Blood fluidity is related to the ability to oxidize lipids at exercise
Issue title: Selected proceedings of the 12th European Conference on Clinical Hemorheology, 22‐26 June 2003, Sofia, Bulgaria
Article type: Research Article
Authors: Brun, Jean‐Frédéric; | Varlet‐Marie, Emmanuelle | Cassan, Delphine | Manetta, Jérôme | Mercier, Jacques
Affiliations: Service Central de Physiologie Clinique, Centre d'Exploration et de Réadaptation des Anomalies du Métabolisme Musculaire (CERAMM), CHU Lapeyronie, Montpellier, France | Laboratoire de Pharmacocinétique Clinique, Faculté de Pharmacie, Université Montpellier I, France
Note: [] Corresponding author: Dr J.F. Brun, MD, PhD, Service Central de Physiologie Clinique, Centre d'Exploration et de Réadaptation des Anomalies du Métabolisme Musculaire (CERAMM), CHU Lapeyronie, 34295 Montpellier‐cédex 5, France. Tel.: +33 04 67 33 82 84; Fax: +33 04 67 33 89 86; Telex: CHR MONTP 480 766 F; E‐mail: drjfbrun@dixinet.com.
Abstract: We previously reported in rugbywomen correlations between RBC deformability and the ability to oxidize at exercise more lipids. This surprising finding might of course be spurious, or reflect the importance of the balance of substrates at exercise on baseline parameters that regulate blood rheology. Actually, the capacity of skeletal muscle to utilize either lipid or carbohydrate as fuels strongly influences whole body metabolism both at rest and during exercise. While the healthy skeletal muscle has substantial metabolic flexibility and is able to switch from predominantly lipid o oxidation during fasting or endurance exercise to increased glucose oxidation in conditions of insulin stimulation, obese individuals and those with type 2 diabetes manifest higher lipid oxidation during insulin‐stimulated conditions despite lower rates of lipid oxidation during fasting or prolonged exercise. A low ability to oxidize and to periodically deplete triglyceride in muscle is associated with raised blood lipids. In addition, high carbohydrate oxidation rates in the mitochondrion are likely to promote more free radical generation. An increase in either blood lipids or free radicals is likely to induce profound hemorheological effects. We present here hemorheological studies in various populations with the use of exercise calorimetry in order to assess this switch of substrates. These studies further evidence negative correlations between the ability to oxidize lipids at exercise and parameters of blood viscosity. Correlations found between RBC deformability and the ability to oxidize at exercise more lipids may be due to effects of endurance training on lipid oxidation which may in turn modify both lipid metabolism and free radical generation, thus influencing RBC rheology.
Keywords: Blood viscosity, hemorheology, erythrocyte deformability, erythrocyte aggregability, substrate oxidation, mitochon‐ drion, crossover concept
Journal: Clinical Hemorheology and Microcirculation, vol. 30, no. 3-4, pp. 339-343, 2004