Effects of resistance exercise, collagen ingestion and circulating oestrogen concentration on collagen synthesis in a female athlete: A case report

Joonsung Lee; Jonathan C Y Tang; John Dutton; Rachel Dunn; William D Fraser; Kevin Enright; David R Clark; Claire E Stewart; Robert M Erskine

doi:10.1113/EP091897

Effects of resistance exercise, collagen ingestion and circulating oestrogen concentration on collagen synthesis in a female athlete: A case report

Exp Physiol. 2024 Jun 20. doi: 10.1113/EP091897. Online ahead of print.

Authors

Joonsung Lee¹, Jonathan C Y Tang^{2

3}, John Dutton², Rachel Dunn^{2

3}, William D Fraser^{2

3

4}, Kevin Enright¹, David R Clark⁵, Claire E Stewart¹, Robert M Erskine^{1

6}

Affiliations

¹ School of Sport and Exercise Sciences, Liverpool John Moors University, Liverpool, UK.
² Bioanalytical Facility, Norwich Medical School, University of East Anglia, Norwich, UK.
³ Clinical Biochemistry, Departments of Laboratory Medicine, Norfolk and Norwich University Hospital NHS Foundation Trust, Norwich, UK.
⁴ Departments of Diabetes and Endocrinology, Norfolk and Norwich University Hospital NHS Foundation Trust, Norwich, UK.
⁵ School of Health Sciences, Robert Gordon University, Aberdeen, UK.
⁶ Division of Surgery and Interventional Science, Institute of Sport, Exercise and Health, University College London, London, UK.

PMID: 38984642
DOI: 10.1113/EP091897

Abstract

We investigated the effects of resistance exercise (RE), hydrolysed collagen (HC) ingestion and circulating oestrogen concentration on collagen synthesis in a naturally menstruating female CrossFit athlete. In a double-blind, randomised cross-over design, the participant (36 years; height 1.61 m; mass 82.6 kg) consumed 0 or 30 g HC prior to performing back-squat RE when endogenous circulating oestrogen concentration was low (onset of menses, OM) and high (late follicular phase, LF) during two consecutive menstrual cycles. Ten 5-mL blood samples were collected during each of the four interventions to analyse concentrations of serum 17β-oestradiol, and biomarkers of type I collagen turnover, that is serum procollagen type I N-terminal propeptide (PINP, a biomarker of collagen synthesis) and plasma β-isomerised C-terminal telopeptide of type I collagen (β-CTX, a biomarker of collagen breakdown), as well as the serum concentration of 18 collagen amino acids. 17β-Oestradiol concentration was 5-fold higher at LF (891 ± 116 pmol L^-1) than OM (180 ± 13 pmol L^-1). The PINP concentration × time area under the curve (AUC) was higher in the 30 g HC OM intervention (201 μg L^-1 h) than the 30 g HC LF (144 μg L^-1 h), 0 g HC OM (151 μg L^-1 h) and 0 g HC LF (122 μg L^-1 h) interventions. β-CTX concentration decreased 1.4-fold from pre-RE to 6 h post-RE in all interventions. Thus, high circulating oestrogen concentration was associated with lower collagen synthesis following RE in this female athlete. Ingesting 30 g HC, however, augmented the collagen synthesis response at LF and particularly at OM. HIGHLIGHTS: What is the central question of this study? Does resistance exercise-induced collagen synthesis vary according to circulating oestrogen concentration in a naturally menstruating female athlete, and if so, does hydrolysed collagen ingestion have any impact? What is the main finding and its importance? Exercise-induced collagen synthesis was low when circulating oestrogen concentration was high and vice versa. However, ingesting 30 g hydrolysed collagen prior to exercise reduced the negative effect of oestrogen on collagen synthesis. As high circulating oestrogen has been associated with greater injury risk in females, supplementing exercise with hydrolysed collagen may help protect these tissues from injury.

Keywords: connective tissue; female; glycine; oestrogen; proline.