An intact nerve preparation for monitoring inputs from single joint afferent fibres.

A preparation is described that permits the monitoring of activity from individual joint afferent nerve fibres in an intact peripheral nerve of the cat. The joint nerve used was the medial articular nerve (MAN) that supplies the medial and anteromedial aspects of the knee joint. This nerve is sufficiently fine that if freed from nearby tissue over a length of 2-5 cm and placed over a platinum hook electrode it is possible to identify and monitor, from the intact nerve, the impulse activity from each group II joint afferent fibre activated by mechanical stimulation of the joint capsule. The signal-to-noise ratio exceeds 5:1 and in most cases was approximately 10:1. With this preparation it is now possible to examine the central actions and security of transmission at central synaptic targets for single, identified group II joint afferent fibres.

An intact peripheral nerve preparation for monitoring inputs from single muscle afferent fibres.

A preparation is described that permits the monitoring of activity from individual muscle afferent nerve fibres in an intact peripheral nerve in the forelimb of the cat. The nerve is a fine branch of the deep radial that supplies the indicis proprius muscle. When it is freed from nearby tissue over a length of 2-5 cm and placed in continuity over a silver hook electrode, it becomes possible to identify and monitor the impulse activity from each muscle afferent fibre activated by stretch or vibration applied to the muscle tendon or by focal mechanical stimulation of the muscle at the presumed site of individual spindle receptors. With this preparation it is possible to examine the central actions and security of transmission at central synaptic targets for single, identified muscle afferent fibres arising in the cat's forearm.

Bidirectional communication of sensory afferent information in a peripheral nerve of the cat forelimb.

Kinaesthetic information is derived from both muscle and joint nerves. However, the segregation, at peripheral levels, of inputs from these sources is by no means clear cut. In the present report, we demonstrate the complexity of peripheral innervation of joint and muscle structures in the cat's forearm, in particular, with evidence for bidirectional signalling for different classes of kinaesthetic afferents within a peripheral nerve segment. Three-way simultaneous recordings were carried out in the anaesthetized cat from single kinaesthetic afferents in three nerves that were freed from nearby tissue in the distal forearm, but remained in continuity. These were the wrist-joint nerve and two components of the indicis proprius nerve, one that projects proximally from the muscle to join the deep radial nerve, the other a distal extension of this nerve that runs through and beyond its own muscle to the region of the wrist-joint capsule where it forms an anastomosis with the wrist-joint nerve. Single-unit recording from the intact nerves demonstrated that some spindle afferent fibres from the indicis proprius muscle may take an "ectopic" path to the central nervous system, conveying their signals over an initial centrifugal path via the distal extension of the indicis proprius nerve, before looping back to project centripetally via the "classic" wrist-joint nerve. As some wrist-joint afferents themselves may project "ectopically" via the distal and then proximal segment of the indicis proprius nerve (rather than via the wrist-joint nerve), the recordings demonstrate that, within the distal segment of the indicis proprius nerve, there is bidirectional traffic of kinaesthetic afferent signals, with wrist-joint impulses travelling centripetally and muscle afferent signals travelling centrifugally. The findings emphasize the complexity of signalling that may be present in sensory nerves, on account of the "ectopic" paths taken by some afferents, and the need to activate deep inputs of joint or muscle origin by natural stimulation of the appropriate receptors in order to examine selectively the central actions and processing of either source of input.

Central projection of proprioceptive information from the wrist joint via a forearm 'muscle' nerve in the cat.

1. Peripheral nerves arising in joint capsules are known to contain a 'contaminating' contribution from muscle afferent fibres. In the present report we provide the first electrophysiological evidence that some joint afferent fibres may take an 'ectopic' path to the central nervous system via a nearby muscle nerve. 2. Experiments were conducted in anaesthetized cats in which a distal extension of the indicis proprius nerve was observed to project beyond its own muscle to the dorsal surface of the wrist joint capsule which is also supplied by the 'classic' wrist joint nerve, a branch of the dorsal interosseous nerve. Both the proximal and distal segments of the indicis proprius nerve were exposed for recording, by means of silver hook electrodes, while each segment remained in continuity. 3. Individual wrist joint afferent fibres with receptive fields on the dorsal surface of the joint capsule could be identified electrophysiologically within the distal segment of the indicis proprius nerve. In each of these cases the same fibre could also be identified at the proximal recording site. The identity of each of these simultaneously recorded units was established (1) by the short fixed interval between their times of spike occurrence, (2) from the exact correspondence of the capsular receptive field for the simultaneously recorded spikes, and (3) by the unfailing correlation in the presence, or absence, of the distally and proximally recorded spikes in association with either manual or controlled stimulation of the wrist joint capsule. Most joint afferent fibres identified with this projection path were in the group II range of conduction velocities and had conventional properties but group III fibres also appeared to be represented. 4. The present demonstration that some joint afferent fibres may be located within 'muscle' nerves emphasizes the importance of activating deep inputs, of joint or muscle origin, by adequate stimulation of the peripheral receptors in order to examine selectively the central actions of either source of input. Electrical stimulation of the peripheral nerves may lead to interpretative ambiguities.

Signalling of static and dynamic features of muscle spindle input by external cuneate neurones in the cat.

1. The present experiments examined the capacity of external cuneate nucleus (ECN) neurones in the anaesthetized cat to respond to static and vibrotactile stretch of forearm extensor muscles. The aim was to compare their signalling capacities with the known properties of main cuneate neurones in order to determine whether there is differential processing of muscle spindle inputs at these parallel relay sites. 2. Static stretch (<= 2 mm in amplitude) and sinusoidal vibration were applied longitudinally to individual muscle tendons and responses recorded from single ECN neurones. The muscle-related ECN neurones that were sampled displayed a high sensitivity to both static and dynamic components of stretch, including muscle vibration at frequencies of 50-800 Hz, consistent with their dominant input being derived from primary spindle afferent fibres. 3. In response to ramp-and-hold muscle stretch, ECN neurones resembled their main cuneate counterparts in the pattern of their responses and in quantitative response measures. Their coefficients of variation in interspike intervals during steady stretch ranged from approximately 0.3 to 0.7, as they do in main cuneate responses, and their stimulus-response relations were graded as a function of stretch magnitude with low variability in responses at a fixed stretch amplitude. 4. In response to muscle vibration, ECN activity was tightly phase locked to the vibration waveform, in particular at frequencies of <= 150 Hz, where vector strength measures (R) were high (R >= 0.8) before declining as a function of frequency, with R values of approximately 0.6 at 300 Hz and <= 0.4 at 800 Hz. Both the qualitative and quantitative aspects of ECN responsiveness to the vibro-stretch disturbances were indistinguishable from those of the main cuneate neurones. 5. The results demonstrate a high transmission fidelity for muscle signals across the ECN and no evidence for differential synaptic transmission across the parallel main and external cuneate nuclei. Earlier limitations observed in the capacity of cerebellar Purkinje cells to respond to primary spindle inputs must therefore be imposed at synapses within the cerebellum.

Parallel organization of proprioceptive inputs from joint receptors to cortical somatosensory areas I and II in the cat.

1. Studies in monkeys indicate that proprioceptive and tactile inputs are conveyed from the thalamus to the primary somatosensory cortex (SI) and thence to the secondary somatosensory area (SII) in a serial scheme. In contrast, in the cat, tactile information is conveyed in parallel from the thalamus to SI and SII. The present study, in the cat, employed reversible inactivation of SI to determine whether proprioceptive inputs to SII from joint receptors depend on an indirect serial path via SI or are conveyed over a direct path from the thalamus. 2. SI and SII foci for knee joint inputs were determined with evoked potential mapping. Reversible inactivation of the SI focus by cooling had no effect on the amplitude, latency or time course of SII potentials evoked by joint inputs. There was also no consistent effect on the response levels of individual SII neurones examined during SI inactivation. Furthermore, there was no attenuation of the later components of the responses, and therefore no evidence that these depended on an indirect path to SII via SI. 3. Results demonstrate that proprioceptive inputs project directly from thalamus to SII over a pathway organized in parallel with that to SI, in contrast to the serial scheme reported for proprioceptive processing in primates.

Parallel processing in cerebral cortex of the marmoset monkey: effect of reversible SI inactivation on tactile responses in SII.

1. Responsiveness within the hand region of the second somatosensory area of cortex (SII) was investigated in the marmoset monkey (Callithrix jacchus) in association with cooling-induced, reversible inactivation of the primary somatosensory area, SI. The aims were to determine whether thalamocortical systems in this primate species are organized according to a serial scheme in which tactile information is conveyed from the thalamus to SI and thence to SII as the next hierarchical level of processing and to establish whether primates are fundamentally different, in this respect, from mammals in which tactile information is conveyed in parallel from the thalamus to both SI and SII. 2. Inactivation of the SI had area was achieved when the temperature at the face of the silver cooling block over this SI region was lowered to < or = 13 degrees C. Inactivation was confirmed by abolition of the SI surface potential evoked by a brief tap stimulus to the hand and by the abolition of responsiveness in single SI neurons located beneath and around the edge of the block. 3. The effect of SI inactivation on SII-evoked potentials was investigated in 20 experiments by simultaneous recording of the SI- and SII-evoked potentials. The SII response was never abolished and was unchanged in the majority (12/20) of experiments. In the remainder, the SII-evoked potentials underwent a reduction in amplitude that was usually < 30% but never > 50%. 4. Tactile responsiveness was examined quantitatively in 47 individual SII neurons of different functional classes before, during, and after the inactivation of SI. Controlled tactile stimuli consisted of trains of sinusoidal vibration or rectangular pulses delivered to the glabrous or hairy skin of the hand. 5. Thirteen of the 47 SII neurons (28%) were unaffected in their response levels in association with SI inactivation. The remaining 34 SII neurons underwent some reduction in responsiveness, but in only 6% (3/47) was responsiveness abolished by SI inactivation. As the same range of functional classes of tactile neurons were represented among the affected and unaffected SII neurons, there was no evidence for a differential susceptibility among SII tactile neurons to the effect of SI inactivation. 6. Where reductions in amplitude of the SII-evoked potential or in response levels of SII neurons were observed, the effects were not attributable to direct spread of cooling from SI to the SII hand area as there was no cooling-induced prolongation of either the evoked potential or spike waveform in SII, an effect that is known to precede cooling-induced reductions in responsiveness. 7. These lines of evidence indicate that reductions in SII responsiveness in association with SI inactivation may be attributable to a loss of a background facilitatory influence rather than to a blockage of a component of peripheral input that comes over a putative serial path to SII via SI. First, as SI was cooled, there was a progressive increase in latency and time course of the SI responses before their disappearance, but no comparable delay in the SII responses as might be expected if SI were placed earlier than SII in a strict hierarchical scheme of thalamocortical processing. Second, SI inactivation failed to bring about a tightening in the phase-locking of SII responses to vibrotactile stimuli as might have been expected if the inputs to the SII neurons come via both a direct path from the thalamus and an indirect intracortical path via SI. Blockage of the indirect intracortical pathway through SI might be expected to reduce temporal dispersion in the input to SII neurons and result in an improvement in phase-locking in the SII responses to skin vibration. Third, the background activity of some SII neurons was reduced during SI inactivation along with the reduction in their responses to tactile stimulation.

The effects of neonatal median nerve injury on the responsiveness of tactile neurones within the cuneate nucleus of the cat.

1. The capacity of cuneate neurones to attain normal functional properties following neonatal median nerve injury was investigated with single neurone recording in anaesthetized cats, 12-24 months subsequent to a controlled crush injury. Effectiveness of the peripheral nerve injury was confirmed by the abolition of the median nerve compound action potential following the crush. 2. Cuneate recording was carried out after denervation of the forearm, apart from the median nerve, to ensure that neurones studied had receptive fields within the distribution zone of the regenerated median nerve. Controlled and reproducible tactile stimuli were used to evaluate the functional capacities of neurones to determine whether they were consistent with those reported earlier for cuneate neurones in cats that had normal peripheral nerve development. 3. Twenty-two cuneate neurones with well-defined tactile receptive fields within the distribution zone of the regenerated median nerve were classified according to their adaptation characteristics and functional properties. Slowly adapting neurones responded throughout static skin indentations and had graded and approximately linear stimulus-response relations over indentation ranges up to 1.5 mm. Rapidly adapting neurones responded to the dynamic phases of skin indentations and could be divided into two broad classes, one most sensitive to vibrotactile stimuli at 200-400 Hz which appeared to receive a predominant input from Pacinian corpuscle receptors, and a non-Pacinian group that included neurones most sensitive to skin vibration at 5-50 Hz which appeared to receive glabrous skin input from the rapidly adapting class of afferent fibres. 4. Based on the stimulus-response relations and on measures of phase locking in the responses to vibrotactile stimuli, it appears that the functional properties of cuneate neurones activated from the field of a regenerated median nerve subsequent to a neonatal nerve crush injury were consistent with those reported previously for 'control' cuneate neurones. The results indicate that cuneate neurones can acquire normal tactile coding capacities despite the disruption caused by prior crush injury to their peripheral nerve source.

Signalling of static and dynamic features of muscle spindle input by cuneate neurones in the cat.

1. The capacity of cuneate neurones to signal information derived from muscle spindle afferent fibres about static stretch or vibration of forearm extensor muscles was examined electrophysiologically in anaesthetized cats. 2. Static stretch (>= 2 mm in amplitude) and sinusoidal vibration (at frequencies of 50-800 Hz) were applied longitudinally to individual muscle tendons by means of a feedback controlled mechanical stimulator, and responses were recorded from individual cuneate neurones and from individual spindle afferent fibres. 3. Cuneate neurones sampled were located caudal to the obex and displayed a sensitivity to both vibration and static stretch of forearm muscles that was consistent with their input arising from primary spindle endings. In response to static muscle stretch, they displayed graded and approximately linear stimulus-response relations, and a stability of response level at fixed lengths that was consistent with these neurones contributing discriminative information about static muscle stretch. 4. In response to sinusoidal muscle vibration the cuneate neurones also showed graded stimulus-response relations (in contrast to spindle afferents which at low vibration amplitudes attain a plateau response level corresponding to a discharge of 1 impulse on each vibration cycle). Lowest thresholds were at 100-300 Hz and bandwidths of vibration sensitivity extended up to approximately 800 Hz. 5. Temporal precision in cuneate responses to muscle vibration was assessed by constructing phase scatter and cycle histograms from which measures of vector strength could be calculated. Cuneate responses displayed somewhat poorer phase locking (and lower vector strengths) than spindle afferent responses to vibration (a reflection of uncertainties associated with synaptic transmission). Nevertheless, the remarkable feature of cuneate responses to muscle vibration is the preservation of tight phase locking at frequencies up to 400-500 Hz, which presumably enables these central neurones to contribute accurate temporal information for the kinaesthetic sense in a variety of circumstances involving dynamic perturbations to skeletal muscle.