Left ventricle geometry, atrial strain, ventricle strain, and hemodynamics across aortic valve before and after transcatheter aortic valve replacements.

Autor: Roslan A; Institut Jantung Negara, Department of Cardiology, Kuala Lumpur, Malaysia. elysess1@gmail.com., Tey YS; Institut Jantung Negara, Department of Cardiology, Kuala Lumpur, Malaysia., Ares F; Institut Jantung Negara, Department of Cardiology, Kuala Lumpur, Malaysia., Ashari A; Institut Jantung Negara, Department of Cardiology, Kuala Lumpur, Malaysia., Shaparudin A; Institut Jantung Negara, Department of Cardiology, Kuala Lumpur, Malaysia., Wan Rahimi WF; Institut Jantung Negara, Department of Cardiology, Kuala Lumpur, Malaysia., Koh HB; Institut Jantung Negara, Department of Cardiology, Kuala Lumpur, Malaysia., Lee TJ; Institut Jantung Negara, Department of Cardiology, Kuala Lumpur, Malaysia., Ahmad Tantawi JA; Institut Jantung Negara, Department of Cardiology, Kuala Lumpur, Malaysia., Kolanthaivelu J; Institut Jantung Negara, Department of Cardiology, Kuala Lumpur, Malaysia., Gurupparan K; Institut Jantung Negara, Department of Cardiology, Kuala Lumpur, Malaysia., Yahaya SA; Institut Jantung Negara, Department of Cardiology, Kuala Lumpur, Malaysia.
Jazyk: angličtina
Zdroj: The Medical journal of Malaysia [Med J Malaysia] 2022 Nov; Vol. 77 (6), pp. 736-743.
Abstrakt: Introduction: Transcatheter aortic valve replacements (TAVRs) has become widespread throughout the world. To date, there are no echocardiographic studies of TAVR patients from Southeast Asia (SEA). We sought to evaluate (1) changes in echocardiographic and strain values pre- and post-TAVR (2) relationship between aortic stenosis (AS) severity and strain values, (3) left ventricle geometry in severe AS, (4) relationship of flow rate to dimensionless index (DVI) and acceleration time (AT), and (5) effect of strains on the outcome.
Materials and Methods: Retrospective study of 112 TAVR patients in our centre from 2009 to 2020. The echocardiographic and strain images pre (within 1 month), post (day after), and 6 months post-TAVR were analyzed by expert echocardiographer.
Results: The ejection fraction (EF) increased at 6 months (53.02 ± 12.12% to 56.35 ± 9.00%) (p=0.044). Interventricular septal thickness in diastole (IVSd) decreased (1.27 ± 0.21 cm to 1.21 ± 0.23 cm) (p=0.038) and left ventricle internal dimension in diastole (LVIDd) decreased from 4.77 ± 0.64 cm to 4.49 ± 0.65 cm (p=0.001). No changes in stroke volume index (SVI pre vs 6 months p=0.187), but the flow rate increases (217.80 ± 57.61 mls/s to 251.94 ± 69.59 mls/s, p<0.001). Global longitudinal strain (GLS) improved from -11.44 ± 4.23% to -13.94 ± 3.72% (p<0.001), left atrial reservoir strain (Lar-S) increased from 17.44 ± 9.16% to 19.60 ± 8.77% (p=0.033). Eight patients (7.5%) had IVSd < 1.0 cm, and 4 patients (3.7%) had normal left ventricle (LV) geometry. There was linear relationship between IVSd and mean PG (r=0.208, p=0.031), between GLS to aortic valve area (AVA) and aortic valve area index (AVAi) (r = - 0.305, p=0.001 and r= - 0.316, p= 0.001). There was also relationship between AT (r=-0.20, p=0.04) and DVI (r=0.35, p<0.001) with flow rate. Patients who died late (after 6 months) had lower GLS at 6 months. (Alive; -13.94 ± 3.72% vs Died; -12.43 ± 4.19%, p=0.001).
Conclusion: At 6 months, TAVR cause reverse remodelling of the LV with the reduction in IVSd, LVIDd, and improvement in GLS and LAr-S. There is a linear relationship between GLS and AVA and between IVSd and AVA.
Databáze: MEDLINE