Runners, cyclists and other athletes improve their performance capacity when they eat 40 g dark chocolate every day for two weeks. Researchers at Kingston University in England discovered this when they did an experiment with a handful of students. Adding a small piece of dark chocolate to their diet improved their endurance capacity.
The researchers gave 9 male students who were reasonably fit 40 g chocolate for a two-week period on two separate occasions. On one occasion the chocolate was white, on the other it was plain. The plain chocolate they used was a Mars product – Dove’s Dark Chocolate, to be precise. This product contains relatively high amounts of (-)-epicatechin, the most important bioactive ingredient in cacao.
The students ate the chocolate instead of their usual dessert, to that their daily energy intake remained constant.
Before and after both supplementation periods the researchers got the students to cycle on an ergometer. They asked the students to first cycle for 20 minutes at moderate intensity, and then finally to sprint at maximal capacity for a few minutes.
The supplementation with dark chocolate extended the amount of time that the subjects were able to sprint during the exertion test.
BL = before chocolate administration began; WC = white chocolate; DC = dark chocolate.
The researchers found no statistically significant effects of supplementation on maximal oxygen uptake, heart rate, lactic acid concentration in the blood or blood pressure. They did discover, however, that giving the students dark chocolate raised the gas exchange threshold [another term for this is ventilatory threshold].
The gas exchange threshold is the point at which during exercise the body no longer takes enough oxygen in through normal breathing. In other words: at a certain level of intensity you start to pant. Supplementation with dark chocolate apparently results in the body being more economical with oxygen during moderately intense exercise, and that athletes only start panting to get enough oxygen at a higher level of intensity.
The researchers suspect that dark chocolate improves performance by boosting the blood concentration of nitrogen monoxide or NO. “Dark chocolate, unique to other dietary nitrate supplements is hypothesised to mediate NO production through endothelium-dependent effects; related to flavanols’ ability to supress vascular arginase enzyme activity, thus increasing the production of NO”, they wrote.
“It can be concluded that ingestion of dark chocolate for 14 days reduced the oxygen cost of moderate intensity exercise and may be an effective ergogenic aid for short-duration moderate intensity exercise”, the researchers write. “However, future double-blinded studies will need to confirm this effect.”
Dark chocolate supplementation reduces the oxygen cost of moderate intensity cycling
Dark chocolate (DC) is abundant in flavanols which have been reported to increase the bioavailability and bioactivity of nitric oxide (NO). Increasing NO bioavailability has often demonstrated reduced oxygen cost and performance enhancement during submaximal exercise.
Nine moderately-trained male participants volunteered to undertake baseline (BL) measurements that comprised a cycle V.O2maxV.O2max test followed by cycling at 80 % of their established gas exchange threshold (GET) for 20-min and then immediately followed by a two-minute time-trial (TT). Using a randomised crossover design participants performed two further trials, two weeks apart, with either 40 g of DC or white chocolate (WC) being consumed daily. Oxygen consumption, RER, heart rate and blood lactate (BLa) were measured during each trial.
DC consumption increased GET and TT performance compared to both BL and WC (P?< ?0.05). DC consumption increased V.O2maxV.O2max by 6 % compared to BL (P?0.05), but did not reach statistical significance compared to WC. There were no differences in the moderate-intensity cycling for V.O2V.O2 , RER, BLa and heart rate between conditions, although, V.O2V.O2 and RER exhibited consistently lower trends following DC consumption compared to BL and WC, these did not reach statistical significance. Conclusion Chronic supplementation with DC resulted in a higher GET and enhanced TT performance. Consequently, ingestion of DC reduced the oxygen cost of moderate intensity exercise and may be an effective ergogenic aid for short-duration moderate intensity exercise. Source: http://jissn.biomedcentral.com/articles/10.1186/s12970-015-0106-7