How to really challenge mice cerebellar plasticity
Jan-Willem Potters used the ErasmusLadder in his thesis research to study the role of specific mutations of plasticity in the cerebellar microcircuit of mice.
Read More arrow_forwardResearchers from the University of Bochum achieved significant scientific results by making mice walk again after a complete spinal cord crush!
Deeper areas in the brain are important for movement processes, such as walking and running. Therefore, the stimulation of axonal regeneration in these areas is essential for functional recovery after spinal cord injury. Hyper- interleukin-6 (hIL-6) was transported and was able to reach the nerve cells deep in the brain stem via transneuronal delivery. This resulted in previously paralyzed animals to start to walk again after two to three weeks!
For automated evaluation of footprints and coordination of mice during walking, researchers used the CatWalk XT, which is a frequently used gait analysis system for analysis of functional recovery after spinal cord injury. CatWalk XT consists of a corridor with a glass plate through which each animal traverses from one side to another. Only where each paw touches the glass plate, the light escapes thought the surface and reflects towards the camera underneath the glass plate. This way, the actual footprints are captured from below and automatically classified by the CatWalk XT software. Later on, the software identifies the changes in position, timing of each footprint and the dimensions. The parameters researchers looked at in this study were max area of each paw touching the glass, total area, stride length, base of support, and regularity index.
Based on positive results and observation of mice walking again after a complete spinal cord crash, this gene therapeutic approach with hIL-6 is a potential strategy for reparation of a spinal cord after injury. Besides, it also opens new possibilities for further improvements of the functional outcome by combining it with other approaches. These combinations of strategies could increase axon regeneration and functional recovery after spinal cord injury. In future, hopefully, also in humans.
Jan-Willem Potters used the ErasmusLadder in his thesis research to study the role of specific mutations of plasticity in the cerebellar microcircuit of mice.
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