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versión impresa ISSN 1517-8692
Rev Bras Med Esporte vol.18 no.3 São Paulo mayo/jun. 2012
EXERCISE AND SPORTS MEDICINE CLINIC
Heart rate and blood lactate concentration response after each segment of the olympic triathlon event
Renata Fiedler LopesI,II; Raul OsieckiI; Luis Manuel Pinto Lopes RamaII
ICEPEFIS Center of the Physical
Performance Studies, Federal University of Paraná Curitiba, PR, Brazil
IISports Sciences and Physical Education College, University of Coimbra Coimbra, Portugal
INTRODUCTION: The physiological responses of
each part of Triathlon are different; better training loads could be prescribed
for athletes considering each segment of this sport.
OBJECTIVE: The purpose of this study was to investigate the behavior of physiological variables heart rate and blood lactate concentration before the event, after each segment of an Olympic Triathlon: swimming, cycling and running, and after recovery time.
METHODS: The sample included twelve male triathletes who participated in a triathlon event with Olympic distance. Capillary blood samples were taken from the fingertip in the beginning of the event (pre-event), after each segment (swimming, cycling, running) and after 1 hour of recovery. Each athlete was monitored during the entire event by a heart rate monitor (Polar® S610). Statistical procedures included: Spearman correlations and Wilcoxon non parametric tests (p<0.05).
RESULTS: The study results showed that the highest intensity was reached during cycling (HRmax: 86.3%; Lac: 6.98 mmol/L) in both physiological parameters, followed by swimming (HRmax: 85.2%, Lac: 5.75 mmol/L) and running (HRmax: 83.6%, lac: 4.47mmol), respectively.
CONCLUSIONS: Training load prescription based on different physiological markers responses such as heart rate and blood lactate concentration - of each triathlon segment will be more efficient for the Olympic triathlon demands.
Keywords: swimming, cycling, running, blood, cardiac monitoring.
Regarding long-duration sports, the use of the heart rate (HR) is frequent in the prescription of the training load. This physiological parameter has been assumed as a good marker of the training intensity, constituting a simple method for the training monitoring for athletes and coaches1.
Another frequently used indicator in this context is the blood lactate concentration response. This marker has been efficient in controlling training, and the athletes' performance can be evaluated from steady values in different moments and the demand imposed by the training load be adjusted. Although the individual behavior in the kinetics of the lactate accumulation has been reckoned, in this study we will consider in agreement with Sjödin and Jacobs2 the steady value of 4.0mmol/L (OBLA Onset Blood Lactate Accumulation). Many authors3-5 consider this steady value as the point of break of balance between lactate production and removal, which leads to increase of its concentration in the blood (anaerobic threshold).
The association of these two parameters heart rate and blood lactate concentration may constitute an important instrument in the control of the training loads. Some studies support the ratio between these two variables in the process adaptation during the training season and in competitions in several modalities, such as in skaters6, cyclists7,8, runners9,10 and racing drivers11.
The aim of our study was to observe whether there is straight relation between exercise intensities and the physiological variables of exertion prediction during an Olympic triathlon event, relating the heart rate values and blood lactate concentration after the performance of each of the segments-modality: swimming, cycling and running.
The sample was composed of 12 Brazilian male triathletes with involvement of a minimum of two years of systematic training, participants in official competitions sponsored by the Brazilian Confederation of Triathlon with Olympic distance. The twelve athletes (mean (SE) aged 27.9 (1.73) years, weight of 73.88 (2.16) kg, height of 177.9 (1.73) cm and % fat 7.3 (0.55) %) performed a triathlon event with distances corresponding to an Olympic triathlon (1,500m swimming, 40km cycling and 10km running).
The experimental protocol was approved by the Ethics Committee of the Federal University of Paraná, according to the Declaration of Helsinki (1975) for human experimentation, and all athletes signed a responsibility and confidentiality consent form before the evaluations performance.
Individual maximum heart rate (HRmax) was determkined in a laboratory. A progressive exertion protocol on treadmill consisted in the performance of two-minute thresholds of initiated exertion, with velocity of 6km/h with increase of 1km/h at every threshold and 1% of steady inclination was used. All athletes reached a respiratory coefficient above 1.0 at the end of the maximal test. All athletes were monitored by Polar® S610 frequency meter for the HR response.
The swimming segment of the event took place in an acclimatized and indoors swimming pool (27ºC) of Olympic dimensions (50m); cycling and running were held outdoors, the former in a closed circuit of 2,100m and the latter on a 400-meter running track. The weather temperature amplitude was of minimum of 18.2ºC and maximum of 25º C and relative humidity was 77.1%.
Blood samples were collected before the event (pre-event), after swimming, after cycling, after running and also one hour after the event. In each of the five collections 25µl of blood were collected from the digital pulp.
The blood was removed from the digital pulp through a heparinized capillary tube calibrated for 25µl and immediately transferred to plastic tubes with a lid (Ependorf) containing 50µl of sodium fluoride at 1%. The samples were analyzed in a lactate analyzer YSP 1500 STAT®.
During the protocol performance all athletes were wearing a Polar® S610 frequency meter programed to record and store data at every five seconds of exertion.
No food or caloric supplementation was allowed during the event in order to minimize factors which could contaminate the results. Only water ad libitum was made available during cycling and running.
Data were expressed in mean and standard error. Due to the sample's dimension, and the fact that distribution normality could not be guaranteed in all variables through the Shapiro-Wilk test, the non-parametric Wilcoxon test with significance level of p < 0.05 was used. The studied variables were correlated between each other through non-parametric Spearman correlation (p < 0.05). The analyses were performed with the SPSS computer statistical package, version 13.0 for Windows.
The olympic triathlon requires that the athletes present high physical fitness for a period longer than two hours. In this study the mean total time of the event was 2h12min31sec, and 23min19s out of this total time were spent in swimming, 1h02min21s during cycling and 47min31s in running.
The main aim of this study is to assess the behavior of some variables which present a straight relationship with performance of an Olympic triathlon event.
The maximal exertion test enabled the maximum heart rate determination and from these values, the percentage of the exertion during the Olympic triathlon event was diagnosed. (table 1).
The HR results revealed that the highest intensity was reached during cycling, followed by swimming and running. This intensity was significantly different between cycling and running (p < 0.05).
All heart rates were highly correlated; that is to say, the athletes who presented higher absolute values in swimming also presented higher heart rates in cycling (0.825, p < 0.01) and running (0.681, p < 0.05); as well as between cycling and running (0.869, p < 0.01).
Table 2 describes the absolute values of the lactate concentration immediately before the event and after each segment of the triathlon and after one hour of recovery.
The pre-event lactate values were slightly high since they have been collected after warm-up in the swimming pool of the athletes. Although the blood lactate concentrations have suffered some alterations due to the room temperature and dehydration, they were higher during cycling (6.98mmol/L), followed by swimming (5.75mmol/L) and running (4.47mmol/L). Such values were in agreement with the percentage intensities of each modality, evidenced by the higher heart rate in cycling (86.3%) followed by swimming (85.2%) and running (83.6%), according to figure 1.
According to the physiological variable heart rate it can be observed that the absolute and relative values of the maximum heart rate were higher than the ones exposed by Rohde et al.12, who found a heart rate mean of 148bpm, or 74% of HRmax during cycling and mean of 159bpm or intensity of 81% in running, concerning the maximum heart rate in a triathlon with distances higher than in an Olympic event. However, in this study supplementation and fluid intake were allowed and not controlled, which could have influenced on a better level of physical and metabolic fitness of the athletes compared to the results obtained in the current study.
Using a ratio proposed by the American College of Sports Medicine13, and corroborated by some authors in different populations14,15, the intensity of 70% of heart rate of reserve would be equivalent to 70% of O2max and such intensities would be reference of approximately 85% of maximum heart rate.
Having this ratio as a starting point, the only modality which would be slightly below the 70% of O2max, but would be still considered as intense exercise, would be the 10-km run, which presented mean of 83.6% of HRmax; the swimming at 85.2% of HRmax and cycling at 86.3% of HRmax reveal the capacity of these athletes in working at this intensity level for more than two hours.
In a similar level of exertion intensity, different individuals can be at distinct phases concerning the lactate kinetics, which is crucial to the determination of the duration and maintenance of the exercise quality16.
The blood lactate values during the event show that, despite the triathlon being a predominantly aerobic event, the glycolytic metabolism is fairly present in all its segments. It is known that the lactate accumulation profile is individual; however, the interpolation to a steady value guarantees an extension control of the training loads concerning the intensities of triathlon event. If the standard proposed by Sjödin and Jacobs2, in which the steady value of 4.0mmol/L identifies the anaerobic threshold (OBLA), is considered, the event would have to be performed with intensity above this value. Authors3-5 who adopt lactacidemia of 4.0mmol/L justify the choice of this steady concentration due to the majority of the subjects present, at this exercise intensity, the maximum balance between lactate production and removal.
As far as we are concerned, no study has ever reported lactate reference values during a triathlon event or the association of the lactacidemia by modality with the respective heart rate values and final performance of an event.
We believe that since swimming is the first modality of a triathlon, it contributes to the initial accumulation of lactate which reflects on the subsequent modalities. Although there seems to be a tendency to the lactate removal during running, the values in cycling were high, characterizing an intense production of metabolites which influence on performance.
It was concluded that the correlation between the two performance physiological variables used in this study, namely heart rate and lactate concentration, were closely related to the intensity of each of the segments-modalities of the Olympic triathlon. The use of these physiological variables enabled to discriminate and characterize the exertion intensity in all modalities, being higher during cycling (86.3% HRmax; 6.98mmol), followed by swimming (85.2% HRmax; 5.75mmol) and running (83.6% HRmax; 4.47mmol).
Considering these results, the need to differently adjust the intensity prescription of the training tasks according to each segment of the triathlon event is justified.
1. Lopes RF, Thiele E, Dourado AC, Osiecki R. Comportamento da frequência cardíaca e concentração de lactato sanguineo durante teste de esforço progressivo em triatletas. Jornal Brasileiro de Medicina (JBM) 2005; 88:54-60. [ Links ]
2. Sjödin B, Jacobs I. Onset of blood lactate accumulation and marathon running performance. Int J Sports Med 1981;2:23-36. [ Links ]
3. Heck H, Mader A, Hess G, Mucke S, Muller R, Hollmann W. Justification of the 4mmol/l lactate threshold. Int J Sports Med 1985;6:117-30. [ Links ]
4. Kinderman W, Simon G, Keul J. The significance of the aerobic-anaerobic transition for the determination of work load intensities during endurance training. Eur J Appl Physiol Occup Physiol 1979;42:25-34. [ Links ]
5. Mader A, Heck HA. Theory of the metabolic origin of anaerobic threshold. Int J Sports Med 1986;7:45-65. [ Links ]
6. Foster C, Fitzgerald DJ, Spatz P. Stability of the blood lactate-heart rate relationship in competitive athletes. Med Sci Sports Exerc 1999;31:578-82. [ Links ]
7. Jeukendrup A, Van Diemen A. Heart rate monitoring during training and competition em cyclists. J Sports Sci 1998;16:S.91-9. [ Links ]
8. Lucía A, Hoyos J, Pérez M, Chicharro J. Heart rate and performance parameters in elite cyclists: a longitudinal study. Med Sci Sports Exerc 2000; 32:1777-82. [ Links ]
9. Conconi F, Grazzi G, Casoni C. The conconi test: Methodology after 12 years os applications. Int J Sports Med 1996;17:509-19. [ Links ]
10. Reid SA, Speedy DB, Thompson JMD, Noakes TD, Mulligan G, Page T,et al. Study of hematological and biochemical parameters in runners completing a standard marathon. Clin J Sport Med 2004; 14:344-53. [ Links ]
11. Gobatto CA, Mendonça ER, Matsushigue KA. Respostas do lactato sanguíneo e da frequência cardíaca em duas diferentes provas do automobilismo. Rev Bras Med Esporte 2000; 6-1:29-34. [ Links ]
12. Rohde T, MacLean DA, Hartkopp A, Pedersen BK. The immune system and serum glutamine during a triathlon. Eur J Appl Physiol 1996;74:428-34. [ Links ]
13. ACSM's Guidelines for exercising Testing and Prescription. American College of Sports Medicine, 7th ed. 2006 [ Links ]
14. Osiecki R, Lopes RF, Oliveira S, Koppe PG, Santos F, Bittencourt L, et al. Relação entre o VO2máx, frequência cardíaca e frequência cardíaca de reserva em mulheres universitárias. Rev Bras Ci e Mov 2005;13(4): 161-167. [ Links ]
15. Swain DP, Parrott JA, Bennett AR, Branch JD, Dowling EA. Validation of a new method for estimating VO2máx based on VO2 reserve. Med Sci Sports Med 2004; 36:1421-6. [ Links ]
16. Mcardle WD, Katch FT, Katch Vl. Sports & Exercise Nutrition. Philadelphia, PA: Lippincott Williams & Wilkins; 1999. [ Links ]
Mailing address: All authors have declared there is not any potential conflict of
interests concerning this article.
Faculdade de Ciências do Desporto e Educação Física
Estádio Universitário Coimbra Pavilhão-III
3040-156 Coimbra, Portugal
All authors have declared there is not any potential conflict of interests concerning this article.