Whole Cell Recordings of Lumbar Motoneurons During Locomotor-Like Activity in the In Vitro Neonatal Rat Spinal Cord

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Whole Cell Recordings of Lumbar Motoneurons During Locomotor-Like Activity in the In Vitro Neonatal Rat Spinal Cord

S. Hochman and B. J. Schmidt

Department of Physiology, Faculty of Medicine, University of Manitoba, Winnipeg, Monitoba R3E 0W3, Canada

Hochman, S. and B. J. Schmidt. Whole cell recordings of lumbar motoneurons during locomotor-like activity in the invitro neonatal rat spinal cord. J. Neurophysiol. 79: 743-752,1998. Whole cell current- and voltage-clamp recordings were obtainedfrom lumbar motoneurons in the isolated neonatal rat spinal cordto characterize the behavior of motoneurons during neurochemicallyinduced locomotor-like activity. Bath application of serotonin(10-100 µM) in combination with N-methyl-D-aspartate (1-12 µM)initially produced tonic membrane depolarization (mean = 26 mV),increased input resistance, decreased rheobase, and increasedspike inactivation in response to depolarizing current pulse injections.After the initial tonic depolarization, rhythmic fluctuationsof the motoneuron membrane potential (locomotor drive potentials;LDPs) developed that were modulated phasically in associationwith ventral root discharge. The peak and trough voltage levelsof the LDP fluctuated above and below the membrane potential recordedimmediately before the onset of rhythmic activity. Similarly,firing frequency was modulated above and below prelocomotion firingrates (in those motoneurons that displayed neurochemically inducedtonic firing immediately before the onset of rhythmic activity).These observations are consistent with an alternation betweenphasic excitatory and inhibitory synaptic drives. The amplitudeof LDPs and rhythmic excitatory drive current increased with membranedepolarization from $-$ 80 to $-$ 40 mV and then decreased with furtherdepolarization, thus displaying nonlinear voltage-dependence.Faster frequency, small amplitude voltage fluctuations were observedsuperimposed on the depolarized phase of LDPs. In some motoneurons,the trajectory of these superimposed fluctuations was consistentwith a synaptic origin, whereas in other cells, the regular sinusoidalappearance of the fluctuations and the occurrence of superimposedplateau potentials were more compatible with the activation ofan intrinsic membrane property. One motoneuron displayed exclusivelyexcitatory phasic drive, and another motoneuron was characterizedby inhibitory phasic drive alone, during rhythmic activity. Thesefindings are compatible with the concept of a central patterngenerator that is capable of delivering both excitatory and inhibitorydrive to motoneurons during locomotion. The data also suggestthat the rhythmic excitatory and inhibitory outputs of the hypotheticalhalf-center model can be dissociated and operate in isolation.

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				B. J. SCHMIDT, S. HOCHMAN, and J. N. MacLEAN NMDA Receptor-mediated Oscillatory Properties: Potential Role in Rhythm Generation in the Mammalian Spinal Cord Ann. N.Y. Acad. Sci., November 16, 1998; 860(1): 189 - 202. [Abstract] [Full Text] [PDF]