement of FC thickness with ground truth (2.95 ± 20.73 µm), giving clinically insignificant bias. There was excellent reproducibility in pre- and post-stenting pullbacks (average FC angle: 200.9 ± 128.0°/202.0 ± 121.1°). Our fully automated, deep-learning FC segmentation method demonstrated excellent performance, generalizability, and reproducibility on multi-center datasets. It will be useful for multiple research purposes and potentially for planning stent deployments that avoid placing a stent edge over an FC., (© 2024. The Author(s).)

Published

2024

22. Pericoronary adipose tissue radiomics from coronary CT angiography identifies vulnerable plaques characteristics in intravascular OCT.

Author

Kim JN, Gomez-Perez L, Zimin VN, Makhlouf MHE, Al-Kindi S, Wilson DL, and Lee J

Abstract

Pericoronary adipose tissue (PCAT) features on CT have been shown to reflect local inflammation, and signals increased cardiovascular risk. Our goal was to determine if PCAT radiomics extracted from coronary CT angiography (CCTA) images are associated with intravascular optical coherence tomography (IVOCT)-identified vulnerable plaque characteristics (e.g., microchannels [MC] and thin-cap fibroatheroma [TCFA]). CCTA and IVOCT images of 30 lesions from 25 patients were registered. Vessels with vulnerable plaques were identified from the registered IVOCT images. PCAT radiomics features were extracted from CCTA images for the lesion region of interest (PCAT-LOI) and the entire vessel (PCAT-Vessel). We extracted 1356 radiomics features, including intensity (first-order), shape, and texture features. Features were reduced using standard approaches (e.g., high feature correlation). Using stratified three-fold cross-validation with 1000 repeats, we determined the ability of PCAT radiomics features from CCTA to predict IVOCT vulnerable plaque characteristics. In identification of TCFA lesions, PCAT-LOI and PCAT-Vessel radiomics models performed comparably (AUC±standard deviation 0.78±0.13, 0.77±0.14). For identification of MC lesions, PCAT-Vessel radiomics model (0.89±0.09) was moderately better associated than that of PCAT-LOI model (0.83±0.12). Both PCAT-LOI and PCAT-Vessel radiomics models also similarly identified coronary vessels thought to be highly vulnerable (i.e., both TCFA and MC) (0.88±0.10, 0.91±0.09). Favorable radiomics features tended to be those describing texture and size of PCAT. PCAT radiomics can identify coronary vessels with TCFA or MC, consistent with IVOCT. CCTA radiomics may improve risk stratification by noninvasively detecting vulnerable plaque characteristics that are only visible with IVOCT.

Published

2023