Release of nociceptin-like substances from the rat spinal cord dorsal horn

Electrophysiological studies have shown that 1-Hz repetitive transcranial magnetic stimulation (rTMS) of the primary motor area (M1) can produce a local decrease in excitability. Functional imaging data suggest that this change may be bilateral. In normal subjects, we measured motor evoked potential (MEP) amplitude at a series of stimulation intensities in the contralateral M1 before and after 15 min of active or sham rTMS at just above the MEP threshold. The slope of the curve relating MEP amplitude and stimulation intensity was decreased in the unstimulated hemisphere by active but not sham rTMS. This demonstrates that rTMS can condition cortical excitability at a distance of one or more synapses and suggest that decreased excitability to TMS is a correlate of decreased blood flow and metabolism.     

Anonymity and pseudonymity in whistleblowing to the U.S. Office of Research Integrity

This study attempts to find out whether the motor evoked potential (MEP) elicited by single pulse and slow-rate (1 Hz) repetitive transcranial magnetic stimulation (TMS) can disclose concealed subclinical impairments in the cerebral motor system of patients with minor head injury. The motor response to single pulse TMS (STMS) of the patient group was characterized by significantly higher threshold compared with that of the control group. The central motor conduction time, as well as the peripheral conduction time were normal in all patients pointing to cortical impairment. Two main patterns of MEP changes in response to repetitive TMS (RTMS) were observed in the patient group. A.--progressive decrease of the MEP amplitude throughout the stimulation session to a near complete abolition. B.--irregularity of the amplitude and the waveform of the MEP in a chaotic form. The MEP latency remained stable during the whole stimulation session. The MEP abnormalities recovered gradually over the period of a few months. The higher threshold of the motor response to STMS and the abnormal patterns of the MEP to RTMS seem to reflect transient impairment of cortical excitability or "cortical fatigue" in patients who sustained minor head injures. Further study is needed to evaluated the extent and the pathophysiological mechanisms of the central nervous system fatigue phenomenon following head injury.     

Crossed and direct effects of digital nerves stimulation on motor evoked potential: a study with magnetic brain stimulation

We studied the influence of contralateral and ipsilateral cutaneous digital nerve stimulation on motor evoked potentials (MEPs) elicited in hand muscles by transcranial magnetic stimulation (TMS). We tested the effect of different magnetic stimulus intensities on MEPs recorded from the thenar eminence (TE) muscles of the right hand while an electrical conditioning stimulus was delivered to the second finger of the same hand with an intensity four times above the sensory threshold. Amplitude decrement of conditioned MEPs as a function of magnetic stimulus intensity was observed. The lowest TMS stimulus intensity produced the largest decrease in conditioned MEPs. Moreover, we investigated the effects of ipsilateral and contralateral electrical digital stimulation on MEPs elicited in the right TE and biceps muscle using an intensity 10% above the threshold. Marked MEP inhibition in TE muscles following both ipsilateral and contralateral digital stimulation is the main finding of this study. The decrease in conditioned MEP amplitude to ipsilateral stimulation reached a level of 50% of unconditioned MEP amplitude with the circular coil and 30% with the focal coil. The amplitude of conditioned MEPs to contralateral digital stimulation showed a decrease of 60% with the circular coil and more than 50% with the focal coil. The onset of the inhibitory effect of contralateral stimulation using the focal coil occurred at a mean of 15 ms later than that of ipsilateral stimulation. No MEP inhibition was observed when recording from proximal muscles. Ipsilateral and contralateral digital stimulation had no effect on F wave at appropriate interstimulus intervals, where the main MEP suppression was noted. We stress the importance of selecting an appropriate test stimulus intensity to evaluate MEP inhibition by digital nerves stimulation. Spinal and cortical sites of sensorimotor integration are adduced to explain the direct and crossed MEP inhibition following digital nerves stimulation.     

Modulation of plasticity in human motor cortex after forearm ischemic nerve block

Deafferentation leads to cortical reorganization that may be functionally beneficial or maladaptive. Therefore, we were interested in learning whether it is possible to purposely modulate deafferentation-induced reorganization. Transient forearm deafferentation was induced by ischemic nerve block (INB) in healthy volunteers. The following five interventions were tested: INB alone; INB plus low-frequency (0.1 Hz) repetitive transcranial magnetic stimulation of the motor cortex ipsilateral to INB (INB+rTMSi); rTMSi alone; INB plus rTMS of the motor cortex contralateral to INB (INB+rTMSc); and rTMSc alone. Plastic changes in the motor cortex contralateral to deafferentation were probed with TMS, measuring motor threshold (MT), motor evoked-potential (MEP) size, and intracortical inhibition (ICI) and facilitation (ICF) to the biceps brachii muscle proximal to the level of deafferentation. INB alone induced a moderate increase in MEP size, which was significantly enhanced by INB+rTMSc but blocked by INB+rTMSi. INB alone had no effect on ICI or ICF, whereas INB+rTMSc reduced ICI and increased ICF, and conversely, INB+rTMSi deepened ICI and suppressed ICF. rTMSi and rTMSc alone were ineffective in changing any of these parameters. These findings indicate that the deafferented motor cortex becomes modifiable by inputs that are normally subthreshold for inducing changes in excitability. The deafferentation-induced plastic changes can be up-regulated by direct stimulation of the "plastic" cortex and likely via inhibitory projections down-regulated by stimulation of the opposite cortex. This modulation of cortical plasticity by noninvasive means might be used to facilitate plasticity when it is primarily beneficial or to suppress it when it is predominately maladaptive.     

Changes in the balance between motor cortical excitation and inhibition in focal, task specific dystonia

Transcranial magnetic stimulation has been used in a double pulse paradigm to investigate the excitability of intrinsic motor cortical circuits in 15 patients with focal task specific dystonia of the right hand and a group of eight age matched controls. The left hemisphere was examined in five patients; in the remainder, both hemispheres were tested. There was no significant difference in stimulation threshold between patients and controls nor between the left and right hemispheres in the patients. There was a significant decrease in early corticocortical suppression when comparing stimulation of the left hemisphere in the patients and controls at interstimulus intervals of 1-15 ms (P < 0.01). There was no difference in the amount of suppression in the right and left hemispheres of the patients. It is concluded that in focal task specific dystonia there is shift in the balance between excitation and inhibition in local circuits of the motor cortex which leads to a net decrease in the amount of short latency suppression. These changes reflect disturbed basal ganglia input to the motor cortex. Reduced excitability of cortical inhibitory circuits may be one factor which contributes to the excessive and inappropriate muscle contraction which occurs during fine motor tasks in patients with focal dystonia.     

Shortening of simple reaction time by peripheral electrical and submotor-threshold magnetic cortical stimulation

Subthreshold transcranial magnetic stimulation (TMS) over the motor cortex can shorten the simple reaction time in contralateral arm muscles if the cortical shock is given at about the same time as the reaction stimulus. The present experiments were designed to investigate whether this phenomenon is due to a specific facilitatory effect on cortical circuitry. The simple visual reaction time was shortened by 20-50 ms when subthreshold TMS was given over the contralateral motor cortex. Reaction time was reduced to the same level whether the magnetic stimulus was given over the bilateral motor cortices or over other points on the scalp (Cz, Pz). Indeed, similar effects could be seen with conventional electrical stimulation over the neck, or even when the coil was discharged (giving a click sound) near the head. We conclude that much of the effect of TMS on simple reaction time is due to intersensory facilitation, although part of it may be ascribed to a specific effect on the excitability of motor cortex.     

Mechanisms of motor dysfunction after transient MCA occlusion: persistent transmission failure in cortical synapses is a major determinant

BACKGROUND AND PURPOSE: Failure of prompt motor recovery after spontaneous recirculation or thrombolytic therapy may be due to an unsatisfactory restoration of synaptic activity within cortex and/or blockade of electrical impulses at the severely ischemic subcortical region. METHODS: Afferent, efferent, and synaptic activities were focally examined within the rat sensorimotor cortex by recording the somatosensory-evoked potential (SEP) and motor area response evoked by stimulation of premotor afferents (PmEP) intracortically and the motor-evoked potential (MEP) generated by stimulation of the forelimb area from the brain stem. The effect of ischemia on electrical activity in the cortex and on axonal conduction in the subcortical region was studied differentially by proximal or distal occlusion of the MCA. RESULTS: MEP consisted of direct and indirect waves generated by direct activation of pyramidal axons and indirect excitation of pyramidal neurons via cortical synapses, respectively. MEP, PmEP, and SEP disappeared on proximal occlusion. Following reperfusion after 1 to 3 hours of ischemia, the direct wave of MEP readily recovered but the indirect wave showed no improvement, suggesting a restored axonal conduction but impaired cortical synaptic transmission. The synaptic defect, which also caused a poor recovery in PmEP and SEP and on electrocorticogram, was persistent and detected 24 hours after 1 hour of proximal occlusion. CONCLUSIONS: Our data suggest that motor dysfunction is caused by loss of cortical excitability and blockade of motor action potentials at the subcortical level during ischemia. After brief transient ischemia, axonal conduction readily recovers; however, a persistent transmission failure at cortical synapses leads to motor dysfunction.     

Intracortical inhibition of lower limb motor-evoked potentials after paired transcranial magnetic stimulation

The aim of the present study was to determine the characteristics of intracortical inhibition in the motor cortex areas representing lower limb muscles using paired transcranial magnetic (TMS) and transcranial electrical stimulation (TES) in healthy subjects. In the first paradigm (n=8), paired magnetic stimuli were delivered through a double cone coil and motor evoked potentials (MEPs) were recorded from quadriceps (Q) and tibialis anterior (TA) muscles during relaxation. The conditioning stimulus strength was 5% of the maximum stimulator output below the threshold MEP evoked during weak voluntary contraction of TA (33+/-5%). The test stimulus (67+/-2%) was 10% of the stimulator output above the MEP threshold in the relaxed TA. Interstimulus intervals (ISIs) from 1-15 ms were examined. Conditioned TA MEPs were significantly suppressed (P<0.01) at ISIs of less than 5 ms (relative amplitude from 20-50% of the control). TA MEPs tended to be only slightly facilitated at 9-ms and 10-ms ISIs. The degree of MEP suppression was not different between right and left TA muscles despite the significant difference in size of the control responses (P<0.001). Also, conditioned MEPs were not significantly different between Q and TA. The time course of TA MEP suppression, using electrical test stimuli, was similar to that found using TMS. In the second paradigm (n=2), the suppression of TA MEPs at 2, 3, and 4 ms ISIs was examined at three conditioning intensities with the test stimulation kept constant. For the pooled 2- to 4-ms ISI data, relative amplitudes were 34+/-6%, 61+/-5%, and 98+/-9% for conditioning intensities of 0.95, 0.90, and 0.85x active threshold, respectively (P<0.01). In conclusion, the suppression of lower limb MEPs following paired TMS showed similar characteristics to the intracortical inhibition previously described for the hand motor area.     

Stereotactic transcranial magnetic stimulation: correlation with direct electrical cortical stimulation

OBJECTIVE: To evaluate stereotactic transcranial magnetic stimulation (TMS) as a tool for presurgical functional mapping of human motor cortex. METHODS: Transcranial magnetic stimulation using a frameless stereotactic system was performed in two patients with tumors near the central sulcus. TMS motor function maps were plotted on the patients' three-dimensional volumetric magnetic resonance imaging data and compared with direct electrical cortical stimulation at surgery with the patient under local anesthesia. RESULTS: Stereotactic TMS was well tolerated by both patients and was consistent with known somatotopic representation of human motor cortex. The results demonstrated a good correlation between the TMS and electrical cortical stimulation maps, with all TMS responses eliciting more than 75% of the maximum motor evoked potential falling within 1 cm of the electrical cortical stimulation site. CONCLUSIONS: Our findings indicate that stereotactic TMS is feasible and can provide accurate noninvasive localization of cortical motor function. It may prove to be a useful method for presurgical planning.     

Motor-evoked potential changes during hypoxic hypoxia

Motor-evoked potentials (MEPs) from forearm muscles were recorded in response to single-shock electrical stimulation of motor cortex of rats (n = 15) under pentobarbital anesthesia and controlled room air ventilation. In addition, electroencephalograms (EEGs) were recorded for all animals. Following baseline MEP recording in room air (21% O2), animals were subjected to graded hypoxia of either 15.75%, 10.5%, or 5.25% oxygen for 10 minutes, then followed by room air ventilation for 15 minutes. The mean baseline latency, amplitude, and duration of the evoked muscle response were 4.3 +/- 0.4 mseconds, 556 +/- 476 microV, and 9.6 +/- 2.3 mseconds, respectively. At moderate hypoxia (15.75%), the latency was 4.2 +/- 0.5 mseconds and the amplitude and the duration were 530 +/- 356 microV (n = 14), and 9.5 +/- 2.2 mseconds, (n = 14). These values did not deviate significantly from baseline (p > 0.56). Only one animal lost MEPs at the 15.75% hypoxia level. At 10.5% hypoxia, 27% of animals (n = 4) lost MEP within minutes. In the remaining animals (n = 11), there was a trend toward a prolongation of latency and a decrease of both amplitude and duration. All animals lost MEPs under extreme hypoxia (5.25%) within 2 minutes. No change was seen in the EEG recording until the level of extreme hypoxia was reached. The loss of MEPs at this level of hypoxia was concurrent with the loss of EEGs. We conclude that hypoxia effects MEPs in experimental animals.     

Study and modulation of human cortical excitability with transcranial magnetic stimulation

Transcranial magnetic stimulation (TMS) can be applied in different paradigms to obtain a measure of various aspects of cortical excitability. These different TMS paradigms provide information about different neurotransmitter systems, enhance our understanding about the pathophysiology of neuropsychiatric conditions, and in the future may be helpful as a guide for pharmacological interventions. In addition, repetitive TMS (rTMS) modulates cortical excitability beyond the duration of the rTMS trains themselves. Depending on rTMS parameters, a lasting inhibition or facilitation of cortical excitability can be induced. These effects can be demonstrated neurophysiologically or by combining rTMS with neuroimaging techniques. The effects do not remain limited to the cortical area directly targeted by rTMS, but affect a wider neural network transynaptically. Modulation of cortical excitability by rTMS may in the future be useful not only as a research tool but also as a therapeutic intervention in neurology, psychiatry, and neurorehabilitation.     

Can motor recovery in stroke patients be predicted by early transcranial magnetic stimulation?

BACKGROUND AND PURPOSE: We used transcranial magnetic stimulation of the motor cortex to evaluate the functional state of corticospinal pathways innervating the first dorsal interosseous muscle of the hand in 26 patients suffering from a first-ever ischemic stroke in the middle cerebral artery territory. METHODS: All patients had complete hand palsy and were tested within the first 24 hours from stroke onset. Patients were also tested clinically with the MRC, Rankin, and National Institutes of Health (NIH) stroke scales at day 1 and with MRC and NIH scales and the Barthel Index at day 14. Electrophysiological testing was repeated at day 14. Patients were divided into three subgroups according to the amplitude of the maximal response (motor evoked potential [MEP]) evoked at day 1. RESULTS: After 2 weeks, all 6 patients with initial MEPs > 5% maximum motor response (Mmax) showed some first dorsal interosseous muscle motor function recovery, whereas 19 of 20 patients with initially absent or small (< 5% Mmax) MEPs were left with complete hand palsy. There were strong positive correlations between MEP amplitude at day 1 and MRC and Barthel Index scores at day 14. However, measurement of central motor conduction time proved to be of little prognostic value. CONCLUSIONS: We conclude that early-performed transcranial magnetic stimulation is a valuable prognostic tool for motor recovery from stroke and that relatively preserved MEP amplitude shortly after stroke is a better prognostic factor than normal central motor conduction time.     

Mechanisms of cortical reorganization in lower-limb amputees

The human motor system undergoes reorganization after amputation, but the site of motor reorganization and the mechanisms involved are unknown. We studied the site and mechanisms of motor reorganization in 16 subjects with traumatic lower-limb amputation. Stimulation at different levels in the CNS was used to determine the site of reorganization. The mechanisms involved were evaluated by measuring the thresholds for transcranial magnetic stimulation (TMS) and by testing intracortical inhibition and facilitation. With TMS, the threshold for muscle activation on the amputated side was lower than that of the intact side, but with transcranial electrical stimulation there was no difference in motor threshold between the two sides. TMS at the maximal output of the stimulator activated a higher percentage of the motor neuron pool (%MNP) on the amputated side than on the intact side. The %MNP activated by spinal electrical stimulation was similar on the two sides. Paired TMS study showed significantly less intracortical inhibition on the amputated side. Our findings suggest that motor reorganization after lower-limb amputation occurs predominately at the cortical level. The mechanisms involved are likely to include reduction of GABAergic inhibition.     

Cortical hyperexcitability in progressive myoclonus epilepsy: a study with transcranial magnetic stimulation

In progressive myoclonus epilepsy (PME), responses to afferent input are frequently abnormal. It is unclear whether the abnormality lies at the cortical, subcortical, or segmental level. To obtain evidence for an exaggerated effect on motor cortical excitability, we used peripheral nerve and transcranial magnetic stimulation in controls and subjects with idiopathic generalized epilepsy and PME. Mean threshold intensity was higher in those with idiopathic generalized epilepsy and PME than in controls, probably as a result of anticonvulsant treatment. A long-latency response to peripheral stimulation and an exaggerated facilitatory effect of peripheral stimulation on the motor evoked potential was present in subjects with PME. Latency differences between the late responses in the upper and lower limbs provided evidence against a segmental reflex and implicated rapidly conducting fibers in the spinal cord. Both the late response and the facilitatory effect had onset latencies consistent with a transcortical pathway, suggesting an exaggerated effect of afferent input on motor cortical excitability in PME.     

Repeated tetanic stimulation in piriform cortex in vitro: epileptogenesis and pharmacology

1. Focal cortical epilepsy was investigated by applying tetanic stimulation repeatedly (100 Hz. 2 s in duration, once every 10 min, 10 episodes) to layer III association fibers in rat piriform cortex slices and recording both extracellular and intracellular responses from the endopiriform nucleus. To promote excitability, piriform slices were incubated in artificial cerebrospinal fluid (ACSF) containing 0.9 mM Mg2+ and 5 mM K+, at an initial temperature of 10-12 degrees C, which was allowed to warm passively to room temperature. 2. Responses recorded extracellularly in the endopiriform nucleus consisted of two types: weak stimulation evoked an early-occurring, small-amplitude, negatively deflecting potential; strong stimulation evoked a more complex response comprising both an early potential of maximal amplitude and a later-occurring epileptiform potential of greater amplitude and longer duration. Late-occurring epileptiform potentials were not observed in slices incubated in ACSF at room temperature. 3. Both the early potential and the late-occurring epileptiform responses were abolished by the non-N-methyl-D-aspartic acid (non-NMDA) subtype of glutamate receptor blocker, 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX; 10 microM). Application of D(-)-2-amino-5-phosphonopentanoic acid (APV; 50 microM) to block NMDA receptors was without effect on the early potential but diminished the late-occurring epileptiform potential. The late-occurring potential was unable to follow stimulation delivered at a frequency of 1 Hz. These results suggest that the early potential was generated monosynaptically and dependent solely on the activation of non-NMDA receptors, whereas the late-occurring epileptiform potential was polysynaptic in origin and possessed both a CNQX- and an APV-sensitive component. 4. Responses increased progressively in both amplitude and duration after tetanic stimulation. The threshold intensity required to evoke the complex dual-component potential was reduced by tetanic stimulation. An increase in multiunit spiking activity, indicating an increase in synchronous discharges, was also observed. A residual potential could be evoked in the presence of CNQX (10 microM) after the tetanic stimulation procedure. 5. Spontaneous discharges occurred as early as after the first episode of tetanic stimulation and persisted for the duration of the experiment. Spontaneous discharges were abolished by either CNQX or by a fourfold increase in extracellular Mg2+ concentration, the latter reversibly. APV reduced the frequency of spontaneous discharges by 38.6 +/- 9.3% (mean +/- SE). The conventional anticonvulsant drug 5,5-diphenylhydantoin, the benzodiazepine receptor agonist midazolam, and the benzodiazepine receptor antagonist flumazenil were without effect on the frequency of spontaneous discharges. Evoked responses were also unaffected by either 5,5-diphenylhydantoin or midazolam. Slices not exposed to cold ACSF, although demonstrating potentiation of evoked responses after tetanization did not produce spontaneous epileptiform discharges. 6. Intracellular recordings from endopiriform neurons revealed the cellular correlates of the extracellular responses. Weak stimulation evoked a small-amplitude depolarizing potential. Increasing the intensity of stimulation increased the amplitude of this response and also evoked a second depolarizing potential of greater amplitude occurring at variable latencies. Maximal stimulation evoked an action potential. After tetanic stimuli, responses resembling a paroxysmal depolarizing shift consisting of a depolarizing potential with superimposed multiple action potentials were evoked reliably. Passive membrane properties after repeated tetanic stimulation were not different when compared with control. 7. This novel model of in vitro focal cortical epilepsy has many features characteristic of conventional kindling including 1) progressive nature; 2) reduced threshold to evoke discharges; and 3) persist     

Molecular mechanism of cell membrane lipids

The effects of nembutal and ketamine anesthesia on motor evoked potentials (MEPs) and spinal segment reflex (H-response, F and M waves) were investigated in rats by magnetic stimulation. These potentials were generated by magnetic stimulation of the motor cortex and the spinal cord (L4-L5). After application of nembutal, MEP and H-response decreased in amplitude, eventually disappearing. The amplitudes of F and M waves increased and persisted at the increased levels during anesthesia. The latencies of F and M waves were constant before and after anesthesia. Following ketamine administration, the threshold, latency and amplitude of the magnetically induced MEPs, and M, F and H responses were not influenced systematically. The results suggested that MEPs and H-response depression and/or disappearance due to synaptic site suppression after nembutal anesthesia, and the increase and persistence of increased F and M waves amplitudes were all due to the increasing motoneuron excitability, whereas ketamine did not affect synaptic sites subjected to magnetic stimulation.     

Mechanisms underlying spinal motor neuron excitability during the cutaneous silent period in humans

The transient suppression of muscle contraction during the cutaneous silent period (CSP) could be produced either through postsynaptic inhibition of motoneurons or through presynaptic inhibition of the excitatory inputs to motoneurons that sustain voluntary contraction. We sought to delineate the mechanisms underlying the CSP in hand muscles by measuring changes in H-reflexes and motor-evoked potentials (MEPs) produced by transcranial magnetic stimulation (TMS) during the CSP in 10 healthy volunteers. H-reflexes and MEPs both measure the excitability of the motoneuron pool and activate similar subpopulations of motoneurons through different pathways. Inhibition of H-reflexes and MEPs of similar size was maximal at the midpoint of the CSP and gradually returned to baseline. The similar time course of recovery suggests that the H-reflex and MEP are affected by inhibition at a common site, most likely postsynaptic inhibition of the motoneurons.     

Rapid rate transcranial magnetic stimulation--a safety study

We assessed the safety of repeated short trains (4 stimuli) of rapid-rate transcranial magnetic stimulation (rrTMS) over the left motor cortex in 6 healthy normal subjects. rrTMS involved two separate blocks of 50 consecutive trains of 4 stimuli at a frequency of 20 Hz and an intensity of 5-10% above active motor threshold. We monitored EEG, and assessed aspects of neurological (balance, gait, two-point discrimination, blood pressure, pulse rate), cognitive (attention, memory, executive function) and motor function (speed of movement initiation and execution and manual dexterity) before and after the two blocks of rrTMS. EMG was also recorded from a number of hand, forearm and arm muscles contralateral to the site of stimulation. Two blocks of repeated rrTMS at 20 Hz and 5-10% above active motor threshold did not produce any adverse effects. Measures of neurological, cognitive and motor function showed no change following rrTMS. From the EMG recording there was evidence of increase in the amplitude of the motor evoked potentials (MEPs) recorded from the biceps in one subject during the first block of rrTMS, but this did not occur in the second block. A similar magnification of MEPs was also observed in another subject only during the second block of stimulation. When applied using parameters falling within published guidelines (Pascual-Leone et al., 1993; Pascual-Leone et al., 1994), repeated rrTMS is a relatively safe technique in healthy normal subjects. As rrTMS allows disruption of cortical function for a longer period, it has the potential of becoming a particularly useful tool for the study of cognitive function as well as sensory or motor function.     

Generation of high-frequency oscillations in local circuits of rat somatosensory cortex cultures

1. Rhythmic cortical activity was investigated with intracellular recordings in cortex-striatum-mesencephalon organotypic cultures grown for 42 +/- 3 (SE) days in vitro. 2. Electrical stimulation of supragranular layers induced a self-sustained high-frequency oscillation (HFO) in pyramidal neurons and interneurons. 3. The HFO started 197 +/- 39 ms after stimulation and had a mean duration of 1.0 +/- 0.2 s and an initial frequency of 38 +/- 2 Hz. A decrease in frequency at a rate of 11.5 +/- 2.7 Hz/s started on average 547 +/- 109 ms after the onset of the HFO. 4. During the HFO, local interneurons and pyramidal neurons synchronized their activities. The synaptic origin of the HFO was confirmed by its reversal potential at -57 +/- 4 mV. 5. These results suggest that a self-maintained HFO can be induced in local cortical circuits by excitation of supragranular layers. This HFO would facilitate synchronization between distant cortical and thalamic regions.     

Spike-wave complexes and fast components of cortically generated seizures. II. Extra- and intracellular patterns

In the previous paper we have demonstrated, by means of field potential and extracellular unit recordings, that bicuculline-induced seizures, which include spike-wave (SW) or polyspike-wave (PSW) complexes, are initiated intracortically and survive ipsilateral thalamectomy. Here, we used multisite field potential and extracellular recordings to validate the patterns of cortical SW/PSW seizures in chronically implanted, behaving cats. To investigate the cellular patterns and excitability during spontaneously occurring and electrically elicited cortical seizures, we used single and dual intracellular recordings from regular-spiking (RS) and fast-rhythmic-bursting (FRB) cortical neurons, in conjunction with field potential recordings from neocortex and related thalamic nuclei, in cats maintained under ketamine-xylazine anesthesia. 1) Invariably, the spontaneous or electrically induced seizures were initiated within the cortex of both behaving and anesthetized animals. Spontaneously occurring, compound seizures consisting of SW/PSW complexes at 2-4 Hz and fast runs at 10-15 Hz, developed without discontinuity from the slow (mainly 0.5-0.9 Hz), sleeplike, cortically generated oscillation. 2) During SW/PSW complexes, RS neurons discharged spike trains during the depth-negative component of the cortical "spike" component of field potentials and were hyperpolarized during the depth-positive field wave. The FRB neurons fired many more action potentials than RS cells during SW/PSW complexes. Averaged activities triggered by the spiky field potentials or by the steepest slope of depolarization in cortical neurons demonstrated similar relations between intracellular activities and field potentials during sleep and seizure epochs, the latter-being an exaggeration of the depolarizing and hyperpolarizing components of the slow sleep oscillation. 3) During the fast runs, RS cells were tonically depolarized and discharged single action potentials or spike doublets (usually with pronounced spike inactivation), whereas FRB cells discharged rhythmic spike bursts, time locked with the depth-negative field potentials. 4) Neuronal excitability, tested by depolarizing current pulses applied throughout the seizures and compared with pre- and postseizure epochs, showed a decreased number of evoked action potentials during both seizure components (SW/PSW complexes and fast runs), eventually leading to null responses during the postictal depression. 5) Data suggest that interconnected FRB neurons may play an important role in the initiation of cortical seizures. We discuss the similarities between the electrographic patterns described in this study and those found in different forms of clinical seizures.