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Exceptional body composition changes attributed to collagen peptide supplementation and resistance training in older sarcopenic men

Published online by Cambridge University Press:  06 June 2016

Stuart M. Phillips*
Affiliation:
Department of Kinesiology, McMaster UniversityHamilton, ON, Canada L8S 4K1
Kevin D. Tipton
Affiliation:
Health and Exercise Sciences Research Group Faculty of Health Sciences and Sport University of Stirling, Stirling FK9 4LA, UK
Luc J. C. van Loon
Affiliation:
Department of Human Biology and Movement SciencesSchool of Nutrition and Translational Research in Metabolism (NUTRIM), Maastricht University6200 MD Maastricht, The Netherlands
Lex B. Verdijk
Affiliation:
Department of Human Biology and Movement SciencesSchool of Nutrition and Translational Research in Metabolism (NUTRIM), Maastricht University6200 MD Maastricht, The Netherlands
Douglas Paddon-Jones
Affiliation:
Department of Nutrition and MetabolismUniversity of Texas Medical BranchGalveston, TX 77555-1144, USA
Graeme L. Close
Affiliation:
Research Institute for Sport and Exercise SciencesLiverpool John Moores UniversityLiverpool L3 5UA, UK
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Abstract

Type
Letters to the Editor
Copyright
Copyright © The Authors 2016 

The results reported by Zdzieblik et al. ( Reference Zdzieblik, Oesser and Baumstark 1 ), on gains in fat-free mass (FFM: mean 4·2(SD3·3) kg) and loss of body fat (mean −5·5(SD3·2) kg) in older sarcopenic men receiving 15 g/d of collagen peptides while resistance training for 12 weeks, are extraordinary. The algebraic difference between the collagen peptide-supplemented and placebo groups in terms of FFM reported by Zdzieblik et al. ( Reference Zdzieblik, Oesser and Baumstark 1 ) was approximately 1·3 kg, which is 2·7 and 5·6 times greater than the standardised mean differences reported in meta-analyses from Cermak et al. ( Reference Cermak, Res and de Groot 2 ) and Finger et al. ( Reference Finger, Goltz and Umpierre 3 ), which examined the impact of protein supplementation on resistance exercise-induced gains in FFM. Neither meta-analysis reported an impact of protein supplementation on loss of fat mass.

We note that the 4·2 kg gain in FFM in the collagen peptide-supplemented group is unrivalled by any study of protein supplementation in older resistance training sarcopenic men( Reference Cermak, Res and de Groot 2 ,3). One study, in which men with COPD received 100 mg of testosterone enanthate (injected weekly), comes close to the findings of Zdzieblik et al. ( Reference Zdzieblik, Oesser and Baumstark 1 ), but in this study men receiving testosterone and performing resistance training gained only 3·3 kg of FFM and lost 1·1 kg of fat mass( Reference Lewis, Fournier and Storer 4 ). Were the observed changes( Reference Zdzieblik, Oesser and Baumstark 1 ) in whole-body FFM representative of skeletal muscle tissue or are changes in other tissues responsible for the greater gains in whole-body FFM?

The constituent amino acid content and protein dose (15 g/d) of collagen peptides ingested contained only 0·4 g of leucine and 1·7 g of arginine, which stimulate muscle protein synthesis and blood flow, respectively( Reference Zdzieblik, Oesser and Baumstark 1 ); however, this dose of leucine would have been insufficient to induce any effect on muscle protein synthesis( Reference Moore, Churchward-Venne and Witard 5 ,6). In addition, 1·7 g of arginine would not have affected blood flow( Reference Tang, Lysecki and Manolakos 6 ,7). In their study, Zdzieblik et al. ( Reference Zdzieblik, Oesser and Baumstark 1 ) proposed that the provision of collagen peptides could enhance creatine synthesis. We find this proposition unlikely given the daily provision of only 1·7 g of arginine and 3·3 g of glycine, as there is no evidence that muscle creatine production is substrate-limited. If this thesis were true, then supplemental protein from almost any source (containing similar quantities of arginine and glycine) would promote the same gains in muscle mass and this has not been seen( Reference Cermak, Res and de Groot 2 ,3).

Collagen peptide-supplemented subjects lost a reported 5·5 kg of fat mass. This loss of fat mass, in 12 weeks, is approximately 80 % of that seen in older men following a hypoenergetic diet (−3138 kJ/d) (−750 kcal/d) or −3·1 MJ/d) while exercising for 6 months( Reference Frimel, Sinacore and Villareal 8 ). There is no obvious mechanism for the magnitude of loss of fat mass. It is notable that neither meta-analysis of protein supplementation in older persons during resistance training reported an effect on fat mass loss( Reference Cermak, Res and de Groot 2 ,3).

In sum, the changes in body composition in these sarcopenic older men, who exercised three times weekly for 12 weeks and consumed 15 g of collagen peptides, are remarkable( Reference Zdzieblik, Oesser and Baumstark 1 ). We find little in the way of plausible mechanistic evidence to suggest that either leucine and arginine or arginine and glycine, to allow the synthesis of muscle creatine, could be responsible for such changes. The simultaneous substantial loss of fat mass in these subjects, of a magnitude on par with that seen in much longer weight loss trials, is similarly noteworthy and deserves more explanation than is given by the authors in their article.

Acknowledgements

All authors contributed to the drafting and editing of this letter and all agreed on the final content.

S. M. P. reports having received grants, honoraria for speaking and expenses for travel from the US National Dairy Council and a grant from Pepsico. D. P.-J. has received research grant support from The Beef Checkoff and the National Dairy Council and compensation for advisory roles with The Beef Checkoff, the National Dairy Council and the Egg Nutrition Center. L. J. C. v. L. reports having received consulting fees from Nutricia.

All other authors report no conflicts of interest, financial or otherwise.

References

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