Acessibilidade / Reportar erro

Effects of the state and specificity of aerobic training on the %VO2max versus %HRmax ratio during cycling

Abstracts

OBJECTIVE: To determine the effects of the status and specificity of exercise training in the ratio between maximum oxygen consumption (%VO2max) and the percentage of maximal heart rate (%HRmax) during incremental exercise on a cycle ergometer. METHODS: Seven runners, 9 cyclists, 11 triathletes, and 12 sedentary individuals, all male and apparently healthy, underwent exhaustive incremental exercise on cycle ergometers. Linear regressions between %VO2max x %HRmax were determined for each individual. Based on these regressions, %HRmax was assessed corresponding to a determined %VO2max (50, 60, 70, 80, and 90%) from each participant. RESULTS: Significant differences were not found between the groups in %HRmax for each of the %VO2max assessed. Analyzing the volunteers as a single group, the average of the corresponding %HRmax to 50, 60, 70, 80, and 90% %VO2max were 67, 73, 80, 87, and 93%, respectively. CONCLUSION: The ratio between %VO2max and %HRmax in the groups assessed during incremental exercise on the bicycle is not dependent on the status and specificity of aerobic exercise training.

oxygen consumption; heart rate; exercise prescription; training status; cycling


OBJETIVO: Determinar os efeitos do estado e especificidade de treinamento aeróbio na relação entre o percentual do consumo máximo de oxigênio (%VO2max) e o percentual da frequência cardíaca máxima (%FCmax) durante o exercício incremental realizado no cicloergômetro. MÉTODOS: Sete corredores, 9 ciclistas, 11 triatletas e 12 sedentários, todos do sexo masculino e aparentemente saudáveis, foram submetidos a um teste incremental até a exaustão no cicloergômetro. Regressões lineares entre %VO2max e %FCmax foram determinadas para cada indivíduo. Com base nessas regressões, foram calculados %FCmax correspondentes a determinados %VO2max (50, 60, 70, 80 e 90%) de cada participante. RESULTADOS: Não foram encontradas diferenças significantes entre todos os grupos nos %FCmax para cada um dos %VO2max avaliados. Analisando-se os voluntários como um único grupo, as médias dos %FCmax correspondentes a 50, 60, 70, 80 e 90% %VO2max foram 67, 73, 80, 87, e 93%, respectivamente. CONCLUSÃO: Nos grupos analisados, a relação entre o %VO2max e %FCmax durante o exercício incremental no ciclismo não é dependente do estado e especificidade do treinamento aeróbio.

Consumo de oxigênio; freqüência cardíaca; prescrição do exercício; estado de treinamento; ciclismo


ORIGINAL ARTICLE

Effects of the state and specificity of aerobic training on the %VO2max versus %HRmax ratio during cycling

Fabrizio Caputo; Camila Coelho Greco; Benedito Sérgio Denadai

Rio Claro, SP - Brazil

Laboratório de Avaliação da Performance Humana - UNESP - Rio Claro

Correspondence Correspondece to Benedito Sérgio Denadai Av. 24 A, 1515 Cep 13506-900 - Rio Claro, SP, Brazil E-mail: bdenadai@rc.unesp.br

ABSTRACT

OBJECTIVE: To determine the effects of the status and specificity of exercise training in the ratio between maximum oxygen consumption (%VO2max) and the percentage of maximal heart rate (%HRmax) during incremental exercise on a cycle ergometer.

METHODS: Seven runners, 9 cyclists, 11 triathletes, and 12 sedentary individuals, all male and apparently healthy, underwent exhaustive incremental exercise on cycle ergometers. Linear regressions between %VO2max x %HRmax were determined for each individual. Based on these regressions, %HRmax was assessed corresponding to a determined %VO2max (50, 60, 70, 80, and 90%) from each participant.

RESULTS: Significant differences were not found between the groups in %HRmax for each of the %VO2max assessed. Analyzing the volunteers as a single group, the average of the corresponding %HRmax to 50, 60, 70, 80, and 90% %VO2max were 67, 73, 80, 87, and 93%, respectively.

CONCLUSION: The ratio between %VO2max and %HRmax in the groups assessed during incremental exercise on the bicycle is not dependent on the status and specificity of aerobic exercise training.

Key words: oxygen consumption, heart rate, exercise prescription, training status, cycling

A training program aiming at enhancing cardiac respiratory performance (maximum aerobic power) comprises 3 basic features: frequency (number of sessions per week), volume (duration), and exercise intensity. Duration and frequency are variables that are relatively easily monitored with consensus in the literature regarding their application. On the other hand, several ways exist to monitor exercise intensity 1-3, and a balance must be considered to regard these methods as valid, applicable, and practical. For the development of cardiorespiratory fitness in apparently healthy individuals, the regular practice of exercising (3 to 5 times a week) involving major muscle groups has been recommended, at an intensity of 60-80% of maximal oxygen consumption (VO2max) 1.

Many studies have determined that heart rate (HR) and oxygen consumption (VO2) are linearly related to submaximal exercise intensity 4. Based on this relation, linear regression between VO2max (%VO2max) percentages and maximum heart rate (%HRmax) have been proposed and can be useful for prescribing exercise intensity. The use of these equations enables the prescription of exercise intensity based on the %HRmax, instead of %VO2max, which demands complicated and expensive gas analysis.

Because of their facility, these regressions have been widely used and recommended, and their specificity is often ignored. The effort to achieve the determined goal may be extremely different from that expected. For example, Londeree and cols 5 verified that the exercise modality may influence the %VO2max x %HRmax ratio and found that the exercises performed in an upright position and with body weight support (running, skiing) had similar regressions. However, exercises performed without body weight support (cycling, rowing) using superior limbs (rowing and arm ergometer) may require specific equations to reduce the error on prediction of exercise intensity. Likewise, Swain and cols 6 verified that aerobic endurance (assessed by VO2max) may change the %VO2max x %HRmax ratio during running. In this study, individuals with greater aerobic endurance had higher %HRmax than those with lower endurance during submaximal exercise (40 — 80% VO2max) for a given %VO2max.

Another potential limitation in using the various equations found in the literature is their structure 6. The majority of these equations, used %HRmax as an independent variable (x-axis) in the linear regression 5,7. This is a questionable choice, because VO2 is clearly the determining factor of the heart rate response during exercise. Additionally, if %HRmax is chosen as an independent variable, the equation obtained cannot be used to predict %HRmax for a given %VO2max, because this procedure requires a transposition of the equation. Transposition of a linear regression does not result in the same values that would have been obtained if the dependent and independent variables were inverted.

Cycling is one of the most commonly used exercises for clinical evaluation of patients and for the development of cardiorespiratory endurance. In this type of exercise, the use of major muscle groups is associated with reduced impact in the joints. These aspects are important for obese individuals who need to enhance cardiorespiratory endurance and lose fat mass, and also for athletes who need to maintain aerobic endurance (runners and players of group sports), who may be temporarily unable to perform their specific function (run). To our knowledge, no studies exist that assess the %VO2max x %HRmax ratio during cycling in individuals with different degrees of aerobic endurance, using %VO2max as an independent variable. Thus, our objective was to determine the effects of the status and specificity of aerobic training on the %VO2max x %HRmax ratio during incremental exercise performed using a cycle ergometer. Knowledge of these ratios may be relevant for prescribing suitable exercise intensity for a certain population.

Methods

Seven runners (RUN) (25.8 ± 6.0 years old, 60.4 ± 4.1 kg, 172.1 ± 6.9 cm), 9 cyclists (CIC) (22.6 ± 2.1 years old, 62.8 ± 5.4 kg, 173.8 ± 5.9 cm), and 11 triathletes well trained in racing (TRI) (21.4 ± 4.1 years old; 66.2 ± 7.0 kg; 174.2 ± 8.4 cm), and 12 sedentary individuals (SED) (26.8 ± 4.1 years old, 74.9 ± 14.3 kg, 175.1 ± 5.1 cm) took part in the study. All individuals were male and apparently healthy. Athletes had at least 2 years of practice in the modality. Each volunteer was informed about the procedures and implications of the experiment, and gave their written consent. The protocol was approved by the ethics committee of the institution.

Subjects were instructed to come to the tests rested, fed, and hydrated, and to refrain from intense effort in the preceding 48 hours. Tests were performed in the same place and at the same hour of the day (± 2PM), with room temperature controlled at 21-22ºC. Cycling tests were performed on a mechanical ergometer bicycle (Monark), with speed maintained at 70 rpm throughout the test. Cardiorespiratory variables (VO2, VCO2, VE, and HR) were assessed using a gas analyzer (Cosmed K4b2, Rome, Italy), collection data at each breath, and then transformed for an average of 20s. Heart rate was monitored through a heart rate monitor (Polar, Kempele, Finland) linked to the gas analyzer. This analyzer was previously validated at several exercise intensities 8. Before each test, the analysis systems of O2 and CO2 were calibrated using room air and a gas with known concentrations of O2 and CO2, whereas the bi-directional turbine (flow meter) was calibrated using a 3-L syringe (Cosmed K4b2, Rome, Italy).

The continuous progressive test had a 105 W initial load for cyclists and triathletes and 70 W for the remaining individuals, and 35 W increase each 3 minutes until voluntary fatigue, or when the subject could no longer maintain > 65 rpm. At the end of each stage, 25 µl of blood from the earlobe was collected to determine blood lactate concentration (YSL 2300 STAT, Ohio, USA). Lactate concentration obtained at the end of the progressive test was considered the lactate peak (peak[LAC]). The highest VO2 and HR obtained during 20s were considered the VO2max and HRmax, respectively. All subjects met at least 2 to 3 criteria for VO2max: 1) respiratory exchange ratio (R) > 1.1; 2) lactate concentration > 8 mM, and; 3) HRmax at least equal to 90% of the maximum predicted for the age 9.

VO2 and heart rate obtained in the final 20 seconds of each load were expressed as the percentage of their maximum. Linear regressions were performed for each individual using the pairs of points of the end of each stage and of their maximum (100%), using %VO2max as an independent variable. Through individual linear regression, HRmax percentage corresponding to 50%, 60%, 70%, 80%, and 90% of VO2max were determined for each individual.

All data were expressed as mean ± SD. VO2max and HRmax values, R and lactate were assessed using one-way variance analysis together with Scheffé's test. Comparison between the groups of %HRmax values corresponding to %VO2max was performed using the Kruskal-Wallis' test. In all tests, a P <0.05 significance level was adopted.

Results

Table I presents maximum VO2, HR, R, and blood lactate values, obtained at the end of the incremental test performed on the cycle ergometer. Cyclists had VO2max values significantly greater compared with those in the other groups (P < 0.05). The runners and triathletes had no differences between each other (P=0.99). As expected, sedentary individuals had the lowest VO2max values (P<0.0001). HRmax of cyclists and sedentary individuals were similar (P = 0.55), however significantly greater in the groups of runners and triathletes (P < 0.04) that were also similar to each other (P = 0.99). Differences for peak[LAC] and R were not observed among the groups assessed (P > 0.23).

HRmax percentages obtained in the 4 groups of individuals in the different VO2max percentage are in Table II. No significant differences existed among the groups regarding %HRmax for each %VO2max assessed (P > 0.58). Means (± SD) of the linear regressions of groups were sedentary individuals - %HRmax = (0.68 ± 0.11)%VO2max + (31.9 ± 11.0), with r2 = 0.98 ± 0.1; triathletes - %HRmax = (0.65 ± 0.08)%VO2max + (35.3± 8.3), with r2 = 0.97 ± 0.2; cyclists - %HRmax = (0.66 ± 0.04) %VO2max + (34.3 ± 3.3), with r2 = 0.97 ± 0.1; runners - %HRmax = (0.70 ± 0.07)%VO2max + (31.3 ± 7.5), with r2 = 0.97 ± 0.1. Figure 1 demonstrates the mean linear regressions of the 39 individuals in the study.


Discussion

This study is the first to assess the effects of the status and specificity of aerobic training on the %VO2max x %HRmax ratio during incremental exercise during cycling. Contrary to that previously reported by Swain and cols 6 during exercise performed in running, in our study we have verified that the %VO2max x %HRmax ratio is independent of aerobic training status or specificity.

VO2max values of our individuals are similar to those values reported in the literature for the profile of individuals assessed in this study 10-12. Observing VO2max values in our athletes, although we did not interfere with the training, we may assume that they have gone through the adaptations of a long-term aerobic training11. As expected, cyclists had the highest VO2max values. On the other hand, it is important to point out that the great transference of aerobic power (VO2max) was demonstrated by runners, once their values were similar to those of the triathletes, and greatly superior to those of the sedentary individuals.

The %VO2max and %HRmax ratio has been widely investigated, with other studies assessing the effects of the type of exercise 5, sex 6, cardiovascular disease 13, obesity 14, and level of aerobic endurance 6. Swain and cols 6 stress that the majority of these studies used %HRmax as an independent variable to determine linear regression, which may therefore increase, mispredicting exercise intensity. In our study, we opted to use %VO2max as an independent variable, enabling %HRmax prediction aiming at prescribing exercise intensity.

The influence of the status and specificity of aerobic training in predictive %HRmax for all %VO2max (50 to 90) was not observed in this study. These data are different from those obtained by Swain and cols 6, who found a small (2%), however, significant, influence of aerobic endurance on the %VO2max x %HRmax ratio. The individuals with greater endurance had a greater %HRmax than those with lower endurance for a given %VO2max. In our study, the difference in aerobic endurance level may be considered greater (VO2max - CIC = 67 mL.kg.min-1 vs. SED = 38 mL.kg.min 1) than the difference (VO2max — greater endurance = 59 mL.kg.min-1 vs. lower endurance = 41 mL.kg.min-1) reported by Swain and cols 6, and this aspect probably cannot explain the differences between the studies. A possible explanation would be that the effect of aerobic endurance in the %VO2max x %HRmax ratio, may depend on the type of exercise assessed, because in the Swain and cols' study6 running was on a treadmill, and in the present study a cycle ergometer was used. Several studies have verified that the physiologic responses to exercise (maximum and submaximum) may depend on the interaction between the type of exercise (running x cycling) and the status and specificity of training 15. In part confirming this hypothesis, Londeree and cols 5 verified that the %VO2max x %HRmax ratio may be different between weight-bearing exercises (running) and nonweight-bearing exercises (cycling).

Use of linear regression data (VO2 and HR) obtained during incremental testing for the prediction of %HRmax may introduce at least 2 biases. The first, is that the ratio between %VO2max x %HRmax is not strictly linear, particularly in high effort intensities (> 90%VO2max). Although the addition of a least square in the regression analysis could have been more appropriate, this procedure increases the prediction error (7%) in moderate effort intensity 5. Because most %HRmax prediction is performed at mild to moderate intensity (40 — 80%VO2max), linear regression seems to be more appropriate. Anyway, each subject (regardless of the group) had a determining coefficient between %VO2max and %HRmax above 0.95, and the whole group had a 0.97 mean value. Based on the Standard Estimate Error (SEE) of the regressions of each subject, a 3 to 4% error may be expected in the %HRmax prediction. The second aspect to be considered is the presence or absence of stable phases in the VO2 values and heart rate during incremental testing. To minimize this problem, we used a protocol with 3-min stages, using only mean values of the 20 final seconds of each load to derive the equation. Data from the literature demonstrate these duration approaches to the values obtained in exercise of constant load performed for a greater period 16. Still in this regard, the %VO2max x %HRmax ratio obtained during incremental exercises must be observed, and it may vary during constant load exercise. In this type of exercise, both the cardiac frequency, because of the termoregulator aspects (cardiovascular deviation) 17, and VO2, due to the presence of a slow component in the exercises above the lactate threshold, that is, heavy to severe exercise 18, may not be stable over time.

Finally, special attention must be paid to the possible effects of cycling on the HRmax values. Although no difference exists in age in the groups, HRmax was significantly higher in cyclists than in runners or triathletes. Although we did not compare HRmax between running and cycling in our study, several studies have found significantly higher values in running than in cycling in sedentary 15, and active 5 individuals, and in endurance runners 15,19. In cyclists, HRmax has not been different between running and cycling 15,19. Thus, the use of certain regressions, eg, HRmax = 220 — age, or HRmax = 208 — 0.7 x age 20 to estimate HRmax indirectly in the cycle ergometer for individuals who are not cyclists should be carefully done. Using these equations potentially increases %HRmax prediction error, and therefore, the exercise intensity. Thus, a high-accuracy level is recommended, and if possible (clinical conditions, time available, and equipment), HRmax should be directly determined for each individual.

Based on these results, we conclude that for assessed groups, %VO2max and %HRmax ratio during incremental exercise on the bicycle is not dependent on the status and specificity of the aerobic training. However, further studies are necessary to assess this ratio in different populations with different characteristics (age, sex, sports modality) and/or who take medication that may interfere with the cardiovascular and metabolic response during exercise.

References

Received for publication: 03/11/2004

Accepted for publication: 06/04/2004

  • 1. American College of Sports Medicine. ACSM's Guidelines for Exercise Testing and Prescription (6th ed.). Baltimore: Williams & Wilkins, 2000.
  • 2. Londeree BR. Effect of training on lactate/ventilatory thresholds: a meta-analysis. Med Sci Sports Exerc. 1997;29: 837-43.
  • 3. Stoudemire NM, Wideman L, Pass KA et al. The validity of regulating blood lactate concentration during running by ratings of perceived exertion. Med Sci Sports Exerc. 1996;28:490-5.
  • 4. Achten J, Jeukendrup AE. Heart rate monitoring: applications and limitations. Sports Med. 2003;33:517-38.
  • 5. Londeree BR, Thomas TR, Ziogas G, Smith TD, Zhang Q. %VO2max versus %HRmax regressions for six modes of exercise. Med Sci Sports Exerc. 1995;27:458-61.
  • 6. Swain DP, Abernathy KS, Smith CS, Lee SJ, Bunn SA. Target heart rates for the development of cardiorespiratory fitness. Med Sci Sports Exerc. 1994;26:112-6.
  • 7. Franklin BA, Hodgson J, Buskirk ER. Relationship between percent maximal O2 uptake and percent maximal heart rate in women. Res Q Exerc Sport. 1980;51:616-24.
  • 8. Doyon KH, Perrey S, Abe D, Hughson RL. Field testing of VO2peak in cross-country skiers with portable breath-by-breath system. Can J Appl Physiol. 2001;26:1-11.
  • 9. Taylor HL, Buskirk ER, Henschel A. Maximal oxygen intake as an objective measure of cardiorespiratory performance. J Appl Physiol. 1955;8:73-80.
  • 10. Billat VL, Faina M, Sardella F et al. A comparison of time to exhaustion at VO2max in elite cyclists, kayak paddlers, swimmers and runners. Ergonomics. 1996; 39:267-77.
  • 11. Jeukendrup AE, Craig NP, Hawley JA. The bioenergetics of world class cycling. J Sci Med Sport. 2000;3:414-33.
  • 12. Boussana A, Matecki S, Galy O et al. The effect of exercise modality on respiratory muscle performance in triathletes. Med Sci Sports Exerc. 2001;33:2036-43.
  • 13. Brawner CA, Keteyian SJ, Ehrman JK. The relationship of heart rate reserve to VO2 reserve in patients with heart disease. Med Sci Sports Exerc. 2002;34:418-22.
  • 14. Miller WC, Wallace JP, Eggert KE. Predicting max HR and the HR-VO2 relationship for exercise prescription in obesity. Med Sci Sports Exerc. 1993;25:1077-81.
  • 15. Caputo F, Stella SG, Mello MT, Denadai BS. Indexes of power and aerobic capacity obtained in cycle ergometry and treadmill running: Comparisons between sedentary, runners, cyclists and triathletes. Rev Bras Med Esporte. 2003;9:231-7.
  • 16. Fardy PS, Hellerstein HK. A comparison of continuous and intermittent progressive multistage exercise testing. Med Sci Sports. 1978;10:7-12.
  • 17. Coyle EF, González-Alonso J. Cardiovascular drift during prolonged exercise: new perspectives. Exerc Sports Sci Rev. 2001;29:88-92.
  • 18. Gaesser GA, Poole DC. The slow component of oxygen uptake kinetics in humans Exerc Sports Sci Rev. 1996;24:35-70.
  • 19. Rice AJ, Scroop GC, Thornton AT et al. Arterial hypoxaemia in endurance athletes is greater during running than cycling. Resp Physiol. 2000;123:235-46.
  • 20. Tanaka H, Monahan KD, Seals DR. Age-predicted maximal heart rate revisited. J Am Coll Cardiol. 2001;37:153-6.
  • Correspondece to

    Benedito Sérgio Denadai
    Av. 24 A, 1515
    Cep 13506-900 - Rio Claro, SP, Brazil
    E-mail:
  • Publication Dates

    • Publication in this collection
      14 Feb 2005
    • Date of issue
      Jan 2005

    History

    • Accepted
      04 June 2004
    • Received
      11 Mar 2004
    Sociedade Brasileira de Cardiologia - SBC Avenida Marechal Câmara, 160, sala: 330, Centro, CEP: 20020-907, (21) 3478-2700 - Rio de Janeiro - RJ - Brazil, Fax: +55 21 3478-2770 - São Paulo - SP - Brazil
    E-mail: revista@cardiol.br