Effects of partial unfused contractions of the gastrocnemius medialis muscle on homonymous and synergist motor neurons in cats

Autogenetic inhibition of homonymous and synergist motoneurones can be elicited by very weak partial twitches of gastrocnemius medialis muscle, but during sustained contractions the amplitude of inhibitory post-synaptic potentials decreases quickly. A similar decrease also occurs during stronger contractions. The mechanism responsible for this decrease is still active in low spinal preparations. Pre-synaptic inhibition of Ib afferent fibres might contribute to this reduction of efficiency in the transmission of Ib afferent inputs to motoneurones.     

Flexible processing of sensory information induced by axo-axonic synapses on afferent fibers.

Recent experiments indicate that afferent information is processed in the intraspinal arborisation of mammalian group I fibres. During muscle contraction, Ib inputs arising from tendon organs are filtered out by presynaptic inhibition after their entry in the spinal cord. This paper reviews the mechanisms by which GABAergic axo-axonic synapses, i.e., the morphological substrate of presynaptic inhibition, exert this filtering effect. Using confocal microscopy, axo-axonic synapses were demonstrated on segmental Ib collaterals. Most synapses were located on short preterminal and terminal branches. Using a simple compartmental model of myelinated axon, the primary afferent depolarisation (PAD), generated by such synapses, was predicted to reduce the amplitude of incoming action potentials by inactivating the sodium current, and this prediction was experimentally verified. A further theoretical work, relying on cable theory, suggests that the electrotonic structure of collaterals and the distribution of axo-axonic synapses allow large PADs (about 10 mV) to develop on some distal branches, which is likely to result in a substantial presynaptic inhibition. In addition, the electrotonic structure of group I collaterals is likely to prevent PAD from spreading to the whole arborisation. Such a non-uniform diffusion of the PAD accounts for differential presynaptic inhibition in intraspinal branches of the same fibre. Altogether, our experimental and theoretical works suggest that axo-axonic synapses can control the selective funnelling of sensory information toward relevant targets specified according to the motor task.     

GABA and Prolonged Spinal Inhibition

TWO explanations have been provided for the relatively long latency and prolonged (often exceeding 100 ms) inhibition of firing of spinal motoneurones which is caused by repetitive impulses produced by electrical or natural stimulation^1–4 in muscle and cutaneous afferent fibres. This prolonged inhibitory process is exemplified by the reduction in the amplitude of monosynaptic excitatory synaptic potentials (EPSPs) and reflexes of extensor motoneurones by tetanic stimulation of group I afferents of flexor motoneurones². In contrast with “direct” inhibition, the prolonged inhibition is not reduced by strychnine but is diminished by Picrotoxin^4,6.     

Measuring Spinal Presynaptic Inhibition in Mice By Dorsal Root Potential Recording In Vivo

Presynaptic inhibition is one of the most powerful inhibitory mechanisms in the spinal cord. The underlying physiological mechanism is a depolarization of primary afferent fibers mediated by GABAergic axo-axonal synapses (primary afferent depolarization). The strength of primary afferent depolarization can be measured by recording of volume-conducted potentials at the dorsal root (dorsal root potentials, DRP). Pathological changes of presynaptic inhibition are crucial in the abnormal central processing of certain pain conditions and in some disorders of motor hyperexcitability. Here, we describe a method of recording DRP in vivo in mice. The preparation of spinal cord dorsal roots in the anesthetized animal and the recording procedure using suction electrodes are explained. This method allows measuring GABAergic DRP and thereby estimating spinal presynaptic inhibition in the living mouse. In combination with transgenic mouse models, DRP recording may serve as a powerful tool to investigate disease-associated spinal pathophysiology. In vivo recording has several advantages compared to ex vivo isolated spinal cord preparations, e.g. the possibility of simultaneous recording or manipulation of supraspinal networks and induction of DRP by stimulation of peripheral nerves.     

After hyperpolarization conductance time-course and repetitive firing in a motoneurone model with early inactivation of the slow potassium conductance system

Early inactivation of the slow potassium conductance system (GK), responsible for the spike afterhyperpolarization (AHP) in spinal alpha motoneurones, has been introduced in a motoneurone model whose G _K kinetics give rise to an exponentially decaying AHP conductance. After this modification, the model displays a plateau shaped time-course of the AHP conductance and a faster shortening of the first interval during repetitive firing induced by current steps of increasing intensities. Both features increase the resemblance between the model and the motoneurone behaviour. Comparison with real motoneurones also suggests that G _K inactivation may be more developed in slow than in fast motoneurones.     

The pattern of innervation of a polyneural muscle: Axolotl iliotibialis

Summary The pattern of innervation on individual iliotibialis muscle fibres from axolotl (Ambystoma mexicanum) has been investigated histologically and elctrophysiologically. These polyneural fibres were found to be innervated on average at five end plate sites. The sites were distributed irregularly along each fibre. Average end plate length was found to be approxiamtely 70 m. Most end plates were separated by less than 1000 m; 26% by less than 150 m; the average separation was 516 m. Advantage was taken of the dual innervation of the muscle to investigate the separation between synaptic terminals from different axons. Some individual fibres were found to be innervated by axons from two different spinal nerves. End plate sites on dually innervated fibres were located by ACh iontophoresis. 30% of such sites were found to be innervated by more than one axon terminal. The average separation of such sites was found to be 950 m. Four different axons were found to innervate some individual muscle fibres. It is suggested that the unusual ability of axolotl muscle fibres to accept synaptic terminals from different axons at closely adjacent sites may be a major factor underlying selective reinnervation in this animal.Vacation student assisted by The Dale Fund of the Physiological Society     

The heterogeneity of the excitatory synaptic inputs in the spinal motor neurons of the frog Rana ridibunda

The synaptic responses induced in motoneurones by the stimulations of the dorsal root (DR), single afferent fibres and reticular formation (RF) were intracellularly recorded in the isolated frog spinal cord. It was shown that argiopine (the selective blocker of glutamate receptors of non-NMDA type) in concentrations ranging from 3.10(-7) to 1.10(-5) M effectively suppressed the di- and polysynaptic, but not the monosynaptic components of EPSP's induced by DR stimulation. The initial reaction to argiopine consisted of the increase of this monosynaptic component of EPSP. In the same concentrations range, argiopine reduced both mono- and polysynaptic EPSP, evoked by RF stimulation. 2-amino-phosphonovaleric acid (1.10(-4) M) did not affect, whereas the kinurenate (1--2.10(-3) M) completely blocked the amplitude of all kinds of synaptic responses. The various effects of argiopine on the responses induced by microstimulation of presynaptic nerve terminals were observed. The data obtained speak in favour of heterogeneity of monosynaptic excitatory inputs in the motoneurones of frog spinal cord. Being the glutamatergic by nature, the inputs differ in the properties of postsynaptic receptors. All of these receptors concerning to non NMDA-type can be divided to argiopine-sensitive and argiopine-resistant. The first seem to be involved in the monosynaptic connections of RF and the second--in those of primary afferents with motoneurones.     

The innervation of the myometrium of the cynomolgus monkey (Macaca fascicularis)

Summary The autonomic innervation of the myometrium of Macaca fascicularis consists of bundles of unmyelinated nerve fibres running between the smooth muscle cells, and is therefore considered to be of the fascicular (= unitary) type. Close contacts between nerve fibres and smooth muscle fibres were not found. Modification of the chromaffin method according to Tranzer and Richards made it possible to visualize the heterogeneity of the nerve fibres in a single bundle. The following fibre types were found to coexist: (1) noradrenergic fibres containing synaptic vesicles with a dense granule, (2) cholinergic fibres containing empty synaptic vesicles, and (3) non-adrenergic noncholinergic (NANC) fibres containing only or predominantly large dense-cored vesicles, which do not react with this method. Noradrenergic fibres are the most numerous (around 60%), followed by NANC fibres (30%) and cholinergic elements (around 10%). The distribution of these three types is similar in the cervix, the isthmus and the body of the uterus in pregnant and non-pregnant females.     

Frequency-dependent selection of alternative spinal pathways with common periodic sensory input

Electrical stimulation of the lumbar cord at distinct frequency ranges has been shown to evoke either rhythmical, step-like movements (25–50 Hz) or a sustained extension (5–15 Hz) of the paralysed lower limbs in complete spinal cord injured subjects. Frequency-dependent activation of previously silent spinal pathways was suggested to contribute to the differential responsiveness to distinct neuronal codes and the modifications in the electromyographic recordings during the actual implementation of the evoked motor tasks. In the present study we examine this suggestion by means of a simplified biology-based neuronal network. Involving two basic mechanisms, temporal summation of synaptic input and presynaptic inhibition, the model exhibits several patterns of mono- and/or oligo-synaptic motor output in response to different interstimulus intervals. It thus reproduces fundamental input–output features of the lumbar cord isolated from the brain. The results confirm frequency-dependent spinal pathway selection as a simple mechanism which enables the cord to respond to distinct neuronal codes with different motor behaviours and to control the actual performance of the latter.     

Pancreatic glucagon cells contain endorphin-like immunoreactivity

Summary On the basis of the histochemical activity of succinic dehydrogenase, only two fibre-types are distinguished in pigeon pectoralis major muscle. These are narrow Red and broad White. The histochemical activity of myofibrillar ATPase was studied in these two distinct fibre-types. Both fibre-types showed high activity for the ATPase. Red fibres of pigeon pectoralis were not alkali-labile, at incubation pH 9.4, as were the Type I fibres of both avian and mammalian muscles. Again unlike Type I fibres, the Red fibres of pigeon pectoralis lacked the characteristic activation of acid-preincubated ATPase reaction. Pigeon pectoralis Red fibres are known to posses some characteristics of fast-twitch fibres (e.g. high fat, considerable phosphorylase, fibrillenstruktur myofibrillar arrangement, focal en plaque pattern of nerve endings). It is emphasized, therefore, that the pigeon pectoralis Red fibres are not equivalent to Type I or slow-twitch, muscle fibres, but they are possibly fast-twitch fatigue resistent or Type II Red muscle fibres.     

Modulation of the Spontaneous Synaptic Activity of Tortoise Spinal Motoneurons by Group-II Metabotropic Glutamate Receptors

We examined the effects of antagonists and an agonist of the metabotropic glutamate receptors (mGluR) on the frequency and amplitude of spontaneous postsynaptic potentials (PSP) and of a miniature fraction of these potentials in the lumbar segments of the spinal cord of the steppe tortoise (in 2- to 3-mm-thick superfused slices). We demonstrated that a common antagonist of the group-I and group-II mGluR, (+)MCPG (400 M), as well as selective antagonists, MCCG (200 M) and EGLU (100-200 M), and a selective agonist of the group-II, DCG IV (1 M), change the frequency of spontaneous PSP, including miniature PSP, but practically do not influence their amplitude. This feature shows that mGluR are presynaptically localized both in premotoneuronal links and immediately in synaptic contacts on the motoneurons. Comparison of the effects of antagonists of the mGluR on the normal synaptic activity and on that under conditions of the GABA receptor blockade shows that mGluR are involved in modulation of both glutamatergic and GABA-ergic transmission. We surmise that the NMDA reception plays a special role in the realization of mGluR-mediated modulating effects. The directions of the effects of the above antagonists and an agonist of the mGluR (an increase and a decrease in the frequency of synaptic potentials, respectively) allow us to postulate that the presynaptically localized group-II mGluR causes a decrease in the probability of release of excitatory and inhibitory transmitters in spinal synaptic structures of the tortoise.     

Presynaptic modulation of sensory afferents in the invertebrate and vertebrate nervous system

• 1.1. Ultrastructural examination of the central terminals of sensory afferent neurons in both invertebrates and vertebrates demonstrates that the synapses that form the substrate for presynaptic inhibition and facilitation are almost universally present.
• 2.2. Presynaptic modulation of afferent input acts in many ways which tailor the inflow of sensory information to the behaviour of the animal, effectively providing a means of turning this on and off, or of combining information of the same or different modalities to refine responsiveness or clarify ambiguity.
• 3.3. Presynaptic modulation may act in several different roles on the same afferent.
• 4.4. A comparison of the mechanisms of presynaptic inhibition in different animals demonstrates the likelihood of a variety of common mechanisms,several of which may act simultaneously on the same terminal.These include changes in the conductance of the afferent membrane to Cl^-, K⁺and Ca²⁺ions, in addition to less well understood mechanisms that directly affect transmitter release.
• 5.5.A single transmitter can produce several effects on a terminal through the same or different receptors.
• 6.6. Ultrastructural studies of afferent terminals reveal that only a proportion of boutons on a given afferent may receive presynaptic input and that this may depend on the region of the nervous system in which these are found or on the identity of the postsynaptic neurons contacted.
• 7.7. The synaptic relationships of afferent terminals can be complex. In invertebrates different types of presynaptic neuron may interact synaptically,as may postsynaptic dendrites in vertebrates.
• 8.8. Axons presynaptic to afferent terminals in vertebrates frequently synapse also with dendrites postsynaptic to the afferents.
• 9.9. In both invertebrates and vertebrates reciprocal interactions between afferents and postsynaptic neurons are seen.
• 10.10. Ultrastructural immunocytochemistry reveals the likely dominance of GABA as an agent of presynaptic inhibition but also demonstrates the possible presence of other transmitters some of whose roles are less completely understood.

     

Enzymatic synthesis of poly-β-hydroxybutyrate inZoogloea ramigera

The enzyme activity synthesizing poly--hydroxybutyrate (PHB) was mainly localized in the PHB-containing particulate fraction ofZoogloea ramigera I-16-M, when it grew flocculatedly in a medium supplemented with glucose. On the other hand, the enzyme activity remained in the soluble fraction, when the bacterium grew dispersedly in a glucose-starved medium.The soluble PHB synthase activity became associated with the particulate fraction as PHB synthesis was initiated on the addition of glucose to the dispersed culture. Conversely, the enzyme activity was released from the PHB-containing granules to the soluble fraction when the flocculated culture was kept incubated without supplementing the medium with glucose.PHB synthase was also incorporated into the newly formed PHB fraction when partially purified soluble PHB synthase was incubated withd(-)--hydroxybutyryl CoA in vitro.Although attempts to solubilize the particulate enzyme were unsuccessful, and the soluble enzyme became extremely unstable in advanced stages of purification, both PHB synthases had the same strict substrate specificity ford(-)--hydroxybutyryl CoA, and showed the same pH optimum at 7.0.Non-Standard Abbreviations PHB poly--hydroxybutyrate     

Morphological and electrophysiological consequences of unilateral pre- versus postganglionic vestibular lesions in the frog

The combined removal of the labyrinthine sense organs and of the ganglion of Scarpa on one side (postganglionic section) resulted in a degeneration of afferent fibres in the eighth nerve of the frog (Rana temporaria) within 2–4 days. If the eighth nerve was sectioned more peripherally (preganglionic section) and its distal part was removed together with the labyrinthine organs degeneration of afferent fibres was absent or restricted to very few fibres. Electrical stimulation of vestibular afferents in vitro evoked monosynaptic field potentials in the ipsilateral and via commissural fibres di-and polysynaptic field potentials in the contralateral vestibular nuclei. Afferent-evoked field potentials recorded on the intact side of chronic frogs ( 60 days) with a preor postganglionic lesion and afferent-evoked field potentials recorded on the operated side of chronic frogs with a preganglionic lesion had amplitudes that were very similar to those recorded in control frogs. Commissurally evoked field potentials recorded on the operated side of chronic frogs with preor postganglionic lesions were significantly increased (by about 90%) with respect to control amplitudes. In both groups the time-course of this increase was very similar, started between 15 and 30 days and saturated for survival periods longer than 60 days. Unilateral inactivation of vestibular afferents, but not degeneration, is the likely common denominator of the central process leading to the reported neural changes. A reactive supersensitivity of central vestibular neurons on the operated side for glutamate as a possible mechanism is unlikely, since converging afferent and commissural inputs are both glutamatergic and only one of them, the commissural input, was potentiated. Comparison of the time-courses of neural changes in the vestibular nuclei and postural recovery in the same individuals excludes a causal relation between both phenomena.Abbreviations HL hemilabyrinthectomy - VNC vestibular nuclear complex - HRP horseradish peroxidase - N. VIII eighth nerve - N. IX ninth nerve     

Electrical and mechanical responses of chromatophore muscle fibers of the squid,Loligo opalescens,to nerve stimulation and drugs

Summary The muscle fibers of brown and red chromatophores in the skin of the squid, Loligo opalescens, respond to motor nerve stimulation with non-propagating excitatory postsynaptic potentials (e.p.s.p.'s) of fluctuating amplitude. Depending on the strength of stimulation several size classes of e.p.s.p.'s are found, indicating polyneuronal innervation. Facilitation and summation are minimal even though the reversal potential of the e.p.s.p.'s is close to zero.Acetylcholine (ACh) and 5-hydroxytryptamine (5-HT) have no effect on membrane characteristics of the muscle fiber, but ACh greatly augments the spontaneous quantal release of transmitter [increase in the frequency of miniature postsynaptic potentials (m.p.s.p.'s)] and thereby causes tonic contraction (miniature tetanus). 5-HT reduces the frequency of miniature potentials and abolishes tonic contraction. Inhibition of cholinesterase by eserine does not affect the amplitude or time course of e.p.s.p.'s and of m.p.s.p.'s. High concentrations of cholinergic blocking agents (atropine, banthine) reduce the postsynaptic effects of nerve stimulation in some cases. The natural transmitter substance of the motoneurones may not be ACh. The action of 5-HT appears to be intracellular.Neighboring muscle fibers are electrically coupled through low resistance pathways. These are most likely provided by the close junctions that form part of the myo-muscular junctions. The specific membrane resistance of the regular muscle fiber membrane was found to range from 1,056 to 1,320 Ohm×cm², that of the close junctions ranges from 12.8 to 22.6 Ohm×cm². The area occupied by close junctions is small, however, and only 10% of the current injected into one cell passes into the next. Some of the e.p.s.p.'s observed in a given muscle fiber most likely represent the electrotonic spread of the e.p.s.p.'s of the neighbor fibers. Of the six classes of e.p.s.p.'s observed in some muscle fibers, only two may originate in these fibers themselves.Chromatophores in aged preparations often exhibit pulsations. These are caused by spike potentials arising within muscle fibers whose membranes have become electrically excitable. Each spike is preceded by a generator depolarization. The electrical coupling of neighboring muscle cells permits conduction of the spike potentials throughout the set of muscle fibers of a pulsating chromatophore. Altered conditions within such preparations also lead to tonic contractions and contractures that are not necessarily accompanied by electrical activity. Several arguments are presented in support of the hypothesis that the tonic condition of nerve terminals (characterized by enhanced spontaneous transmitter release) and of muscle fibers (characterized by inability to relax) is due to an abnormal condition of intracellular calcium (lack of Ca-binding by sarcoplasmic reticulum or other storage sites).No evidence could be found for an inhibitory innervation of the chromatophore muscles. The nerve-induced relaxation of tonically contracted muscle fibers is caused by the action of motoneurones.Preliminary experiments on muscle fibers of the anterior byssus retractor muscle of Mytilus support the hypothesis that the tonic behavior (catch) of other molluscan muscles is due to mechanisms similar to those found in the chromatophore muscles.This investigation was supported by Public Health Service Grant No. NB 04145 from the National Institute of Neurological Diseases and Blindness. We are grateful to the director of the Friday Harbor Laboratories, Prof. R. L. Fernald for providing space and facilities for this investigation.Supported by a Training Grant GM 1194 from the National Institute of General Medical Sciences.     

Presynaptic selection of afferent inflow in the spinal cord.

The synaptic effectiveness of sensory fibers ending in the spinal cord of vertebrates can be centrally controlled by means of specific sets of GABAergic interneurons that make axo-axonic synapses with the terminal arborizations of the afferent fibers. In the steady state, the intracellular concentration of chloride ions in these terminals is higher than that predicted from a passive distribution, because of an active transport mechanism. Following the release of GABA by spinal interneurons and activation of GABA(A) receptors in the afferent terminals, there is an outwardly directed efflux of chloride ions that produces primary afferent depolarization (PAD) and reduces transmitter release (presynaptic inhibition). Studies made by intrafiber recording of PAD, or by measuring changes in the intraspinal threshold of single afferent terminals (which is reduced during PAD), have further indicated that muscle and cutaneous afferents have distinctive, but modifiable PAD patterns in response to segmental and descending stimuli. This has suggested that PAD and presynaptic inhibition in the various types of afferents is mediated by separate sets of last-order GABAergic interneurons. Direct activation, by means of intraspinal microstimulation, of single or small groups of last-order PAD-mediating interneurons shows that the monosynaptic PAD elicited in Ia and Ib afferents can remain confined to some sets of the intraspinal collaterals and not spread to nearby collaterals. The local character of PAD allows cutaneous and descending inputs to selectively inhibit the PAD of segmental and ascending intraspinal collaterals of individual muscle spindle afferents. It thus seems that the intraspinal branches of the sensory fibers are not hard wired routes that diverge excitation to spinal neurons, but are instead dynamic pathways that can be centrally controlled to address information to selected neuronal targets. This feature appears to play an important role in the selection of information flow in muscle spindles that occurs at the onset of voluntary contractions in humans.     

A test of the binary chloroplast membrane hypothesis by using a nonpenetrating chemical probe,p-(diazonium)-benzenesulfonic acid

Summary Spinach chloroplasts were exposed to³⁵S-labeledp-(diazonium)-benzenesulfonic acid (DABS), a water soluble compound which does not penetrate lipophilie regions of membranes, and which is highly reactive toward amino acid functionagroups such as -amino, sulfhydryl, histidine, and tyrosine groups. Amino groups inl lipids can also form similar, stable covalent bonds by diazo coupling. Both chloroplast lipids and proteins were labeled with DABS, the total binding being about 1 DABS per 10 chlorophylls, depending on the reaction conditions.After diazo coupling and subsequent digitonin fractionation into photosystems I and II enriched fractions, it was observed that PS-I was more highly labeled than PS-III usually by a factor of 10 to 24 times (on a per chlorophyll basis). After digitonin isolation, however, the PS-II portion bound an amount of DABS similar to the PS-I binding, We interpret these data as consistent with the binary membrane hypothesis (Arntzen. Dilley and Crane (1969),J. Cell Biol. 43:16), which visualizes PS-I on the externa, half of a 90 Å grana membrane, and PS-II occurring on the interior half of thel membrane. The alternative explanation that PS-II and PS-I are arranged as a mosaic, and that the low DABS binding in PS-II is caused by burial of the diazo reactive groups in the interior of the proteins (and only exposed through the denaturing effect of digitonin) is not directly ruled out. However, this alternative is not consistent with the facts that: (a) most of the membrane proteins in PS-I and PS-II are identical in electrophoretic properties and therefore probably have similar overall structures; and (b) digitonin does not lead to appreciable denaturation of proteins, evidenced by the retention of PS-II electron transport activity.     

Functional properties of the Golgi tendon organs

Golgi tendon organs are encapsulated mechanoreceptors present at the myo-tendinous and myo-aponeurotic junctions of mammalian skeletal muscles. Within the tendon organ capsule, the terminal branches of a large diameter afferent fibre, called Ib fibre, are intertwined with collagen bundles in continuity with tendon or aponeurosis at one end. The other end is connected with a fascicle of 5-25 muscle fibres, contributed by several motor units. The contraction of these fibres, exerting strain on the collagenous bundle and causing deformation of sensory terminals, is the adequate stimulus of the tendon organ. For this stimulus, the tendon organ has a very low threshold, so that a single fibre twitch can elicit a discharge from the receptor. A tendon organ can thus signal the contraction of a single one of the 10-15 motor units which contribute fibres to the fascicle connected with the receptor. The number of tendon organs present in a muscle, taken together with the fact that a given motor unit can activate several tendon organs, strongly suggests that the contraction of every motor unit in this muscle is monitored by at least one tendon organ. The exact nature of the information provided by tendon organs to the central nervous system remains an open question because no simple relation could be established between the discharge frequency of a receptor and the contractile forces of its activating motor units. It is known, however, that, due to their dynamic sensitivity, tendon organs are efficient in signaling rapid variations of contractile force. The dynamic parameters of muscle contraction prevail in the information carried by afferent discharges from tendons organs.     

Mitochondria in fine afferent nerve fibres of the knee joint in the cat: a quantitative electron-microscopical examination

The distribution of mitochondria, their content and concentration (expressed as the ratio of the mean volume of mitochondria and the surface of the sensory axon) were determined in group-III and-IV nerve fibres innervating the knee joint capsule in the cat. Mitochondria mainly accumulated in axonal swellings (beads) and end bulbs of the terminal branches. Between single nerve fibres, marked differences in the content and the concentration of mitochondria were obtained in proximal portions (inside of the perineurium) and in distal portions (unmyelinated sensory endings). In group-III nerve fibres, the mitochondrial concentration ranged from 0.005 to 0.030 m³/m² (proximal portion) and from 0.016 to 0.080 m³/m² (distal portion). In unmyelinated group-IV nerve fibres, the values also showed a broad variation ranging from 0.001 to 0.011 m³/m² (proximal portion) and from 0.003 to 0.019 m³/m² (distal portion). The wide range of mitochondrial concentrations may reflect different energy consumption during receptive processes: nerve fibres with a low mechanical threshold and a high probability of excitatory events may be rich in mitochondria, whereas fibres with a high mechanical threshold and a low probability of excitatory events may be poor in mitochondria.     

Primary afferent depolarization of C fibres in the spinal cord of the cat

The excitability of primary afferent terminals of cutaneous C fibres was tested in the spinal cord of decerebrated cats. C fibre terminal excitability was decreased in the spinal state, and increased by conditioning volleys that activated only A fibres of another cutaneous nerve and by stimulating hair mechanically. It is suggested that C fibre input and therefore nociceptive information to the central nervous system is susceptible to presynaptic control by segmental and suprasegmental mechanisms.