A meta-analytic approach to quantify the dose-response relationship between melatonin and core temperature.
Study Goal
The researchers aimed to quantify the dose-response relationship between exogenous melatonin and core body temperature reduction and explore moderating variables like sex and measurement site.
Results Summary
The meta-analysis found a logarithmic dose-response relationship, with a 5-mg dose reducing core temperature by ~0.2°C. Higher doses (>5 mg) did not significantly increase this effect.
Population
193 participants (mixed sexes) from 30 data-sets.
Effective Dosage
0-5 mg (higher doses also tested but showed negligible additional effects).
Duration
Not specified.
Interactions
None mentioned.
| Intervention | Direction | Endpoint | Population | Dosage | Impact | Claim # |
|---|---|---|---|---|---|---|
melatonin | decrease | body temperature | athletes | - | reduction | #1 |
exogenous melatonin | decrease | body core temperature | 193 participants | - | effects | #2 |
exogenous melatonin | decrease | core temperature | 193 participants | 0.21 °C (0.18-0.24 °C) | pooled reduction | #3 |
melatonin | decrease | temperature lowering effects | - | logarithmic | dose-response relationship | #4 |
melatonin | decrease | temperature | - | ~0.00-0.22 °C | reduced temperature | #5 |
melatonin | decrease | oral temperature | - | 0.13 °C (0.05-0.20 °C) | pooled mean reduction | #6 |
melatonin | decrease | tympanic temperature | - | 0.26 °C (0.20-0.32 °C) | pooled mean reduction | #7 |
melatonin | decrease | rectal temperature | - | 0.22 °C (0.19-0.25 °C) | pooled mean reduction | #8 |
5-mg dose of melatonin | decrease | core temperature | - | ~0.2 °C | lowered | #9 |
A melatonin-mediated reduction in body temperature could be useful as a "pre-cooling" intervention for athletes, as long as the melatonin dose is optimised so that substantial soporific effects are not induced. However, the melatonin-temperature dose-response relationship is unclear in humans. Individual studies have involved small samples of different sexes and temperature measurement sites. Therefore, we meta-analysed the effects of exogenous melatonin on body core temperature to quantify the dose-response relationship and to explore the influence of moderating variables such as sex and measurement site. Following a literature search, we meta-analysed 30 data-sets involving 193 participants and 405 ingestions of melatonin. The outcome was the mean difference (95 % confidence limits) in core temperature between the melatonin and placebo-controlled conditions in each study, weighted by the reciprocal of each standard error of the difference. The mean (95 % confidence interval) pooled reduction in core temperature was found to be 0.21 °C (0.18-0.24 °C). The dose-response relationship was found to be logarithmic (P < 0.0001). Doses of 0-5 mg reduced temperature by ~0.00-0.22 °C. Any further reductions in temperature were negligible with doses >5 mg. The pooled mean reduction was 0.13 °C (0.05-0.20 °C) for oral temperature vs 0.26 °C (0.20-0.32 °C) for tympanic and 0.22 °C (0.19-0.25 °C) for rectal temperature. In conclusion, our meta-regression revealed a logarithmic dose-response relationship between melatonin and its temperature lowering effects. A 5-mg dose of melatonin lowered core temperature by ~0.2 °C. Higher doses do not substantially increase this hypothermic effect and may induce greater soporific effects.