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The total polyphenol content of various commercial cocoa beverages, with and without the addition of cow's milk

Published online by Cambridge University Press:  22 January 2016

M. Santos
Affiliation:
Functional Food Centre, Department of Sport and Health Sciences, Oxford Brookes University, Gipsy Lane, Headington, Oxford OX3 0BP.
S. Coe
Affiliation:
Functional Food Centre, Department of Sport and Health Sciences, Oxford Brookes University, Gipsy Lane, Headington, Oxford OX3 0BP.
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Abstract

Type
Abstract
Copyright
Copyright © The Authors 2016 

Polyphenols, specifically flavonoids are found abundantly in many plant foods such as fruit, vegetables, tea and cocoa, and are beneficial for health. Specifically, polyphenols in cocoa may reduce chronic inflammation( Reference Simos, Verginadis, Toliopoulos, Velalopoulou, Karagounis, Karkabounas and Evangelou 1 , Reference Panickar and Anderson 2 ). The purity of cocoa influences the polyphenol content, with high purity cocoa powder containing a greater concentration of polyphenols compared to more processed powders. Cocoa powder can be made into beverage form, and the addition of ingredients such as diary milk may alter the bioavailability of the polyphenols in a sample( Reference Roura, Andrés-Lacueva, Estruch, Mata Bilbao, Izquierdo-Pulido and Lamuela-Raventós 3 ).

The aim of this study was to determine the total polyphenol content of a range of cocoa beverages, with and without dairy cows milk. From the results of this study, the two beverages with the least and the greatest polyphenol content will be determined.

Total polyphenol content of the test beverages was measured using the Folin-Ciocalteu method( Reference Sharma and Gujral 4 ). Cocoa drinks were purchased from Waitrose supermarket and were made using a standard protocol. Table 1 shows the various cocoa powders used and the polyphenol content of each beverage per gram of sample, with or without semi skimmed milk.

Table 1.

Values are means of three independent experiments (One-way ANOVA, Tukey post hoc). SD = standard deviation. *= significantly greater polyphenol content compared to the same drink made with water. a,b = significantly different polyphenol content between cocoa powders; p < 0·05. Cocoa powders included: Green & Blacks Organic Cocoa Fair Trade1; Cadbury Fair Trade Drinking Chocolate2; Waitrose Luxuriously Rich Drinking Chocolate3; Cadbury Fair Trade Bournville Cocoa4; Options Instant White Chocolate5

Overall, when made with both water and milk the pure cocoa beverages (Green & Blacks and Cadbury Bournville) were shown to be richer in total polyphenols compared to lower purity cocoa powder varieties. The addition of semi skimmed milk to Green & Blacks and Cadbury Bournville cocoa beverages significantly increased the amount of available polyphenols.

These results show that milk may enhance the in vitro concentration of cocoa polyphenols, yet human studies would need to be performed. Although the addition of milk to cocoa powder has been shown to alter the absorption rate of polyphenols in humans, the overall polyphenol concertation was shown to be similar compared to the beverages made with water( Reference Keogh, Mclnerney and Clifton 5 ). The results from the current trial will be used for a future human trial looking at the effect of a high polyphenol pure cocoa beverage compared to a low polyphenol control on chronic inflammatory status.

References

1. Simos, YV, Verginadis, II, Toliopoulos, TI, Velalopoulou, AP, Karagounis, IV, Karkabounas, SC & Evangelou, AM (2012) Redox Rep, 17, 181–6.Google Scholar
2. Panickar, KS & Anderson, RA (2011) Neurosci, 183, 114.Google Scholar
3. Roura, E, Andrés-Lacueva, C, Estruch, R, Mata Bilbao, ML, Izquierdo-Pulido, M & Lamuela-Raventós, RM (2008) Brit J Nutr, 100, 846851.Google Scholar
4. Sharma, P & Gujral, HS (2010) Food Chem, 120, 673678.Google Scholar
5. Keogh, JB, Mclnerney, J & Clifton, PM (2007) J Food Sci, 72, S230S233.CrossRefGoogle Scholar
Figure 0

Table 1.