Functional recovery, serotonergic sprouting, and endogenous progenitor fates in response to delayed environmental enrichment after spinal cord injury.

Environmental enrichment (EE) is a way to induce voluntary locomotor training that positively affects locomotor recovery after acute spinal cord injury (SCI). The beneficial effect on SCI outcome is thought to be based on enhanced plasticity in motor pathways, triggered by locomotor-specific sensory feedback to the spinal cord circuitry for locomotion (central pattern generators [CPGs]). In view of chronic SCI, we tested the hypothesis that EE improves motor outcome after SCI in the rat when started after a clinically relevant delay of 3 weeks. At the CPG level (i.e., the spinal L1-L2 level), where EE-related sensory feedback is processed, two key mechanisms of anatomical plasticity were examined: (1) serotonergic innervation, and (2) survival and differentiation of spinal cord progenitor cells. Delayed EE improved interlimb coordination, which was associated with an increased serotonergic innervation of the ventro-lateral grey matter within the L1-L2 segments. Although spinal cord progenitor cells were found to differentiate into both neurons and glial cells, EE did not affect their survival. These results show that EE induces a substantial improvement of motor outcome after SCI when commenced after a clinically-relevant delay. Increased serotonergic innervation of the lumbar CPG area is therefore suggested to play an important role in the EE-induced recovery of interlimb coordination.

Acute rolipram/thalidomide treatment improves tissue sparing and locomotion after experimental spinal cord injury.

Traumatic spinal cord injury (SCI) causes severe and permanent functional deficits due to the primary mechanical insult followed by secondary tissue degeneration. The cascade of secondary degenerative events constitutes a range of therapeutic targets which, if successfully treated, could significantly ameliorate functional loss after traumatic SCI. During the early hours after injury, potent pro-inflammatory cytokines, including tumor necrosis factor alpha (TNF-alpha) and interleukin-1 beta (IL-1beta) are synthesized and released, playing key roles in secondary tissue degeneration. In the present investigation, the ability of rolipram and thalidomide (FDA approved drugs) to reduce secondary tissue degeneration and improve motor function was assessed in an experimental model of spinal cord contusion injury. The combined acute single intraperitoneal administration of both drugs attenuated TNF-alpha and IL-1beta production and improved white matter sparing at the lesion epicenter. This was accompanied by a significant (2.6 point) improvement in the BBB locomotor score by 6 weeks. There is, at present, no widely accepted intervention strategy that is appropriate for the early treatment of human SCI. The present data suggest that clinical trials for the acute combined application of rolipram and thalidomide may be warranted. The use of such "established drugs" could facilitate the early initiation of trials.

Strain and locomotor speed affect over-ground locomotion in intact rats.

A variety of animal models for neurological disease and injury exist and locomotor performance is an important outcome parameter in studies employing these models. The CatWalk, an automated quantitative gait analysis method is a method to study over-ground locomotor performance in large groups of animals. In the present study, we used the CatWalk which allowed us to investigate strain differences in over-ground locomotion in three commonly used strains of laboratory rat (i.e. Lewis, Wistar and Sprague-Dawley rats) based on objective data-analysis in a large number of animals. The present results revealed marked strain differences on the static paw parameters; base-of-support, and the relative paw position. Furthermore, strain differences were noted on the static parameter stride length and the dynamic parameters stance-, swing- and stepcycle duration, which are due logically to morphological differences between strains. The parameters related to coordination did not reveal any differences between the strains. Furthermore, the swing duration and the cruciate and alternate patterns i.e. regular step patterns Ca ("cruciate" pattern type a) and Ab ("alternate" pattern type b) were shown to be differentially affected by the locomotor speed. We conclude that differences in gait traits exist between the three laboratory rat strains investigated and several of the examined gait parameters showed strain dependent interdependency with locomotor speed.

Characterization of retinaldehyde dehydrogenase-2 induction in NG2-positive glia after spinal cord contusion injury.

The transcriptional activator retinoic acid (RA) supports axonal regeneration of several neuronal cell populations in vitro, and it has been suggested that its receptor RARbeta2 may be used to support axonal regeneration in the adult mammalian spinal cord. We have previously shown that spinal cord injury induces activity of the RA synthesizing enzyme retinaldehyde dehydrogenase (RALDH)2 in NG2-positive cells. This report quantifies the increase of RALDH2 protein in the injured spinal cord and characterizes the RALDH2/NG2 expressing cells probably as a unique RA synthesizing subpopulation of activated oligodendrocyte precursors or "polydendrocytes". In the uninjured spinal cord low levels of RALDH2 are present in oligodendrocytes as well as in the meninges and in blood vessels. Following injury there is a significant increase in RALDH2 in these latter two tissues and, given that the RALDH2/NG2 positive cells are clustered in the same area, this implies that these are specific foci of RA synthesis. It is presumed that these cells release RA in a paracrine fashion in the region of the wound; however, the RALDH2/NG2-immunoreactive cells expressed the retinoid receptors RARalpha, RARbeta, RXRalpha and RXRbeta, suggesting that RA also serves an autocrine function.

Stimulation of neurite outgrowth on neonatal cerebral astrocytes is enhanced in the presence of BDNF.

An area of increasing interest in spinal cord injury (SCI) research is the development of multi-factorial strategies to promote repair. In this respect, a prominent role is played by cell transplantation, the reparative effect of which can be enhanced by additional use of neurotrophic factors. Immature astrocytes have shown their merit in stimulating axon regeneration upon transplantation into the injured spinal cord. Brain-derived neurotrophic factor (BDNF) influences a wide range of descending axon tracts in the injured spinal cord. In the present study, we hypothesized that the neurite outgrowth of neonatal cortical neurons on immature astrocytes is enhanced in the presence of BDNF. To test this hypothesis, neonatal cortical neurons were cultured on neonatal astrocytes for 2 days in absence or presence of BDNF. The length of the longest neurite and the number of primary neurites per neuron were taken as measures to study neurite outgrowth. We show that BDNF dose-dependently enhanced neurite outgrowth of neonatal cerebral cortical neurons grown on immature astrocytes. Compared to conditions without BDNF, the length of the longest neurite increased by 25.5 and 28.8% in presence of 10 and 100 pg/ml BDNF, respectively. BDNF did not alter the density of the immature astrocytes. We conclude that the presence of BDNF enhances the neurite outgrowth on immature astrocytes. A multi-factorial strategy based on transplantation of neonatal astrocytes in the presence of additional BDNF is recommended and may stimulate axon regrowth after experimental injury to the central nervous system.

CatWalk-assisted gait analysis in the assessment of spinal cord injury.

Gait analysis plays an important role in the assessment of neurological function in many disease models. In this review, we focus on the newly developed CatWalk system for gait analysis. CatWalk was originally developed as a tool to enhance assessment of functional outcome in spinal cord injury (SCI) models. Although it is also of value in models of among others (neuropathic) pain and peripheral nerve damage, we will limit ourselves to its use in SCI models in this review. The system is positioned against well-established locomotor function tests, and it is indicated how CatWalk can enhance the usefulness of such tests. Development of the system started with the idea that it should enable objective assessment of coordination, and powerful measures of coordination are nowadays included in the analysis options provided by CatWalk. Therefore, a major part of this review is devoted to the history and meaning of these coordination measures.

Circulating insulin-like growth factor I and functional recovery from spinal cord injury under enriched housing conditions.

Voluntary locomotor training as induced by enriched housing of rats stimulates recovery of locomotion after spinal cord injury (SCI). Generally it is thought that spinal neural networks of motor- and interneurons located in the ventral and intermediate laminae within the lumbar intumescence of the spinal cord, also referred to as central pattern generators (CPGs), are the 'producers of locomotion' and play a pivotal role in the amelioration of locomotor deficits after SCI. It has been suggested that locomotor training provides locomotor-specific sensory feedback into the CPGs, which stimulates remodeling of central nervous system pathways, including motor systems. Several molecules have been proposed to potentiate this process but the underlying mechanisms are not yet known. To understand these mechanisms, we studied the role of insulin-like growth factor (IGF) I in functional recovery from SCI under normal and enriched environment (EE) housing conditions. In a first experiment, we discovered that subcutaneous administration of IGF-I resulted in better locomotor recovery following SCI. In a second experiment, detailed analysis of the observed functional recovery induced by EE revealed full recovery of hindlimb coordination and stability of gait. This EE-dependent functional recovery was attenuated by alterations in the pre-synaptic bouton density within the ventral gray matter of the lumbar intumescence or CPG area. Neutralization of circulating IGF-I significantly blocked the effectiveness of EE housing on functional recovery and diminished the EE-induced alterations in pre-synaptic bouton density within the CPG area. These results support the use of IGF-I as a possible therapeutic aid in early rehabilitation after SCI.

Limitations in transplantation of astroglia-biomatrix bridges to stimulate corticospinal axon regrowth across large spinal lesion gaps.

Regrowth of injured axons across rather small spinal cord lesion gaps and subsequent functional recovery has been obtained after many interventions. Long-distance regeneration of injured axons across clinically relevant large spinal lesion gaps is relatively unexplored. Here, we aimed at stimulating long-distance regrowth of the injured corticospinal (CS) tract. During development, an oriented framework of immature astrocytes is important for correct CS axon outgrowth. Furthermore, a continuous growth promoting substrate may be needed to maintain a CS axon regrowth response across relatively large spinal lesion gaps. Hence, we acutely transplanted poly(D,L)-lactide matrices, which after seeded with immature astrocytes render aligned astrocyte-biomatrix complexes (R. Deumens, et al. Alignment of glial cells stimulates directional neurite growth of CNS neurons in vitro. Neuroscience 125 (3) (2004) 591-604), into 2-mm long dorsal hemisection lesion gaps. In order to create a growth promoting continuum, astrocyte suspensions were also injected rostral and caudal to the lesion gap. During 2 months, locomotion was continuously monitored. Histological analysis showed that astrocytes injected into host spinal tissue survived, but did not migrate. None of the astrocytes on the biomatrices survived within the lesion gap. BDA-labeled CS axons did not penetrate the graft. However, directly rostral to the lesion gap, 120.9+/-38.5% of the BDA-labeled CS axons were present in contrast to 12.8+/-3.9% in untreated control animals. The observed anatomical changes were not accompanied by locomotor improvements as analyzed with the BBB and CatWalk. We conclude that although multifactorial strategies may be needed to stimulate long-distance CS axon regrowth, future studies should focus on enhancing the viability of cell/biomatrix complexes within large spinal lesion gaps.

Neurite outgrowth promoting effects of enriched and mixed OEC/ONF cultures.

Olfactory ensheathing cell (OEC) transplants stimulate axon regeneration and partial functional recovery after spinal cord injury. However, it remains unclear whether enriched OEC or mixed transplants of OEC and olfactory nerve fibroblasts (ONF) are optimal for stimulating axon regrowth. The neurite outgrowth stimulating effects of enriched OEC, ONF, and mixed OEC/ONF cultures on neonatal cerebral cortical neurons were compared using co-cultures. We show that (1) OEC are more neurite outgrowth promoting than ONF, and (2) ONF do not enhance the neurite outgrowth stimulating effects of OEC in mixed OEC/ONF cultures. Hence, our data indicate that there is no preference for the use of enriched OEC or mixed OEC/ONF cultures with respect to stimulation of neurite growth in vitro.

Regeneration of descending axon tracts after spinal cord injury.

Axons within the adult mammalian central nervous system do not regenerate spontaneously after injury. Upon injury, the balance between growth promoting and growth inhibitory factors in the central nervous system dramatically changes resulting in the absence of regeneration. Axonal responses to injury vary considerably. In central nervous system regeneration studies, the spinal cord has received a lot of attention because of its relatively easy accessibility and its clinical relevance. The present review discusses the axon-tract-specific requirements for regeneration in the rat. This knowledge is very important for the development and optimalization of therapies to repair the injured spinal cord.

The assessment of locomotor function in spinal cord injured rats: the importance of objective analysis of coordination.

The Basso, Beattie and Bresnahan (BBB) locomotor rating scale is the most widely used open field test and has been accepted as a valid way to assess locomotor function after spinal cord contusion injury in the rat. A limitation within the BBB locomotor rating scale is the correct assessment of forelimb (FL)-hindlimb (HL) coordination. This limitation can have major implications for the final assessment of locomotor function. In the present study, we show an objective method to assess coordination based on the regularity index (RI), achieved through the use of the CatWalk method. The RI grades the degree of coordination as the result of the number of normal step sequence patterns multiplied by four and divided by the total amount of paw placements. Using the RI, single walkway crossings can be objectively analyzed on coordination. Integration of the CatWalk based coordination into the BBB scale indicates that objective analysis of coordination results in reliable and more sensitive assessment of locomotor function. This new method has been tested successfully in determination of positive effects of enriched housing on functional recovery after spinal cord injury (SCI).