Relationships Between Skin Temperature and Temporal Summation of Heat and  Cold Pain

Mauderli, André P.; Vierck, Charles J.; Cannon, Richard L.; Rodrigues, Anthony; Shen, Chiayi

doi:10.1152/jn.01066.2002

Cited by 42 publications

(33 citation statements)

References 58 publications

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“…Body temperature is known to rise when strong pain is felt [9], and this supports the rise in VAS score observed in the current study. Postoperative pain, a stressor in both humans and animals, has been previously reported to alter several molecular/ biochemical stress markers including adrenocorticotropic hormone (ACTH) [1], corticosteroids [11], ornithine decarboxylase [14], and core body temperature [2].…”

Section: Discussionsupporting

confidence: 90%

Gender differences in postoperative pain after laparoscopic cholecystectomy

et al. 2006

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Section: Discussionsupporting

confidence: 90%

Gender differences in postoperative pain after laparoscopic cholecystectomy

et al. 2006

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“…This population appears to be functionally distinct from conventional C-type polymodal nociceptor neurons that exhibit broad spikes and lack inward rectification (Scroggs et al, 1994;Fang et al, 2005). The high-threshold cold receptors we describe probably underlie the common sensation of unpleasant cold discomfort (Mauderli et al, 2003), accompanying, for example, sudden body immersion in cold water or exposure to very cold air. Polymodal nociceptors that appear to respond only to overtly injurious cold, and that elicit sensations of burning cold pain, may require more prolonged and/or deeper cooling for activation and require further study (Wahren et al, 1989;Simone and Kajander, 1997).…”

Section: Discussionmentioning

confidence: 72%

“…Figure 1C shows the distribution of threshold temperatures in a large population of CS trigeminal neurons (n ϭ 393) during temperature ramps down to 19°C. Because of pronounced thermal gradients across the skin, this range of temperatures (from 35 to 19°C) in culture covers those values to which intracutaneous sensory nerve endings of humans are subjected in vivo, even during maintained surface exposure to noxious cold temperatures (Morin and Bushnell, 1998;Mauderli et al, 2003). We considered low-threshold CS neurons (LT-CS) those with a threshold temperature Ͼ26.5°C.…”

Section: Cold-sensitive Neurons Display Different Temperature Thresholdsmentioning

confidence: 99%

Variable Threshold of Trigeminal Cold-Thermosensitive Neurons Is Determined by a Balance between TRPM8 and Kv1 Potassium Channels

Madrid¹,

Peña²,

et al. 2009

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Molecular determinants of threshold differences among cold thermoreceptors are unknown. Here we show that such differences correlate with the relative expression of I KD , a current dependent on Shaker-like Kv1 channels that acts as an excitability brake, and I TRPM8 , a cold-activated excitatory current. Neurons responding to small temperature changes have high functional expression of TRPM8 (transient receptor potential cation channel, subfamily M, member 8) and low expression of I KD . In contrast, neurons activated by lower temperatures have a lower expression of TRPM8 and a prominent I KD . Otherwise, both subpopulations have nearly identical membrane and firing properties, suggesting that they belong to the same neuronal pool. Blockade of I KD shifts the threshold of cold-sensitive neurons to higher temperatures and augments cold-evoked nocifensive responses in mice. Similar behavioral effects of I KD blockade were observed in TRPA1 Ϫ/Ϫ mice. Moreover, only a small percentage of trigeminal cold-sensitive neurons were activated by TRPA1 agonists, suggesting that TRPA1 does not play a major role in the detection of low temperatures by uninjured somatic cold-specific thermosensory neurons under physiological conditions. Collectively, these findings suggest that innocuous cooling sensations and cold discomfort are signaled by specific low-and high-threshold cold thermoreceptor neurons, differing primarily in their relative expression of two ion channels having antagonistic effects on neuronal excitability. Thus, although TRPM8 appears to function as a critical cold sensor in the majority of peripheral sensory neurons, the expression of Kv1 channels in the same terminals seem to play an important role in the peripheral gating of cold-evoked discomfort and pain.

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“…This number is even greater considering that fewer TRPM8 ϩ DRG neurons were NF200 positive. Additionally, as sensory afferents expressing TRPV1 and CGRP are considered to be largely nociceptors, coexpression of these markers with Trpm8 GFP demonstrates that a portion of TRPM8 neurons are putative nociceptors and that activation of neurons coexpressing TRPV1 may account for the sensation of burning pain that occurs at cold extremes (Yarnitsky and Ochoa, 1990;Davis, 1998;Mauderli et al, 2003). Interestingly, Trpm8 GFP was observed in neurons that label with either marker exclusively, or with both CGRP and TRPV1, further demonstrating diversity of channel expression, in this case in nociceptors (supplemental Fig.…”

Section: Discussionmentioning

confidence: 99%

Diversity in the Neural Circuitry of Cold Sensing Revealed by Genetic Axonal Labeling of Transient Receptor Potential Melastatin 8 Neurons

Takashima¹,

Daniels²,

Knowlton³

et al. 2007

J. Neurosci.

192

214

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Sensory nerves detect an extensive array of somatosensory stimuli, including environmental temperatures. Despite activating only a small cohort of sensory neurons, cold temperatures generate a variety of distinct sensations that range from pleasantly cool to painfully aching, prickling, and burning. Psychophysical and functional data show that cold responses are mediated by both C-and A␦-fibers with separate peripheral receptive zones, each of which likely provides one or more of these distinct cold sensations. With this diversity in the neural basis for cold, it is remarkable that the majority of cold responses in vivo are dependent on the cold and menthol receptor transient receptor potential melastatin 8 (TRPM8). TRPM8-null mice are deficient in temperature discrimination, detection of noxious cold temperatures, injury-evoked hypersensitivity to cold, and nocifensive responses to cooling compounds. To determine how TRPM8 plays such a critical yet diverse role in cold signaling, we generated mice expressing a genetically encoded axonal tracer in TRPM8 neurons. Based on tracer expression, we show that TRPM8 neurons bear the neurochemical hallmarks of both C-and A␦-fibers, and presumptive nociceptors and non-nociceptors. More strikingly, TRPM8 axons diffusely innervate the skin and oral cavity, terminating in peripheral zones that contain nerve endings mediating distinct perceptions of innocuous cool, noxious cold, and first-and second-cold pain. These results further demonstrate that the peripheral neural circuitry of cold sensing is cellularly and anatomically complex, yet suggests that cold fibers, caused by the diverse neuronal context of TRPM8 expression, use a single molecular sensor to convey a wide range of cold sensations.

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Relationships Between Skin Temperature and Temporal Summation of Heat and Cold Pain

Cited by 42 publications

References 58 publications

Gender differences in postoperative pain after laparoscopic cholecystectomy

Gender differences in postoperative pain after laparoscopic cholecystectomy

Variable Threshold of Trigeminal Cold-Thermosensitive Neurons Is Determined by a Balance between TRPM8 and Kv1 Potassium Channels

Diversity in the Neural Circuitry of Cold Sensing Revealed by Genetic Axonal Labeling of Transient Receptor Potential Melastatin 8 Neurons

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