Factors influencing serum caffeine concentrations following caffeine ingestion

Tina L Skinner; David G Jenkins; Michael D Leveritt; Alastair McGorm; Kate A Bolam; Jeff S Coombes; Dennis R Taaffe

doi:10.1016/j.jsams.2013.07.006

Factors influencing serum caffeine concentrations following caffeine ingestion

J Sci Med Sport. 2014 Sep;17(5):516-20. doi: 10.1016/j.jsams.2013.07.006. Epub 2013 Aug 7.

Authors

Tina L Skinner¹, David G Jenkins², Michael D Leveritt², Alastair McGorm², Kate A Bolam², Jeff S Coombes², Dennis R Taaffe³

Affiliations

¹ The University of Queensland, School of Human Movement Studies, Australia. Electronic address: tskinner@hms.uq.edu.au.
² The University of Queensland, School of Human Movement Studies, Australia.
³ The University of Queensland, School of Human Movement Studies, Australia; The University of Newcastle, School of Environmental and Life Sciences, Australia; Edith Cowan University, Edith Cowan University Health and Wellness Institute, Australia.

PMID: 23932441
DOI: 10.1016/j.jsams.2013.07.006

Abstract

Objectives: To determine whether differences in training status, body composition and/or habitual caffeine intake influenced serum caffeine concentrations following caffeine ingestion.

Design: Single-blind.

Methods: Trained cyclists/triathletes (n=14) and active (n=14) males consumed 6 mg kg(-1) anhydrous caffeine. Peak, total and time to peak serum caffeine concentrations were determined from venous blood samples at baseline and 6 time-points over 4h following intake. Body composition was assessed by dual energy X-ray absorptiometry and habitual caffeine intake by a questionnaire.

Results: Trained cyclists/triathletes had 16% lower peak caffeine concentrations following caffeine ingestion compared to active individuals, although this was not statistically significant (p=0.066). There was no significant difference between trained cyclists/triathletes and active males in total (p=0.131) or time to peak (p=0.249) serum caffeine concentrations. Fat mass was significantly associated with total (r=0.427, p=0.038) but not peak (r=0.343, p=0.101) or time to peak serum caffeine concentration (β=0.00008, p=0.961). There were no associations between habitual caffeine intake and peak, total or time to peak serum caffeine concentrations.

Conclusions: Following caffeine ingestion three findings from the study were evident: (1) endurance-trained athletes trended towards lower peak caffeine concentrations compared to active males; (2) higher fat mass was associated with higher concentrations of caffeine in the blood over 4h, and (3) habitual caffeine intake does not appear to influence serum caffeine concentrations. Identification of the optimal conditions to ensure peak availability of caffeine within the blood and/or overcoming some of the variation in how individuals respond to caffeine requires consideration of the training status and body composition of the athlete.

Keywords: Caffeine; DXA; Ergogenic; Exercise; Sport; Supplement.

MeSH terms

Adolescent
Adult
Body Composition
Caffeine / administration & dosage*
Caffeine / blood*
Caffeine / pharmacokinetics
Exercise Test
Female
Humans
Male
Single-Blind Method
Young Adult

Substances

Caffeine