Variability of measurements of sweat sodium using the regional absorbent-patch method

There is interest in including recommendations for the replacement of the sodium lost in sweat in individualized hydration plans for athletes. Although the regional absorbent-patch method provides a practical approach to measuring sweat sodium losses in field conditions, there is a need to understan...

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Bibliographic Details
Published in:International journal of sports physiology and performance 2014-09, Vol.9 (5), p.832-838
Main Authors: Dziedzic, Christine E, Ross, Megan L, Slater, Gary J, Burke, Louise M
Format: Article
Language:English
Subjects:
Absorption
Adult
Bicycling
Biomarkers - metabolism
Electric Conductivity
Exercise
Hot Temperature
Humans
Ion-Selective Electrodes
Male
Models, Biological
Photometry
Reproducibility of Results
Sodium
Sodium - metabolism
Specimen Handling - instrumentation
Specimen Handling - methods
Sweat - metabolism
Sweating
Time Factors
Water-Electrolyte Balance
Young Adult
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Summary:There is interest in including recommendations for the replacement of the sodium lost in sweat in individualized hydration plans for athletes. Although the regional absorbent-patch method provides a practical approach to measuring sweat sodium losses in field conditions, there is a need to understand the variability of estimates associated with this technique. Sweat samples were collected from the forearms, chest, scapula, and thigh of 12 cyclists during 2 standardized cycling time trials in the heat and 2 in temperate conditions. Single measure analysis of sodium concentration was conducted immediately by ion-selective electrodes (ISE). A subset of 30 samples was frozen for reanalysis of sodium concentration using ISE, flame photometry (FP), and conductivity (SC). Sweat samples collected in hot conditions produced higher sweat sodium concentrations than those from the temperate environment (P = .0032). A significant difference (P = .0048) in estimates of sweat sodium concentration was evident when calculated from the forearm average (mean ± 95% CL; 64 ± 12 mmol/L) compared with using a 4-site equation (70 ± 12 mmol/L). There was a high correlation between the values produced using different analytical techniques (r2 = .95), but mean values were different between treatments (frozen FP, frozen SC > immediate ISE > frozen ISE; P < .0001). Whole-body sweat sodium concentration estimates differed depending on the number of sites included in the calculation. Environmental testing conditions should be considered in the interpretation of results. The impact of sample freezing and subsequent analytical technique was small but statistically significant. Nevertheless, when undertaken using a standardized protocol, the regional absorbent-patch method appears to be a relatively robust field test.
ISSN:1555-0265
1555-0273
DOI:10.1123/ijspp.2013-0480