Myelinated afferent nerve fibers from the skin of the rabbit ear

Developing a sense of touch

The sensation of touch is mediated by mechanosensory neurons that are embedded in skin and relay signals from the periphery to the central nervous system. During embryogenesis, axons elongate from these neurons to make contact with the developing skin. Concurrently, the epithelium of skin transforms from a homogeneous tissue into a heterogeneous organ that is made up of distinct layers and microdomains. Throughout this process, each neuronal terminal must form connections with an appropriate skin region to serve its function. This Review presents current knowledge of the development of the sensory microdomains in mammalian skin and the mechanosensory neurons that innervate them.

Long-Term Effects of Botulinum Toxin Complex Type A Injection on Mechano- and Metabo-Sensitive Afferent Fibers Originating from Gastrocnemius Muscle

The aim of the present study was to investigate long term effects of motor denervation by botulinum toxin complex type A (BoNT/A) from Clostridium Botulinum, on the afferent fibers originating from the gastrocnemius muscle of rats. Animals were divided in 2 experimental groups: 1) untreated animals acting as control and 2) treated animals in which the toxin was injected in the left muscle, the latter being itself divided into 3 subgroups according to their locomotor recovery with the help of a test based on footprint measurements of walking rats: i) no recovery (B0), ii) 50% recovery (B50) and iii) full recovery (B100). Then, muscle properties, metabosensitive afferent fiber responses to potassium chloride (KCl) and lactic acid injections and Electrically-Induced Fatigue (EIF), and mechanosensitive responses to tendon vibrations were measured. At the end of the experiment, rats were killed and the toxin injected muscles were weighted. After toxin injection, we observed a complete paralysis associated to a loss of force to muscle stimulation and a significant muscle atrophy, and a return to baseline when the animals recover. The response to fatigue was only decreased in the B0 group. The responses to KCl injections were only altered in the B100 groups while responses to lactic acid were altered in the 3 injected groups. Finally, our results indicated that neurotoxin altered the biphasic pattern of response of the mechanosensitive fiber to tendon vibrations in the B0 and B50 groups. These results indicated that neurotoxin injection induces muscle afferent activity alterations that persist and even worsen when the muscle has recovered his motor activity.

Activation and retrograde transport of protein kinase G in rat nociceptive neurons after nerve injury and inflammation

Nerve injury elicits both universal and limited responses. Among the former is regenerative growth, which occurs in most peripheral neurons, and among the latter is the long-term hyperexcitability that appears selectively in nociceptive sensory neurons. Since positive injury signals communicate information from the site of an injury to the cell body, we hypothesize that a nerve injury activates both universal and limited positive injury signals. Studies in Aplysia indicate that protein kinase G is a limited signal that is responsible for the induction of long-term hyperexcitability. Given that long-term hyperexcitability contributes to chronic pain after axotomy in rodent neuropathic pain models, we investigated its underlying basis in the rat peripheral nervous system. Using biochemical assays, Western blots, and immunocytochemistry we found that the Type 1alpha protein kinase G is the predominant isoform in the rat periphery. It is present primarily in axons and cell bodies of nociceptive neurons, including populations that are isolectin B4-positive, isolectin B4-negative, and those that express transient receptor potential vanilloid receptor-1. Surprisingly, protein kinase G is not present in the facial nerve, which overwhelmingly contains axons of motor neurons. Crushing the sciatic nerve or a cutaneous sensory nerve activates protein kinase G in axons and results in its retrograde transport to the neuronal somata in the DRG. Preventing the activation of protein kinase G by injecting Rp-8-pCPT-cGMPS into the crush site abolished the transport. The protein kinase A inhibitor Rp-8-pCPT-cAMPS had no effect. Extracellular signal-related kinases 42/44 are also activated and transported after nerve crush, but in both motor and sensory axons. Chronic pain has been linked to long-term hyperexcitability following a nerve inflammation in several rodent models. We therefore injected complete Freund's adjuvant into the hindpaw to induce an inflammation and found that protein kinase G was activated in the sural nerve and transported to the DRG. In contrast, the extracellular signal-related kinases in the sensory axons were not activated by the complete Freund's adjuvant. These studies support the idea that the extracellular signal-related kinases are universal positive axonal signals and that protein kinase G is a limited positive axonal signal. They also establish the association between protein kinase G, the induction of long-term hyperexcitability, and chronic pain in rodents.

Selective responsiveness of polymodal nociceptors of the rabbit ear to capsaicin, bradykinin and ultra-violet irradiation

1. The activity of single C- and A-fibre cutaneous sensory units was recorded from the great auricular nerve of anaesthetized rabbits to compare the effects of chemical with other forms of stimulation under several experimental conditions. Chemical agents were delivered by close arterial injection. 2. Small intra-arterial injections of bradykinin (0.2 microgram) and a substantial range of capsaicin doses (2-200 micrograms) consistently activated C polymodal nociceptors without exciting other types of C- or A-fibre cutaneous sense organs. 3. Topical application of xylene to the receptive field of polymodal nociceptors evoked a strong excitation which lasted several minutes. 4. The responses of polymodal nociceptors to mechanical, chemical (bradykinin, xylene) and noxious thermal stimuli were suppressed or abolished after large intra-arterial doses of capsaicin. Capsaicin desensitization of polymodal nociceptors to one kind of stimulation often was not paralleled by similar changes in responsiveness to other stimuli. However, on the average, capsaicin desensitization altered responses to thermal, chemical and mechanical stimuli without afferent selectivity. 5. Background discharge developed in C polymodal nociceptors of the rabbit ear following ultra-violet irradiation sufficient to produce evidence of delayed inflammation. Noxious heat and bradykinin injection (0.2 micrograms) evoked more activity from C polymodal nociceptors in the irradiated ears than from control units.

A comparative light microscopic analysis of the sensory innervation of the mystacial pad. II. The common fur between the vibrissae

The innervation to the common fur between the vibrissae was examined in the hamster, mouse, rat, gerbil, rabbit, guinea pig, and cat. Samples were taken from central locations among the more caudal vibrissae in the mystacial pad and processed with Richardson's variant of the Bielschowsky silver technique or with Winkelmann's silver technique to selectively stain peripheral axons and terminals. Additional samples were taken among the rostral vibrissae in the rat. We found major unpredictable species-related variations in the distribution of receptor types, innervation density, and the quantity of innervation in the skin between neighboring vibrissae. The common fur is composed of numerous larger guard hairs and even more numerous smaller vellus hairs. The guard hairs usually are richly innervated with fully developed piloneural complexes composed primarily of a pallisade of lanceolate endings and a circumferential array of Ruffini and free nerve endings. The vellus hairs are usually innervated by individual or shared free nerve endings. The piloneural complexes in the cat, rat, and mouse are usually complete, whereas those in the other species were usually incomplete and lacked Ruffini endings. There is considerable interspecies variation in the relative quantity of innervation between homologous neighboring vibrissae. The quantity of innervation is related to a combination of receptor completeness, innervation density, and distance between vibrissae. The quantity of intervibrissal fur innervation is by far highest in the cat, relatively high in the rabbit, relatively low in the hamster and caudal mystacial pad of the rat, and lowest in the mouse, gerbil, guinea pig, and rostral mystacial pad of the rat. The differences in the innervation between the cat and the rabbit correlate well with published physiologic data on types of receptor units. Also, barrels are most prominent in species having relatively low quantities of intervibrissal innervation and are less prominent or absent in species having high quantities of intervibrissal innervation.

Effects of sympathetic stimulation on mechanoreceptive and nociceptive afferent units from the rabbit pinna

Single afferent units from the rabbit great auricular nerve were examined using cutaneous stimuli before, during and after tetanic stimulation of the cervical sympathetic trunk for 1-4 min. G-hair units showed a depression of responses during and for 1-2 min after sympathetic stimulation; D-hair units showed a similar pattern but the average depression was less. These changes are not likely to be due to a reduction in blood flow since no comparable effect was produced by arterial occlusion. Sensitive C-mechanoreceptor units were excited transiently by sympathetic stimulation and by arterial occlusion. Responses of nociceptors, both A-fibre high threshold mechanoreceptors and C-fibre polymodal nociceptors were unaffected by sympathetic stimulation.

Multiple afferent innervation of primate facial hairs--Henry Head and Max von Frey revisited

Large guard hairs as well as small vellus hairs are multiple innervated having lanceolate terminals of variable number. Ruffini corpuscles consisting of fine axonal ramifications are arranged circularly and located external to the lanceolate terminals. Free nerve endings (FNE's) can also be identified on some hairs distinct from Ruffini terminals. Ruffini terminals and FNE's are usually innervated by axons from the superficial dermal nerve net whereas lanceolate terminals are innervated by axons from the deeper portions of the dermal nerve net. All guard hairs have both types of terminals (lanceolate and Ruffini) confirming Hoggan and Hoggan, Retzius and Symonowicz, and most guard hairs have presumptive FNE's. Many vellus hairs have only small Ruffini endings or FNE's. The diameter of axons supplying Ruffini terminals is 1-2 micrometer and those to lanceolate terminals is 2-4 micrometers. Axons innervating lanceolate and Ruffini terminals branch rarely as correlated with small punctate receptive fields. FNE's branch widely and are correlated with large receptive fields of known nociceptors. The multiplicity of anatomically defined terminals is consistent with the known diversity of physiologically defined hair mechanoreceptive afferents as well as perceptual complexity of human hairy skin. The concept of multiple innervation of hairs confirms Head's prediction and could provide the anatomical basis of Head's basic thesis of altered sensibilities in nerve regeneration (i.e. epicritic and protopathic responses). Head's concept of two separate nervous systems, however, is an over-simplification in the light of current knowledge.

The distribution of cutaneous receptors in the rabbit's hind limb and differential electrical stimulation of their axons

1. The receptive field properties and conduction velocities of single dorsal root axons, activated from the sural and cutaneous branches of the posterior tibial (medial plantar) nerves, were examined in anaesthetized rabbits.2. The sural nerve sample included all types of units previously recorded from the saphenous nerve (Brown & Iggo, 1967). In particular it was shown that electrical stimulation of the sural nerve at strengths up to 1.3T produced a volley of impulses in a pure population of slowly adapting units (Type I units).3. The medial plantar sample showed an absence of Type I slowly adapting units and Type T hair follicle units. Corresponding to this there were no touch corpuscles or tylotrich hairs in the skin of the hind foot and the fastest medial plantar axons conducted at 60-70 m/sec as opposed to 80-85 m/sec for the sural nerve. Stimulation of the medial plantar nerve at stimulus strengths close to threshold produced a volley of impulses in a nearly pure population of Type G hair follicle units.