An integrative machine learning model for predicting early safety uutcomes in patients undergoing transcatheter aortic valve implantation /

Yerassyl Kurmanaliyev; Kristina Šutienė; Rima Braukylienė; Ali Aldujeli; Martynas Jurenas; Rugile Kregzdyte; Laurynas Braukyla; Rassul Zhumagaliyev; Serik Aitaliyev; Nurlan Zhanabayev; Rauan Botabayeva; Yerlan Orazymbetov; Ramunas Unikas

doi:10.3390/medicina61030374

Title	An integrative machine learning model for predicting early safety uutcomes in patients undergoing transcatheter aortic valve implantation /
Authors	Kurmanaliyev, Yerassyl ; Šutienė, Kristina ; Braukylienė, Rima ; Aldujeli, Ali ; Jurenas, Martynas ; Kregzdyte, Rugile ; Braukyla, Laurynas ; Zhumagaliyev, Rassul ; Aitaliyev, Serik ; Zhanabayev, Nurlan ; Botabayeva, Rauan ; Orazymbetov, Yerlan ; Unikas, Ramunas
DOI	10.3390/medicina61030374
Full Text
Is Part of	Medicina.. Basel : MDPI. 2025, vol. 61, iss. 3, art. no. 374, p. 1-14.. ISSN 1010-660X. eISSN 1648-9144
Keywords [eng]	aortic stenosis ; transcatheter aortic valve implantation ; early safety outcomes ; ADASYN ; random forest ; SHAP
Abstract [eng]	Background: Early safety outcomes following transcatheter aortic valve implantation (TAVI) for severe aortic stenosis are critical for patient prognosis. Accurate prediction of adverse events can enhance patient management and improve outcomes. Aim: This study aimed to develop a machine learning model to predict early safety outcomes in patients with severe aortic stenosis undergoing TAVI. Methods: We conducted a retrospective single-centre study involving 224 patients with severe aortic stenosis who underwent TAVI. Seventy-seven clinical and biochemical variables were collected for analysis. To handle unbalanced classification problems, an adaptive synthetic (ADASYN) sampling approach was used. A fined-tuned random forest (RF) machine learning model was developed to predict early safety outcomes, defined as all-cause mortality, stroke, life-threatening bleeding, acute kidney injury (stage 2 or 3), coronary artery obstruction requiring intervention, major vascular complications, and valve-related dysfunction requiring repeat procedures. Shapley Additive Explanations (SHAPs) were used to explain the output of the machine learning model by attributing each variable’s contribution to the final prediction of early safety outcomes. Results: The random forest model identified left femoral artery diameter and aortic valve calcification volume as the most influential predictors of early safety outcomes. SHAPs analysis demonstrated that smaller left femoral artery diameter and higher aortic valve calcification volume were associated with poorer early safety prognoses. Conclusions: The machine learning model highlights of early safety outcomes after TAVI. These findings suggest that incorporating these variables into pre-procedural assessments may improve risk stratification and inform clinical decision-making to enhance patient care.
Published	Basel : MDPI
Type	Journal article
Language	English
Publication date	2025
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„An integrative machine learning model for predicting early safety uutcomes in patients undergoing transcatheter aortic valve implantation /“