Hot Environments Decrease Exercise Capacity While Elevating
Multiple Neurotransmitters Independent of Humidity
Jiexiu Zhao
1
, Lili Lai
1
, Stephen S. Cheung
2
, Shuqiang Cui
3
, Nan An
1
,
Wenping Feng
1
, Santiago Lorenzo
4
and Ye Tian
1
1
Sport Biological Center, China Institute of Sport Science, Beijing, China
2
Department of Kinesiology, Brock University, Ontario, Canada
3
Departments of Kinesiology, Beijing Institute of Sport Science, Beijing, China
4
L|E|C|O|M, Bradenton, FL, U.S.A.
1 INTRODUCTION
The purpose of this study was to test the hypothesis
that different neurotransmitters and hormones are
presented at exercise fatigue in hot temperatures
with differing relative humidities (RH).
2 METHODS
Eight trained male athletes performed a graded
maximum oxygen uptake (VO2max) test in five
different environmental conditions: 21°C/20% RH
(Normal); 33°C/20% RH (Hot 20%), 33°C/40% RH
(Hot 40%), 33°C/60% RH (Hot 60%), and
33°C/80% RH (Hot 80%). Blood samples were
taken pre- and post-exercise and analyzed for
noradrenaline (NA), adrenaline (ADR), dopamine
(DA), serontonin (5-HT), 5-hydroxyindoleacetic
acid (5-HIAA), and prolactin (PRL). Weight, oral
temperature and skin temperature were recorded pre-
and post-exercise. Heart rate was monitored
continuously throughout exercise.
3 RESULTS
Compared to Normal, Hot 20%, Hot 40% and Hot
80% had lower VO2max levels (P < 0.05). Pooling
data across all five conditions, NA (P < 0.0001),
PRL (P < 0.0001), 5-HT (P = 0.002), 5-HIAA (P =
0.029), and DA (P = 0.016) levels were affected by
exercise, with the levels each being significantly
associated with performance time. However, ADR
did not show any significant effect between pre- and
post-exercise (P = 0.187).
4 DISCUSSION
The main findings of this study were two aspects.
First, hot-wet condition (Hot 80%) and hot-dry
conditions (Hot 20%, Hot 40%) have similar
negative effects on VO2max performance. This is in
a protocol with a relative short duration – “in real”
life – e.g. a prolonged competition the negative
effect of high humidity on thermoregulation would
be expected to aggravate hyperthermia and hence
have a larger effect on VO2max and performance.
Second, irrespective of thermal status, NA, DA,
PRL, 5-HT, and 5-HIAA are associated with the
performance time of the VO2max protocol.
Although the finding of neurotransmitters being
impacted by exercise fatigue in heat is not a new
concept, this is one of the first laboratory studies to
systematically investigate the effects of hot
temperature and different humidities on multiple
neurotransmitters simultaneously. The effects of a
hot environment on aerobic performance have been
well documented, but the specific influence of
relative humidity on performance and on the
physiological response to exercise remains largely
unexplored. Although exercise capacity at moderate
intensity in a warm environment is progressively
impaired as the relative humidity increases, the
present investigation demonstrated that VO2max
was generally lower in hot conditions than in
Normal and there were no differences across
humidity levels. There was a significant effect of
time for NA, PRL, 5-HT, 5-HIAA, and DA
concentrations after exercise in the five different
conditions. The levels of NA, DA, PRL, 5-HT, and
5-HIAA were strongly associated with exercise time,
suggesting that the duration and/or intensity of
exercise had an important influence on
neurotransmitter levels irrespective of environmental
conditions. High correlation of NA, DA and 5-HT
with performance time of VO2max provides support
for the hypothesis that central fatigue should be
determined by the collaboration of the different
neurotransmitter systems, with the most important
role possibly being for the catecholamines DA, NA,
and 5-HT in high temperature.
Zhao J., Lai L., S. Cheung S., Cui S., An N., Feng W., Lorenzo S. and Tian Y..
Hot Environments Decrease Exercise Capacity While Elevating Multiple Neurotransmitters Independent of Humidity.
Copyright
c
2014 SCITEPRESS (Science and Technology Publications, Lda.)
Figure 1: Relationships between performance time versus post-exercise concentrations of Dopamine (A), ADRrenaline (B),
Noradrenaline (C), Serotonin (D), 5-hydroxyindoleacetic acid (E) and Prolactin (F).
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