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Aims  Consensus‐derived guidelines recommend renal stenting for patients with atherosclerotic renal artery disease (ARAD) and heart failure (HF). The aim of this prospective multi‐centre observational study was to verify our hypothesis that changes in E/e′, an echocardiographic correlate of left ventricular (LV) filling pressure, following renal stenting may differ between ARAD patients with and without HF.    Methods and results  This study enrolled  de novo  ARAD patients undergoing renal stenting at 14 institutions. The primary endpoint was the difference in E/e′ change between ARAD patients with and without HF. Clinical and echocardiographic data were prospectively collected at baseline, the day following renal stenting, and 1 month and 6 months afterwards. ARAD patients with HF were defined as patients with New York Heart Association (NYHA) Class 2 and more, or a history of HF hospitalization. A total of 76 patients were included, and 39% were ARAD patients with HF. ARAD patients with HF had significantly lower estimated glomerular filtration rate ( P  = 0.028) and higher NYHA functional class ( P  < 0.001) and Minnesota Living with Heart Failure Questionnaire (MLHFQ) score ( P  = 0.001) than ARAD patients without HF. Also, ARAD patients with HF had significantly lower LV ejection fraction ( P  = 0.003) and e′‐velocity ( P  = 0.003) and higher E/e′ ratio ( P  = 0.001), left atrial volume index (LAVI) ( P  = 0.046), LV end‐diastolic volume (LVEDV) ( P  = 0.001), LV end‐systolic volume (LVESV) ( P  = 0.001), and LV mass index ( P  = 0.009) than ARAD patients without HF. All procedures were successful. In contrast to blood pressure and renal function, there was a significant interaction in E/e′ ( P  interaction  < 0.001) between time and HF, and ARAD patients with HF showed a significant ( P  < 0.001) decrease in E/e′ albeit those without HF. By the same token, there was a significant interaction in NYHA class ( P  interaction  < 0.001), MLHFQ score ( P  interaction  = 0.018), E‐velocity ( P  interaction  = 0.002), LAVI ( P  interaction  = 0.001), LVEDV ( P  interaction  = 0.003), and LVESV ( P  interaction  = 0.001) between time and HF with a significant improvement in all these variables in ARAD patients with HF (NYHA class,  P  = 0.001; MLHFQ score,  P  = 0.002; E‐velocity,  P  = 0.005; LAVI,  P  = 0.001; LVEDV,  P  = 0.017; and LVESV,  P  = 0.011).    Conclusions  Change in LV filling pressure after renal stenting differed between ARAD patients with and without HF, with a significant improvement in LV filling pressure in patients with HF‐ARAD. These unique findings might support clinical cardiac benefits of renal stenting in ARAD patients with HF.

Cardiac function response to stenting in atherosclerotic renal artery disease with and without heart failure: results from the Carmel study