Advertisement
Browse Subject Areas
?

Click through the PLOS taxonomy to find articles in your field.

For more information about PLOS Subject Areas, click here.

  • Loading metrics

Open Access

Peer-reviewed

Research Article

The Correlation between Running Economy and Maximal Oxygen Uptake: Cross-Sectional and Longitudinal Relationships in Highly Trained Distance Runners

  • Andrew J. Shaw ,

    a.shaw@lboro.ac.uk

    Affiliations English Institute of Sport, Loughborough University, Loughborough, United Kingdom, School of Sport, Exercise and Health Sciences, Loughborough University, Loughborough, United Kingdom

  • Stephen A. Ingham,

    Affiliation English Institute of Sport, Loughborough University, Loughborough, United Kingdom

  • Greg Atkinson,

    Affiliation Health and Social Care Institute, Teesside University, Middlesbrough, United Kingdom

  • Jonathan P. Folland

    Affiliation School of Sport, Exercise and Health Sciences, Loughborough University, Loughborough, United Kingdom

Abstract

A positive relationship between running economy and maximal oxygen uptake (V̇O2max) has been postulated in trained athletes, but previous evidence is equivocal and could have been confounded by statistical artefacts. Whether this relationship is preserved in response to running training (changes in running economy and V̇O2max) has yet to be explored. This study examined the relationships of (i) running economy and V̇O2max between runners, and (ii) the changes in running economy and V̇O2max that occur within runners in response to habitual training. 168 trained distance runners (males, n = 98, V̇O2max 73.0 ± 6.3 mL∙kg-1∙min-1; females, n = 70, V̇O2max 65.2 ± 5.9 mL kg-1∙min-1) performed a discontinuous submaximal running test to determine running economy (kcal∙km-1). A continuous incremental treadmill running test to volitional exhaustion was used to determine V̇O2max 54 participants (males, n = 27; females, n = 27) also completed at least one follow up assessment. Partial correlation analysis revealed small positive relationships between running economy and V̇O2max (males r = 0.26, females r = 0.25; P<0.006), in addition to moderate positive relationships between the changes in running economy and V̇O2max in response to habitual training (r = 0.35; P<0.001). In conclusion, the current investigation demonstrates that only a small to moderate relationship exists between running economy and V̇O2max in highly trained distance runners. With >85% of the variance in these parameters unexplained by this relationship, these findings reaffirm that running economy and V̇O2max are primarily determined independently.

Citation: Shaw AJ, Ingham SA, Atkinson G, Folland JP (2015) The Correlation between Running Economy and Maximal Oxygen Uptake: Cross-Sectional and Longitudinal Relationships in Highly Trained Distance Runners. PLoS ONE 10(4): e0123101. https://doi.org/10.1371/journal.pone.0123101

Academic Editor: Oyvind Sandbakk, Norwegian University of Science and Technology, NORWAY

Received: October 31, 2014; Accepted: February 27, 2015; Published: April 7, 2015

This is an open access article, free of all copyright, and may be freely reproduced, distributed, transmitted, modified, built upon, or otherwise used by anyone for any lawful purpose. The work is made available under the Creative Commons CC0 public domain dedication

Data Availability: All relevant data are within the paper.

Funding: These authors have no support or funding to report.

Competing interests: The authors have declared that no competing interests exist.

Introduction

Running economy (RE) and maximal oxygen uptake (V̇O2max) are two of the primary determinants of endurance running performance [14]. The combination of RE and V̇O2max, defined as the velocity at V̇O2max (vV̇O2max), has been found to account for ~94% of the inter-individual variance in running performance over 16.1 km [5]. Consequently, exceptional values of both RE and V̇O2max are considered requirements for success in elite endurance competitions, and endurance runners strive to improve both parameters through training in order to maximise performance. As the margin of success is extremely small in elite distance running, subtle enhancements in either parameter could result in substantial performance gains. Therefore, understanding the relationship of RE and V̇O2max both between and within individuals is necessary to understand and optimise performance.

Within cohorts of trained [6,7] and elite [8] distance runners, it has been suggested that a superior RE, quantified as the submaximal oxygen uptake, is associated with a lower V̇O2max. These findings have been used to postulate that superior economy compensates for a lower V̇O2max in some individual to achieve a similar performance level [3,8,9]. However, these investigations have often been restricted to small sample sizes (<25 participants [3,6,8]), and the validity of their statistical techniques has been questioned due to the expression both variables relative to body mass (i.e. mL∙kg-1∙min-1); creating a common divisor that is known to produce spurious correlations [10]. Partial correlation analysis would provide an appropriate method to account for the influence of body mass on both variables whilst avoiding statistical artefacts, however this method has yet to be used to examine the relationship between RE and V̇O2max. Furthermore, studies have solely employed oxygen cost (OC) as a measure of RE, rather than the more valid and comprehensive measurement of energy cost (EC; [11]). Thus, whether a genuine association exists between RE and V̇O2max remains unclear from the limited cross-sectional observations to date.

Moreover, the concurrent alterations in RE and V̇O2max that occur within athletes over time with training might further reveal if there is an inherent association between these variables, whilst also informing the optimisation of both variables and thus performance. Previous investigations in well trained athletes have noted enhancements in cycling efficiency following short-term, intensive endurance training, but with no change in V̇O2max evident [9,12,13]. In contrast, a recent investigation reported an association between individual changes in cycling efficiency and V̇O2max in response to endurance training and across a competitive season; despite no change in mean group V̇O2max [14]. These preliminary findings highlight the significance of this relationship for elite endurance athletes, as enhancements in either RE or V̇O2max might only be achievable at the expense of the other variable. However, this previous investigation was limited to measurements of gross efficiency, with no data presented on movement economy. Moreover, analysis of this longitudinal relationship was restricted to observations within small cohorts of athletes, and with responses to run training yet to be explored.

The primary aim of the current investigation was to explore the cross-sectional relationship between V̇O2max and RE, quantified as EC (OC data are also presented for comparative purposes), within a large cohort of highly trained distance runners. The secondary aim was to examine the longitudinal relationship between the changes in V̇O2max and RE occurring within athletes in response to endurance training.

Materials and Methods

Overview

The cross-sectional investigation involved retrospective analysis of data from 168 healthy endurance trained athletes with competitive distances ranging from 800m to the marathon (males, n = 98; females, n = 70; Table 1), who undertook testing and monitoring as part of their sport science support from the English Institute of Sport. The following tests were performed after written informed consent was obtained as a part of sports science support provision, with procedures approved by the Internal Review Board of English Institute of Sport. Of the participants assessed, 97 (males, n = 57; females, n = 40) were classed as middle distance runners, defined by a primary competitive distance≤3000m [15], with 71 classed as long distance runners (males, n = 41; females, n = 30). During the season following their final visit, athlete’s best performance times in their primary competitive distance were 89.1±6.1% and 91.2±4.4% of the current British record for males and females, respectively. Data were collected from two laboratories, with all tests conducted as part of athlete support services between November 2004 and April 2013. Participants provided informed consent prior to physiological assessments, in addition to an athlete agreement providing permission for the use of their data in anonymous retrospective analysis. During each visit to the laboratory, participants completed first submaximal and then maximal running assessments (detailed below). Participants wore appropriate clothing (shorts and a vest or t-shirt) and racing shoes, and laboratory conditions were similar throughout all running assessments (temperature 20.6±1.9°C, relative humidity 45.9±9.8%). As differences in RE and V̇O2max have been noted between sexes [1618], males and females were analysed separately for cross sectional analyses.

thumbnail
Download:
Table 1. Physiological and anthropometrical characteristics of athletes within the cross sectional and longitudinal investigations.

https://doi.org/10.1371/journal.pone.0123101.t001

The longitudinal aspect of the study was based on 54 participants (males, n = 27; females, n = 27) from amongst the larger cohort of 168 runners, that had completed at least one follow up assessment, with a median trial separation of 203 days (range: 37–2567 days) in order to assess within-athlete changes in both RE and V̇O2max over time. The number of repeat assessments in the longitudinal analysis varied between participants, with a median of 3 visits per athlete (range: 2–10 visits), summating to 182 assessments in total. No evidence is currently available regarding sex differences in the concurrent alterations in RE and V̇O2max in response to habitual endurance training, thus data for males and females were combined for longitudinal analysis.

Protocol

Submaximal running assessments.

Following a warm-up (~10 min at 10–12 km∙h-1), participants completed a discontinuous submaximal incremental test consisting of six to nine stages of 3 minutes continuous running, with increments of 1 km∙h-1 on a motorised treadmill of known belt speeds (HP cosmos Saturn, Traunstein, Germany) interspersed by 30 s rest periods for blood sampling. As the speeds assessed were typically between 10.5 km∙h-1 and 18 km∙h-1, treadmill gradient was maintained at 1% throughout submaximal assessments in order to reflect the energetic cost of outdoor running [19]. This protocol has been shown to reliable measures of running economy when quantified as both EC and OC (typical error ~3%; [20]). Moreover, the controlled laboratory environment enabled assessments of EC whilst avoiding the confounding influence of air resistance that is evident during outdoor running as speed increases [21]. Recent performance times of participants were used to determine an appropriate starting speed to provide ~4 speeds prior to lactate turnpoint (LTP). Increments were continued until blood lactate concentration had risen exponentially, typically defined as an increase in blood lactate of ~2 mmol∙L-1 from the previous stage. HR (s610i, Polar, Finland) and pulmonary gas exchange (detailed below) were monitored throughout the test.

Maximal running assessments.

V̇O2max was determined by a continuous incremental treadmill running ramp test to volitional exhaustion. After a warm-up, participants initially ran at a speed 2 km∙h-1 below the final speed of the submaximal test and at a 1% gradient. Each minute, the incline was increased by 1% until volitional exhaustion. The test duration was typically 6–8 minutes.

Measurements

Anthropometry.

Prior to exercise on laboratory visits, body mass was measured using digital scales (Seca 700, Seca, Hamburg, Germany) to the nearest 0.1 kg. Stature was recorded to the nearest 1 cm using a stadiometer (Harpenden Stadiometer, Holtain Limited, UK).

Pulmonary gas exchange.

Breath-by-breath gas exchange data was quantified via an automated open circuit metabolic cart (Oxycon Pro, Carefusion, San Diego, USA). Participants breathed through a low dead-space mask, with air sampled at 60 mL∙min-1. Prior to each test, two point calibrations of both gas sensors were completed, using a known gas mixture (16% O2, 5% CO2) and ambient air. Ventilatory volume was calibrated using a 3 L (±0.4%) syringe. This system has previously been shown to be a valid apparatus for the determination of oxygen consumption (V̇O2) and carbon dioxide production (V̇CO2) at both low and maximal exercise intensities [22]. As previous data from our laboratory has demonstrated a steady state V̇O2, and V̇CO2 is achieved within the first 2 minutes of each stage for highly trained endurance runners [20], mean values from breathe-by-breathe measures over the final 60 seconds of each stage were used to quantify V̇O2, carbon dioxide production V̇CO2, and RER.

Blood lactate.

A 20μL capillary blood sample was taken from the earlobe for analysis of blood lactate ([La]b) (Biosen C-line, EKF diagnostics, Germany). The LTP was identified via the modified Dmax method [23]. LTP was quantified as the point on the third order polynomial curve fitted to the speed-lactate relationship that generated the greatest perpendicular distance to the straight line formed between the stage proceeding an increase in [La]b greater than 0.4 mmol.L-1 (lactate threshold) and the final stage. The four stages prior to LTP were identified for each participant, with an average of these four stages used to quantify OC and EC.

Calculation of running economy.

V̇O2 and V̇CO2 during the final minute of each submaximal stage were used to calculate EC. Updated nonprotein respiratory quotient equations [24] were used to estimate substrate utilisation (g∙min-1) during the monitored period. The energy derived from each substrate was then calculated by multiplying fat and carbohydrate usage by 9.75 kcal and 4.07 kcal, respectively, reflecting the mean energy content of the metabolised substrates during moderate to high intensity exercise [25]. EC was quantified as the sum of these values, expressed in kcal∙km-1. V̇O2 during the final minute of each submaximal stage was used to determine oxygen cost (OC) in mL∙km-1 to enable comparisons to previous investigations.

Statistical analyses.

Data are presented as mean±SD for all dependant variables. Data analysis was conducted using SPSS for windows (v21; IBM Corporation, Armonk, NY). When an individual visited the laboratory for repeated assessments, an average of the assessments was calculated and used for the cross sectional analysis. Pearsons product-moment coefficients were calculated to assess the relationship between body mass and EC, OC and V̇O2max. As body mass was strongly related to both RE measures (EC, OC) and V̇O2max, partial correlations controlling for body mass, and associated 95% confidence intervals (CI), were used to assess the relationship between absolute V̇O2max and both EC and OC. This method removes the influence of body mass on both RE and V̇O2max whilst avoiding spurious correlations created by correlating two variables with a common divisor [26]. For graphical display of these relationships, values of EC and V̇O2max adjusted for body mass for each individual were calculated based on individual residuals. This involved summating the individual’s residual, in comparison to the cohort relationship with body mass (e.g. EC vs body mass), with the group mean for that variable [27]. For the longitudinal analysis, in order to assess any relationships between the changes over time in absolute V̇O2max and the changes in both EC and OC over repeat visits, partial correlation coefficients were calculated using ANCOVA [28]; providing a comprehensive model that accounts variations in both body mass and the number of visits per athlete. Cohen's d effect size descriptors (trivial 0.0–0.1, small 0.1–0.3, moderate 0.3–0.5, large 0.5–0.7, very large 0.7–0.9, nearly perfect 0.9–1, perfect 1) were used to infer correlation magnitude [29]. Significance was accepted at P≤0.05.

Results

Participant Characteristics

Participant characteristics are shown in Table 1. The well trained status of the participants was emphasised by the high V̇O2max and vLTP values for both males and females.

Cross-sectional analysis

Partial correlation analysis controlling for body mass, revealed small positive relationships between EC and V̇O2max (males r = 0.26, CI 0.07–0.44, P = 0.009; females r = 0.25, CI 0.02–0.46, P = 0.036; Fig 1), and a moderate positive relationship between OC and V̇O2max (males r = 0.33, CI 0.14–0.50, P = 0.001; females r = 0.33, CI 0.10–0.52, P = 0.006).

thumbnail
Download:
Fig 1. Scatter plot of energy cost (Kcal∙km-1) adjusted for body mass (BM) vs V̇O2max (L∙min-1) adjusted for BM for both females (A; n = 70; r = 0.25; P = 0.036) and males (B; n = 98; r = 0.26; P = 0.009) within the cross-sectional analysis.

https://doi.org/10.1371/journal.pone.0123101.g001

Longitudinal analysis

Partial correlation analysis from ANCOVA revealed moderate positive relationships between the changes in EC and V̇O2max over time (r = 0.35; CI 0.19–0.49, P < 0.001; Fig 2), and changes in OC and V̇O2max over time (r = 0.44; CI 0.29–0.57, P < 0.001).

thumbnail
Download:
Fig 2. Scatter plot of the changes over time in energy cost (Kcal∙km-1) adjusted for body mass (BM) vs the changes over time in V̇O2max (L∙min-1) adjusted for BM (r = 0.35; P < 0.001) within the longitudinal analysis.

https://doi.org/10.1371/journal.pone.0123101.g002

Discussion

The present investigation explored the cross-sectional and longitudinal relationships between RE and V̇O2max in a large cohort of highly trained distance runners. The major contribution of this study to the field is that only a small to moderate association exists between RE and V̇O2max (R2 ~ 12%) when body mass is appropriately accounted for. With >85% of the variance in these parameters unexplained by this relationship, these findings reaffirm that RE and V̇O2max are primarily determined independently.

Cross-sectional analysis revealed a small positive between-participant relationships between V̇O2max and the metabolic cost of running, when quantified as both EC (r ~ 0.25) and OC (r ~ 0.33). These results support the findings of Pate et al. [7], who reported a similar relationship (r = 0.29) between submaximal V̇O2 and V̇O2max in a similarly large cohort of habitual distance runners. Conversely, a stronger, moderate positive relationship has been reported between submaximal V̇O2 and V̇O2max in smaller cohorts of elite distance runners (r = 0.59; [8]) and physically active individuals (r = 0.48; [30]). However, all aforementioned investigations are confounded by statistical artefacts that arise when correlating two variables with common divisors [10,26], and thus should be regarded with caution. Within the current study, spurious correlations between RE and V̇O2max were avoided by removing the influence of body mass with partial correlations, which enabled the true relationship between these variables to be examined. As a lower metabolic cost is reflective of a more economical runner, our findings confirm the existence of a small inverse association between RE and V̇O2max in endurance runners.

The longitudinal analysis of the relationship between the changes in RE and the changes in V̇O2max within participants in response to training has not previously been documented. Supporting the findings from our cross sectional analysis, a moderate positive relationship (r = 0.35) was observed between the changes in EC and V̇O2max over repeated assessments. Moreover, these findings support recent observations from competitive road cyclists that highlighted a similar moderate relationship (r = 0.44) between changes in gross efficiency and V̇O2max across a training season [14].

It has been postulated that variations in lipid oxidation rates between individuals might, in part, explain the relationship between OC and V̇O2max that some previous studies have documented; with a higher V̇O2max facilitating greater lipid oxidation and consequently a greater OC during sub-maximal exercise [7]. Whilst OC may be sensitive to lipid oxidation, the calculation of EC includes the RER and thus is insensitive to differences in substrate metabolism. The influence of substrate metabolism could conceivably explain the marginally stronger relationship observed between OC and V̇O2max, than EC and V̇O2max, in both the cross sectional (r ~ 0.33 vs r ~ 0.25) and longitudinal observations (r = 0.44 vs r = 0.35). More importantly, a positive relationship was documented between EC and V̇O2max that is clearly independent of variations in lipid metabolism.

The mechanisms that underpin the small relationship between EC and V̇O2max remain unclear. It has been argued that for athletes of a similar, high performance level, there would be an inevitable relationship between EC and V̇O2max in order to produce a similar velocity at V̇O2max [31]. However, we have found no evidence for this possibility, despite all the participants in this study being highly trained and high performing runners, perhaps in part because of the variable performance ability of the athletes. It is also possible that less economical runners recruit a larger muscle mass (braking, oscillation etc.) and it is conceivable that this could contribute to a higher V̇O2max. However there is considerable evidence that V̇O2max during whole body exercise such as running is largely dependent on oxygen delivery rather than utilisation [32], which might question this explanation. Thus, further investigation would be required to identify the factors driving the interdependence of EC and V̇O2max.

Though reaching statistical significance, the association between RE and V̇O2max was small. The current study found only ~ 7% (between-participant cross sectional data) and 12% (within-participant longitudinal data) of the variance in RE was explained by V̇O2max. This small association likely reflects the distinct nature of these variables and their physiological determinants. V̇O2max is known to be determined by factors such as cardiac output [33], total haemoglobin mass [34], and mitochondrial capacity [1]. Conversely, RE is thought to be closely associated to multiple biomechanical and anthropometrical factors, including effective storage and re-utilisation of elastic energy [35,36], vertical oscillation [37] and ground contact time [38]. As there are few common determinants of both RE and V̇O2max, adaptations that lead to enhancements in one of these variables are unlikely to directly influence in the opposing variable.

In conclusion, the current investigation demonstrates that only a small to moderate relationship exists between running economy and V̇O2max in highly trained distance runners. With >85% of the variance in these parameters unexplained by this relationship, these findings reaffirm that running economy and V̇O2max are primarily determined independently.

Acknowledgments

The authors would like to thank Dr Barry Fudge, Dr Jamie Pringle, Dr Charles Pedlar and Kate Spilsbury for their time and efforts collecting data on behalf of the English Institute of Sport that enabled this retrospective analysis, in addition to David Green for his time and assistance during data collation.

Author Contributions

Conceived and designed the experiments: AJS JPF SAI. Performed the experiments: AJS JPF SAI. Analyzed the data: AJS JPF SAI GA. Contributed reagents/materials/analysis tools: AJS JPF SAI GA. Wrote the paper: AJS JPF SAI GA.

References

  1. 1. Di Prampero P (2003) Factors limiting maximal performance in humans. Eur J Appl Physiol 90: 420–429. pmid:12910345
  2. 2. Ingham S, Whyte G, Pedlar C, Bailey D, Dunman N, Nevill A (2008) Determinants of 800-m and 1500-m running performance using allometric models. Med Sci Sports Exerc 40: 345–350. pmid:18202566
  3. 3. Lucía A, Hoyos J, Pérez M, Santalla A, Chicharro J (2002) Inverse relationship between VO2max and economy/efficiency in world-class cyclists. Med Sci Sports Exerc 34: 2079–2084. pmid:12471319
  4. 4. Joyner MJ (1991) Modeling: optimal marathon performance on the basis of physiological factors. J Appl Physiol 70: 683–687. pmid:2022559
  5. 5. McLaughlin JE, Howley ET, Bassett DR, Thompson DL, Fitzhugh EC (2010) Test of the classic model for predicting endurance running performance. Med Sci Sports Exerc 42: 991–997. pmid:19997010
  6. 6. Fletcher JR, Esau SP, Macintosh BR (2009) Economy of running: beyond the measurement of oxygen uptake. J Appl Physiol 107: 1918–1922. pmid:19833811
  7. 7. Pate R, Macera C, Bailey S, Bartoli W, Powell K (1992) Physiological, anthropometric, and training correlates of running economy. Med Sci Sports Exerc 24: 1128–1133. pmid:1435160
  8. 8. Morgan DW, Daniels JT (1994) Relationship between VO2max and the aerobic demand of running in elite distance runners. Int J Sports Med 15: 426–429. pmid:8002123
  9. 9. Santalla A, Naranjo J, Terrados N (2009) Muscle efficiency improves over time in world-class cyclists. Med Sci Sports Exerc 41: 1096–1101. pmid:19346977
  10. 10. Atkinson G, Davison R, Passfield L, Nevill A (2003) Could the correlation between maximal oxygen uptake and “economy” be spurious? Med Sci Sports Exerc 35: 1242–1243. pmid:12840650
  11. 11. Shaw AJ, Ingham SA, Folland JP (2014) The valid measurement of running economy in runners. Med Sci Sports Exerc 46: 1968–1973. pmid:24561819
  12. 12. Hopker J, Coleman D, Passfield L (2009) Changes in cycling efficiency during a competitive season. Med Sci Sports Exerc 41: 912–919. pmid:19276841
  13. 13. Iaia F, Hellsten Y, Nielsen J, Fernstrom M, Sahlim K, Bangsbo J (2009) Four weeks of speed endurance training reduces energy expenditure during exercise and maintains muscle oxidative capacity despite a reduction in training volume. J Appl Physiol 106: 73–80. pmid:18845781
  14. 14. Hopker J, Coleman D, Jobson S, Passfield L (2012) Inverse Relationship between V˙ O2max and Gross Efficiency. Int J Sports Med 33: 789–794. pmid:22562732
  15. 15. Brandon LJ (1995) Physiological factors associated with middle distance running performance. Sport Med 19: 268–277. pmid:7604199
  16. 16. Daniels J, Daniels N (1992) Running economy of elite male and elite female runners. Med Sci Sports Exerc 24: 483–489. pmid:1560747
  17. 17. Helgerud J, Støren O, Hoff J (2010) Are there differences in running economy at different velocities for well-trained distance runners? Eur J Appl Physiol 108: 1099–1105. pmid:20024579
  18. 18. Helgerud J (1994) Maximal oxygen uptake, anaerobic threshold and running economy in women and men with similar performances level in marathons. Eur J Appl Physiol Occup Physiol 68: 155–161. pmid:8194545
  19. 19. Jones A, Doust J (1996) A 1% treadmill grade most accurately reflects the energetic cost of outdoor running. J Sports Sci 14: 321–327. pmid:8887211
  20. 20. Shaw AJ, Ingham SA, Fudge BW, Folland JP (2013) The reliability of running economy expressed as oxygen cost and energy cost in trained distance runners. Appl Physiol Nutr Metab 38: 1268–1272. pmid:24195628
  21. 21. Pugh L (1970) Oxygen intake in track and treadmill running with observations on the effect of air resistance. J Physiol: 823–835. pmid:4322767
  22. 22. Rietjens G, Kuipers H, Kester A, Keizer H (2001) Validation of a computerized metabolic measurement system (Oxycon-Pro) during low and high intensity exercise. Int J Sports Med 22: 291–294. pmid:11414673
  23. 23. Bishop D, Jenkins D, Mackinnon L (1998) The relationship between plasma lactate parameters, Wpeak and 1-h cycling performance in women. Med Sci Sport Exerc Exerc 30: 1270–1275. pmid:9710868
  24. 24. Péronnet F, Massicotte D (1991) Table of nonprotein respiratory quotient: an update. Can J Sport Sci 16: 23–29. pmid:1645211
  25. 25. Jeukendrup AE, Wallis GA (2005) Measurement of substrate oxidation during exercise by means of gas exchange measurements. Int J Sports Med 26: S28–37. pmid:15702454
  26. 26. Pearson K (1896) On a form of spurious correlation which may arise when indices are used in the measurement of organs. Proc R Soc London: 489–498.
  27. 27. Moya-Laraño J, Corcobado G (2008) Plotting partial correlation and regression in ecological studies. Web Ecol 8: 35–46.
  28. 28. Bland JM, Altman DG (2009) Statistics notes Calculating correlation coefficients with repeated observations: Part 1—correlation within subjects. Br Med J 446: 1–7.
  29. 29. Hopkins WG, Marshall SW, Batterham AM, Hanin J (2009) Progressive statistics for studies in sports medicine and exercise science. Med Sci Sports Exerc 41: 3–13. pmid:19092709
  30. 30. Sawyer B, Blessinger J (2010) Walking and running economy: inverse association with peak oxygen uptake. Med Sci Sports 42: 2122–2127. pmid:20351592
  31. 31. Noakes T, Tucker R (2004) Inverse Relationship Between VO2Max and Economy in World-Class Cyclists. Med Sci Sport Exerc 36: 1083–1084. pmid:15179181
  32. 32. Wagner P (2000) New Ideas on Limitations to Vo2max. Exerc Sport Sci Rev 28: 10–14. pmid:11131681
  33. 33. Blomqvist CG, Saltin B (1983) Cardiovascular adaptations to physical training. Annu Rev Physiol 45: 169–189. pmid:6221687
  34. 34. Schmidt W, Prommer N (2008) Effects of various training modalities on blood volume. Scand J Med Sci Sports 18: 57–69. pmid:18665953
  35. 35. Hunter GR, Katsoulis K, McCarthy JP, Ogard WK, Bamman MM, Wood D, et al. (2011) Tendon length and joint flexibility are related to running economy. Med Sci Sports Exerc 43: 1492–1499. pmid:21266930
  36. 36. Scholz MN, Bobbert MF, van Soest AJ, Clark JR, van Heerden J (2008) Running biomechanics: shorter heels, better economy. J Exp Biol 211: 3266–3271. pmid:18840660
  37. 37. Tartaruga MP, Brisswalter J, Peyré-Tartaruga LA, Avila AOV, Alberton CL, Coertjens M, et al. (2012) The relationship between running economy and biomechanical variables in distance runners. Res Q Exerc Sport 83: 367–375. pmid:22978185
  38. 38. Di Michele R, Merni F (2014) The concurrent effects of strike pattern and ground-contact time on running economy. J Sci Med Sport 17: 414–418. pmid:23806876