Effects of Nebivolol Versus Carvedilol on Cardiopulmonary Function at High Altitude in Healthy Subjects.

Effects of Nebivolol Versus Carvedilol on Cardiopulmonary Function at High Altitude in Healthy Subjects.

Comparison of the Cardiovascular, Metabolic and Respiratory Effects of Nebivolol and Carvedilol at High Altitude in Healthy Subjects.

Exposure of healthy subjects to high altitude hypoxia elicits changes in cardiovascular, respiratory and metabolic features as weel as in exercise performance similar, for some aspects, to those observed in chronic heart failure. Exposure to high altitude hypoxia represents a suitable model to assess different treatments proposed for this pathological condition. Our aim was to evaluate the impact of two different third-generation beta-blockers used in heart failure (carvedilol and nebivolol) on cardiovascular, respiratory, metabolic profile and on exercise performance at high altitude.

Methods. Study Subjects. Adults, males and females, non smoking healthy volunteers, sea-level residents not engaged in regular endurance exercise training, taking no medications will be recruited. As there are no studies comparing the effects of beta-blockers on exercise performance at high altitude, the sample size set for each treatment arm was defined on the basis of the sample size of previous investigations showing significant changes in exercise performance in normal subjects taking no medications. Study design. Time 0. Screening, enrollement and randomization. Subjects meeting the inclusion/exclusion criteria will undergo at sea-level, general laboratory investigations and physical examination. Eligible subjects will be double blindly randomized to either placebo (one tablet twice daily), carvedilol (one 25 mg tablets twice daily), or to nebivolol (one 5 mg tablet in the morning and one placebo tablet in the evening). Time 1. Before starting the medications, at sea level after an overnight fast, subject will undergo: blood pressure and heart rate measurement, 24 hour ambulatory blood pressure monitoring, Doppler heart ultrasound, cardiopulmonary exercise test, resting energy expenditure measurement. Time 2. After three weeks of allocated treatment, at sea-level, after an overnight fast, subjects will undergo: blood pressure and heart rate measurement, 24 hour ambulatory blood pressure monitoring, Doppler heart ultrasound, cardiopulmonary exercise test, resting energy expenditure measurement. Time 3. Under treatment within the first two days of high altitude exposure (Regina Margherita hut, Monte Rosa, altitude 4559 m), subjects will undergo after an overnight fast to blood pressure and heart rate measurement, 24 hour ambulatory blood pressure monitoring, Doppler heart ultrasound, cardiopulmonary exercise test, resting energy expenditure measurement, acute mountain sickness quantification by the Lake Louise Score. Protocol for blood pressure and heart rate measurement. Blood pressure and heart rate were measured according to current European guidelines(Task Force for the Management of Arterial Hypertension of the European Society of Hypertension(ESH) and of the European Society of Cardiology (ESC). 2007 Guidelines for the Management of Arterial Hypertension. J Hypertens 2007; 25:1105-1187. Protocol for 24 hour ambulatory blood pressure monitoring. Ambulatory blood pressure monitoring was performed according to current European guidelines(O'Brien E, et al. Practice guidelines of the European Society of Hypertension for clinic, ambulatory and self blood pressure measurement. J Hypertens 2005; 23: 1697-701). Protocol for Doppler heart ultrasound. All echographic-Doppler examinations will be performed by the same two operators using a portable device (Vivid I, GE Ultrasound) according to current guidelines (Lang RM, et al. Recommendations for chamber quantification. Eur J Echocardiogr 2006; 7 : 79-108 Protocol for cardiopulmonary exercise test. Tests will be performed and evaluated according to current European Society of Cardiology guidelines (Eur J Cardiovasc Prev Rehabil 13:150-164 2006; Eur J Cardiovasc Prev Rehabil 2006; 13:300-311). All tests will be performed using the same cyclo-ergometer (Ergometrics 100, Ergoline, Bitz, Germany)and metabolic cart (Oxycon Mobile software v. 4.6, VIASYS Healthcare GmbH, Wurburg, Germany). The exercise protocol will include 10 minutes of monitored sitting rest, followed by 3 minutes of unloaded pedalling and by 30 W load increments every 2 minutes up to exhaustion. Breath-by-breath ventilation, respiratory gases, one-lead ECG and pulse oxymetry (SpO2) will be recorded throughout each test. Arterial blood pressure will be measured by a mercury sphygmomanometer in duplicate at the end of the resting phase and of each 30 W step, and at peak exercise. Cardiopulmonry exercise tests will be blindly and independently evaluated by two expert readers. The anaerobic threshold will be identified by the standard technique (Wasserman K. Breathing during exercise. N Engl J Med 1978; 298:780-785. VE/VCO2 slope will be calculated as the slope of the linear relationship between VE and VCO2 measured up to the respiratory compensation point. Protocol for resting energy expenditure measurement. The energy expenditure was calculated according to the abbreviated formula provided by Weir (Weir JB. New methods for calculating metabolic rate with special reference to protein metabolism. J Physiol Lond 1949; 55:14-21). O2 consumption and CO2 production (integrated over 1 min) were measured for 30 min. Baseline values were calculated by averaging the readings taken during the last 10 min. Protocol for assessment of acute mountain sickness. Acute mountain sickness (AMS) will be assessed by means of the Lake Louise AMS Scoring system (Roach RC, Bärtsch P et al. The Lake Louise AMS Scoring Consensus Committee. The Lake Louise acute mountain sickness scoring system. In: Sutton JR, Houtson CS, Coates G, eds. Hypoxia and Molecular Medicine. Burlington, VT: Queen City Printers; 1993:272-274). Statistical analysis. Data will be reported as means ± SD. Data management and analysis will be performed with SPSS version 13.0 (SPSS Inc, Chicago, IL, USA). Differences among groups, changes over time within each group (time effect), and any interaction (differing trends over time among groups), will be assessed by two-way repeated measures ANOVA with unpaired Student's t-test with Bonferroni correction whenever needed. For all parameters during cardiopulmonary exercise test, mean values will be computed over 20 seconds. Spearman correlations will be used to assess the relationship between peak VO2 and other respiratory and haemodynamic variables at altitude. A P level of < 0.05 was considered statistically significant.

hypoxia, autonomic nervous system, blood pressure, heart rate, exercise, heart failure, receptors, adrenergic, beta.

Time 1: sea level, baseline, no treatment. Time 2: sea level, after three weeks of allocated treatment. Time 3: within the first two days of high altitude exposure, under treatment.

Time 1: sea level, baseline, no treatment. Time 3: within the first two days of high altitude exposure, under treatment.

Minute ventilation at peak of exercise. Minute ventilation = tidal volume (ml) multiplied by the respiratory rate (breaths/min)

Time 1: sea level, baseline, no treatment. Time 2: sea level, after three weeks of allocated treatment. Time 3: within the first two days of high altitude exposure, under treatment.

Difference in peak exercise minute ventilation between Time 1 and Time 3 (Time 3 - Time 1. Minute ventilation = tidal volume (ml) multiplied by the respiratory rate (breaths/min).

Time 1: sea level, baseline, no treatment. Time 3: within the first two days of high altitude exposure, under treatment.

Time 1: sea level, baseline, no treatment. Time 2: sea level, after three weeks of allocated treatment. Time 3: within the first two days of high altitude exposure, under treatment.

Time 1: sea level, baseline, no treatment. Time 2: sea level, after three weeks of allocated treatment. Time 3: within the first two days of high altitude exposure, under treatment.

Time 1: sea level, baseline, no treatment. Time 2: sea level, after three weeks of allocated treatment. Time 3: within the first two days of high altitude exposure, under treatment.

Time 1: sea level, baseline, no treatment. Time 2: sea level, after three weeks of allocated treatment. Time 3: within the first two days of high altitude exposure, under treatment.

Time 1: sea level, baseline, no treatment. Time 2: sea level, after three weeks of allocated treatment. Time 3: within the first two days of high altitude exposure, under treatment.

Inclusion Criteria Men or women of any racial background healthy sealevel resident age >= 18 years, =< 65 years SBP< 130 mmHg and DBP< 80 mmHg, average of two measures at the sceening visit FG < 100 mg/dl (5.6 mmol/l) BMI < 25 written informed consent signed Exclusion Criteria engagement in regular exercise training smoking habit being enrolled in another research study any current or previous cardiovascular, metabolic disease or any other cronic disease any current treatment for any medical condition any medical condition preventing or contraindication exposure to altitude hypoxia any gastrointestinal disorder interfering with drug absorption known allergy or contraindications to beta-blockers pregnant or lactating women; women in reproductive age not using recognized contraceptive methods. malignancy within the last 5 years drug abuse or alcohol abuse within the last 5 years history of noncompliance to medical regimens incapacity or unwillingness to sign the informed consent participation in any investigational clinical trial within the last 3 months

Laboratorio Ricerche Cardiologiche. Istituto Auxologico Italiano. Ospedale S. Luca. Via Spagnoletto, 3. Regina Margherita Hut (Monte Rosa, Italian Alps, 4559 m)

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