Abstract
The aim of this study was to investigate possible correlations between a) jumping ability (squat jump and countermovement jump performance) and c) anthropometric indexes with the distances covered at different intensities during soccer matches by Greek elite soccer players (n=11). Match running performance was analyzed using a global positioning system (GPS) within the second division professional league. Body weight and height were moderately correlated with the distance that was covered in the first half with the speed from 19.7 to 23.7 km/h (r=-0.605, p<0.05 and r=-0.616, p<0.05, respectively). No correlations were found between SJ and CMJ performance with match running performance in all the velocities. The players covered greater distances in the first half at all speed levels except for walking (6–11.9 km/h: 1,548 vs. 1,260 m, p<0.01; 12–15.7 km/h: 896 vs. 696 m, p<0.001; 15.8–19.6 km/h: 438 vs. 347 m, p<0.01; 19.7–23.7 km/h: 176 vs. 142 m, p<0.01; 23+ km/h: 71 vs. 52 m, p<0.001). The results demonstrated that match running performance depends on the tactical strategies of each team. Shorter players and who weight less may perform better in higher velocities. However, more studies with greater samples are needed to estimate the relations that were mentioned.
Keywords: Jump, Power, Performance, Speed, Match running performance, Anthropometrics.
Received: 16 August 2019 / Revised: 23 September 2019 / Accepted: 25 October 2019/ Published: 6 December 2019
Contribution/ Originality
This study is one of very few studies which have investigated the relationship between match running performance with anthropometric and power indexes. The paper’s primary contribution is finding that match running performance does not correlated with player’s power and shorter players may perform better in higher velocities.
1. INTRODUCTION
Soccer is an intermittent type of sport which incorporates actions with low and high intensity and duration. The global positioning systems (GPSs) that have been used for few decades to help coaches to quantify the physiological demands of soccer (Bangsbo et al., 1991). Elite soccer players during a match cover a distance around 9-14 km (Bradley et al., 2010) and perform a lot of activities like accelerations, decelerations, jumps, changes of direction and other (Mohr et al., 2005).
Power actions seem to be critical for the outcome of the match (Castagna et al., 2003). Reilly et al. (2000) had mentioned that these actions can discriminate a successful and an unsuccessful performance. High intensity running represents only 10% of the total distance that is covered but is crucial in scoring, keeping ball in possession and stopping an opponent from scoring (Dalen et al., 2016). In addition, changes of direction (COD) and acceleration ability are basic elements for soccer performance (Reilly, 1990; Bangsbo et al., 1991). Researchers understand the significance of high intensity activities in soccer and most research focuses on these movements (Mascio and Bradley, 2013). A lot of studies present the verities of high intensity running: a) across playing positions (Mascio and Bradley, 2013), b) at different levels (Ingebrigtsen et al., 2012) and c) during the match (Mohr et al., 2005).
Soccer players have to perform a lot of high and low intensity actions for an extended period of time (90 minutes). Energy systems, the aerobic and the anaerobic are necessary to provide energy to muscles during the match. However, for high intensity actions that last less than 7 sec the basic energy system that is being activated is phosphagen system which is also called “ATP-CP system”. This is the quickest way to resynthesize ATP and more specific creatine phosphate in muscles is a donor of a phosphate to ADP to produce ATP. This is an anaerobic process because it does not use oxygen (Mougios, 2006). However, the amount of CP in muscles is limited so this system provides energy for just a few seconds.
In the literature only a few studies have looked into the correlations between match running performance and aerobic indexes (Castagna et al., 2010; Bradley et al., 2014) and even fewer studies have focused on the examination of the relationship between match running performance and performance on anaerobic tests (Rampinini et al., 2007; Redkva et al., 2018). In these two studies concerning anaerobic indexes, researchers used tests to assess repeated sprint ability (RSA) and vertical jump ability of soccer players. Rampinini et al. (2007) mentioned that correlations were observed between performances at RSA test and the distance that was covered in very high intensity running (> 19.8 km/h) and with sprints, but no correlation with vertical jump performance was observed and Redkva et al. (2018) mentioned that no correlation between repeated sprint ability and match running performance were observed either. It is known that a high level of aerobic power helps soccer players to perform more frequent maximal anaerobic actions of short time (Bishop et al., 2004). Vertical jump performance is being used by coaches as an index of bottom limb muscular power (Brocherie et al., 2014). Furthermore, researchers have mentioned associations between jump tests and player in a competitive level (Arnason et al., 2004). The majority of sprints in the field last 1-2 sec and all the other power actions like heading, tackling, shooting last less than 2 sec (Dwyer and Gabbett, 2012). All of the above actions are being characterized by power. No research today has looked into the relation between vertical jump performance in two tests and (squat jump (SJ) and countermovement jump (CMJ)) and the distance that is covered in elite soccer players during a season. Therefore, it is assumed that jump performance in SJ and CMJ is not related to the total distance that is covered and other running intensities. Finally, it is known that an anthropometric profile can affect performances. More specifically, it is known that, high body fat percentage or decreased lean body mass can affect one’s aerobic performance, speed and jumping ability (Maciejczyk et al., 2014). However, in the literature there are not any studies that research the correlation of anthropometric indexes and match running performance. The aim of this study was to assess the correlations of a) SJ performance and the total distance that is covered in a soccer match and in each half, b) SJ and the distance covered in a different running intensity during a soccer match and in each half particularly, c) CMJ performance and the total distance that is covered in a soccer match and in each half particularly, d) CMJ and the distance covered in different running intensities in a soccer match and in each half particularly, e) anthropometric characteristics and the total distance that is covered in a soccer match and in each half particularly, and f) to determine the differences in running performances within the 2 halves of the matches.
2. METHODS
2.1. Experimental Approach to the Problem
The purpose of this study was to test the hypothesis that the performance of SJ and CMJ may be correlated with the high speed running performance (velocity > 19.7 km/h) of the match in elite soccer players. Moreover, it investigates the distance that was covered in the two halves and the total distance in different velocities. Furthermore, to avoid having differences in the participation time among the players, the participants were only players who played 90 minutes with the goalkeepers being excluded from the study. The duration of the training season for all athletes was 46 weeks per year. More specifically, the participants performed six 90-minute training sessions per week and had an additional personal training session every week for individual improvement. Additionally, all soccer players played 1 match per week throughout the season. The duration of the study was 1 season, from the beginning to end, in which the team performed 31 official matches.
2.2. Subjects
Eleven, healthy, professional adult soccer players from the second division of the Greek league volunteered to participate in this study. All the players have trained for at least 12 years. All testing procedures and any possible risks or discomforts were fully explained in detail to the participants before the beginning of the study. The study was approved in advance by the ethical committee of the Department of Physical Education and Sport Science, University of Thessaloniki in accordance with the ethical standards in sport and exercise research. Each participant voluntarily provided written informed consent before participating. Participants’ characteristics are shown in Table 1.
Table-1. Participants’ physical characteristics. *†
| Variable | Value |
| Age (y) | 27.5 ± 4.7 |
| Height (cm) | 180 ± 5.7 |
| Weight (kg) | 76.3 ± 6.1 |
| Body fat (%) | 9.8 ± 2.7 |
†Data are presented as mean ± SD.
2.3. Anthropometrics
Body mass was measured as close as possible to 0.1 kg using an electronic digital scale, the participants were in their underclothes and barefoot. Their height was measured as close to 0.1 cm as possible (Seca 220e, Hamburg, Germany). The participants body fat percentage was estimated based on the sum of four (biceps, triceps, suprailiac, subscapular) skinfold thicknesses measured using a specific caliper (Lafayette, Ins. Co., Indiana) on the right side of the body. Furthermore, the estimation of the body density was calculated according to the Durnin and Rahaman (1967) equation for males older than the age of 16 years old, and estimated by the equation of Siri (1956).
2.4. Vertical Jump Testing
The participants performed 2 jump tests: a) SJ and b) CMJ. In SJ participants in a stationary semi-squatted position (90o angle at the knees) performed a maximal VJ. In CMJ the participants from an upright standing position performed a fast preliminary motion downwards by flexing their knees and hips followed by an explosive upward motion by extending their knees and hips. All 2 tests were performed with the arms in akimbo. The VJ height was measured with an ergojump contact platform (Chronojump-Boscosystem, Spain). Flight times was measured by a digital timer connected to the contact platform and was used for the jump height to be calculated. The coefficients of variation for test-retest trials were 2.8 and 3 % for SJ and CMJ respectively.
2.5. Global Positioning System Analysis (GPS)
To measure the match performance, players wore 50-Hz GPS units (LAGALACOLLI Sport, Roma, Italy) on their upper torso in a vest garment to reduce movement artefacs. Units were activated according to the manufacturer’s guidelines right before the pre match warm-up. Players wore the same GPS devices for each match to avoid any interunit variation. After each match the data was analyzed using 6 indices for each half and for the entire match (0.1 – 5.99 km/h-walking, 6 – 11.9 km/h-jogging, 12 – 15.7 km/h-running, 15.8 – 19.6 km/h-high intensity running, 19.7 – 23.7 km/h-fast running, 23.8+ km/h-sprint, total distance). The match indices’ intraclass correlation coefficient (ICC) and coefficient of variation (CV) ranged 0.93 and 0.97 and 13% respectively.
3. STATISTICAL ANALYSIS
Data is being presented as means ± SD. Data normality was verified with the 1-sample Kolmogorov-Smirnoff test; therefore, a non-parametric test was not necessary. All statistical analyses were conducted using SPSS (version 16.0; SPSS Inc., Chicago, IL, USA). Results are reported as mean ± SD. Relationships between SJ and CMJ performance and anthropometric characteristics with selected running indices were evaluated using a bivariate correlation. Paired samples t-test was used to compare the distances covered by the players in the first and second halves of the match. Statistical significance was set at p ≤ 0.05.
4. RESULTS
The distance that was covered by the soccer players in the first half using high speed running (19.7 - 23.7 km/h) was moderated in correlation to height (r = -0.616, p < 0.05) and weight (r = -0.605, p < 0.05) Table 2. No correlations were found between performances in SJ and CMJ with all the other indices of match running performance (p > 0.05) Table 2.
Table-2. Correlation coefficients between anthropometric characteristics and jump performance with match running distances at different intensities.
| First half distance covered | |||||||
0.1-5.99 |
6-11.9 |
12-15.7 |
15.8-19.6 |
19.7-23.7 |
23.8+ |
Total |
|
| Height | r = 0.52 |
r = -0.43 |
r = -0.44 |
r = -0.49 |
r = -0.62* |
r = -0.38 |
r = -0.51 |
| Weight | r = 0.54 |
r = -0.44 |
r = -0.49 |
r = -0.55 |
r = -0.61* |
r = -0.22 |
r = -0.54 |
| % Body fat | r = 0.54 |
r = -0.24 |
r = -0.18 |
r = -0.17 |
r = -0.35 |
r = -0.25 |
r = -0.13 |
| SJ | r = -0.09 |
r = -0.15 |
r = -0.22 |
r = -0.09 |
r = 0.26 |
r = 0.58 |
r = -0.17 |
| CMJ | r = 0.04 |
r = -0.34 |
r = -0.34 |
r = -0.23 |
r = 0.12 |
r = 0.55 |
r = -0.33 |
| Second half distance covered | |||||||
| Height | r = 0.56 |
r = 0.06 |
r = -0.3 |
r = -0.36 |
r = -0.52 |
r = -0.25 |
r = 0.01 |
| Weight | r = 0.51 |
r = 0.06 |
r = -0.31 |
r = -0.37 |
r = -0.38 |
r = -0.05 |
r = -0.01 |
| % Body fat | r = -0.4 |
r = -0.58 |
r = -0.36 |
r = -0.35 |
r = -0.30 |
r = -0.41 |
r = -0.55 |
| SJ | r = -0.09 |
r = -0.20 |
r = -0.28 |
r = -0.15 |
r = 0.07 |
r = 0.42 |
r = -0.2 |
| CMJ | r =0.010 |
r = -0.23 |
r = -0.39 |
r = -0.28 |
r = -0.12 |
r = 0.37 |
r = -0.25 |
| Total distance covered | |||||||
| Height | r = 0.58 |
r = -0.01 |
r = -0.36 |
r = -0.42 |
r = -0.53 |
r = -0.18 |
r = -0.18 |
| Weight | r = 0.53 |
r = 0.01 |
r = -0.38 |
r = -0.43 |
r = -0.39 |
r = -0.01 |
r = -0.21 |
| % Body fat | r = -0.38 |
r = -0.46 |
r = -0.24 |
r = -0.18 |
r = -0.27 |
r = -0.49 |
r = -0.42 |
| SJ | r = -0.11 |
r = -0.31 |
r = -0.34 |
r = -0.20 |
r = 0.06 |
r = 0.41 |
r = -0.33 |
| CMJ | r = -0.02 |
r = -0.39 |
r = -0.46 |
r = -0.36 |
r = -0.13 |
r = 0.39 |
r = -0.46 |
SJ: squat jump; CMJ: countermovement jump; Significant correlation (p < 0.05).
Furthermore, the main total distance covered during a match was 8,618 m. Additionally, players covered greater distances in the first half at all running speed levels (velocity >5.99 km/h). More specifically, they ran 288 m (18.6 %) more when jogging (p < 0.01) (6 – 11.9 km/h), 200 m (22.3 %) more when running (p < 0.001) (12 – 15.7 km/h) and 91 m (20.6 %) more in high intensity running (p < 0.01) (15.8 – 19.6 km/h). In addition, they covered a 34 m (19.4 %) greater distance when running at high speed (p < 0.01) (19.7 – 23.7 km/h) and 19 m (26.1 %) more when sprinting (p < 0.001) (23.8+ km/h). Finally, the total distance that was covered during the first half was 752 m (16.1 %) greater (p < 0.01) than that covered during the second half of a match Figure 1a.
Figure-1a. Distance covered at different speed velocities by players during the first and second half. * Denotes significant (p < 0.01) difference with 1st half distance. † Denotes significant (p < 0.001) difference with 1st half distance. b. Total distance covered at different speed velocities by players during the match.
5. DISCUSSION
The body mass and height of the soccer players were related to the distance covered in the first half using high speed running (19.7 – 23.7 km/h). In the literature we can find only one study (Rienzi et al., 2000) who have tried to correlate anthropometric profile of soccer players with a match running performance. (Rienzi et al., 2000)observed that body mass and muscle mass was related to the total distance covered by South American international players. However, (Rienzi et al., 2000) used video analysis of the national team matches and not GPS to estimate the covered distance. High body fat is not useful for players because in increases the physiological strain (Rienzi et al., 2000) and it is a disadvantage in activities which involve body displacement. Furthermore, jump performance and acceleration can be negatively influenced by high body fat due to an increased body weight. Therefore, soccer players with low body fat percentages may be able to perform better. However, all elite players have an upper standard value of percentage level and this may be the reason why there were not any correlations observed between in body fat percentage and match running performance. The results from our study indicate that shorter and thinner players can cover greater distances in high speed running (19.7 – 23.7 km/h) than the taller and heavier players during the first half. Surprisingly, no other correlations were observed between anthropometric indexes and other match running variables.
The findings show that there are no correlations of SJ and CMJ performances and match running performance. In the literature two researchers’ have tried to correlate the performances in anaerobic tests (vertical jump, repeated sprint tests) and the distances covered during a soccer match. More specifically, Redkva et al. (2018) mentioned no correlations between repeated sprint test and match running performance. Additionally, another study, Rampinini et al. (2007) observed a significant correlation between the ability of repeated sprint and match running performance, but no correlations to vertical jump performance. Furthermore, it should be mentioned that the study of Redkva et al. (2018) was performed in friendly soccer matches and not official. This may influence the results of their study.
As mentioned before the present study failed to show a significant correlation between SJ and CMJ performance to the selected soccer match variables. Similar results had been mentioned by Rampinini et al. (2007) the only known study which was tried to correlate a VJ to match running performance. Jump tests are used as indexes of bottom limb power. Our hypothesis was that a soccer player with a high level of power could perform more meters with high speed running during a match (> 19.7 km/h). These kinds of activities (jumps, sprints) use energy from the same system (posphagen system). A possible explanation for the lack of correlations may be the fact that SJ and CMJ are two specific activities that differ from the actions presented by the players during a soccer match. More specifically, during a match, players perform short sprints (~ 6 – 16 m), which last around 2 sec and are repeated every 72 sec (Dwyer and Gabbett, 2012). Additionally, it is known that aerobic metabolism can influence the repeated maximum short efforts because it helps the resynthesis of phosphocreatine stores (Bishop and Edge, 2006). Furthermore, the tactical role of players, individual playing position, the quality of the opponent, and the degree of motivation can alter the relationship between jump performance and match running variables.
The total distance that was covered during the second half of the soccer patches was 16.1 % shorter than the first half. This finding is in accordance with previous studies among professional soccer players which presented decreases from 1 to 12.6 % (Bradley et al., 2010; Metaxas, 2018). In the present study significant differences between the two halves in all running velocities (> 5.99 km/h) were observed. In addition, coaches and researchers pay more attention to high intensity running, where in the present study decreases were observed in the distance covered from 19.4 % to 26.1 %. Many researchers have mentioned similar results (Krustrup et al., 2005; Metaxas, 2018) to ours but some researchers did not observe any differences between the two half times in one of the best European teams (Salvo et al., 2007). Furthermore, one crucial factor for the reduction of the covered distance during the second half could be fatigue. Finally, formation and tactical strategies could influence the match running performance during the two halves (Aquino et al., 2017).
6. CONCLUSION
In conclusion, the results indicate that the players’ match running performance do not depend on the index of vertical jumping ability. Height and weight could be related to some intensities of a match running performance, but the small sample and the moderate negative correlations which were found do not allow their use for predictive reasons. The players cover greater distances during the first half of a soccer match. Coaches have to pay attention in aerobic fitness training which could help players limit their fatigue during the second half.
| Funding: This study received no specific financial support. |
| Competing Interests: The authors declare that they have no competing interests. |
| Acknowledgement: The authors would like to thank the soccer players for their cooperation. |
REFERENCES
Aquino, R., L.H.P. Vieira, C. Carling, G.H. Martins, I.S. Alves and E.F. Puggina, 2017. Effects of competitive standard, team formation and playing position on match running performance of Brazilian professional soccer players. International Journal of Performance Analysis in Sport, 17(5): 695-705.Available at: https://doi.org/10.1080/24748668.2017.1384976.
Arnason, A., S.B. Sigurdsson, A. Gudmundsson, I. Holme, L. Engebretsen and R. Bahr, 2004. Physical fitness, injuries, and team performance in soccer. Medicine & Science in Sports & Exercise, 36(2): 278-285.Available at: https://doi.org/10.1249/01.mss.0000113478.92945.ca.
Bangsbo, J., L. Nørregaard and F. Thorsoe, 1991. Activity profile of competition soccer. Canadian Journal of Sport Sciences, 16(2): 110-116.
Bishop, D. and J. Edge, 2006. Determinants of repeated-sprint ability in females matched for single-sprint performance. European Journal of Applied Physiology, 97(4): 373-379.Available at: https://doi.org/10.1007/s00421-006-0182-0.
Bishop, D., J. Edge and C. Goodman, 2004. Muscle buffer capacity and aerobic fitness are associated with repeated-sprint ability in women. European Journal of Applied Physiology, 92(4-5): 540-547.Available at: https://doi.org/10.1007/s00421-004-1150-1.
Bradley, P., M. Bendiksen, A. Dellal, M. Mohr, A. Wilkie, N. Datson, C. Orntoft, M. Zebis, A. Gomez-Diaz and J. Bangsbo, 2014. The application of the Yo-Yo intermittent endurance level 2 test to elite female soccer populations. Scandinavian Journal of Medicine & Science in Sports, 24(1): 43-54.Available at: https://doi.org/10.1111/j.1600-0838.2012.01483.x.
Bradley, P.S., D.M. Mascio, D. Peart, P. Olsen and B. Sheldon, 2010. High-intensity activity profiles of elite soccer players at different performance levels. The Journal of Strength & Conditioning Research, 24(9): 2343-2351.Available at: https://doi.org/10.1519/jsc.0b013e3181aeb1b3.
Brocherie, F., O. Girard, F. Forchino, H. Al Haddad, D.G.A. Santos and G.P. Millet, 2014. Relationships between anthropometric measures and athletic performance, with special reference to repeated-sprint ability, in the Qatar national soccer team. Journal of Sports Sciences, 32(13): 1243-1254.Available at: https://doi.org/10.1080/02640414.2013.862840.
Castagna, C., S. D'Ottavio and G. Abt, 2003. Activity profile of young soccer players during actual match play. Journal of Strength and Conditioning Research, 17(4): 775-780.
Castagna, C., V. Manzi, F. Impellizzeri, M. Weston and J.C.B. Alvarez, 2010. Relationship between endurance field tests and match performance in young soccer players. The Journal of Strength & Conditioning Research, 24(12): 3227-3233.Available at: https://doi.org/10.1519/jsc.0b013e3181e72709.
Dalen, T., I. Jørgen, E. Gertjan, H.G. Havard and W. Ulrik, 2016. Player load, acceleration, and deceleration during forty-five competitive matches of elite soccer. The Journal of Strength & Conditioning Research, 30(2): 351-359.Available at: https://doi.org/10.1519/jsc.0000000000001063.
Durnin, J. and M.M. Rahaman, 1967. The assessment of the amount of fat in the human body from measurements of skinfold thickness. British Journal of Nutrition, 21(3): 681-689.Available at: https://doi.org/10.1079/bjn19670070.
Dwyer, D.B. and T.J. Gabbett, 2012. Global positioning system data analysis: Velocity ranges and a new definition of sprinting for field sport athletes. The Journal of Strength & Conditioning Research, 26(3): 818-824.Available at: https://doi.org/10.1519/jsc.0b013e3182276555.
Ingebrigtsen, J., M. Bendiksen, M.B. Randers, C. Castagna, P. Krustrup and A. Holtermann, 2012. Yo-Yo IR2 testing of elite and sub-elite soccer players: performance, heart rate response and correlations to other interval tests. Journal of Sports Sciences, 30(13): 1337-1345.Available at: https://doi.org/10.1080/02640414.2012.711484.
Krustrup, P., M. Mohr, H. Ellingsgaard and J. Bangsbo, 2005. Physical demands during an elite female soccer game: Importance of training status. Medicine and Science in Sports and Exercise, 37(7): 1242.Available at: https://doi.org/10.1249/01.mss.0000170062.73981.94.
Maciejczyk, M., M. Więcek, J. Szymura, Z. Szyguła, S. Wiecha and J. Cempla, 2014. The influence of increased body fat or lean body mass on aerobic performance. Plos One, 9(4): 1-6.Available at: https://doi.org/10.1371/journal.pone.0095797.
Mascio, D.M. and P.S. Bradley, 2013. Evaluation of the most intense high-intensity running period in English FA premier league soccer matches. The Journal of Strength & Conditioning Research, 27(4): 909-915.Available at: https://doi.org/10.1519/jsc.0b013e31825ff099.
Metaxas, T.I., 2018. Match running performance of elite soccer players: VO2 max and players position influences. Age (y), 27(6): 4-4.
Mohr, M., P. Krustrup and J. Bangsbo, 2005. Fatigue in soccer: A brief review. Journal of Sports Sciences, 23(6): 593-599.Available at: https://doi.org/10.1080/02640410400021286.
Mougios, V., 2006. Exercise biochemistry. 1st ed Edn., United Kingdom: Human Kinetics. pp:145-157.
Rampinini, E., D. Bishop, S. Marcora, D.F. Bravo, R. Sassi and F. Impellizzeri, 2007. Validity of simple field tests as indicators of match-related physical performance in top-level professional soccer players. International Journal of Sports Medicine, 28(03): 228-235.Available at: https://doi.org/10.1055/s-2006-924340.
Redkva, P.E., M.R. Paes, R. Fernandez and S.G. da-Silva, 2018. Correlation between match performance and field tests in professional soccer players. Journal of Human Kinetics, 62(1): 213-219.Available at: https://doi.org/10.1515/hukin-2017-0171.
Reilly, T., 1990. Football. In physiology of sports. London: E & FN Spon. pp: 371-426.
Reilly, T., J. Bangsbo and A. Franks, 2000. Anthropometric and physiological predispositions for elite soccer. Journal of Sports Sciences, 18(9): 669-683.Available at: https://doi.org/10.1080/02640410050120050.
Rienzi, E., B. Drust, T. Reilly, J.E.L. Carter and A. Martin, 2000. Investigation of anthropometric and work-rate profiles of elite South American international soccer players. Journal of Sports Medicine and Physical Fitness, 40(2): 162-169.
Salvo, D.V., R. Baron, H. Tschan, F.C. Montero, N. Bachl and F. Pigozzi, 2007. Performance characteristics according to playing position in elite soccer. International Journal of Sports Medicine, 28(03): 222-227.Available at: https://doi.org/10.1055/s-2006-924294.
Siri, W.E., 1956. The gross composition of the bod. Advances in Biological and Medical Physics, 4: 239-280.
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