Regeneration in the spinal cord

Important advances have been made in our understanding of conditions that influence the intrinsic capacity of mature CNS neurons to initiate and maintain a regrowth response. The combination of exogenous neurotrophic support with strategies to alter the terrain at the injury site itself suggests that there are important interactions between them that lead to increased axonal regeneration. The ability of chronically injured neurons to initiate a regeneration response is unexpected. Our view of the role that inhibitors play in restricting axonal growth has also expanded. The findings indicate that the windows of opportunity for enhancing growth after spinal cord injury may be more numerous than previously thought.     

Correlations in the development of the spinal cord, dura mater and spinal canal in humans

The spinal cord axial structures (AS) (its dura mater and vertebral canal) demonstrate the greatest growth rate during the intrauterine period and on the 18th month. After birth for the dura mater this age is 3 years, and for the spinal cord and the vertebral canal--7 years of age. The pubertal jump in growth of these formations is noted during the adolescent age (17-21 years). During the first two decades AS demonstrate asymptotic type of growth. In AS development the following periods in common have been revealed: a) intensive growth in children up to 7 years of age; b) growth stabilization (from 8 up to 16 years of age); c) period of a relative morphological stability (22-35 years); d) period of unstable compensatory-adaptive rearrangements (36-60 years); e) period of involutive changes (61-90 years).     

Energy transfers in the spinal engine

Locomotion is generally perceived as being the function of the legs. The trunk is considered to be carried along in a more or less passive way. This popular hypothesis appears to have been accepted with little substantiation. In light of the numerous observations contradicting this view, we have proposed an alternative hypothesis in which the spine and its surrounding tissues comprise the basic engine of locomotion. This theory is consistent with available experimental data which suggest that the motion of the spine precedes that of the legs. Indeed, the variations in the power delivered to the pelvis by the spine are strikingly similar to, but slightly ahead of, the variation in power at the hip.     

Anatomy of the crocodilian spinal vein

The crocodilian spinal vein is remarkably robust yet historically overlooked. Using corrosion casting, we describe the anatomy of this vessel and its connections with the caval and hepatic venous systems in representatives from four crocodilian genera. The spinal vein arises from an enlarged occipital sinus over the medulla and extends the entire length of the vertebral column. Unlike in squamate reptiles, the spinal vein is single (nonplexiform), voluminous, and situated dorsal to the spinal cord, and plexi lateral to the cord span between emerging intercostal veins. The connections with the other venous systems are otherwise similar to those in other tetrapods. The overall anatomy of this vessel and its abundant connections with the other venous systems indicate it likely plays a primary role in returning blood to the heart from all parts of the body. Preliminary studies of function suggest that this vessel could also play an adaptive role during basking and diving.     

Analysis of spinal cord proteome in the rats with mechanical allodynia after the spinal nerve injury

Proteome analysis was carried out to identify the proteins associated with neuropathic pain after peripheral nerve injury. Five proteins displayed different expression levels among three groups of rats. Among these proteins, creatine kinase B expression level was lower in the pain-positive rats compared to the sham or pain-negative rats. Therefore, a lower creatine kinase B expression level may be important in the development and maintenance of neuropathic pain.     

Manipulations of spinal cord excitability evoke developmentally-dependent compensatory changes in the lamprey spinal cord

We have examined homeostatic or compensatory plasticity evoked by tonic changes in spinal cord excitability in the lamprey, a model system for investigating spinal cord function. In larval animals, reducing excitability by incubating in tetrodotoxin or the glutamate receptor antagonists CNQX or CNQX/AP5 for 20–48 h resulted in a diverse set of cellular and synaptic changes that together were consistent with an increase in spinal cord excitability. Similar changes occurred to a tonic increase in excitation evoked by incubating in high potassium physiological solution (i.e. responses were unidirectional). We also examined developmental influences on these effects. In animals developing from the larval to adult form effects were reduced or absent, suggesting that at this stage the spinal cord was more tolerant of changes in activity levels. Responses had returned in adult animals, but they were now bi-directional (i.e. opposite effects were evoked by an increase or decrease in excitability). The spinal cord can thus monitor and adapt cellular and synaptic properties to tonic changes in excitability levels. This should be considered in analyses of spinal cord plasticity and injury.     

Woroschiloff's locating device for interventions on the spinal cord and its influence on spinal stereotaxis

111 years ago the first locating device for the spinal cord was constructed, which became the basis for the contemporary spinal cord stereotaxy. Woroschiloff invented this device to operate stereotactically in different spinal cord segments. Nowadays only the fixation of the spinal cord stereotactic device to the wound retractor has changed from his concept, and control of the surgical instrument has been improved in three perpendicular planes corresponding to the special stereotactic maps of the human spinal cord.     

Motor mechanisms in the turtle spinal cord

We reveal the intrinsic motor capacity of the spinal cord by examining motor behaviours produced by spinal segments caudal to a complete transection of the spinal cord. The turtle spinal cord generates three forms of the scratch reflex in the absence of neural inputs from supraspinal structures. Each form exhibits a characteristic motor neuron discharge pattern. We test the ability of the spinal cord to generate organized motor patterns in the absence of movement-related sensory feedback by examining motor neuron discharge patterns in spinal preparations that are immobilized with a neuromuscular blocking agent. The motor neuron discharge pattern associate with each form is observed in the spinal immobilized preparation. Each of these motor patterns is therefore generated centrally within the spinal cord.