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Acute Low and Moderate Doses of a Caffeine-Free Polyphenol-Rich Coffeeberry Extract Improve Feelings of Alertness and Fatigue Resulting from the Performance of Fatiguing Cognitive Tasks

  • Rachelle A. Reed
  • Ellen Siobhan Mitchell
  • Caroline Saunders
  • Patrick J. O’ConnorEmail author
Original Research

Abstract

Claims that ingested nutrients can enhance cognitive performance are common but rarely tested. Here, the influence of acute consumption of a polyphenol-rich, non-caffeinated coffeeberry extract on performance of a series of fatiguing cognitive tasks, motivation to do the cognitive tasks, and mood state responses were tested in 30 healthy adults using a block-randomized, double-blind, placebo-controlled, cross-over design. The effects of 300 and 100 mg coffeeberry extracts were compared to beverages without the extract (placebo) and with 75 mg caffeine (positive control). Outcomes were measured before and twice after beverage consumption. Significant self-reported mood effects were found for the positive control indicating sample responsiveness. The coffeeberry extract beverages had non-significant effects on the cognitive test battery performance and motivation to complete these cognitive tasks. The ingestion of the 300 mg and 100 mg coffeeberry extract beverages significantly attenuated perceptions of increased fatigue and decreased alertness resulting from the completion of the fatiguing cognitive tasks. The magnitude of these mental energizing effects was similar for the low and moderate dose extract beverages; thus, there was not support for a dose-response effect. It was concluded that beverages containing low (100 mg) and moderate (300 mg) amounts of a polyphenol-rich, non-caffeinated coffeeberry extract significantly attenuate both increases in self-reported fatigue and decreases in self-reported alertness resulting from the completion of a series of fatiguing cognitive tasks.

Keywords

Cognition Mental energy Mental fatigue Polyphenols 

Notes

Acknowledgements

The authors thank the participants for their efforts. The hard work of Katie Fritz and Brian Huong is acknowledged for assistance with data collection, entry, and cleaning. The current address for Caroline Saunders is Suntory Beverage & Food Europe LTD, Reading, UK.

Funding Information

The University of Georgia received funding from PepsiCo, Inc. to support this investigation (Contract No. 61660).

Compliance with Ethical Standards

Informed consent was obtained from every participant in the study. The University of Georgia’s Institutional Review Board approved all study protocols and materials.

Conflict of Interest

Drs. Reed and O’Connor have no conflicts of interest. Dr. Saunders has no current conflict of interest but was previously employed as a nutrition scientist at PepsiCo. Dr. Mitchell has a conflict of interest because she is currently senior principal scientist for PepsiCo Global Nutrition R&D.

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Copyright information

© Springer Nature Switzerland AG 2018

Authors and Affiliations

  1. 1.University of GeorgiaAthensUSA
  2. 2.PepsiCo Global Nutrition R&DPurchaseUSA

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