Refine
Has Fulltext
- yes (8)
Is part of the Bibliography
- yes (8)
Document Type
- Journal article (7)
- Doctoral Thesis (1)
Keywords
- team sport (3)
- blood flow (2)
- clothing (2)
- near-infrared spectroscopy (2)
- oscillation (2)
- oxygen uptake (2)
- oxygenation (2)
- speed (2)
- textile (2)
- tissue saturation index (2)
Institute
The aim of this study was to evaluate the effect of a repeated sprint training with multi-directional change-of-direction (COD) movements (RSmulti) compared to repeated shuttle sprints (RSS) on variables related to COD speed and reactive agility. Nineteen highly-trained male U15 soccer players were assigned into two groups performing either RSmulti or RSS. For both groups, each training session involved 20 repeated 15 s sprints interspersed with 30 s recovery. With RSmulti the COD movements were randomized and performed in response to a visual stimulus, while the RSS involved predefined 180° COD movements. Before and following the six training sessions, performance in the Illinois agility test (IAT), COD speed in response to a visual stimulus, 20 m linear sprint time and vertical jumping height were assessed. Both groups improved their performance in the IAT (p < 0.01, ES = 1.13; p = 0.01, ES = 0.55). The COD speed in response to a visual stimulus improved with the RSmulti (p < 0.01, ES = 1.03), but not the RSS (p = 0.46, ES = 0.28). No differences were found for 20 m sprint time (P=0.73, ES = 0.07; p = 0.14, ES = 0.28) or vertical jumping height (p = 0.46, ES = 0.11; p = 0.29, ES = 0.12) for the RSmulti and RSS, respectively. In conclusion, performance in the IAT improved with the RSmulti as well as RSS. With the RSmulti however, the COD movements are performed in response to a visual stimulus, which may result in specific adaptations that improve COD speed and reactive agility in young highly trained soccer players.
Here, we evaluated the influence of breathing oxygen at different partial pressures during recovery from exercise on performance at sea-level and a simulated altitude of 1800 m, as reflected in activation of different upper body muscles, and oxygenation of the m. triceps brachii. Ten well-trained, male endurance athletes (25.3±4.1 yrs; 179.2±4.5 cm; 74.2±3.4 kg) performed four test trials, each involving three 3-min sessions on a double-poling ergometer with 3-min intervals of recovery. One trial was conducted entirely under normoxic (No) and another under hypoxic conditions \((Ho; F_iO_2 = 0.165)\). In the third and fourth trials, the exercise was performed in normoxia and hypoxia, respectively, with hyperoxic recovery \((HOX; F_iO_2 = 1.00)\) in both cases. Arterial hemoglobin saturation was higher under the two HOX conditions than without HOX (p<0.05). Integrated muscle electrical activity was not influenced by the oxygen content (best d = 0.51). Furthermore, the only difference in tissue saturation index measured via near-infrared spectroscopy observed was between the recovery periods during the NoNo and HoHOX interventions (P<0.05, d = 0.93). In the case of HoHo the athletes’ \(P_{mean}\) declined from the first to the third interval (P < 0.05), whereas Pmean was unaltered under the HoHOX, NoHOX and NoNo conditions. We conclude that the less pronounced decline in \(P_{mean}\) during 3 x 3-min double-poling sprints in normoxia and hypoxia with hyperoxic recovery is not related to changes in muscle activity or oxygenation. Moreover, we conclude that hyperoxia \((F_iO_2 = 1.00)\) used in conjunction with hypoxic or normoxic work intervals may serve as an effective aid when inhaled during the subsequent recovery intervals.
Einleitung: Es konnte gezeigt werden, dass die Applikation von Kompressionsbekleidung zu einem erhöhten Blutfluss bei Patienten mit venöser Insuffizienz führt und das Thromboserisiko bei bettlägerigen und postoperativen Patienten reduziert. Davon ausgehend, dass Kompressionsbekleidung auch bei gesunden und trainierten Athlet/innen zu einer verbesserten Hämdynamik führt, wurde eine Vielzahl an Studien durchgeführt, die nach einer Leistungssteigerung durch das Tragen von Kompressionsbekleidung während sportlicher Belastung gesucht haben. Die Ergebnisse der bisher veröffentlichten Studien widersprechen sich jedoch häufig und lassen kein abschließendes Fazit bezüglich ergogener Effekte von Kompressionsbekleidung auf die Leistung während körperlicher Belastung zu. Auch ist unklar, welche physiologischen und/oder biomechanischen Mechanismen bei gesunden und trainierten Athlet/innen zu einer potentiellen Leistungssteigerung führen könnten.
Ziel der vorliegenden Arbeit war es daher: 1) Belastungsarten und –intensitäten zu identifizieren, bei denen das Tragen von Kompressionsbekleidung leistungssteigernde Effekte verspricht, 2) die identifizierten Potentiale anhand empirischer Datenerhebung zu evaluieren und 3) die physiologischen und biomechanischen Mechanismen zu untersuchen, die einer möglichen Leistungssteigerung mit Kompressionsbekleidung bei gesunden und trainierten Athlet/innen zugrunde liegen könnten.
Methodik: Mittels eines Übersichtsartikels und Berechnung von Effektstärken wurden verschiedene Belastungsarten und -intensitäten identifiziert, bei denen das Tragen von Kompressionsbekleidung leistungssteigernde Effekte verspricht (Studie 1). Auch wurden die möglichen Mechanismen zusammengetragen, die einer Leistungssteigerung zugrunde liegen könnten. Basierend auf diesen Ergebnissen wurden die Untersuchungsprotokolle für die weiteren Studien entwickelt.
In Studie 2 absolvierten hoch-trainierte Eisschnellläufer/innen eine 3000 m Wettkampfsimulation mit und ohne Kompressionsbekleidung in randomisierter Reihenfolge. Physiologische Daten wurden mittels mobiler Spirometrie und Nahinfrarotspektroskopie (NIRS) erhoben.
Des Weiteren wurden Athletinnen aus Mannschaftssport und Leichtathletik einer intermittierenden Sprintbelastung mit dreißig 30 m Sprints und einer Abgangszeit von einer Minute mit und ohne Kompressionsbekleidung in randomisierter Reihenfolge unterzogen (Studie 3). Neben mobiler Spirometrie und NIRS wurden biomechanische Daten mittels kinematischer Bewegungsanalyse und Elektromyographie erhoben.
Ergebnisse:Studie 1 zeigte ein leistungssteigerndes Potential mit der Applikation von Kompressionsbekleidung bei hoch-intensiver und weniger bei submaximaler Belastungsintensität. Insbesondere hoch-intensive Ausdauer- (> 3 Minuten), Sprint- und Sprungbelastung als auch die Erholungsfähigkeit von Kraft- und Schnellkraft scheinen durch Kompressionsbekleidung verbessert. Die Ergebnisse zeigen auch, dass bisher nur wenige Daten bei weiblichen Sportlern erhoben wurden. Auch evaluierten nur wenige Studien die Effekte von Kompressionsbekleidung bei Athlet/innen auf höchstem Leistungsniveau.
In Studie 2 zeigte die Applikation von Kompressionsbekleidung während der 3000 m Wettkampfsimulation bei hoch-trainierten Eisschnellläufer/innen keinen Effekt auf die Laufleistung. Auch blieben mittels NIRS gemessenes Blutvolumen und Muskeloxygenierung im m. quadrizeps femoris sowie alle weiteren kardio-respiratorischen, metabolischen und subjektiven Parameter unbeeinflusst.
Dagegen war die Laufleistung während eines intermittierenden (30 x 30 m) Sprintprotokolls mit Kompressionsbekleidung signifikant verbessert (Studie 3). Auch in dieser Untersuchung blieben alle gemessenen hämodynamischen, kardio-respiratorischen und metabolischen Parameter unbeeinflusst. Die kinematische Bewegungsanalyse zeigte jedoch, dass Kompressionsbekleidung zu veränderter Lauftechnik führt und die Schrittlänge bei gleichbleibender Schrittfrequenz vergrößert. Auch wurde die Sprintbelastung lokal an der Oberschenkelmuskulatur subjektiv weniger anstrengend empfunden.
Zusammenfassung und Fazit: Die Applikation von Kompressionsbekleidung zeigte keine generelle leistungssteigernde Wirkung während körperlicher Belastung bei gesunden und trainierten Athlet/innen. Abhängig von Belastungsart und –intensität manifestieren sich ergogene Effekte während hoch-intensiver Lauf- insbesondere intermittierender Sprintbelastungen. Im Zusammenhang mit weiteren Untersuchungen scheinen die ergogenen Effekte jedoch nicht auf veränderter Hämodynamik zu basieren. Der blutflusssteigernde Effekt von Kompressionsbekleidung, der in klinischen Studien bei Patienten mit venöser Insuffizienz gezeigt wurde, lässt sich nicht in gleichem Maße bei gesunden und trainierten Athlet/innen nachweisen. Vielmehr scheinen kinematische und subjektive Parameter, wie eine veränderte Lauftechnik und verringertes Belastungsempfinden, die intermittierende Sprintleistung verbessert zu haben.
Background
Repeated sprint performance is determined by explosive production of power, as well as rapid recovery between successive sprints, and there is evidence that compression garments and sports taping can improve both of these factors.
Methods
In each of two sub-studies, female athletes performed two sets of 30 30-m sprints (one sprint per minute), one set wearing compression garment with adhesive silicone stripes (CGSS) intended to mimic taping and the other with normal clothing, in randomized order. Sub-study 1 (n = 12) focused on cardio-respiratory, metabolic, hemodynamic and perceptual responses, while neuronal and biomechanical parameters were examined in sub-study 2 (n = 12).
Results
In both sub-studies the CGSS improved repeated sprint performance during the final 10 sprints (best P < 0.01, d = 0.61). None of the cardio-respiratory or metabolic variables monitored were altered by wearing this garment (best P = 0.06, d = 0.71). Also during the final 10 sprints, rating of perceived exertion by the upper leg muscles was reduced (P = 0.01, d = 1.1), step length increased (P = 0.01, d = 0.91) and activation of the m. rectus femoris elevated (P = 0.01, d = 1.24), while the hip flexion angle was lowered throughout the protocol (best P < 0.01, d = 2.28) and step frequency (best P = 0.34, d = 0.2) remained unaltered.
Conclusion
Although the physiological parameters monitored were unchanged, the CGSS appears to improve performance during 30 30-m repeated sprints by reducing perceived exertion and altering running technique.
Background
Repeated sprint performance is determined by explosive production of power, as well as rapid recovery between successive sprints, and there is evidence that compression garments and sports taping can improve both of these factors.
Methods
In each of two sub-studies, female athletes performed two sets of 30 30-m sprints (one sprint per minute), one set wearing compression garment with adhesive silicone stripes (CGSS) intended to mimic taping and the other with normal clothing, in randomized order. Sub-study 1 (n = 12) focused on cardio-respiratory, metabolic, hemodynamic and perceptual responses, while neuronal and biomechanical parameters were examined in sub-study 2 (n = 12).
Results
In both sub-studies the CGSS improved repeated sprint performance during the final 10 sprints (best P < 0.01, d = 0.61). None of the cardio-respiratory or metabolic variables monitored were altered by wearing this garment (best P = 0.06, d = 0.71). Also during the final 10 sprints, rating of perceived exertion by the upper leg muscles was reduced (P = 0.01, d = 1.1), step length increased (P = 0.01, d = 0.91) and activation of the m. rectus femoris elevated (P = 0.01, d = 1.24), while the hip flexion angle was lowered throughout the protocol (best P < 0.01, d = 2.28) and step frequency (best P = 0.34, d = 0.2) remained unaltered.
Conclusion
Although the physiological parameters monitored were unchanged, the CGSS appears to improve performance during 30 30-m repeated sprints by reducing perceived exertion and altering running technique.
The aim of the study was to evaluate the reliability and validity of cardiorespiratory and metabolic variables, that is, peak oxygen uptake (V'O\(_{2peak}\)) and heart rate (HR\(_{peak}\)), obtained from an agility‐like incremental exercise test for team sport athletes. To investigate the test–retest reliability, 25 team sport athletes (age: 22 ± 3 years, body mass: 75 ± 7 kg, height: 182 ± 6 cm) performed an agility‐like incremental exercise test on the SpeedCourt (SC) system incorporating multidirectional change‐of‐direction (COD) movements twice. For each step of the incremental SC test, the athletes covered a 40‐m distance interspersed with a 10‐sec rest period. Each 40 m distance was split into short sprints (2.25–6.36 m) separated by multidirectional COD movements (0°–180°), which were performed in response to an external visual stimulus. All performance and physiological data were validated with variables obtained from a ramp‐like treadmill and Yo‐Yo intermittent recovery level 2 test (Yo‐Yo IR2). The incremental SC test revealed high test–retest reliability for the time to exhaustion (ICC = 0.85, typical error [TE] = 0.44, and CV% = 3.88), V'O\(_{2peak}\), HR\(_{peak}\), ventilation, and breathing frequency (ICC = 0.84, 0.72, 0.89, 0.77, respectively). The time to exhaustion (r = 0.50, 0.74) of the incremental SC test as well as the peak values for V'O\(_{2}\) (r = 0.59, 0.52), HR (r = 0.75, 0.78), ventilation (r = 0.57, 0.57), and breathing frequency (r = 0.68, 0.68) were significantly correlated (P ≤ 0.01) with the ramp‐like treadmill test and the Yo‐Yo IR2, respectively. The incremental SC test represents a reliable and valid method to assess peak values for V'O\(_{2}\) and HR with respect to the specific demand of team sport match play by incorporating multidirectional COD movements, decision making, and cognitive components.
Purpose:
The aim of the study was to evaluate the mucosal immune function and circadian variation of salivary cortisol, Immunoglobin-A (sIgA) secretion rate and mood during a period of high-intensity interval training (HIIT) compared to long-slow distance training (LSD).
Methods:
Recreational male runners (n = 28) completed nine sessions of either HIIT or LSD within 3 weeks. The HIIT involved 4 × 4 min of running at 90–95% of maximum heart rate interspersed with 3 min of active recovery while the LSD comprised of continuous running at 70–75% of maximum heart rate for 60–80 min. The psycho-immunological stress-response was investigated with a full daily profile of salivary cortisol and immunoglobin-A (sIgA) secretion rate along with the mood state on a baseline day, the first and last day of training and at follow-up 4 days after the last day of training. Before and after the training period, each athlete's running performance and peak oxygen uptake (V·O\(_{2peak}\)) was determined with an incremental exercise test.
Results:
The HIIT resulted in a longer time-to-exhaustion (P = 0.02) and increased V·O\(_{2peak}\) compared to LSD (P = 0.01). The circadian variation of sIgA secretion rate showed highest values in the morning immediately after waking up followed by a decrease throughout the day in both groups (P < 0.05). With HIIT, the wake-up response of sIgA secretion rate was higher on the last day of training (P < 0.01) as well as the area under the curve (AUC\(_{G}\)) higher on the first and last day of training and follow-up compared to the LSD (P = 0.01). Also the AUC\(_{G}\) for the sIgA secretion rate correlated with the increase in V·O\(_{2peak}\) and running performance. The AUC\(_{G}\) for cortisol remained unaffected on the first and last day of training but increased on the follow-up day with both, HIIT and LSD (P < 0.01).
Conclusion:
The increased sIgA secretion rate with the HIIT indicates no compromised mucosal immune function compared to LSD and shows the functional adaptation of the mucosal immune system in response to the increased stress and training load of nine sessions of HIIT.
Purpose: Research dealing with ischemic preconditioning (IPC) has primarily focused on variables associated to endurance performance with little research about the acute responses of IPC on repeated multidirectional running sprint performance. Here we aimed to investigate the effects of IPC of the arms and the legs on repeated running sprint performance with changes-of-direction (COD) movements.
Methods: Thirteen moderately-to-well-trained team-sport athletes (7 males; 6 females; age: 24 ± 2 years, size: 175 ± 8 cm, body mass: 67.9 ± 8.1 kg) performed 16 × 30 m all-out sprints (15 s rest) with multidirectional COD movements on a Speedcourt\(^{©}\) with IPC (3 × 5 min) of the legs (IPC\(_{leg}\); 240 mm Hg) or of the arms (remote IPC: IPC\(_{remote}\); 180–190 mm Hg) 45 min before the sprints and a control trial (CON; 20 mm Hg).
Results: The mean (±SD) time for the 16 × 30 m multidirectional COD sprints was similar between IPC\(_{leg}\) (Mean t: 16.0 ± 1.8 s), IPC\(_{remote}\) (16.2 ± 1.7 s), and CON (16.0 ± 1.6 s; p = 0.50). No statistical differences in oxygen uptake (mean difference: 0%), heart rate (1.1%) nor muscle oxygen saturation of the vastus lateralis (4.7%) and biceps brachii (7.8%) between the three conditions were evident (all p > 0.05).
Conclusions: IPC (3 × 5 min) of the legs (220 mm Hg) or arms (180–190 mm Hg; remote IPC) applied 45 min before 16 × 30 m repeated multidirectional running sprint exercise does not improve sprint performance, oxygen uptake, heart rate nor muscle oxygen saturation of the vastus lateralis muscle when compared to a control trial.