Neurophysiology of Skin Thermal Sensations

Filingeri, Davide

doi:10.1002/cphy.c150040

Cited by 95 publications

(78 citation statements)

References 301 publications

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“…In humans and primates, fast‐conducting myelinated Aδ‐fibres innervate the skin with varying density depending on the skin site (Filingeri, ), selectively respond to skin cooling (range 30–14°C; maximal impulse frequency within 27–22°C range; conduction velocity 3.8–4.4 m s −1 ; receptive field <1 mm) and mediate innocuous cold sensations (Darian‐Smith et al . ).…”

Section: Introductionmentioning

confidence: 99%

“…). In contrast, unmyelinated C fibres respond to skin warming, fire optimally within a temperature range of 30–45°C (maximal impulse frequency within 36–42°C range; conduction velocity 0.4–2 m s −1 receptive field <1 mm) and mediate innocuous warm sensations (Konietzny & Hensel, ; Filingeri, ; but note that a subclass of C fibre, i.e. C2, responds to noxious skin cooling <15°C and mediates noxious cold sensations; Campero et al .…”

Section: Introductionmentioning

confidence: 99%

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Warm hands, cold heart: progressive whole‐body cooling increases warm thermosensitivity of human hands and feet in a dose‐dependent fashion

Filingeri

Morris

Jay

2016

Experimental Physiology

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Edited by: Paul Fadel New Findings r What is the central question of this study?Investigations on inhibitory/facilitatory modulation of vision, touch and pain show that conditioning stimuli outside the receptive field of testing stimuli modulate the central processing of visual, touch and painful stimuli. We asked whether contextual modulation also exists in human temperature integration. r What is the main finding and its importance?Progressive decreases in whole-body mean skin temperature (the conditioning stimulus) significantly increased local thermosensitivity to skin warming but not cooling (the testing stimuli) in a dose-dependent fashion. In resembling the central mechanisms underlying endogenous analgesia, our findings point to the existence of an endogenous thermosensory system in humans that could modulate local skin thermal sensitivity to facilitate thermal behaviour.Although inhibitory/facilitatory central modulation of vision and pain has been investigated, contextual modulation of skin temperature integration has not been explored. Hence, we tested whether progressive decreases in whole-body mean skin temperature (T sk ; a large conditioning stimulus) alter the magnitude estimation of local warming and cooling stimuli applied to hairy and glabrous skin. On four separate occasions, eight men (27 ± 5 years old) underwent a 30 min whole-body cooling protocol (water-perfused suit; temperature, 5°C), during which a quantitative thermosensory test, consisting of reporting the perceived magnitude of warming and cooling stimuli (±8°C from 30°C baseline) applied to the hand (palm/dorsum) and foot (sole/dorsum), was performed before cooling and every 10 min thereafter. 101 Contextual modulation of skin temperature integration stimuli, in a dose-dependent fashion. In highlighting a novel feature of human temperature integration, these findings point to the existence of an endogenous thermosensory system that could modulate local skin thermal sensitivity in relationship to whole-body thermal states.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Warm hands, cold heart: progressive whole‐body cooling increases warm thermosensitivity of human hands and feet in a dose‐dependent fashion

Filingeri

Morris

Jay

2016

Experimental Physiology

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“…In humans, magnitude estimation of skin thermal sensations is determined by afferent impulses produced by peripheral skin thermoreceptors (Filingeri et al, 2017b) and by their integration operated by central (sub-cortical/cortical) neural structures (Filingeri, 2016). Due to the central, and not peripheral, nature of MS lesions within the nervous system (Noseworthy et al, 2000), it could be therefore suggested that the pronounced reduction in cold sensitivity observed in our relapsingremitting MS group could be dependent on heat-induced alterations in the processing of afferent somatosensory inputs within central neural centers.…”

Section: Magnitude Estimation Of Warm and Cold Stimulimentioning

confidence: 99%

“…Indeed, the neuro-anatomical and -physiological differences between the human peripheral and central pathways for cold (served by myelinated nerve fibers) and warm (served by non-myelinated nerve fibers) skin thermosensitivity (Dostrovsky & Craig, 1996;Iannetti et al, 2003), allow for the independent assessment of myelinated and nonmyelinated afferent neural pathways (Filingeri, 2016). The opportunity to concurrently and non-invasively evaluate both myelinated and non-myelinated afferent pathways is particularly relevant in the context of a demyelinating disease such as MS (Noseworthy et al, 2000).…”

Section: Introductionmentioning

confidence: 99%

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Afferent thermosensory function in relapsing–remitting multiple sclerosis following exercise‐induced increases in body temperature

Filingeri

Chaseling

Hoang

et al. 2017

Experimental Physiology

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New Findings What is the central question of this study?Between 60 and 80% of multiple sclerosis (MS) patients experience transient worsening of symptoms with increased body temperature (heat sensitivity). As sensory abnormalities are common in MS, we asked whether afferent thermosensory function is altered in MS following exercise‐induced increases in body temperature. What is the main finding and its importance?Increases in body temperature of as little as ∼0.4°C were sufficient to decrease cold, but not warm, skin thermosensitivity (∼10%) in MS, across a wider temperature range than in age‐matched healthy individuals. These findings provide new evidence on the impact of heat sensitivity on afferent function in MS, which could be useful for clinical evaluation of this neurological disease. In multiple sclerosis (MS), increases in body temperature result in transient worsening of clinical symptoms (heat sensitivity or Uhthoff's phenomenon). Although the impact of heat sensitivity on efferent physiological function has been investigated, the effects of heat stress on afferent sensory function in MS are unknown. Hence, we quantified afferent thermosensory function in MS following exercise‐induced increases in body temperature with a new quantitative sensory test. Eight relapsing–remitting MS patients (three men and five women; 51.4 ± 9.1 years of age; Expanded Disability Status Scale score 2.8 ± 1.1) and eight age‐matched control (CTR) subjects (five men and three women; 47.4 ± 9.1 years of age) rated the perceived magnitude of two cold (26 and 22°C) and two warm stimuli (34 and 38°C) applied to the dorsum of the hand before and after 30 min cycling in the heat (30°C air; 30% relative humidity). Exercise produced similar increases in mean body temperature in MS [+0.39°C (95% CI: +0.21, +0.53) P = 0.001] and CTR subjects [+0.41°C (95% CI: +0.25, +0.58) P = 0.001]. These changes were sufficient to decrease thermosensitivity significantly to all cold [26°C stimulus, −9.1% (95% CI: −17.0, −1.5), P = 0.006; 22°C stimulus, −10.6% (95% CI: −17.3, −3.7), P = 0.027], but not warm, stimuli in MS. Contrariwise, CTR subjects showed sensitivity reductions to colder stimuli only [22°C stimulus, −9.7% (95% CI: −16.4, −3.1), P = 0.011]. The observation that reductions in thermal sensitivity in MS were confined to the myelinated cold‐sensitive pathway and extended across a wider (including milder and colder) temperature range than what is observed in CTR subjects provides new evidence on the impact of rising body temperature on afferent neural function in MS. Also, our findings support the use of our new approach to investigate afferent sensory function in MS during heat stress.

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Liquid‐Metal‐Based Dynamic Thermoregulating and Self‐Powered Electronic Skin

Xiang

Liu

Jiang

et al. 2021

Adv Funct Materials

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Electronic skin (E‐skin) is an emerging and promising human‐machine interface. Besides skin‐like functions of tactile perception and stretchability, skin‐like comfortabilities, including breathability, moisture permeability, softness, and thermoregulating ability are, also crucial factors for E‐skins. Thermoregulation is one of the most important roles of human skin. People can feel comfortable when their skins are regulated at a certain range of temperature. Moreover, it is a dynamic process according to the surrounding temperature. Current E‐skins do not have the function of dynamically regulating their temperature. Here, a thermoregulating E‐skin (TE‐skin) based on liquid metal as a phase change material with its melting point in the comfortable temperature range of human skin is reported. Compared with conventional E‐skins, the TE‐skin can dynamically termoregulate according to the surrounding temperature through a phase change. Combining with the principle of triboelectric nanogenerator, the TE‐skin is also able to act as a self‐powered sensor. Based on the self‐powered TE‐skin, an intelligent dialing communications system is further developed, which can be used to call a cellphone on human skin. For the first time, this study introduces the dynamic thermoregulating concept to E‐skins and could open up new opportunities for E‐skin developments.

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Neurophysiology of Skin Thermal Sensations

Cited by 95 publications

References 301 publications

Warm hands, cold heart: progressive whole‐body cooling increases warm thermosensitivity of human hands and feet in a dose‐dependent fashion

Warm hands, cold heart: progressive whole‐body cooling increases warm thermosensitivity of human hands and feet in a dose‐dependent fashion

Afferent thermosensory function in relapsing–remitting multiple sclerosis following exercise‐induced increases in body temperature

Liquid‐Metal‐Based Dynamic Thermoregulating and Self‐Powered Electronic Skin

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