Reduction in postsynaptic inhibition during maintained electrical stimulation of different nerves in the cat hindlimb

Heckman, C. J.; Miller, J. F.; Munson, Meghan; Paul, Kush; Rymer, W. Z.

doi:10.1152/jn.1994.71.6.2281

Cited by 19 publications

(21 citation statements)

References 0 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…6 and 7). Long-duration cutaneous-evoked EPSPs are not seen in intact spinal cords of unanesthetized animals (Crenna et al 1982;Heckman et al 1994), and consistent with this, in normal awake rats, longlasting reflexes cannot be evoked even with a conditioning stimulation that evokes EMG (Fig. 7).…”

Section: Acute Release Of Descending Inhibition Of Low-threshold Epspsupporting

confidence: 70%

“…In normal and acute spinal rats, caudal trunk stimulation does not by itself evoke a longlasting reflex, although in acute spinal rats, a weak tonic contraction can be evoked by strong C-fiber stimulation. Thus the long-lasting reflexes in chronic spinal rats are more excitable and lower threshold, as in other animal models of spasticity (Taylor et al 1999), and similar to the exaggerated flexor withdrawal reflexes seen in spastic humans after chronic spinal cord injury (Hornby et al 2003;Kuhn and Macht 1948;Roby-Brami and Bussel 1987).…”

Section: Discussionmentioning

confidence: 65%

“…Furthermore, the characteristics of this reflex are consistent with triggered spasms in the tail. That is, the high reflex excitability (from rest), involvement of both low-and high-threshold afferents, and enhancement with repetition are similar to the characteristics of triggered spasms Hornby et al 2003;Kuhn and Macht 1948).…”

Section: Discussionmentioning

confidence: 75%

“…However, these EPSPs do not initially evoke large spastic reflexes because of the lack of motoneuron excitability (Bennett et al 2001c;Li et al 2004a). For example, in acute spinal rats and cats, there are unusually long polysynaptic EPSPs (ϳ200 -500 ms) in response to a low-threshold cutaneous stimulation pulse (Baker and Chandler 1987;Crenna et al 1982;Li et al 2004a) that are not seen in spinal cord intact preparations (Crenna et al 1982;Heckman et al 1994). However, these EPSPs do not trigger spasms immediately after injury.…”

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Spastic Long-Lasting Reflexes in the Awake Rat After Sacral Spinal Cord Injury

Bennett

Sanelli

Cooke

et al. 2004

Journal of Neurophysiology

147

116

View full text Add to dashboard Cite

Spastic long-lasting reflexes in the awake rat after sacral spinal cord injury. J Neurophysiol 91: 2247-2258, 2004; 10.1152/jn.00946.2003. Following chronic sacral spinal cord transection in rats the affected tail muscles exhibit marked spasticity, with characteristic long-lasting tail spasms evoked by mild stimulation. The purpose of the present paper was to characterize the long-lasting reflex seen in tail muscles in response to electrical stimulation of the tail nerves in the awake spastic rat, including its development with time and relation to spasticity. Before and after sacral spinal transection, surface electrodes were placed on the tail for electrical stimulation of the caudal nerve trunk (mixed nerve) and for recording EMG from segmental tail muscles. In normal and acute spinal rats caudal nerve trunk stimulation evoked little or no EMG reflex. By 2 wk after injury, the same stimulation evoked long-lasting reflexes that were 1) very low threshold, 2) evoked from rest without prior EMG activity, 3) of polysynaptic latency with Ͼ6 ms central delay, 4) about 2 s long, and 5) enhanced by repeated stimulation (windup). These reflexes produced powerful whole tail contractions (spasms) and developed gradually over the weeks after the injury (Յ52 wk tested), in close parallel to the development of spasticity. Pure low-threshold cutaneous stimulation, from electrical stimulation of the tip of the tail, also evoked long-lasting spastic reflexes, not seen in acute spinal or normal rats. In acute spinal rats a strong C-fiber stimulation of the tip of the tail (20 ϫ T) could evoke a weak EMG response lasting about 1 s. Interestingly, when this C-fiber stimulation was used as a conditioning stimulation to depolarize the motoneuron pool in acute spinal rats, a subsequent low-threshold stimulation of the caudal nerve trunk evoked a 300 -500 ms long reflex, similar to the onset of the longlasting reflex in chronic spinal rats. A similar conditioned reflex was not seen in normal rats. Thus there is an unusually long low-threshold polysynaptic input to the motoneurons (pEPSP) that is normally inhibited by descending control. This pEPSP is released from inhibition immediately after injury but does not produce a long-lasting reflex because of a lack of motoneuron excitability. With chronic injury the motoneuron excitability is increased markedly, and the pEPSP then triggers sustained motoneuron discharges associated with long-lasting reflexes and muscle spasms.

show abstract

Section: Acute Release Of Descending Inhibition Of Low-threshold Epspsupporting

confidence: 70%

Section: Discussionmentioning

confidence: 65%

Section: Discussionmentioning

confidence: 75%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Spastic Long-Lasting Reflexes in the Awake Rat After Sacral Spinal Cord Injury

Bennett

Sanelli

Cooke

et al. 2004

Journal of Neurophysiology

147

116

View full text Add to dashboard Cite

show abstract

“…All procedures were approved by the animal care committee at Northwestern University. Full details are available in previous publications (Heckman et al, 1994;Lee and Heckman, 1998a). Briefly, all surgical preparations of the spinal cord and hindlimb were done under deep gaseous anesthesia (1.5-3.0% isoflurane in a 3:1 mixture of O 2 and N 2 O).…”

mentioning

confidence: 99%

Adjustable Amplification of Synaptic Input in the Dendrites of Spinal Motoneurons In Vivo

2000

Self Cite

View full text Add to dashboard Cite

The impact of neuromodulators on active dendritic conductances was investigated by the use of intracellular recording techniques in spinal motoneurons in the adult cat. The well known lack of voltage control of dendritic regions during voltage clamp applied at the soma was used to estimate dendritic amplification of a steady monosynaptic input generated by muscle spindle Ia afferents. In preparations deeply anesthetized with pentobarbital, Ia current either decreased with depolarization or underwent a modest increase at membrane potentials above Ϫ40 mV. In unanesthetized decerebrate preparations (which have tonic activity in axons originating in the brainstem and releasing serotonin or norepinephrine), active dendritic currents caused strong amplification of Ia input. In the range of Ϫ50 to Ϫ40 mV, peak Ia current was over four times as large as that in the pentobarbital-anesthetized preparations. Exogenous administration of a noradrenergic agonist in addition to the tonic activity further enhanced amplification (sixfold increase). Amplification was not seen in preparations with spinal transections. Overall, the dendritic amplification with moderate or strong neuromodulatory drive was estimated to be large enough to allow the motoneurons innervating slow muscle fibers to be driven to their maximum force levels by remarkably small synaptic inputs. In these cells, the main role of synaptic input may be to control the activation of a highly excitable dendritic tree. The neuromodulatory control of synaptic amplification provides motor commands with the potential to adjust the level of amplification to suit the demands of different motor tasks. Key words: motoneuron; spinal cord; neuromodulation; electrophysiology; serotonin; norepinephrine; plateau potential; bistable; dendritic amplificationVoltage-sensitive conductances within the dendritic tree of the postsynaptic neuron play a major role in synaptic integration (Johnston et al., 1996;Yuste and Tank, 1996). Many types of voltage-sensitive conductances are under the control of neuromodulatory inputs acting via second messenger systems. Thus, the potential exists for the neuromodulatory inputs to control synaptic integration by altering the activation of voltage-sensitive currents in the dendrites of neurons.The spinal motoneuron is subject to potent neuromodulatory control by axons that originate in the brainstem and release either serotonin (5-HT) or norepinephrine (NE) (Hounsgaard et al., 1988;Takahashi and Berger, 1990;Wang and Dun, 1990;White et al., 1991;Binder et al., 1996). In the presence of these neuromodulators, motoneurons exhibit a persistent inward current (Hounsgaard and Kiehn, 1989;Svirskis and Hounsgaard, 1998;Lee and Heckman, 1999a). The composition of this current may vary in different types of motoneurons (Hounsgaard and Kiehn, 1989;Hsiao and Chandler, 1995;Zhang et al., 1995;Lee and Heckman, 1998b). In spinal motoneurons in the adult cat, the total persistent inward current (I PIC ) is exceedingly large Heckman, 1998a, 1999a). Activation of I...

show abstract

Effect of reversible dorsal cold block on the persistence of inhibition generated by spinal reflexes

et al. 1995

View full text Add to dashboard Cite

The effects of bilateral focal cooling of dorsolateral thoracic spinal cord on segmental reflex pathways to the triceps surae muscles were assessed in decerebrate cats from the reflex forces produced by single shocks or trains of electrical stimuli applied to the ipsilateral caudal cutaneous sural and the contralateral tibial nerves. The validity of the dorsal cold block technique as a substitute for acute surgical dorsal hemisection was established by showing that focal cooling reliably reproduced the stretch-induced "clasp knife" inhibition of triceps surae reflexive force seen following dorsal hemisection. Under control (warm) conditions, the inhibitory components of electrically evoked ipsilateral sural and contralateral tibial reflexes faded rapidly during sustained trains, with a resultant production of large-amplitude reflex force as measured from either the entire triceps surae or from the medial gastrocnemius muscle alone. Dorsal cold block greatly reduced the amplitude of reflexive force evoked by sustained electrical stimulation of either nerve. Indeed, the cold block completely reversed the sign of train-evoked reflexes to a net inhibition of reflex force output in one-half of the sural and one-half of the contralateral tibial stimulation experiments. Peak transient forces evoked by single shocks to the sural or contralateral tibial nerves were also sometimes reduced, but this result was more variable than for prolonged nerve stimulation. The persistence of activity in segmental inhibitory pathways during dorsal cold block, as indicated by instances of reflex sign reversal, suggests that descending bulbospinal pathways traversing the dorsolateral funiculi may be responsible for "fading" of segmental inhibitory reflex components in decerebrate cats with intact spinal cords during sustained afferent input. The possibility that the enhanced magnitude and duration of segmental inhibition during cold block will increase the likelihood of disruption of the size principle for motoneuron recruitment is also discussed.

show abstract

Reduction in postsynaptic inhibition during maintained electrical stimulation of different nerves in the cat hindlimb

Cited by 19 publications

References 0 publications

Spastic Long-Lasting Reflexes in the Awake Rat After Sacral Spinal Cord Injury

Spastic Long-Lasting Reflexes in the Awake Rat After Sacral Spinal Cord Injury

Adjustable Amplification of Synaptic Input in the Dendrites of Spinal Motoneurons In Vivo

Effect of reversible dorsal cold block on the persistence of inhibition generated by spinal reflexes

Contact Info

Product

Resources

About