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Dear editor,
In this letter I would like to challenge the correctness of the term cold-induced vasodilation (CIVD) in a recent paper of Flouris et al. (2008) in this journal.
The first author who described CIVD was Sir Thomas Lewis, who observed that skin vasodilation occurred in the fingers 5–10 min after exposure to cold (Lewis 1930). He found that this reaction did not occur when the water temperature in which the fingers were immersed was higher than 18°C. The lower the temperature, the more marked the reaction was. Most experiments conducted since this time has used water temperatures of 0, 5 or 8°C to evoke CIVD (Daanen 2003).
It is also possible to evoke CIVD responses using exposure to cold air. Kramer and Schulze (1948) observed that the timing of the CIVD responses was similar for ice water bath immersion and exposure to −18°C air in a still air box. They also observed that while most subjects showed a CIVD response in ice water, the response was often absent when the fingers were exposed to cold air. More recent studies confirmed that the good reproducibility of CIVD in water (O’Brien 2005) and the poor reproducibility of CIVD in cold air, in particular in the toes (Cheung and Mekjavic 2007; Van der Struijs et al. 2008). Wind speed is an important factor that increases the number of evoked CIVD responses; Brajkovic and Ducharme (2004) showed that the number of evoked CIVD responses increased from 3% at 2 m/s wind to 53% at 8 m/s wind speed.
In the study of Flouris et al. (2008), 10 subjects were exposed to a cold environment (−20°C) dressed in arctic clothing including thin gloves and arctic mittens and the finger temperatures were monitored. The term CIVD was used to describe the observed changes.
However, in this study, the extremities were not exposed to cold and the term CIVD thus seems inappropriate. The finger temperatures ranged from 7.2 to 33.5°C and the observed fluctuations during the experiment did not resemble the typical cyclic CIVD reaction. Although one cannot rule out that some CIVD may have occurred for temperatures just above 7.2°C, it is more likely that the observed temperature fluctuations are attempts of the body to release body heat through the fingers as a part of the normal thermoregulatory process; rather than an expression of CIVD. The mean body temperature (weighted average of core and mean skin temperature) fluctuated around 36.5°C, which is relatively high and stresses the need to release body heat. It is well documented that the finger blood flow shows a sudden increase above a certain threshold in body core temperature and is modified by mean skin temperature (Wyss et al. 1974; Wenger et al. 1975; Wyss et al. 1975; Daanen et al. 1992).
In summary, the observed fluctuations in finger skin temperature in the paper of Flouris et al. (2008) should not be termed CIVD, and are better attributed to heat loss mechanisms that depend on body core temperature and mean skin temperature.
References
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Open Access This is an open access article distributed under the terms of the Creative Commons Attribution Noncommercial License (https://creativecommons.org/licenses/by-nc/2.0), which permits any noncommercial use, distribution, and reproduction in any medium, provided the original author(s) and source are credited.
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Daanen, H. Cold-induced vasodilation. Eur J Appl Physiol 105, 663–664 (2009). https://doi.org/10.1007/s00421-008-0958-5
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DOI: https://doi.org/10.1007/s00421-008-0958-5