Cephalic sensory influence on forelimb movement in newborn opossums, Monodelphis domestica.

Like other marsupials, the opossum Monodelphis domestica is born very immature and crawls, unaided by the mother, from the urogenital opening to a nipple where it attaches and pursues its development. If the alternate, rhythmic movements of the forelimbs which allow this locomotion are generated by the developing spinal motor networks, sensory information is nonetheless needed to guide the newborn to a nipple. Behavioral, anatomical and physiological studies suggest that the auditory and the visual systems are insufficiently developed in newborn opossums to influence spinal motor centers, while the vestibular, trigeminal, and olfactory systems are likelier candidates. The trigeminal, vestibular and olfactory regions of the brain were electrically stimulated to test their relative effectiveness at eliciting forelimb movement in newborn opossums, using in vitro preparations of brain-spinal cord with the limbs attached. The minimal stimulation of the cervical spinal cord needed to induce forelimb movement was considered as threshold (T). Stimulations of the trigeminal ganglion (5G) at ∼2T and of the vestibular complex at ∼20T could induce the same movement, and were not statistically different, in contrast to the ∼600T necessary for the olfactory bulb (OB). Neurofilament-200 immunohistochemistry and retrograde tracing with Texas-Red conjugated Dextran Amines were used to study trigeminal innervation of the facial skin and pathways by which trigeminal inputs may be relayed to the spinal cord. Numerous nerve fibers were observed in the snout dermis, especially in the maxillary region, but also elsewhere in the head skin. Some 5G cells project to the upper spinal cord, but more project to the caudal medulla where they could contact secondary trigeminal neurons or reticular cells projecting to the spinal cord. These results support a significant influence of the trigeminal and the vestibular systems, but not of olfaction, on forelimb movement of neonatal opossums.

Double-barrel fibular graft for metaphyseal areas reconstruction around the knee.

UNLABELLED: The metaphyses around the knee (distal femoral and proximal tibial) are junction areas subject to considerable stress. Double-barrel free vascular fibular graft (D-FVFG) provides good bone augmentation and restores the metaphyseal cone; the present study assessed its capacity to restore metaphyseal anatomy and axis and investigated its impact on the neighboring knee joint. MATERIAL AND METHODS: Eight D-FVFGs performed for metaphyseal segmental bone defect were followed up for a mean 6.5 years (range, 3-14 years). There were seven femoral nonunions, five of which were septic, and one chondrosarcoma of the tibia. Osteosynthesis used an external fixator (EF) in six cases (four of which bridged the knee), a double plate on the tibia in one case, and intramedullary nailing of the femur in two cases, including one to replace an EF. Adjuvant bone graft was associated in six cases. A protective leg brace was maintained for a mean 16.0±4.0 months. Three arthrolyses were required after final union. RESULTS: Union was achieved in all cases, after a mean 6.4±2.1 months. Sixty-four percent of defect volume was reconstructed. The immediate postoperative mechanical femorotibial angle was 180.3±6.0° and 174.5±5.7° at FU. Mean knee flexion was 96.9±36.0° and extension -5.0±10.0°. Three patients showed symptomatic arthritis at follow-up. DISCUSSION: D-FVFG satisfactorily restored the anatomy of the metaphyseal area. EF knee bridging seemed to impair varus correction, on top of the systematic problem of stiffness. When possible, internal fixation in first intention or as EF replacement appears to be preferable. Arthritic deterioration of the knee is worsened by initial joint lesions and femorotibial varus. LEVEL OF EVIDENCE: Level IV. TYPE OF STUDY: retrospective.

Serotonin refines the locomotor-related alternations in the in vitro neonatal rat spinal cord.

Serotonergic projections from raphe nuclei arrive in the lumbar enlargement of the spinal cord during the late fetal period in the rat, a time window during which the locomotor-related left/right and flexor/extensor coordinations switch from synchrony to alternation. The goal of the present study was to investigate the role played by serotonin (5-HT) in modulating the left/right and flexor/extensor alternations. Fictive locomotion was induced by bath application of N-methyl-D,L-aspartate (NMA) in the in vitro neonatal rat spinal cord preparation. By means of cross-correlation analysis we demonstrate that 5-HT, when added to NMA, improves left/right and flexor/extensor (recorded from the 3rd and 5th lumbar ventral roots, respectively) alternations. This effect was partly reproduced by activation of 5-HT(2A/2C) receptors. We then tested the contribution of endogenous 5-HT to NMA-induced fictive locomotion. Reducing the functional importance of endogenous 5-HT, either by inhibiting its synthesis with daily injections of p-chloro-phenylalanine (PCPA), starting on the day of birth, or by application of ketanserin (a 5-HT(2) receptor antagonist) or SB269970 (a 5-HT(7) receptor antagonist), disorganized the NMA-induced locomotor pattern. This pattern was restored in PCPA-treated animals by adding 5-HT to the bath. Blocking 5-HT(7) receptors disorganized the locomotor-like rhythm even in the absence of electrical activity in the brain stem, suggesting that NMA applied to the spinal cord does not cause 5-HT release by activating a spino-raphe-spinal loop. These results demonstrate that 5-HT is critical in improving the locomotor-related alternations in the neonatal rat.

Vestibulo-reticular projections in adult lamprey: their role in locomotion.

This study describes the anatomical projections from vestibular secondary neurons to reticulospinal neurons in the adult lamprey and the modulation of vestibular inputs during fictive locomotion. Anatomical tracers were applied in the posterior (PRRN) and middle rhombencephalic reticular nuclei as well as to the proximal stumps of cut vestibular nerve branches to identify the neurons projecting to the reticular nuclei that were in close proximity with vestibular primary afferents. Labeled neurons were found in the intermediate (ION) and posterior (PON) octavomotor nuclei, and were more numerous on the side of the injection (around 56-87 and 101-107 for the ION and the PON, respectively). Morphologies varied but cells were mostly round or oval. Axonal projections from the PON formed a dense bundle, whereas those from the ION were less densely packed. Based on their morphology and the distribution of their projections, most vestibulo-reticular neurons were presumed to be vestibulospinal cells. Reticulospinal cells from the PRRN were recorded intracellularly in the in vitro brainstem-spinal cord preparation and large excitatory post-synaptic potentials (EPSPs) were evoked following stimulation of the ipsilateral anterior and the contralateral posterior branches of the vestibular nerves, whereas inhibitory post-synaptic potentials (IPSPs) or smaller EPSPs were elicited by stimulation of the ipsilateral posterior or of the contralateral anterior branches. During fictive locomotion, both the excitatory and the inhibitory responses displayed phasic changes in amplitude such that the amplitude of the EPSPs was minimal when the spinal cord activity switched from the ipsilateral to the contralateral side of the recorded reticulospinal cell. The IPSPs were then of maximal amplitude. We propose that this modulation could serve to reduce the influence of vestibular inputs in response to head movements during locomotion.

The in vitro neonatal rat spinal cord preparation: a new insight into mammalian locomotor mechanisms.

The in vitro neonatal rat spinal cord preparation is the first mammalian nervous system isolated from the brainstem to the caudal end of the spinal cord. It permits the study of the cellular properties of mammalian locomotor networks and is unique in containing all the nervous structures related to locomotion. Although being a very immature system, this model has been considered as an adult preparation in which mammalian locomotor central pattern generators can be studied in detail. Nevertheless, one can also follow the development of locomotor functions during the perinatal period. Contrary to the adult, all neuroactive substances can directly reach the cellular structures in the brainstem-spinal cord preparation. When a neuroactive substance is applied to the bath, a single rhythmic activity is recorded along the cord. In fact, three rhythms can be isolated: one at the cervical level for the forelimbs, one at the lumbar level for the hind limbs and one in the sacrococcygeal region for the tail. Studies carried out on this preparation deal with three major areas: (1) relations between spontaneous activity and maturation of spinal network, (2) organisation of the different spinal networks, (3) key role of the descending pathways.

Relationship between vestibular primary afferents and vestibulospinal neurons in lampreys.

The distribution of vestibular primary afferents as well as their relationship with vestibulospinal and other brainstem neurons were studied in lampreys using anatomical tracers. Afferents from the anterior (aVIIIn) and the posterior (pVIIIn) branches of the vestibular nerve were located mainly in the ventral nucleus of the octavolateral area. The relationship between afferents and vestibulospinal neurons was studied by applying one fluorescent tracer to the whole vestibular nerve or one of its branches and applying another tracer to the spinal cord. Some afferents showed large, bulb-like enlargements (bulbs) and about 20 of these were found in the anterior and the intermediate octavomotor nucleus, whereas about 40 were found in the posterior octavomotor nucleus. Some of the bulbs made apparent contact with vestibulospinal neurons in the intermediate octavomotor nucleus and originated mostly from the aVIIIn, whereas bulbs in the posterior octavomotor nucleus originated from the pVIIIn. Applications of biocytin to hemisegments of rostral spinal cord labeled vestibulospinal neurons located in the ipsilateral intermediate octavomotor nucleus and the contralateral posterior octavomotor nucleus. In addition, vestibular primary afferents with bulbs in apparent contact with vestibulospinal neurons were transneuronally labeled by biocytin. They were observed in the ipsilateral aVIIIn and the contralateral pVIIIn and could be followed in the labyrinths, where they innervated the vertical and horizontal arms of the semicircular canal crests. Taken together, these results indicate that vestibular primary afferents from the aVIIIn innervate predominantly vestibulospinal neurons of the intermediate octavomotor nucleus, whereas afferents from the pVIIIn innervate vestibulospinal neurons in the posterior octavomotor nucleus. This anatomical organization suggests that afferents carrying bulbs convey dynamic information to vestibulospinal neurons, which, in turn, project to the spinal cord networks.

Perinatal development of lumbar motoneurons and their inputs in the rat.

The rat is quite immature at birth and a rapid maturation of motor behavior takes place during the first 2 postnatal weeks. Lumbar motoneurons undergo a rapid development during this period. The last week before birth represents the initial stages of motoneuron differentiation, including regulation of the number of cells and the arrival of segmental and first supraspinal afferents. At birth, motoneurons are electrically coupled and receive both appropriate and inappropriate connections from the periphery; the control from supraspinal structures is weak and exerted mainly through polysynaptic connections. During the 1st postnatal week, inappropriate sensori-motor contacts and electrical coupling disappear, the supraspinal control increases gradually and myelin formation is responsible for an increased conduction velocity in both descending and motor axons. Both N-methyl-D-aspartate (NMDA) and non-NMDA receptors are transiently overexpressed in the neonatal spinal cord. The contribution of non-NMDA receptors to excitatory amino acid transmission increases with age. Activation of gamma-aminobutyric acid(A) and glycine receptors leads to membrane depolarization in embryonic motoneurons but to hyperpolarization in older motoneurons. The firing properties of motoneurons change with development: they are capable of more repetitive firing at the end of the 1st postnatal week than before birth. However, maturation does not proceed simultaneously in the motor pools innervating antagonistic muscles; for instance, the development of repetitive firing of ankle extensor motoneurons lags behind that of flexor motoneurons. The spontaneous embryonic and neonatal network-driven activity, detected at the levels of motoneurons and primary afferent terminals, may play a role in neuronal maturation and in the formation and refinement of sensorimotor connections.

Anatomical study of vestibulospinal neurons in lampreys.

The present study was carried out to characterize anatomically the vestibulospinal (VS) system of lampreys. Cobalt-lysine or Texas Red dextran amines were applied in vitro to the rostral spinal cord. Two distinct populations of VS neurons were labeled in the ventral nucleus of the area octavolateralis. The rostral group, comprising the intermediate octavomotor nucleus (ION), contained between 100 and 150 neurons, having somata of variable size and morphology. Intracellular injections of Lucifer Yellow in single neurons revealed ION VS neurons with dendrites extending in the ventrolateral alar plate as well as medially in the basal plate. The caudal group, comprising the posterior octavomotor nucleus (PON), contained approximately 65 neurons, most of which were unipolar with round or oval somata. To study the projections of VS axons, cobalt-lysine was injected into the ION or PON regions in the brainstem. Axons from the ION projected to the ipsilateral spinal cord, whereas PON axons decussated within the basal plate giving out descending and ascending branches. The descending branch projected to the contralateral spinal cord. Injections of two fluorescent dextran-amines, each restricted to one side of the spinal cord, did not double-label VS cells in either octavomotor nuclei, indicating that the projections of each nucleus are restricted to one side. Injections of horseradish peroxidase further caudally in the spinal cord revealed that VS axons from the ION reached past the gill region. Our results indicate that the organization of the VS system of lampreys is similar to that observed in other vertebrates.

Development of spontaneous locomotor behaviors in the opossum, Monodelphis domestica.

The development of spontaneous locomotor behaviors was studied in the opossum Monodelphis domestica. The newborn opossum performs alternate, rhythmic movements with its forelimbs to crawl on the mother's belly where it attaches to a nipple, and its hindlimbs are little more than embryonic buds. The forelimbs retain the above movements for about 3 weeks, while the hindlimbs begin to move late in the second week. When detached from the nipple at 2-3 weeks, the pup can support its weight on the forelimbs and pivot around its hindquarter. Around the fourth week, the young can detach from the mother, its hindlimbs can support weight and linear locomotion appears, but the four limbs are not well coordinated. However, it can swim with coordinated movements of all limbs. Coordination when walking appears around the sixth week. During development, the duration of the step cycle decreases significantly. The durations of the stance and swing phases of the step cycle decrease in absolute terms, but swing increases as a percentage of the step cycle. The results are discussed in relation to the development of nervous and skeletomuscular components as well as sensorimotor reflexes.

The vestibular primary afferents and the vestibulospinal projections in the developing and adult opossum, Monodelphis domestica.

The gray short-tailed opossum Monodelphis domestica is born in a very immature state (eyes and ears closed, budlike hindlimbs, etc.) 14 days post-coitum, but it can locomote with its forelimbs from the mother's genital aperture to a nipple to which it attaches. The forelimb movements allowing this behavior may be the expression of central pattern generators in the spinal cord, but sensory clues must guide it. One such system may be the vestibular system, which senses linear and angular acceleration and has a strong influence on posture and balance at rest and during locomotion in adult animals. Using the neuronal tracer DiI, we have looked at the vestibular primary afferents and the vestibular nuclear projections to the cervical spinal cord in newborn and postnatal opossums, as well as in the adult animal. The projections in the adult opossum conform to those described for other mammals. Fibers of the vestibular portion of the eighth nerve distribute to all four vestibular nuclei and toward the cerebellar primordium on the day of birth. In addition, some of the fibers project to the contralateral vestibular ganglion, a projection that is not found in the adult opossum. Projections from the lateral, medial and inferior vestibular nuclei to the cervical cord are also present in the newborn. Although we cannot exclude the possibility that chemical and/or tactile guidance is used for directing the movements of the newborn opossum, our results support the hypothesis that the vestibular system may be directly involved in the control of these movements. However, not all components of the system are equally developed at birth, and the circuit from the utricle to the lateral vestibular nucleus and from the latter to the cervical cord may be better formed than that from the semicircular canals to the medial and inferior vestibular nuclei to the cervical cord.

The development of sensorimotor reflexes in the Brazilian opossum Monodelphis domestica.

The development of a number of sensorimotor reflexes was studied in the Brazilian opossum Monodelphis domestica. At birth, an opossum's forelimbs execute rhythmic, alternate movements which resemble swimming, whereas the hindlimbs are little more than embryonic buds that do not move independent of the trunk. It is possible, therefore, to witness the entire development of hindlimb motility, the advent of coordination between forelimbs and hindlimbs, and the development of ambulation. The following sequence in the appearance and maturation of the reflexes was observed: rooting, an innate reflex in mammals which disappears over time; withdrawal of the forelimbs followed by withdrawal of the hindlimbs; crossed extension of the forelimbs and then of the hindlimbs; grasp, the forelimbs preceding the hindlimbs; body righting on a surface; forward hopping of the forelimbs followed by the hindlimbs; lateral and medial hopping of the forelimbs, then the hindlimbs; chin tactile placing; body righting in the air; and, finally, visual placing. Limb tactile placing is not significantly expressed, even in the adult. This behavioral sequence generally matches the sequence of somatic (trunk, limbs, head) and neural (spinal cord and brain) structures involved in the control of these behaviors.

The ontogenic development of sensorimotor reflexes and spontaneous locomotion in the Mongolian gerbil (Meriones unguiculatus).

Most behavioral studies on the ontogeny of sensorimotor reflexes and locomotion were done in quadrupedal species with equally developed forelimbs (FL) and hindlimbs (HL). In contrast, the Mongolian gerbil has long and strong HL but relatively small FL, indicating their differential use for locomotion. We have used the gerbil to study the ontogeny of a number of reflexes and locomotor acts to see if their sequence of appearance, their maturation, as well as their intensity of expression, differed from some other mammals. The following sequence was observed: forward FL hopping, FL grasp, forward HL hopping, surface body righting, chin tactile placing, lateral FL hopping, lateral HL hopping, medial FL hopping, medial HL hopping, visual placing, air body righting, and FL and HL tactile placing. When comparing FL and HL, a given reflex does not necessarily appear earlier in the limb that expresses it more strongly. The results are discussed in relation to the development of the central nervous system, the limb, and the locomotor behavior.

The ontogenesis of sensorimotor reflexes in the Mongolian gerbil Meriones unguiculatus.

The ontogeny of a number of sensorimotor reflexes has been studied in the Mongolian gerbil. In contrast to a number of other mammals, the gerbil has relatively long and strong hindlimbs but small forelimbs, indicating their different importance for a number of locomotor acts, and during the developmental period studied, the hindlimbs grow at a much faster rate than the forelimbs. The following sequence of appearance and maturation of the reflexes was observed: rooting, forelimb hopping, surface body righting, forelimb grasp, hindlimb hopping, chin tactile placing, visual placing, air body righting and, at the same time, forelimb and hindlimb tactile placing. This sequence concords with the general gradient of development and maturation of the spinal and brain centers subserving these reflexes, as evaluated from Nissl preparations. The results indicate that there is no clearcut rostro-caudal gradient of postnatal maturation of the spinal cord and the spinally mediated reflexes, but that there is a general caudo-rostral gradient of brain maturation and of the brain-mediated reflexes. Comparisons with other mammals are made.