Overall treatment main effect of supplementing 400 mg of ATP approached significance for both increased low peak torque (Figure 2B) and decreased torque fatigue (Figure 2C). Analysis (Least Squares Means) of the data by each set showed that ATP supplementation significantly increased low peak torque in set 2 (62.3 and 67.2 Nm in placebo- and ATP-supplemented
participants, respectively https://www.selleckchem.com/products/azd8186.html (p < 0.01)). Set 3 torque fatigue also tended to be less with ATP-supplementation (60.5% and 57.8% in placebo- and ATP-supplemented participants, respectively (p < 0.10)). However, the improvements seen in leg low peak torque did not lead to increased leg average power, total work, or a decrease in work fatigue. Figure 2 High Selleckchem GANT61 Peak Torque (A); Low Peak Torque (B) and Torque Fatigue (C) over 3 successive sets of 50-contraction knee extensions in Dibutyryl-cAMP clinical trial placebo – - ♦- – and 400 mg ATP/d —▪— supplemented participants. Treatment with ATP approached an overall treatment main effect over placebo supplementation for Low Peak Torque and Torque
Fatigue (B and C, † p < 0.11). ATP supplementation resulted in a significant improvement in Set 2 Low Peak Torque (B, * p < 0.01) and a trend for less Torque Fatigue in Set 3 (C, # p < 0.10). Blood chemistries and differential cell counts were measured before and after each supplementation period. While some measurement comparisons between placebo and ATP-supplemented participants Casein kinase 1 showed numerical differences that were statistically significant, none of the significant observations were clinically relevant and these data showed no untoward effects of the supplementation (data shown in Additional file 1: Table S1 and Table S2). Discussion The current study shows that 400 mg ATP per day was effective in improving leg muscle low peak torque in set 2 (p < 0.01),
and tended to decrease leg muscle fatigue in set 3 (p < 0.10) of three successive sets of knee extension exercises. However, the improvement in low peak torque and decreased fatigue were not sufficient to translate into improvements in leg muscle power or work performed. These observations lead us to speculate that supplemental ATP may provide cumulative benefits in strenuous, repetitive, and exhaustive exercise activities, which could lead to improved strength and lean body mass gains. There is limited human data related to the potential for oral ATP to manifest physiologic modifications that would improve skeletal muscle efficiency or work performed [21]. As muscle undergoes prolonged work, ATP synthesis increases in an attempt to keep up with energy demand [22]. To accomplish this, the muscle needs substrates, such as oxygen and glucose, supplied from the peripheral circulation. Endogenous muscle stores of ATP are limited and support maximal work for only a fraction of, or at most 1–2 seconds and is replenished by the supply of intercellular phosphocreatine for only an additional 2–7 seconds [7].