Efectos del entrenamiento de intervalos de alta intensidad en altitud simulada. Revisión sistemática / Effects of high-intensity interval training at simulated Altitude. Systematic review

Introducción: en la actualidad, los entrenadores buscan la manera de mejorar las capacidades físicas de los atletas mediante diferentes estrategias de entrenamiento, como la exposición constante o intermitente a la altitud y el entrenamiento de intervalos de alta intensidad. Objetivo: Revisar la literatura actual y describir los efectos sobre el organismo del entrenamiento de intervalos de alta intensidad en altitud simulada en sujetos sedentarios, físicamente activos y entrenados. Resultados: el número de artículos revisados evidencia que, en hipoxia simulada en cámara hipobárica o normobárica (n=13) o máscara de simulación de altitud (n=1), todos utilizaron intensidades altas (n=13) a submáximas (n=1). Los participantes de las investigaciones fueron mujeres con obesidad sedentarias (n=3), hombres y mujeres físicamente activos (n=9) y sujetos entrenados (n=3). El tiempo de intervención de los estudios fue de 3 a 12 semanas, con una altitud simulada de 1824 a 4500 m.s.n.m. Se observaron efectos beneficiosos sobre la composición corporal, aptitud cardiorrespiratoria, aumentos en hemoglobina, eritropoyetina, consumo energético, fuerza máxima concéntrica e isométrica, fuerza absoluta y mejor tolerancia al ejercicio (percepción del esfuerzo). Conclusiones: La combinación de entrenamientos de intervalos de alta intensidad, combinado con una exposición en altitud simulada, puede evidenciar mejoras significativas en el rendimiento cardiorrespiratorio, así como en aspectos de composición corporal, lo que permitiría una mejor predisposición a intensidades más elevadas de actividad y ejercicio físico.

Introduction: Today, coaches are looking for ways to improve athletes' physical abilities through different training strategies, such as constant or intermittent exposu-re to altitude and high intensity interval training. Objective: To review the current literature and describe the effects on the body of simulated high-intensity interval training at altitude in sedentary, physically active, and trained subjects. Results: the number of articles reviewed evidences that, in simulated hypoxia in hypobaric or normobaric chamber (n = 13) or altitude simulation mask (n = 1), all used high intensities (n = 13) to submaximal (n = 1). The research participants were women with sedentary obesity (n = 3), physically active men and women (n = 9), and trained subjects (n = 3). The intervention time of the studies was 3 to 12 weeks, with a simulated altitude of 1824 to 4500 meters. Beneficial effects on body composition were observed, as well as cardiorespiratory fitness, increases in hemoglobin, erythro-poietin, energy consumption, concentric and isometric maximum strength, absolute strength and better exercise tolerance (perception of effort). Conclusions: The combination of high intensity interval training combined with a simulated altitude exposure can show significant improvements in cardiorespiratory performance, as well as in aspects of body composition, which would allow a better predisposition to higher intensities of activity and physical exercise.

Energy expenditure during a Vinyasa yoga session.

BACKGROUND: Vinyasa yoga has been recently promoted as one of the most popular mindful exercises to improve overall health, including body weight management. The purpose of this study was to determine the metabolic response of 24 moderately trained individuals during a 90-min group Vinyasa yoga routine. METHODS: Heart rate (HR) time course of 12 males and 12 females (age: 39±7.33 years) was recorded during two group Vinyasa yoga sessions consisted of four sections (warm-up, high-intensity Surya Namaskar (HSN), no Surya Namaskar postures, and cool-down). Maximal oxygen uptake (V̇O2peak) and maximum HR had been estimated earlier after a maximal treadmill test. V̇O2 during Vinyasa yoga sessions was estimated from individual regression equations using the relationship of V̇O2 and HR values derived from V̇O2peak test, while the metabolic rate (kcal/min) was calculated from the relationship of HR and kcal/min. Total session energy consumption was the average value of the two yoga sessions. RESULTS: The 2 (gender) × 4 (sections) mixed ANOVA revealed no significant interaction between the two factors (P=0.101) for the mean metabolic rate (7.1±2.6 kcal/min). Mean metabolic rate thought was higher (P=0.015) in males compared to females at each section. Also, significant differences were found among the four Vinyasa yoga sections (P<0.001) in the rate of energy expenditure, with HSN presenting the highest mean values (P<0.05). CONCLUSIONS: It seems that systematic participation in Vinyasa yoga may effectively improve cardiorespiratory fitness and promote body weight loss, as an alternative method to traditional aerobic exercise.

Perceptions and use of recovery strategies: Do swimmers and coaches believe they are effective?

This study aimed to investigate swimmer's use and coach prescription of recovery strategies during training and competition while examining perceived challenges, barriers, and beliefs in the importance of their effectiveness. A mixed-methods sequential explanatory design was implemented. Thirty-seven male and 45 female sub-elite to elite swimmers (age 18 ± 3 y), and 4 male and 6 female coaches (age 40 ± 9 y) completed an online, 78-item recovery strategy survey. Swimmers and coaches responded to questions regarding when, why, and how they used recovery strategies, perceived challenges and barriers to strategy inclusion during training and competition. Data were coded and analysed thematically. Fisher's Exact Test was conducted on 5-point Likert scale responses. Most recovery strategies were used and prescribed more during competition. Swimmers reported active recovery as the most effective recovery strategy (44%), whereas coaches rated sleep or napping (40%). Swimmers and coaches perceived most recovery strategies to be more effective and important during competition than in training. Swimmers used, and coaches prescribed, recovery strategies more during the competition, highlighting the discrepancies in use between training and competition. Targeted education programmes should enhance athletes and coach's recovery knowledge and practical application of strategies, while accounting for individual sport and life demands.

Evidence-based post-exercise recovery strategies in rugby: a narrative review.

In the sport of rugby, athletes need a multitude of sport-specific skills along with endurance, power, and speed to optimize performance. Further, it is not unusual for athletes to play several competitive matches with insufficient recovery time. Rugby requires repeated bouts of high-intensity actions intermixed with brief periods of low-to-moderate active recovery or passive rest. Specifically, a match is characterized by repeated explosive activities, such as jumps, shuffles, and rapid changes of direction. To facilitate adequate recovery, it is necessary to understand the type of fatigue induced and, if possible, its underlying mechanisms. Common approaches to recovery may include nutritional strategies as well as active (active recovery) and passive recovery (water immersions, stretching, and massage) methods. However, limited research exists to support the effectiveness of each strategy as it related to recovery from the sport of rugby. Therefore, the main aim of the current brief review is to present the relevant literature that pertains to recovery strategies in rugby.

Optimizing recovery to support multi-evening cycling competition performance.

Road criterium and track bicycle racing occur at high speeds, demand repeated high power outputs, last 10-90 min, and offer little chance for recovery after the event. Consecutive evenings of criterium and track racing are respectively known as speed-week or six-day events and take place in evening hours over the course of a week. Given the schedule and timing of these competitions, return to homeostasis can be compromised. No recommendations exist on how to optimize recovery for cyclists participating in these types of repeated evening competitions. Criterium and track cyclists spend considerable time, near and above the individual lactate threshold and therefore mostly utilize carbohydrate as their chief energy substrate. Henceforth, pre - and post-race nutrition and hydration is examined and recommendations are brought forward for carbohydrate, protein, and fluid intake. As evening high-intensity exercise perturbs sleep, strategies to optimize sleep are discussed and recommendations for an optimal sleep environment are given. Active recovery is examined, and the benefits of a short duration low intensity exercise reviewed. Passive recovery methods such as compression garments and cold water immersion are recommended, while evidence for massage, pneumatic compression devices, and neuromuscular electrical stimulation is still lacking. Optimizing recovery strategies will facilitate a return to the resting state following strenuous night competition.