Programming training loads MTB cyclists during first 7-days of the stay in conditions of high-altitude hypoxia

Programming training loads MTB cyclists during first 7-days of the stay in conditions of high-altitude hypoxia

Introduction Hematological effects of training in accordance with the LH-TH (live high - train high) model is well-defined (Stray-Gundersen, Levine 2008). Special attention has been paid to conditioning of the effect of a 2-3 week stay at altitude combined with various combinations of training loads...

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Veröffentlicht in:Journal of science and cycling 2017-09, Vol.6 (3)
Hauptverfasser: Garnys, Michal, Gabrys Tomasz, Smatlan-Gabrys, Urszula, Stanisz, Lidia, Rzepka, Remigiusz, Galinski, Marek, Lukasiewicz, Artur
Format: Artikel
Sprache:eng
Schlagworte:
Altitude
Athletes
Exercise
Heart rate
High altitude
Hypoxia
Loads (forces)
Medical electronics
Oxygen consumption
Physiological tests
Physiology
Sea level
Training
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Zusammenfassung:Introduction Hematological effects of training in accordance with the LH-TH (live high - train high) model is well-defined (Stray-Gundersen, Levine 2008). Special attention has been paid to conditioning of the effect of a 2-3 week stay at altitude combined with various combinations of training loads (Friedmann-Bette 2008). However, the issue of selection of intensity of training loads (external loads) in one week stay in the conditions of hypoxia and respond to changes in the physiological parameters (internal load) in relation to the conditions observed in lowland has not been described in literature. The first aim of this investigation was to determine a direction and range of training loads during the first week of MTB cyclists stay at the altitude of 2250 m above sea level. The second aim of this investigation was amounts of intensity basic training loads applied during first 7-days of the stay in conditions of high-altitude hypoxia Methods The participants of the study were The MTB XCO Nationals Teams Russia and Poland athletes (women n=9, 25,4/2.1year, 50,3/2.2kg, 160,3/5.5cm), 72 hours before they came to the altitude of 2250 m. and on the second day of stay. The participants of the study done the gradet incremental exercise test (GXTs) at the altitude of 170 m (Lonato del Garda, Italy) and 2250 m (Livignio-Trepale Italy). The GXTs test was executed on ergometer Cyclus 2 (RBM, Germany). The I-st step was 1Wxkg-1 b.m. and increased every 3 minutes by 0,5 Wxkg-1 b.m.. In last 30 the seconds of every exercise grade was taken 20 µl of arterialized blood to the sign LA (Biosen S-line, EKF, Germany). In the course of effort VO2, VE, VCO2 was measured by means of K4b2 analyser. The heart rate monitor, Polar V650 (Polar Finland ) measured HR during GXTs. At the level of aerobic threshold (LT) (Farell et al. 1979), anaerobic threshold (AT) (Powers et al. 1983) i VO2max. the powers value was set. The purpose of the training was to execute the seven day program at the altitude of 2300-2100 m above sea level. Results After physiological tests, it was determined the direction of oxygen consumption (VO2), ventylatory (VE), HR, oxygen puls (O2HR) and mocy (P) na poziomie VO2max., LT (lactat treshold) and AT (anaerobic trehsold) changes. The character of changes of physiological indicators shows that in all cases changes are closely related to each other. The scope of changes is individual.. On LT: P↓ (6-8%), VO2↑ (4-6%), VE↔, HR↔, O2HR↑ (4-6%). On AT: P↔; VO2↑ (8-
ISSN:2254-7053