Artificial Intelligence in Transcatheter Aortic Valve Replacement: Its Current Role and Ongoing Challenges
Abstract
:1. Introduction
- Making a diagnosis of severe aortic stenosis
- Patient selection
- Procedural planning and execution
- Predicting post-procedural morbidity and mortality
2. Diagnosis of Severe Aortic Stenosis
3. Patient Selection
4. Pre-Procedural Planning
5. Predicting Mortality Risk
6. Predicting Specific Outcomes
Reference | Study Cases | Comparison | Outcome | ML Model | Main Results |
---|---|---|---|---|---|
Diagnosing severe AS | |||||
Kwon [5] | 39,371 EKGs. 6453 for internal validation and 10 865 for external validation | none | More than moderate. AS confirmed by echocardiography. | DNN + CNN | AUC 0.884 (95% CI, 0.880–0.887) and 0.861 (95% CI, 0.858–0.863) for internal and external validation, respectively |
Chang [9] | 589 CTs (412 training, 40 validation and 137 testing) | Manually measured AV calcium volume and Agatston score | Accurate grading of AS severity | modified 3D U-net CNN | Agatston score accuracy of grading = 92.9%. AUC = 0.933 (95% CI 0.885–0.981), outperformed radiologist readers. |
Patient selection | |||||
Hasimbegovic [13] | 532 patients from VICTORY Registry | Heart team decision | SAVR versus TAVR | ML-based 3-layer model | AUC 0.91 (90% accuracy, 92% sensitivity and 90% specificity) |
Pre-procedural planning | |||||
Santaló-Corcoy [20] | 200 CTs (35 for training, and 17 for testing) | Manual CT measurement by an expert cardiologist using 3Mensio. | Correlation between manual and automated measurements | DL algorithms (MeshDeformNet) for landmark detection followed by segmentation | mean absolute relative error was within 5% for most measurements, except for coronary height (11.6% and 16.5%). |
Theriault-Lauzier [21] | 94 CTs of severe AS (K-fold cross-validation with K=) | Manually segmented AV annulus | Correlation between manual and automated measurements | recursive multiresolution CNN for localization of the AV annulus centroid | average out-of-plane localization error of 0.9 ± 0.8 mm for the evaluation dataset. The proposed algorithm is on par with automated methods for localization and approaches in providing an expert-level accuracy. |
Samin [22] | 60 CTs (24 retrospectively, 36 prospectively) | fluoroscopy | accurate prediction (<5° difference) of LP | Not detailed | Automated 3D analysis of CTs accurately predicted the LP aortic annulus and the corresponding C-arm position required in 8/8, 16/17, and 10/11 in patients with mild, moderate, or severe calcifications. |
Predicting mortality risk | |||||
Abdul Ghaffar [37] | 354 TAVR cases divided into 2 cohorts | STS score | In-hospital and 30-day CV and all-cause mortality | TDA and a cloud-based supervised AutoML platform (OptiML) | The patient similarity network identified five patient phenogroups with substantial variations in clinical comorbidities and in-hospital and 30-day outcomes. Group 5 was associated with higher rates of 30-day CV mortality (OR 18, 95% CI 3–94), and 30-day all-cause mortality (OR 3, 95% CI 1.2–9). |
Gomes [38] | Retrospective study of 451 TAVR cases | STS score | In-hospital and 30-day all-cause mortality; Secondary outcomes; Stroke, vascular complications; Paravalvular leak; and PPI | neural networks, support vector machines, and RF | performance of all MLmodels in predicting all-cause intrahospital mortality (AUC 0.94–0.97) was significantly higher than both the STS score (AUC 0.64), the STS/ACC TAVR score (AUC 0.65). Secondary outcomes could not be accurately predicted. |
Agasthi [39] | 1055 TAVR cases | TAVI2-SCORE and CoreValve score. | One-year mortality | GTB | AUC for GTB vs. TAVI2-SCORE and CoreValve Score was 0.72 (95% CI 0.68–0.78) vs. 0.56 (95%CI 0.51–0.62) and 0.53 (95% CI 0.47–0.59) |
Hernandez-Suarez [40] | NIS database (2012–2015). (development: 7615, validation: 3268). | none | In-hospital mortality | Logistic regression, artificial NN, naive Bayes, and random forest | The prediction models showed good AUC performance AUC (>0.80). The best model was obtained by logistic regression (area under the curve: 0.92; 95% confidence interval: 0.89 to 0.95). Most obtained models plateaued after 10 variables were introduced. |
Predicting specific complications | |||||
Judson [41] | 9360 cases from the BIOME dataset (2017–2021) | standard multivariate model | short length of stay (<36 h) and long length of stay (≥72 h) | RF | The predictive power, of both the short LOS (AUC 0.82) and long LOS (AUC 0.85) ML model, was more robust than the standard multivariate model (SLOS AUC 0.65, LLOS AUC 0.65). |
Khan [42] | 92,363 cases from National Readmission Database (2015–2018; 70% training, 20% validation, 10% testing) | none | 30-day readmission for heart failure | “AutoScore” package, a ML-based automatic clinical score generator | AUC of TAVR-HF Score was 0.761 (95% CI 0.744–0.778) |
Okuno [46] | 2279 TAVR patients from Swiss TAVR registry (2/3 training, 1/3 test) | none | 30-day Cerebrovascular events | ANN | The constructed model uses less than 107 clinical and imaging variables, and has AUC of 0.79 (0.65–0.93). |
Truong [49] | 557 cases-single center (75% training, 25% test) | logistic regression | Permanent pacemaker implantation (PPI) | RF | The RF model performed better than logistic regression model in predicting PPI risk (AUC: 0.81 vs. 0.69). |
Navarese [51] | 5185 cases from RISPEVA, validated in 5043 cases from the prospective POL-TAVI | PARIS and HAS-BLED scores | Major and minor bleeding within 30 days and 1 year | ML and univariate analyses were used for variable selection | The Optimism bootstrap-corrected AUC was 0.79 (95% CI: 0.75–0.83). Compared with PARIS and HAS-BLED, PREDICT-TAVR showed superior net benefit and improved predictive performance for all bleeding risk thresholds >2.5% |
Jia [52] | 668 cases-single center | Traditional Cox-PH and RF | Major or life-threatening bleeding | CNN | The BLeNet model outperformed the Cox-PH and RSF models [optimism-corrected c-index of BLeNet vs. Cox-PH vs. RSF: 0.81 (95% CI: 0.79–0.92) vs. 0.72 (95% CI: 0.63–0.77) vs. 0.70 (95% CI: 0.61–0.74)] |
Lopes [58] | 1478 cases-single center (70% training, 30% testing) | traditional logistic regression | One year mortality and improvement in dyspnea | SVM, RFC, MLP, and GTB | The RF classifier achieved the highest AUC (0.70) for predicting mortality. Logistic regression had the highest AUC (0.56) in predicting the improvement of dyspnea. |
7. Limitations, Challenges and Future Directions
Funding
Conflicts of Interest
References
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Benjamin, M.M.; Rabbat, M.G. Artificial Intelligence in Transcatheter Aortic Valve Replacement: Its Current Role and Ongoing Challenges. Diagnostics 2024, 14, 261. https://doi.org/10.3390/diagnostics14030261
Benjamin MM, Rabbat MG. Artificial Intelligence in Transcatheter Aortic Valve Replacement: Its Current Role and Ongoing Challenges. Diagnostics. 2024; 14(3):261. https://doi.org/10.3390/diagnostics14030261
Chicago/Turabian StyleBenjamin, Mina M., and Mark G. Rabbat. 2024. "Artificial Intelligence in Transcatheter Aortic Valve Replacement: Its Current Role and Ongoing Challenges" Diagnostics 14, no. 3: 261. https://doi.org/10.3390/diagnostics14030261
APA StyleBenjamin, M. M., & Rabbat, M. G. (2024). Artificial Intelligence in Transcatheter Aortic Valve Replacement: Its Current Role and Ongoing Challenges. Diagnostics, 14(3), 261. https://doi.org/10.3390/diagnostics14030261