Biomechanics and Medicine in Swimming XI

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work load(watt) L-condition(bpm) W-condition(bpm) Decreasing 50 130.4±16.8 112.4±15.4 * Decreasing 45 129.5±18.1 110.9±15.7 * Decreasing 40 126.7±19.2 108.8±15.8 * Decreasing 35 123.0±19.4 105.2±15.7 * Decreasing 30 120.0±19.1 101.7±15.7 * Decreasing 25 115.8±18.6 98.4±15.6 * Decreasing 20 112.5±18.3 96.0±14.9 * Increasing 25 111.7±17.0 94.7±14.8 * Increasing 30 112.2±16.3 95.5±14.9 * Increasing 35 113.2±16.5 97.4±14.5 * Increasing 40 115.1±16.4 98.7±14.5 * ANOVA:p< 0.05, *;p< 0.05 L-condition vs W-condition Figure 1. The phase lags to (top) the top of the work rate and (bottom) the bottom of the work rate both in the W-condition and on the Lcondition. Figure 2. The amplitude of heart rate both conditions chaPter3.PhysioLogyandBioenergetics Figure 3. The ln HF under arm caking exercise both conditions. Figure 4. Comparison of T30 in both conditions. Figure 5. The ln HF both condition during 1 –minute after exercise. 209
BiomechanicsandmedicineinswimmingXi results Table 1 shows changes in heart rate during arm cranking exercise during gradually increasing and decreasing workload. During the calibration test (20, 60 and 40%VO 2peak ), heart rate in the W-condition was significantly lower than on the L-condition (p< 0.05, respectively). Heart rate in the W-condition was significantly lower than in the L-condition during triangular exercise (ANOVA; p< 0.05). Figure 1 shows the mean response time of heart rate (phase lags) to (a) the top of the work rate and (b) the bottom of the work rate in both conditions. The phase lags to the top the work rate in the W-condition was significantly shorter than on the L-condition (p< 0.05). Furthermore, phase lags to the bottom of the work rate in the W-condition were significantly shorter than on the L-condition (p< 0.05). The amplitude (difference between maximal and minimal values) was no significant different in each condition (Figure 2). The ln HF in the W-condition was significantly higher than on the L-condition during triangular exercise (p< 0.05) (Figure 3). Figure 4 shows T30 in both conditions. T30 in the W-condition was significantly lower than on the L-condition (p< 0.05). During 1 minute after exercise, the ln HF in the W-condition was significantly higher than on the Lcondition (p< 0.05) (figure 5). dIscussIon The results of the present study are as follows; 1) the heart rate phase response to gradually increasing and decreasing arm cranking exercise was shorter in the water than on land, but no differences in heart rate amplitude were observed, 2) the reactivation in cardiac parasympathetic tone after arm cranking exercise was greater in water than on land. These results may expand our understanding of heart rate responses modulated by the autonomic nervous system to gradually increasing and decreasing exercise in water. In the present study, heart rate in water exercise was significantly reduced as compared to land exercise. This fact may depend on immersion-induced bradycardia, and be caused by increased venous return due to water pressure. It is thought that the heart rate response to exercise under the anaerobic threshold level is mainly due to the attenuation of cardiac parasympathetic nervous activity (Xenakis et al., 1975). In the present study, since peak heart rate values in W-condition and Lcondition were 113 bpm and 131 bpm, respectively, it is speculated that exercise intensity was below the anaerobic threshold level. Thereby, heart rate response to gradually increasing and decreasing exercise can be also explained by activation of the cardiac parasympathetic nervous system. Indeed, the ln HF (an index of cardiac parasympathetic nerve activity) was higher in the W-condition as compared with on the L-condition, supporting our speculation. Sone et al. (1997) have suggested that the contribution of the withdrawal of cardiac parasympathetic activity to the increase in heart rate with increasing exercise intensity was greater at lower heart rate, and that the cardiac parasympathetic system was more activated during heart rate decreases than during heart rate increases at the same heart rate. The density of the high frequency spectrum of heart rate during light work rates is higher than during heavier workloads (Nabekura et al., 2007). In this present study, the phase lags at the top and bottom of the work rate in the W-condition were significantly shorter than in the L-condition, suggesting that immersion-induced bradycardia might have coursed an increase in the phase lags at the top and bottom of the work rate. In the present study, T30 in W-condition was greater than in Lcondition suggesting that the cardiac parasympathetic nervous system rapidly reactivates in the water. It has been reported that an increase of central blood volume due to water immersion might accelerate the recovery process of cardio-respiratory system (Miyamoto et al., 2001). Given this, the increased venous return shown in the present investigation may contribute to the rapid reactivation of the cardiac parasympathetic nervous system. In fact, the ln HF in the W-condition was significantly higher than in the L-condition 1 minute after exercise. 210 conclusIon The results of the present study suggest that the activation of the cardiac parasympathetic nervous system caused by water immersion may produce an attenuation of heart rate time response to gradually increasing and decreasing exercise. This attenuation of the phase lags during exercise in the water may contribute to a reactivation of cardiac parasympathetic nervous system after exercise. Thus, exercise and recovery in water may enhance the stability of the autonomic nervous activity not only during exercise but also after exercise. reFerences Kimura M, Suzuki M, Yazawa M, and Muraoka I (2001). Effect of Water Immersion on Heart Rate Responses during Arm Cranking Exercise. Adv. Exerc. Sports Physiol., 8, 41-48. Fukuoka Y, Nakagawa Y, Ogoh K, Shiojiri T and Fukuba Y (2002). Dynamics of the heart rate response to sinusoidal work in humans: influence of physical activity and age. Clin Sci, 102, 31-38. Nabekura Y, Yoshioka Y, Nakagaki K, Tsujimura S and Sengoku Y (2007). Effect of Short-term Training on Heart Rate Response during Sinusoidal Exercise. Adv. Exerc. Sports Physiol., 14, 29-39. Imai K, Sato H, Hori M, Kusuoka H, Ozaki H, Yokoyama H, Takeda H, Inoue M and Kamada T (1994). Vagally mediated heart rate recovery after exercise is accelerated in athletes but blunted in patients with chronic heart failure. J Am Coll Cardiol., 24, 1529-1535. Nishimura K, Seki K, Ono K and Onodera S (2006). Effects of the Supine Floating on Rectal Temperature and Cardiac Parasympathetic Nervous System Activity after Exercise with a Cycle Ergometer. Japanese Journal of Aerospace and Environmental Medicine, 43, 11-18. Xenakis, A.P., Quarry, V.M. and Spodick, D.H. (1975). Immediate Cardiac response to exercise: physiologic investigation by systolic time intervals at graded workloads. Am Heart J., 89, 178-185. Sone R, Yamazaki F, Fukuoka Y and Ikegami H (1997). Respiratory variability in R-R interval during Sinusoidal exercise. Eur J Appl Physiol Occup Physiol., 75, 39-46. Miyamoto T, Nakanishi Y and Kinoshita H (2001). Effects of Increased Central Blood Volume on Cardio-Respiratory and Metabolic Responses during Recovery after Exercise. Descente Sports Science, 22, 127-138.
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Pahlen Norge AS Pahlen Norge AS Cha
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