Cardiac Diastolic Maladaptation is Associated with the Severity of Exercise Intolerance in Sickle Cell Anemia Patients

Overview

Journal Sci Rep

Specialty Science

Date 2024 May 15

PMID 38750085

Authors

Thomas dHumieres

Antoine Bouvarel

Laurent Boyer

Laurent Savale

Henri Guillet

Lara Alassaad

Gonzalo De Luna

Enora Berti

Sihem Iles

Anne Laure Pham Hung dAlexandry dOrengiani

Etienne Audureau

Marie-Joelle Troupe

Reine-Claude Schlatter

Anais Lamadieu

Frederic Galacteros

Genevieve Derumeaux

Laurent A Messonnier

Pablo Bartolucci

Affiliations

Soon will be listed here.

Abstract

This pilot study focusing on Sickle Cell Anemia (SCA) patients offers a comprehensive and integrative evaluation of respiratory, cardiovascular, hemodynamic, and metabolic variables during exercise. Knowing that diastolic dysfunction is frequent in this population, we hypothesize that a lack of cardiac adaptation through exercise might lead to premature increase in blood lactate concentrations in SCA patients, a potential trigger for acute disease complication. SCA patients were prospectively included in PHYSIO-EXDRE study and underwent a comprehensive stress test with a standardized incremental exercise protocol up to 4 mmol L blood lactate concentration (BL4). Gas exchange, capillary lactate concentration and echocardiography were performed at baseline, during stress test (at ∼ 2 mmol L) and BL4. The population was divided into two groups and compared according to the median value of percentage of theoretical peak oxygen uptake (% ) at BL4. Twenty-nine patients were included (42 ± 12 years old, 48% of women). Most patients reached BL4 at low-intensity exercise [median value of predicted power output (W) was 37%], which corresponds to daily life activities. The median value of % at BL4 was 39%. Interestingly, diastolic maladaptation using echocardiography during stress test along with hemoglobin concentration were independently associated to early occurrence of BL4. As BL4 occurs for low-intensity exercises, SCA patients may be subject to acidosis-related complications even during their daily life activities. Beyond assessing physical capacities, our study underlines that diastolic maladaptation during exercise is associated with an early increase in blood lactate concentration.

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