Thermal and tactile interactions in the perception of local skin wetness at rest and during exercise in thermo-neutral and warm environments
Thermal and tactile interactions in the perception of local skin wetness at rest and during exercise in thermo-neutral and warm environments
The central integration of thermal (i.e. cold) and mechanical (i.e. pressure) sensory afferents is suggested as to underpin the perception of skin wetness. However, the role of temperature and mechanical inputs, and their interaction, is still unclear. Also, it is unknown whether this intra-sensory interaction changes according to the activity performed or the environmental conditions. Hence, we investigated the role of peripheral cold afferents, and their interaction with tactile afferents, in the perception of local skin wetness during rest and exercise in thermo-neutral and warm environments. Six cold-dry stimuli, characterized by decreasing temperatures [i.e. −4, −8 and −15 °C below the local skin temperature (Tsk)] and by different mechanical pressures [i.e. low pressure (LP): 7 kPa; high pressure (HP): 10 kPa], were applied on the back of 8 female participants (age 21 ± 1 years), while they were resting or cycling in 22 or 33 °C ambient temperature. Mean and local Tsk, thermal and wetness perceptions were recorded during the tests. Cold-dry stimuli produced drops in Tsk with cooling rates in a range of 0.06–0.4 °C/s. Colder stimuli resulted in increasing coldness and in stimuli being significantly more often perceived as wet, particularly when producing skin cooling rates of 0.18 °C/s and 0.35 °C/s. However, when stimuli were applied with HP, local wetness perceptions were significantly attenuated. Wetter perceptions were recorded during exercise in the warm environment. We conclude that thermal inputs from peripheral cutaneous afferents are critical in characterizing the perception of local skin wetness. However, the role of these inputs might be modulated by an intra-sensory interaction with the tactile afferents. These findings indicate that human sensory integration is remarkably multimodal.
121-130
Filingeri, Davide
42502a34-e7e6-4b49-b304-ce2ae0bf7b24
Redortier, Bernard
62554e66-2f29-4574-be82-1ad8fea25035
Hodder, Simon
590bb6c3-a326-444a-bef3-67074b43cef8
Havenith, George
b10502e4-2c20-4881-85bd-76d87087f02d
1 January 2014
Filingeri, Davide
42502a34-e7e6-4b49-b304-ce2ae0bf7b24
Redortier, Bernard
62554e66-2f29-4574-be82-1ad8fea25035
Hodder, Simon
590bb6c3-a326-444a-bef3-67074b43cef8
Havenith, George
b10502e4-2c20-4881-85bd-76d87087f02d
Filingeri, Davide, Redortier, Bernard, Hodder, Simon and Havenith, George
(2014)
Thermal and tactile interactions in the perception of local skin wetness at rest and during exercise in thermo-neutral and warm environments.
Neuroscience, .
(doi:10.1016/j.neuroscience.2013.11.019).
Abstract
The central integration of thermal (i.e. cold) and mechanical (i.e. pressure) sensory afferents is suggested as to underpin the perception of skin wetness. However, the role of temperature and mechanical inputs, and their interaction, is still unclear. Also, it is unknown whether this intra-sensory interaction changes according to the activity performed or the environmental conditions. Hence, we investigated the role of peripheral cold afferents, and their interaction with tactile afferents, in the perception of local skin wetness during rest and exercise in thermo-neutral and warm environments. Six cold-dry stimuli, characterized by decreasing temperatures [i.e. −4, −8 and −15 °C below the local skin temperature (Tsk)] and by different mechanical pressures [i.e. low pressure (LP): 7 kPa; high pressure (HP): 10 kPa], were applied on the back of 8 female participants (age 21 ± 1 years), while they were resting or cycling in 22 or 33 °C ambient temperature. Mean and local Tsk, thermal and wetness perceptions were recorded during the tests. Cold-dry stimuli produced drops in Tsk with cooling rates in a range of 0.06–0.4 °C/s. Colder stimuli resulted in increasing coldness and in stimuli being significantly more often perceived as wet, particularly when producing skin cooling rates of 0.18 °C/s and 0.35 °C/s. However, when stimuli were applied with HP, local wetness perceptions were significantly attenuated. Wetter perceptions were recorded during exercise in the warm environment. We conclude that thermal inputs from peripheral cutaneous afferents are critical in characterizing the perception of local skin wetness. However, the role of these inputs might be modulated by an intra-sensory interaction with the tactile afferents. These findings indicate that human sensory integration is remarkably multimodal.
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Accepted/In Press date: 8 November 2013
e-pub ahead of print date: 20 November 2013
Published date: 1 January 2014
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Local EPrints ID: 449188
URI: http://eprints.soton.ac.uk/id/eprint/449188
ISSN: 0306-4522
PURE UUID: 164b0aa1-7887-4cb7-8eba-d7c2c7a329a2
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Date deposited: 19 May 2021 16:31
Last modified: 17 Mar 2024 04:05
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Author:
Bernard Redortier
Author:
Simon Hodder
Author:
George Havenith
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