Modality-Dependent Modulation of Conduction by Impulse Activity in Functionally Characterized Single Cutaneous Afferents in the Rat

Thalhammer, J. G.; Raymond, Scott B.; Popitz-Bergez, F.; Strichartz, Gary R.

doi:10.3109/08990229409051392

Cited by 65 publications

(74 citation statements)

References 57 publications

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“…Whatever the mechanisms involved, the variations in activity-dependent slowing have important functional implications. The progressive increase in latency of the type 1 fibres was clearly associated with a progressive decrease in excitability, which resulted in conduction block for these nociceptor fibres only, as also noted by Thalhammer et al (1994). The rise in electrical threshold indicates that the fibre would also have a higher threshold for excitation by a natural stimulus, and the absence of any plateau in the latencies suggests that the maximum continuous rate of nociceptor discharge is severely limited by the properties of the axons.…”

Section: Discussionmentioning

confidence: 88%

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Activity‐dependent slowing of conduction differentiates functional subtypes of C fibres innervating human skin

Serra

Campero

Ochoa

et al. 1999

The Journal of Physiology

193

207

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Repetitive firing in axons can lead to their subexcitability and reduced conduction velocity, due to prolonged hyperpolarization (Gasser, 1935;Bergmans, 1970;Bostock & Grafe, 1985). Such activity-dependent changes in membrane potential and conduction velocity are much more pronounced in unmyelinated fibres than in myelinated ones (Ritchie & Straub, 1957;Grafe et al. 1997), and have been used in microneurographic recordings from humans as a 'marking' technique for C fibres activated by natural stimuli (Hallin &

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Section: Discussionmentioning

confidence: 88%

“…We have found that these fibres can be segregated into at least three different classes on the basis of their response to repetitive stimulation, and that it is possible unambiguously to differentiate nociceptive from cold-specific C fibres innervating human skin, as has previously been shown for the rat (Thalhammer et al 1994;Gee et al 1996).…”

mentioning

confidence: 77%

Activity‐dependent slowing of conduction differentiates functional subtypes of C fibres innervating human skin

Serra

Campero

Ochoa

et al. 1999

The Journal of Physiology

193

207

View full text Add to dashboard Cite

show abstract

“…1996; Shin and Raymond 1991;Thalhammer et al 1994) and human (Bostock et al 2003;Serra et al 1999;Weidner et al 2002) C-fiber axons. In most of these studies, single-fiber recordings in situ provided a method for correlation of electrophysiological parameters with the function of the C-fiber.…”

Section: Discussionmentioning

confidence: 99%

Activity-Dependent Modulation of Axonal Excitability in Unmyelinated Peripheral Rat Nerve Fibers by the 5-HT(3) Serotonin Receptor

Lang

Moalem‐Taylor²,

Tracey³

et al. 2006

Journal of Neurophysiology

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. Activity-dependent modulation of axonal excitability in unmyelinated peripheral rat nerve fibers by the 5-HT(3) serotonin receptor. J Neurophysiol 96: 2963-2971, 2006. First published September 6, 2006 doi:10.1152/jn.00716.2006. Activity-dependent fluctuations in axonal excitability and changes in interspike intervals modify the conduction of trains of action potentials in unmyelinated peripheral nerve fibers. During inflammation of a nerve trunk, long stretches of axons are exposed to inflammatory mediators such as 5-hydroxytryptamine . In the present study, we have tested the effects of m-chlorophenylbiguanide (mCPBG), an agonist at the 5-HT(3) serotonin receptor, on activity-and potential-dependent variations in membrane threshold and conduction velocity of unmyelinated C-fiber axons of isolated rat sural nerve segments. The increase in axonal excitability during application of mCPBG was much stronger at higher frequencies of action potentials and/or during axonal membrane hyperpolarization. The effects on the postspike recovery cycle also depended on the rate of stimulation. At an action potential frequency of 1 Hz or in hyperpolarized axons, mCPBG produced a loss of superexcitability. In contrast, at 0.33 Hz, a small increase in the postspike subexcitability was observed. Similar effects on excitability changes were found when latency instead of threshold was recorded, but only at higher action potential frequencies: at 1.8 Hz, mCPBG increased conduction velocity and reduced postspike supernormality. The latter effect would increase the interspike interval if pairs of action potentials were conducted along several cm in an inflamed nerve trunk. These data indicate that activation of axonal 5-HT(3) receptors not only enhances membrane excitability but also modulates action potential trains in unmyelinated, including nociceptive, nerve fibers at high impulse rates.

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“…Although adaptation in the transformation process is supported by decreased CV (Thalhammer et al 1994;Schmelz et al 1995;Serra et al 1999) and reduced kinetics of sensory neuron-specific sodium channels (Waxman et al 1999), there is no evidence for adaptation in the transduction process so far.…”

Section: (F ) Adaptationmentioning

confidence: 99%

A multi-scale view of skin thermal pain: from nociception to pain sensation

Zhu

2010

Phil. Trans. R. Soc. A.

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All biological bodies live in a thermal environment, including the human body, where skin is the interface with a protecting function. When the temperature is out of the normal physiological range, skin fails to protect, and the pain sensation is evoked. Furthermore, in medicine, with advances in laser, microwave and similar technologies, various thermal therapeutic methods have been widely used to cure disease/injury involving skin tissue. However, the corresponding problem of pain relief has limited further application and development of these thermal treatments. Skin thermal pain is induced through both direct (i.e. an increase/decrease in temperature) and indirect (e.g. thermomechanical and thermochemical) ways, and is governed by complicated thermomechanical-chemicalneurophysiological responses. However, a complete understanding of the underlying mechanisms is still far from clear. In this article, starting from an engineering perspective, we aim to recast the biological behaviour of skin in engineering system parlance. Then, by coupling the concepts of engineering with established methods in neuroscience, we attempt to establish multi-scale modelling of skin thermal pain through ion channel to pain sensation. The model takes into account skin morphological plausibility, the thermomechanical response of skin tissue and the biophysical and neurological mechanisms of pain sensation.

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Modality-Dependent Modulation of Conduction by Impulse Activity in Functionally Characterized Single Cutaneous Afferents in the Rat

Cited by 65 publications

References 57 publications

Activity‐dependent slowing of conduction differentiates functional subtypes of C fibres innervating human skin

Activity‐dependent slowing of conduction differentiates functional subtypes of C fibres innervating human skin

Activity-Dependent Modulation of Axonal Excitability in Unmyelinated Peripheral Rat Nerve Fibers by the 5-HT(3) Serotonin Receptor

A multi-scale view of skin thermal pain: from nociception to pain sensation

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