posted on 2019-08-22, 10:58authored byRobert W. Davies, Joseph J. Bass, Brian P. Carson, Catherine Norton, Marta Kozior, Miryam Amigo-Benavent, Daniel J. Wilkinson, Matthew S. Brook, Philip J. Atherton, Kenneth Smith, Philip M. Jakeman
.The aim of this study was to test the effects of two disparate isonitrogenous,
isocaloric pre-exercise feeds on deuterium-oxide (D2O) derived measures of myofibrillar protein
synthesis (myoPS) in humans. Methods: In a double-blind parallel group design, 22 resistance-trained
men aged 18 to 35 years ingested a meal (6 kcal·kg−1
, 0.8 g·kg−1
carbohydrate, 0.2 g·kg−1
fat) with
0.33 g·kg−1 nonessential amino acids blend (NEAA) or whey protein (WHEY), prior to resistance
exercise (70% 1RM back-squats, 10 reps per set to failure, 25% duty cycle). Biopsies of M. vastus
lateralis were obtained pre-ingestion (PRE) and +3 h post-exercise (POST). The myofibrillar fractional
synthetic rate (myoFSR) was calculated via deuterium labelling of myofibrillar-bound alanine,
measured by gas chromatography–pyrolysis–isotope ratio mass spectrometry (GC-Pyr-IRMS). Data are
a mean percentage change (95% CI). Results: There was no discernable change in myoFSR following
NEAA (10(−5, 25) %, p = 0.235), whereas an increase in myoFSR was observed after WHEY (28 (13, 43)
%, p = 0.003). Conclusions: Measured by a D2O tracer technique, a disparate myoPS response was
observed between NEAA and WHEY. Pre-exercise ingestion of whey protein increased post-exercise
myoPS, whereas a NEAA blend did not, supporting the use of NEAA as a viable isonitrogenous
negative control.