Sickle Cell Trait and Exercise, Effect of Hot Environment (TDex)

Introduction

The sickle cell disease is an inherited disorder characterized by abnormal hemoglobin called hemoglobin S or sickle hemoglobin in red blood cells of subjects. The homozygous form (hemoglobin SS) causes sickle cell anemia and is the most severe kind of sickle cell disease. Hemoglobin SC disease and hemoglobin Sβ thalassemia are two other common forms of sickle cell disease. The sickle cell trait carriers are person who inherited the hemoglobin S from one parent and a normal hemoglobin A from the other (heterozygous AS). These people are generally healthy. However, more and more cases of serious complications have been reported, especially during efforts and stays at high altitude like hemorheological and microcirculatory disturbances, and rhabdomyolysis. Increased percentage of red cell sicking was observed in sickle cell trait (AS) carriers compared to normal individual after 45 min of walking at 33°C of temperature. AS individuals also showed an impairment in red blood deformability at rest, at the end, and 24 hours after maximal exercise as compared to normal individuals AA, showing the vulnerability of red blood cells of these seemingly healthy subjects. The stiffness of red blood cells along with blood viscosity also increased in AS group compared to AA group, as consequence the risk of vascular accidents increases. In athletes and military warfighters, an exercise collapse and sudden death associated with sickle cell trait has been observed. Several cases of sudden death in AS individuals have been reported by many authors during exercise, however the exact causes remain very poorly understood.

As constraints related to exercise in tropical climate, it was observed a reduction of power and volemia due to dehydration, diversion of blood volume to the cutaneous territories. It was also reported an impairment of carbohydrate metabolism.

Our objectives in this work are:

• To characterize the microvascular response to exercise in a hot environment in sickle cell trait active young adults,
• To highlight biological mechanisms underlying any microvascular response specificities of the sickle cell trait carriers,
• To describe the vascular consequences of postprandial metabolic disturbances induced by exercise in hot environment,
• To understand fasting and post-prandial glucose metabolism at rest, during and after exercise,
• To test the recovery in a neutral thermal environment (22 °C) as a means of normalizing post-exercise vascular function.

Experimental protocol

Thirty male volunteers (15 healthy: AA and 15 sickle cell trait carriers: AS) non-smoking, aged 18-30 years, BMI between 19 and 25kg/m2 living in the Caribbean for at least 6 months will be enrolled in the study. All subjects will be in good health physically active (≥ 3h/week) with no history of heat stroke during exercise. They are not taking any medications and are not regularly consume alcohol.

Participants will be subjected to four experimental sessions:

1. A familiarization session at fasting in a warm environment (33 °C) in which resting parameters like reactive hyperemia index, tympanic temperature, heart rate, cerebral and muscular oxygenation, pulse wave velocity and electrocardiogram (ECG) will be measured. Then a test of the intensity of exercise (VO2max) will be performed followed by a medical interview.

   The other 3 sessions will be performed early in the morning at fasting with 45 minutes of exercise on ergocycle. The exercise includes 15 minutes of warm up, then participants will be asked to pedal as fast as possible for 6 seconds. The test of 6 seconds will be repeated twice or more with recovery each time. During exercise, hydration will be controlled (2.5 ml water / kg every 15 minutes), oxygen consumption will be measured; and microvascular function and blood samples taken at different times of experiment in each session (T0, T60, T75, T90, T120). The design of this study is a crossover trial divided into 3 sessions presented in randomized order:

2. Exercise performed in hot environment (33 °C) with recovery in the same environment.

3. Exercise and recovery performed in a control (thermoneutral) environment (22 °C)

4. Exercise performed in a hot environment (33 °C) with recovery in a thermoneutral environment (22 °C).

At the end of each session, a standardized meal will be given to each participant.

This study will be conducted in accordance with the guidelines developed in the Declaration of Helsinki, and all procedures were approved by the Committee for the Protection of Persons East-III. Written informed consent will be obtained from all participants.

Biochemical procedures

Blood samples will be use for hemorheological tests (viscosity of blood, stiffness, aggregability and sickling of red cells etc.) Dosage of creatine kinase (CK-MM, MB), myoglobin and troponin will be performed to assess the degree of rhabdomyolysis and the integrity of heart.

Glycemia and lactatemia will be determined using strips. Cortisol, insulin, adrenalin, glucagon and lactate dehydrogenase (LDH) assays will be performed using appropriated kits.

Plasma inflammatory profile will be determined by measuring markers such as myeloperoxidase (MPO), malondialdehyde (MDA), advanced oxidation protein products (AOPP), nitrotyrosin, and endothelin-1 using appropriated kits.

Adhesion molecules such as VCAM-1, ICAM-1 and P-selectin will be measured using ELISA kit from Diaclone or Eurobio.

The oxidative stress on red blood cells will be assessed by measuring glutathione ratio GSSH/GSSG, superoxide dismutase (SOD), catalase, and glutathione peroxidase (GPx).

Statistical analysis Data will be expressed as means with their standard errors. Statistical analyses will be performed with SPSS for MAC and p < 0·05 considered statistically significant.

All the data will be analysed by using repeated-measures ANOVA followed by Post hoc comparisons with the Student's paired t test. The tests of Kolmogorov-Smirnov, Newman Keuls and Duncan will be applied as appropriate.

Expected outcomes

• Better understanding of physio-pathological mechanisms leading to severe vascular events following physical exercise in tropical climate in healthy sickle cell carriers.
• Opening of tracks for identification of physical activity programs and nutritional interventions adapted to sickle cell patients in hot environment.
• Understanding of mechanisms leading to disturbances of glucose metabolism under tropical climate in AA and in AS subjects.