Disruption of Proprioceptive Information During Electrical Stimulation of the Cutaneous Afferents

Restoration of proprioception with neurotechnology is critical to improve effectiveness of robotic neuro-prostheses. Unfortunately, after initial enthusiasm clinical results showed that unlike touch, proprioception could not be reliably induced. Here we show that concurrent activation of multiple sensory modalities may trigger unwanted sensory regulation mechanisms that disrupt proprioception. We recorded intra-spinal neural activity induced by stimulation of proprioceptive afferents from the radial nerve in three monkeys. Then, we superimposed stimulation of the radial nerve cutaneous branch and quantified its impact on spinal neural activity via population analysis. Proprioceptive pulses produced robust neural trajectories in the neural manifold that were disrupted by concurrent stimulation of cutaneous afferents. This disruption correlated with a reduction of afferent volleys and multi-unit activity both in the spinal cord and somatosensory cortex. Our results suggest that limited specificity not only impacts localization of artificial percepts, but also their nature to an extent that was never considered.

Disruption Of Proprioceptive Information During Electrical Stimulation Of The Cutaneous Afferents

Restoration of proprioception with neurotechnology is critical to improve effectiveness of robotic neuro-prostheses. Unfortunately, after initial enthusiasm clinical results showed that unlike touch, proprioception could not be reliably induced. Here we show that concurrent activation of multiple sensory modalities may trigger unwanted sensory regulation mechanisms that disrupt proprioception. We recorded intra-spinal neural activity induced by stimulation of proprioceptive afferents from the radial nerve in three monkeys. Then, we superimposed stimulation of the radial nerve cutaneous branch and quantified its impact on spinal neural activity via population analysis. Proprioceptive pulses produced robust neural trajectories in the neural manifold that were disrupted by concurrent stimulation of cutaneous afferents. This disruption correlated with a reduction of afferent volleys and multi-unit activity both in the spinal cord and somatosensory cortex. Our results suggest that limited specificity not only impacts localization of artificial percepts, but also their nature to an extent that was never considered.

Neuromechanical assessment of lidocaine test block in spastic lower limbs

The objective of this study was to quantify in spastic lower limbs the changes in reflex EMGs and in ankle stiffness after a lidocaine block of the soleus nerve to better understand physiological effects of lidocaine. Twenty patients were prospectively included and assessed before and after lidocaine block of the soleus nerve. We studied clinical and neuromechanical parameters of the triceps surae, including quantification of the maximum Hoffmann’s reflex (Hmax) and tendinous reflex (T) normalized to the maximum direct motor response (Mmax), and passive ankle stiffness assessed by sinusoidal length perturbations. All patients whatever the aetiology of spasticity were improved in clinical parameters of spasticity after the block (62% reduction of the Ashworth score, 85% reduction of stretch reflex scores, increased score on the Physicians’ Rating Scale). All patients presented a reduction of the Hmax–Mmax ratio (mean reduction of 67%) and the T–Mmax ratio (82%). Ankle stiffness was decreased by an average of 23%. Measured stiffness was correlated with the Ashworth score and the T–Mmax ratio. Relatively greater change in the T reflex than in the H reflex suggests that lidocaine block reduces hyperreflexia not only by interfering with generation of afferent volleys in the injected nerve, but also probably by altering generation of the volleys at the level of muscle spindles in the affected spastic muscles, presumably by blocking the transmission along gamma-efferent fibers.

Enhanced propriospinal excitation from hand muscles to wrist flexors during reach-to-grasp in humans

In humans, propriospinal neurons located at midcervical levels receive peripheral and corticospinal inputs and probably participate in the control of grip tasks, but their role in reaching movements, as observed in cats and primates, is still an open question. The effect of ulnar nerve stimulation on flexor carpi radialis (FCR) motor evoked potential (MEP) was tested during reaching tasks and tonic wrist flexion. Significant MEP facilitation was observed at the end of reach during reach-to-grasp but not during grasp, reach-to-point, or tonic contractions. MEP facilitation occurred at a longer interstimulus interval than expected for convergence of corticospinal and afferent volleys at motoneuron level and was not paralleled by a change in the H-reflex. These findings suggest convergence of the two volleys at propriospinal level. Ulnar-induced MEP facilitation was observed when conditioning stimuli were at 0.75 motor response threshold (MT), but not 1 MT. This favors an increased excitability of propriospinal neurons rather than depression of their feedback inhibition, as has been observed during tonic power grip tasks. It is suggested that the ulnar-induced facilitation of FCR MEP during reach may be due to descending activation of propriospinal neurons, assisting the early recruitment of large motoneurons for rapid movement. Because the feedback inhibitory control is still open, this excitation can be truncated by cutaneous inputs from the palmar side of the hand during grasp, thus assisting movement termination. It is concluded that the feedforward activation of propriospinal neurons and their feedback control may be involved in the internal model, motor planning, and online adjustments for reach-to-grasp movements in humans.

Ultrafast Frequencies: A New Challenge for Electroencephalography, with Remarks on Ultraslow Frequencies

EEG frequencies are not limited to the usual 0.5–70/sec (or 0.3–100/sec) range. In recent years, ultrafast activities between 100 and 1000/sec have been the topic of various studies with regard to physiological and paroxysmal conditions. Personal work on ultrafast frequencies in deep structures (elicited with pentylenetetrazol in rats) is mentioned in passing and will be the object of a special study. Other work focusing on the sensorimotor cortex and thalamocortical connections has proved to be seminal for ultrafast EEG research in conjunction with evoked responses (N20 response, SSEP) and experimental neurophysiological studies of afferent volleys, including those causing paroxysmal cortical responses. The well known decremental seizures with initially flat tracings require clarification with ultrafast recordings. In the physiological-neurocognitive domain, Pfurtscheller's event-related desynchronization might also benefit from the use of ultrafast recording. A plea for additional ultraslow recording (DC recording) is also being made, since paroxysmal flattening (electrodecrement) may be associated with an ultraslow negative baseline deflection. The combination of ultrafast (facilitated by digital technique) and ultraslow (technically difficult in patients, easier in experimental animals) would finally denote the frequency-wise complete EEG.

Limbic Gamma Rhythms. II. Synaptic and Intrinsic Mechanisms Underlying Spike Doublets in Oscillating Subicular Neurons

Stanford, Ian M., Roger D. Traub, and John G. R. Jefferys. Limbic gamma rhythms. II. Synaptic and intrinsic mechanisms underlying spike doublets in oscillating subicular neurons. J. Neurophysiol. 80: 162–171, 1998. Gamma oscillations were evoked in the subiculum in rat transverse hippocampal slices by tetanic stimulation (200 ms/100 Hz) of either CA1 or subiculum. Gamma oscillations in the subiculum differed from those in CA1 in containing population spike doublets as well as singlets. The present study addresses the origin of this more complex form of gamma oscillation in the subiculum. Intracellular recordings from subicular neurons revealed that 63% of them fired double action potentials on cycles of the gamma oscillation that generated population spike doublets after tetanic stimulation of either CA1 or subiculum. The remaining cells produced excitatory postsynaptic potentials (EPSPs), and occasional single spikes, on each cycle. Neurons that fired occasional single action potentials during gamma rhythms were “regular spiking” cells. They did not produce burst discharges during depolarizing steps, had minimal membrane potential sags on hyperpolarizing steps, and responded to single afferent volleys with a single action potential on an EPSP followed by a large inhibitory postsynaptic potential complex. Fast spiking cells were observed too infrequently to be studied in detail. Neurons that fired doublets during gamma rhythms were “intrinsic burst” (IB) cells. They generated bursts of action potentials on step membrane depolarizations, had significant membrane potential sags on step hyperpolarizations with an anodal break potential on return to rest, and fired multiple action potentials in response to high-intensity single afferent volleys. IB neurons did not fire action potential doublets during 1-s membrane depolarizations. Double action potentials, however, were evoked in these cells by depolarizing pulses at 40 Hz from hyperpolarized membrane potentials (−100 mV). Computer simulations suggest that the hyperpolarization between the depolarizations was essential for action potential doublets. The results in this and the previous paper suggest the following: either CA1 or subiculum alone can generate gamma oscillations gated by local networks of interneurons, oscillations in CA1 project through pyramidal cell axons to subiculum with a time lag expected from axon conduction delays, and oscillating sequences of EPSPs and intrinsic and/or synaptic hyperpolarizing potentials in IB subicular neurons generate gamma frequency spike doublets, which depend on both the intrinsic properties of these neurons and their temporally patterned synaptic input. This phenomenon could amplify gamma output from CA1 and modify its coupling to gamma oscillations in the wider limbic system.

Heptanol But Not Fluoroacetate Prevents the Propagation of Spreading Depression in Rat Hippocampal Slices

Largo, Carlota, Geoffrey C. Tombaugh, Peter G. Aitken, Oscar Herreras, and George G. Somjen. Heptanol but not fluoroacetate prevents the propagation of spreading depression in rat hippocampal slices. J. Neurophysiol. 77: 9–16, 1997. We investigated whether heptanol and other long-chain alcohols that are known to block gap junctions interfere with the generation or the propagation of spreading depression (SD). Waves of SD were triggered by micro-injection of concentrated KCl solution in stratum (s.) radiatum of CA1 of rat hippocampal tissue slices. DC-coupled recordings of extracellular potential ( V o) were made at the injection and at a second site ∼1 mm distant in st. radiatum and sometimes also in st. pyramidale. Extracellular excitatory postsynaptic potentials (fEPSPs) were evoked by stimulation of the Schaffer collateral bundle; in some experiments, antidromic population spikes were evoked by stimulation of the alveus. Bath application of 3 mM heptanol or 5 mM hexanol completely and reversibly prevented the propagation of the SD-related potential shift (Δ V o) without abolishing the Δ V o at the injection site. Octanol (1 mM) had a similar but less reliably reversible effect. fEPSPs were depressed by ∼30% by heptanol and octanol, 65% by hexanol. Antidromic population spikes were depressed by 30%. In isolated, patch-clamped CA1 pyramidal neurons, heptanol partially and reversibly depressed voltage-dependent Na currents possibly explaining the slight depression of antidromic spikes and, by acting on presynaptic action potentials, also the depression of fEPSPs. Fluoroacetate (FAc), a putative selective blocker of glial metabolism, first induced multiple spike firing in response to single afferent volleys and then severely suppressed synaptic transmission (confirming earlier reports) without depressing the antidromic population spike. FAc did not inhibit SD propagation. The effect of alkyl alcohols is compatible with the idea that the opening of normally closed neuronal gap junctions is required for SD propagation. Alternative possible explanations include interference with the lipid phase of neuron membranes. The absence of SD inhibition by FAc confirms that synaptic transmission is not necessary for the propagation of SD, and it suggests that normally functioning glial cells are not essential for SD generation or propagation.

Reduction of Ib autogenetic inhibition in motoneurons during contractions of an ankle extensor muscle in the cat

1. Triceps surae and plantaris (Pl) motoneurons were recorded intracellularly in chloralose or pentobarbital sodium (Nembutal)-anesthetized cats during unfused tetanic contractions of gastrocnemius medialis muscle (GM) produced by stimulating either a cut branch of the GM nerve or the muscle directly. 2. In alpha-motoneurons, during a series of GM twitches at 10/s, contraction-induced inhibitory potentials, probably the result of input from Golgi tendon organs (autogenetic inhibition), rapidly subsided before the end of the series. In contrast, excitatory potentials, probably the result of the activation of spindle primary endings during relaxation from contraction, persisted. 3. In gastrocnemius lateralis-soleus (GL-S) and Pl motoneurons lacking an excitatory connection with Ia afferents from GM, the sustained contraction of this muscle also elicited a declining inhibition. Rapid reduction of contraction-induced autogenetic inhibition was also observed in homonymous gamma-motoneurons. During unfused tetanic contractions lasting 0.5-4s, inhibitory potentials quickly subsided, but an abrupt increase in contractile force elicited a new series of decreasing inhibitory potentials. 4. The assumption that the inhibition induced by GM unfused tetanic contractions was due to activation of homonymous Ib afferents was supported by observations of the effects of electrical stimulation of the GM nerve. In Pl motoneurons lacking an excitatory connection with Ia afferents from GM, repetitive trains applied to the GM nerve, at a strength just above threshold for group I fibers, elicited rapidly declining inhibitory potentials similar to those produced by GM contraction. It was verified that during such stimulation, the amplitude of the group I afferent volleys did not decrease. 5. Reduction of contraction-induced Ib inhibition during sustained GM contraction was still present after a low spinalization of the preparation. As GM tendon organ discharges were verified to persist throughout prolonged contractions, the observed decline of autogenetic inhibition is likely to depend on a spinal mechanism, possibly involving presynaptic inhibition of Ib afferents and/or mutual inhibition of Ib-inhibitory interneurons.