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.

Preoperative housing in an enriched environment significantly reduces the duration of post-operative pain in a rat model of knee inflammation.

The influence of the environment on clinical post-operative pain received recently more attention in human. A very common paradigm in experimental pain research to model the effect of housing conditions is the enriched environment (EE). During EE-housing, rats are housed in a large cage (i.

Environmental housing affects the duration of mechanical allodynia and the spinal astroglial activation in a rat model of chronic inflammatory pain.

In this study, we aimed at investigating the effect of an enriched environment (EE) on the recovery from chronic inflammatory pain. Inflammatory pain was induced by the injection of 2 mg of carrageenan (CAR) into the right knee of male Sprague-Dawley rats (n=34). Rats were housed either singly (S-housed) or in an EE (EE-housed).

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.

Mice lacking L1 have reduced CGRP fibre in-growth into spinal transection lesions.

Repair strategies for spinal cord injury often focus on promoting regeneration of injured axons and stimulating subsequent functional recovery. Although many of these strategies have proven their merits, less is known about potential unwanted side-effects, such as sprouting of nociceptive CGRP immunoreactive axons, which may bring about pain-related behavior. Sprouting of CGRP axons into lesion sites spontaneously occurs after spinal cord injury (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.

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.