The main purpose of this project is to analyze the effect of set configuration of resistance exercise on cardiovascular responses and adaptations of postmenopausal women. Additionally, since previous studies have shown that individual´s blood pressure level can influence on the impact of resistance training programs on cardiovascular changes, we aim to contrast acute and chronic changes to resistance training programs in normotensive and hypertensive postmenopausal women.
Menopause causes hormonal changes that affect to acute and chronic physiological responses to exercise of postmenopausal women. In this regard, studies about the cardiovascular responses to resistance training in women are scarce, being particularly relevant to identify those load parameters that modulate these adaptations. Previous studies have identified that set configuration of muscular exercise influence on cardiovascular stress, albeit these results have been mainly obtained in healthy young male subjects. The project is divided into two studies. The first one is devoted to contrast the acute effect of three resistance training sessions with the same volume, intensity, length a work-to-rest ratio, but differing in set configuration. Thus, a sample of 60 postmenopausal women (30 normotensive and 30 hypotensive) will be recruited in local sport facilities in order to carry out in a randomized order three experimental sessions and a control session. Before and after each session hemodynamic (systolic, diastolic and mean blood pressure), cardiac performance (heart rate, cardiac output, stroke volume among others), cardiac and vascular autonomic modulation (hear rate and blood pressure variability), baroreflex effectiveness (baroreflex sensitivity), neuromuscular fatigue, arterial stiffness and metabolic (lactate concentrations) responses and resting energy expenditure (oxygen consumption) will be evaluated. This first analysis will allow us to identify the two set configurations with the highest and the lowest cardiovascular stress respectively, being these exercise structures used in the second study, in which the effect of 12 weeks resistance training programs differing in set configuration will be contrasted. To do this, a sample of 40 postmenopausal women will be randomly assigned to a control group and to two resistance training programs (higher and lower set configuration respectively) which be carried out throughout 12 weeks with a frequency of 2 session per week. Training loads will be readjusted every four weeks. Before and after the training programs and after a 4 weeks follow-up period the following components will be evaluated: body composition by bioimpedance, muscular thickness by echography, neuromuscular performance (isokinetic torque-velocity and power-velocity relationship), resting metabolic rate by indirect calorimetry, foot bone mineral density, beat-to-beat blood pressure by photoplethysmography, cardiac performance by impedance cardiography , cardiac autonomic modulation by heart rate variability analysis, baroreflex sensitivity analysis, sympathetic vasomotor tone (blood pressure variability) and arterial stiffness. This project will provide useful information for optimizing the resistance exercise prescription for postmenopausal women by identifying exercise structures that potentially allow to preserve physiological adaptations and at the same time to blunt the acute cardiovascular stress.
Resistance training protocol with the lowest cardiovascular stress identified in the first study of the project. It can be expected to be a short set configuration protocol
Resistance training protocol with the highest cardiovascular stress identified in the first study of the project. It can be expected to be a short set configuration protocol
Faculty of Sport Sciences and Physical Education
Bastiagueiro, A Coruña, Spain
Baroreflex sensitivity
Simultaneous electrocardiogram and beat-to-beat blood pressure recordings obtained by a photoplethysmography sensor will be used for calculating baroreflex sensitivity by sequential methods. Units: mmHg/ms
Time frame: 25 minutes
Blood pressure
Systolic, diastolic and mean blood pressure will be obtained by a photoplethysmography sensor. Units: mmHg
Time frame: 25 minutes
Heart rate variability in time domain
Standard deviation of the normal-to-normal interval (SDNN) and root of the mean squared differences of successive NN intervals (RMSSD) will be obtained by analyzing inter-beat intervals from electrocardiogram recordings. Units: ms
Time frame: 25 minutes
Heart rate variability in frequency domain
Obtained from spectral analysis of electrocardiogram recordings. High (HF) and Low (LF) frequency bands power will be determined by Fast Fourier Transformation method. Units: ms2/Hz
Time frame: 25 minutes
Blood pressure variability
It will be calculated by spectral analysis of beat-to-beat blood pressure recordings obtained by a photoplethysmography sensor. Units: mmHg2/Hz
Time frame: 25 minutes
Resting metabolic rate
It will be obtained by measuring oxygen consumption at rest. Units: kcal/·day
Time frame: 60 minutes
Arterial stiffness
It will be assessed by finger-toe pulse wave velocity method. Units: m/s
Time frame: 15 minutes
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Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
TREATMENT
Masking
NONE
Enrollment
40
Bone mineral density
It will be obtained by a Ultrasound Bone Densitometer. Units: g/cm
Time frame: 10 minutes
Skeletal muscle mass
Estimated by Bioelectrical impedance analysis. Units: kg and percentage of body mass
Time frame: 10 minutes
Fat mass
Estimated by Bioelectrical impedance analysis. Units: kg and percentage of body mass
Time frame: 10 minutes
Body mass
Measured in kg
Time frame: 10 minutes
Body mass index
Measured in kg/m\^2
Time frame: 2 minutes
Height
Measured in m
Time frame: 10 minutes
Muscle thickness
Measured with an ultrasound device. Units: mm
Time frame: 20 minutes
Torque-velocity relationship
Relationship between torque (N/m) and angular velocity (°/s). Obtained by performing maximum torque at specific velocities in an isokinetic dynamometer
Time frame: 60 minutes
Power-velocity relationship
Relationship betweenPower (W) and angular velocity (°/s). Obtained by performing maximum torque at specific velocities in an isokinetic dynamometer
Time frame: 60 minutes
Maximum isometric torque
Maximum torque recorded at fixed angular position. It will be measured with an isokinetic dynamometer. Units: N/m
Time frame: 60 minutes
Lipid profile to determine cardiovascular risk
* Total Cholesterol in mg/dL * High-Density Lipoprotein in mg/dL * Triglycerides in mg/dL * Calculated Low-Density Lipoprotein in mg/dL
Time frame: 5 minutes