Body composition and maximal exercise capacity after heart transplantation

Julien Regamey; Pierre Monney; Patrick Yerly; Lucie Favre; Matthias Kirsch; Piergiorgio Tozzi; Olivier Lamy; Roger Hullin

doi:10.1002/ehf2.13642

Body composition and maximal exercise capacity after heart transplantation

ESC Heart Fail. 2022 Feb;9(1):122-132. doi: 10.1002/ehf2.13642. Epub 2021 Dec 2.

Authors

Julien Regamey¹, Pierre Monney¹, Patrick Yerly¹, Lucie Favre², Matthias Kirsch³, Piergiorgio Tozzi³, Olivier Lamy⁴, Roger Hullin¹

Affiliations

¹ Service de Cardiologie, Département Coeur-Vaisseaux, Lausanne University Hospital (CHUV) and University of Lausanne (UNIL), Lausanne, Switzerland.
² Service d'Endocrinologie, Diabétologie et Métabolisme, Département de Médecine, Lausanne University Hospital (CHUV) and University of Lausanne (UNIL), Lausanne, Switzerland.
³ Service de Chirurgie Cardiaque, Département Cœur-Vaisseaux, Lausanne University Hospital (CHUV) and University of Lausanne (UNIL), Lausanne, Switzerland.
⁴ Centre des Maladies osseuses, Département de l'Appareil Locomoteur, Lausanne University Hospital (CHUV) and University of Lausanne (UNIL), Lausanne, Switzerland.

Abstract

Aims: Maximal exercise capacity as measured by peak oxygen consumption (pVO₂ ) in cardiopulmonary exercise testing (CPET) of heart transplant recipients (HTR) is limited to a 50-70% level of healthy age-matched controls. This study investigated the relationship between body composition and pVO₂ during the first decade post-transplant.

Methods and results: Body composition was determined by dual-energy X-ray absorptiometry (DXA) and pVO₂ by CPET in 48 HTR (n = 38 males; mean age 51 ± 12 years). A total of 95 assessments were acquired 1-9 years post-transplant, and the results of four consecutive periods were compared [Period 1: 1-2 years (n = 25); 2: 3-4 years (n = 23); 3: 5-6 years (n = 23); 4: 7-9 years (n = 24)]. Linear regression analysis analysed the correlation between pVO₂ and pairs of appendicular lean mass (ALM) and fat mass (FM). The relation between ALM and daily dose of calcineurin inhibitor (CNI) was explored using partial correlation controlling for age, gender, and height. pVO₂ increased from 0.98 (0.34) to 1.35 (0.35) L/min (P < 0.01) between Periods 1 and 4 corresponding to 54.5-63.3% of predicted value. Peak heart rate (HR) raised from 115 ± 19 to 131 ± 23 b.p.m. (P = 0.05), and anaerobic threshold (AT = VO₂ achieved at AT) increased from 0.57 (0.18) to 0.83 (0.35) L/min (P < 0.01) between Periods 1 and 3. Median FM normalized to height² (FMI) always remained elevated (>8.8 kg/m² ). ALM normalized to body mass index increased from 0.690 (0.188) to 0.848 (0.204) m² (P = 0.02) between Periods 1 and 4, explaining 45% of the variance of pVO₂ (R² = 0.455; P < 0.001). Eighty-one per cent of the variance of pVO₂ (R² = 0.817; P < 0.001) in multiple regression was explained by AT (β = 0.488), ALM (β = 0.396), peak HR (β = 0.366), and FMI (β = -0.181). ALM was negatively correlated with daily CNI dose (partial R = -0.258; P = 0.01).

Conclusions: After heart transplantation, the beneficial effect of peripheral skeletal muscle gain on pVO₂ is opposed by increased FM. Our findings support lifestyle efforts to fight adiposity and CNI dose reduction in the chronic stable phase to favour positive adaptation of peripheral muscle mass.

Keywords: Body composition; Heart transplant; Maximal exercise capacity; Peak oxygen consumption.

MeSH terms

Absorptiometry, Photon
Adult
Body Composition
Exercise Test
Exercise Tolerance*
Heart Transplantation*
Humans
Male
Middle Aged