Nutritional ergogenic and thermogenic aids are commonly used to optimise carbohydrate utilisation and potentially enhance glycogen-sparing ability⁽Reference Cermak and van Loon^1–Reference Outlaw, Wilborn and Smith²⁾. However, less is known about the potential effects during exercise, particularly on the responses of carbohydrate oxidation (CHO) and blood lactate concentration (BLC), which are known indicators of exercise intensity and determine exercise performance⁽Reference Alkhatib³⁾. This study investigated whether the potential thermogenic effects of Yerba Maté (YM), the plant of (Illex Paraguariensis), affect carbohydrate oxidation rate (CHO) and BLC levels during low and moderate intensity exercise.

Male and female participants (n = 11) ingested either 1 g of YM or placebo capsules (PLA) in a randomised crossover experimental design. Within laboratory conditions, participants rested for 1 hr before performing two incremental exercise ergometry tests in separate visits with the power output being initiated and increased by 0·5 W.kg⁻¹ of body mass every 3 min stage until exhaustion. Cardiorespiratory measurements and indirect calorimetry technique were applied to analyse CHO and energy expenditure derived from carbohydrate (EE_cho), and capillary blood samples were collected and analysed for BLC at rest and for each exercise intensity domain. Data were analysed using a repeated measures ANOVA design.

CHO was reduced significantly (e.g. 0·37 ± 0·24 vs. 0·59 ± 0·19, 0·75 ± 0·24 vs. 1·00 ± 0·33 and 1·36 ± 0·48 vs. 1·64 ± 0·47 g.min⁻¹ at 40, 50, 60 and 70% of ${\dot V}\!O_2 $ _peak respectively, P < 0·001, ANOVA main effects) in the YM compared with PLA at all sub-maximal exercise intensities up to the level of 70% of maximal oxygen uptake (${\dot V}\!O_2 $_peak), which corresponded to reaching carbohydrate saturation level (respiratory exchange ratio = 1), (p < 0·001, ANOVA main effects). EE_CHO was also reduced in the YM compared with PLA (Table 1). These effects were combined by a trend, though not significant towards a decrease in BLC (P = 0·07) at the same given exercise intensities in YM compared with PLA (Table 1).

Table 1. Carbohydrate oxidation rate (CHO) and Energy derived from carbohydrate (EE_CHO) at low to moderate exercise intensities, all data presented as (Mean ± SD).

Reduced CHO, EE_cho seem to be reflected by BLC changes at moderate exercise intensities, through acute YM ingestion at submaximal exercise intensities. These effects suggest a potential role for YM during exercise for glycogen sparing, exercise tolerance and metabolic weight loss outcomes.