CELLULAR FUNCTION OF THE IA-MOTONEURON CIRCUIT FOLLOWING PERIPHERAL NERVE REGENERATION

Bullinger, Katie Leigh. Ph.D., Biomedical Sciences Ph.D. Program, Wright State University, 2009. Cellular function of the regenerated Ia-motoneuron circuit following peripheral nerve injury. Successful regeneration of a severed peripheral nerve is insufficient to restore the stretch reflex. This deficit occurs despite successful muscle reinnervation and functional restoration of the circuit components. For example, Ia afferents encode muscle stretch, Ia-motoneuron synapses reform to the extent of restoring low frequency transmission, and activation of motoneurons results in muscle force output. However, when recording intracellularly from reinnervated rat motoneurons during ramp hold and release muscle stretch, no excitatory synaptic potentials are detected in 2/3 motoneurons (Haftel et al., 2005), a clear sign that the synapses connecting Ia afferents with motoneurons are physiologically disrupted. This thesis examines extensively the cellular properties of the presynaptic Ia afferent, postsynaptic motoneuron, and the function of their central synapse to identify where along this circuit deficits are occurring. Using intraaxonal recordings from regenerated muscle afferents, we found that not only were regenerated afferents capable of encoding stretch information, but they were, by many parameters, indistinguishable from normal. In addition, intracellular recordings from regenerated motoneurons indicated that intrinsic motoneuron properties (rheobase, input resistance, and afterhyperpolarization potential) returned to control levels with reinnervation. To