Academic literature on the topic 'Motor evoced potentials-latency and amplitude'

Aim. To assess motor evoked potentials parameters in a complex of intraoperative neurophysiological monitoring at the time of discectomy for a herniated intervertebral disc under general anesthesia, to determine their dependence on age, sex, height.Methods. Intraoperative motor evoked potentials monitoring during microdiscectomy under inhalational anesthesia was conducted in 43 patients for the herniated disc at L4-L5 or L5-S1 levels. In all patients, the herniated disc diagnosis was confirmed by the magnetic resonance imaging data. Monitoring was performed using the «Neuro-IOM» device («Neurosoft», Russia). Latency and amplitude of muscle response for m. abductor hallucis and m. tibialis anterior were analyzed.Results.. The obtained data suggest that the motor evoked potentials allow to objectify the presence of motor disorders, which persist at the end of microdiscectomy. The data on the relationship between latency of muscles responses on the side of radiculopathy and the healthy side with patients’ age, body height and weight are obtained. The motor evoked potentials amplitude had a direct correlation with the patients’ body weight. Increase in latency of transcranial motor evoked potentials on the side of the clinical motor fall-out compared with the healthy limb was defined. Due to the expressed variability of motor evoked potentials responses amplitude under general anesthesia, significant differences for a given parameter were not obtained.Conclusion. There is relationship between latency of motor evoked potentials and patients’ age, body height and weight; an increase in the latency of transcranial motor evoked potentials on the side of the clinical motor fall-out compared with the healthy limb was revealed.

Cortical motor mapping in pre-surgical applications can be performed using motor evoked potential (MEP) amplitudes evoked with neuronavigated transcranial magnetic stimulation. The MEP latency, which is a more stable parameter than the MEP amplitude, has not so far been utilized in motor mapping. The latency, however, may provide information about the stress in damaged motor pathways, e.g. compression by tumors, which cannot be observed from the MEP amplitudes. Thus, inclusion of this parameter could add valuable information to the presently used technique of MEP amplitude mapping. In this study, the functional cortical representations of first dorsal interosseous (FDI), abductor pollicis brevis (APB) and abductor digiti minimi (ADM) muscles were mapped in both hemispheres of ten healthy righthanded volunteers. The cortical muscle representations were evaluated by the area and centre of gravity (CoG) by using MEP amplitudes and latencies. As expected, the latency and amplitude CoGs were congruent and were located in the centre of the maps but in a few subjects, instead of a single centre, several loci with short latencies were observed. In conclusion, MEP latencies may be useful in distinguishing the cortical representation areas with the most direct pathways from those pathways with prolonged latencies. However, the potential of latency mapping to identify stressed motor tract connections at the subcortical level will need to be verified in future studies with patients.

Object. The authors conducted a study to provide an objective electrophysiological assessment of descending motor pathways in rats, which may become a means for predicting outcome in spinal cord injury research. Methods. Transcranial magnetic motor evoked potentials (TMMEPs) were recorded under various conditions in awake, nonanesthetized, restrained rats. Normative data were collected to determine the reproducibility of the model and to evaluate the effect of changing the stimulus intensity on the evoked signals. In addition, an experiment was performed to determine if the TMMEPs produced were the result of auditory startle response (ASR) potentials elicited by the sound generated by the movement of the copper coil inside its casing during magnetic stimulation. Transcranial magnetic motor evoked potentials were elicited after magnetic stimulation. At 100% stimulus intensity, the mean forelimb onset latency was 4.2 ± 0.39 msec, and the amplitude was 9.16 ± 3.44 mV. The hindlimb onset latency was 6.5 ± 0.47 msec, and the amplitude was 11.47 ± 5.25 mV. As the stimulus intensity was decreased, the TMMEP onset latency increased and the response amplitude decreased. The ASR potentials were shown to have longer latencies, smaller amplitudes, and were more variable than those of the TMMEPs. Conclusions. These experiments demonstrate that TMMEPs can be recorded in awake, nonanesthetized rats. The evoked signals were easy to elicit and reproduce. This paper introduces noninvasive TMMEPs as a new technique for monitoring the physiological integrity of the rat spinal cord.

Object. The repetitive application of high-frequency anodal monopolar stimulation during surgery in or near the motor cortex allows a qualitative and quantitative evaluation of motor evoked potentials (MEPs). Using this method, motor pathways and motor function can be continuously monitored during surgery. Methods. In this prospective study, 70 patients underwent MEP monitoring during surgery performed in the central region. All procedures were performed after general anesthesia had been induced without the aid of muscle relaxants. The motor pathways were monitored during the entire surgical procedure by repetitive high-frequency anodal monopolar stimulation (frequency 400–500 Hz; train 7–10 pulses; impulse duration 0.2–0.7 msec; and stimulation intensity 16.9 ± 7.76 mA). The MEPs were continuously evaluated to assess their latency, potential duration, and amplitude. Recorded alterations in these parameters were subsequently correlated with surgical maneuvers and with postoperative neurological deterioration. The monitoring parameters (latency, potential duration, and amplitude) had a broad interindividual range of variation. A correlation between individual intraoperative changes in the potentials and surgical maneuvers or postoperative neurological deterioration was observed in eight cases. A spontaneous shift in latency greater than 15% or a sudden reduction in the amplitude of the potential greater than 80% was considered a warning criterion. In all cases in which there was an irreversible change in latency or a complete loss of potentials were observed, there was postoperative neurological deterioration. Conclusions. Improved surgical safety can be achieved using intraoperative neurophysiological monitoring procedures. Repetitive stimulation of the motor cortex proved to be a reliable method for monitoring subcortical motor pathways. Changes in MEP latency and MEP amplitude served as warning criteria during surgery and possessed prognostic value.

Background Many commonly used anesthetic agents produce a dose-dependent amplitude reduction and latency prolongation of evoked responses, which may impair diagnosis of intraoperative spinal cord injury. Dexmedetomidine is increasingly used as an adjunct for general anesthesia. Therefore, the authors tested the hypothesis that dexmedetomidine does not have a clinically important effect on somatosensory and transcranial motor evoked responses. Methods Thirty-seven patients were enrolled and underwent spinal surgery with instrumentation during desflurane and remifentanil anesthesia with dexmedetomidine as an anesthetic adjunct. Upper- and lower-extremity transcranial motor evoked potentials and somatosensory evoked potentials were recorded during four defined periods: baseline without dexmedetomidine; two periods with dexmedetomidine (0.3 and 0.6 ng/ml), in a randomly determined order; and a final period 1 h after drug discontinuation. The primary outcomes were amplitude and latency of P37/N20, and amplitude, area under the curve, and voltage threshold for transcranial motor evoked potential stimulation. Results Of the total, data from 30 patients were evaluated. Use of dexmedetomidine, as an anesthetic adjunct, did not have an effect on the latency or amplitude of sensory evoked potentials greater than was prespecified as clinically relevant, and though the authors were unable to claim equivalence on the amplitude of transcranial motor evoked responses due to variability, recordings were made throughout the study in all patients. Conclusion Use of dexmedetomidine as an anesthetic adjunct at target plasma concentrations up to 0.6 ng/ml does not change somatosensory or motor evoked potential responses during complex spine surgery by any clinically significant amount.

Background Paraplegia is a devastating complication for patients undergoing repair of thoracoabdominal aortic aneurysms. A monitor to detect spinal cord ischemia is necessary if anesthesiologists are to intervene to protect the spinal cord during aortic aneurysm clamping. Methods The medical records of 60 patients who underwent thoracoabdominal aortic aneurysm repair with regional lumbar epidural cooling with evoked potential monitoring were reviewed. The authors analyzed latency and amplitude of motor evoked potentials, somatosensory evoked potentials, and H reflexes before cooling and clamping, after cooling and before clamping, during clamping, and after release of aortic cross clamp. Results Twenty minutes after the aortic cross clamp was placed, motor evoked potentials had 88% sensitivity and 65% specificity in predicting spinal cord ischemia. The negative predictive value of motor evoked potentials at 20 min after aortic cross clamping was 96%. Conclusions Rapid loss of motor evoked potentials or H reflexes after application of the aortic cross clamp identifies a subgroup of patients who are at high risk of developing spinal cord ischemia and in whom aggressive anesthetic and surgical interventions may be justified.

Background Most techniques used to monitor spinal cord tracts are sensitive to the effects of anesthesia, particularly to volatile anesthetic agents. The aim of this prospective study was to show that evoked potentials recorded from the peripheral nerves after spinal cord stimulation, so-called neurogenic motor evoked potentials, are resistant to clinical concentrations of isoflurane or desflurane, compared with somatosensory-evoked potentials. Methods Twenty-three patients were studied during surgery to correct scoliosis. The background anesthetic consisted of a continuous infusion of propofol. Isoflurane (n = 12) or desflurane (n = 11) were then introduced to achieve 0.5 and 1.0 end-tidal minimum alveolar concentrations (MAC), both in 50% oxygen-nitrous oxide and in 100% oxygen. Somatosensory-evoked potentials were elicited and recorded using a standard method, defining cortical P40 and subcortical P29. Neurogenic motor-evoked potentials were elicited by electric stimulation of the spinal cord via needle electrodes placed by the surgeon in the rostral part of the surgical field. Responses were recorded from needle electrodes inserted in the right and left popliteal spaces close to the sciatic nerve. Stimulus intensity was adjusted to produce a supramaximal response; that is, an unchanged response in amplitude with subsequent increases in stimulus intensity. Measurements were obtained before introducing volatile agents and 20 min after obtaining a stable level of each concentration. Results Isoflurane and desflurane in both 50% oxygen-nitrous oxide and 100% oxygen were associated with a significant decrease in the amplitude and an increase in the latency of the cortical P40, whereas subcortical P29 latency did not vary significantly. Typical neurogenic motor-evoked potentials were obtained in all patients without volatile anesthetic agents, consisting of a biphasic wave, occurring 15 to 18 ms after stimulation, with an amplitude ranging from 1.3 to 4.1 microV. Latency or peak-to-peak amplitude of this wave was not significantly altered with isoflurane and desflurane, either in the presence or in the absence of nitrous oxide. Conclusions Compared with cortical somatosensory-evoked potentials, neurogenic motor-evoked potential signals are well preserved in patients undergoing surgery to correct scoliosis under general anesthesia supplemented with isoflurane or desflurane in concentrations as great as 1 MAC.

Transcranial magnetic stimulation (TMS) is a noninvasive technique to assess neural impulse conduction along the cortico-diaphragmatic pathway. The reliability of diaphragm motor-evoked potentials (MEP) induced by TMS is unknown. Notwithstanding large variability in MEP amplitude, we found good-to-excellent reproducibility of all MEP characteristics (latency, duration, amplitude, and area) both within- and between-day in healthy adult men and women. Our findings support the use of TMS and surface EMG to assess diaphragm activation in humans.

In order to determine whether short and middle latency vestibular evoked potentials (VsEPs) can be recorded in humans in response to angular acceleration stimuli in the vertical plane, a drum, head-holder, and stepper motor were designed to deliver upward acceleration impulses of 10,000°/s2 (1.8° displacement) to the human head. Forehead and mastoid electrodes recorded electrical activity that was filtered, differentially amplified, and averaged in short (12.7 milliseconds) and middle (63.5 milliseconds) latency time frames. Control recordings were used to eliminate various types of artifact. Recordings were conducted in 7 normal subjects and in 4 control patients with congenital, profound hearing loss and absence of caloric responses. Short and middle latency VsEPs with high intrasubject and intersubject consistency were recorded in normal subjects and not in control patients. The middle latency responses were larger in amplitude than the short latency responses. The effects of stimulus intensity and repetition rate on VsEP waveform, latency, and amplitude were studied. Experiments have shown that the responses are not electrical artifact, nor are they contaminated by auditory, somatosensory, or passive eye movement potentials.

OBJECTIVE Motor evoked potentials (MEPs) are a critical indicator for monitoring motor function during neurological surgery. In this study, the influence of depth of anesthesia on MEP response was assessed. METHODS Twenty-eight patients with brain tumors who underwent awake craniotomy were included in this study. From a state of deep anesthesia until the awake state, MEP amplitude and latency were measured using 5-train electrical bipolar stimulations on the same site of the precentral gyrus each minute during the surgery. The depth of anesthesia was evaluated using the bispectral index (BIS). BIS levels were classified into 7 stages: < 40, and from 40 to 100 in groups of 10 each. MEP amplitude and latency of each stage were compared. The deviation of the MEP measurements, which was defined as a fluctuation from the average in every BIS stage, was also considered. RESULTS A total of 865 MEP waves in 28 cases were evaluated in this study. MEP amplitude was increased and latency was decreased in accordance with the increases in BIS level. The average MEP amplitudes in the > 90 BIS level was approximately 10 times higher than those in the < 40 BIS level. Furthermore, the average MEP latencies in the > 90 BIS level were 1.5–3.1 msec shorter than those in the < 60 BIS level. The deviation of measured MEP amplitudes in the > 90 BIS level was significantly stabilized in comparison with that in the < 60 BIS level. CONCLUSIONS MEP amplitude and latency were closely correlated with depth of anesthesia. In addition, the deviation in MEP amplitude was also correlated with depth of anesthesia, which was smaller during awake surgery (high BIS level) than during deep anesthesia. Therefore, MEP measurement would be more reliable in the awake state than under deep anesthesia.

H TMS διακρίνεται έναντι άλλων εργαλείων απεικόνισης λόγω της ικανότητάς της να ενεργοποιεί νευρώνες σε επιλεγμένες φλοιϊκές περιοχές. Η παρούσα μελέτη προσπαθεί να διερευνήσει το νευροφυσιολογικό προφίλ της μυικής προκλητής απάντησης διάμεσου διακρανιακής μαγνητικής διέγερσης (TMS) σε ένα σεβαστό αριθμό ασθενών με σχιζοφρένεια υπό φαρμακευτική αγωγή. Σε 51 ασθενείς υπό φαρμακευτική αγωγή και διάγνωση σχιζοφρένειας και 51 υγιείς μάρτυρες απόλυτα σύμφωνους ως προς το φύλο, το ύψος και την ηλικία με τους ασθενείς που συμμετείχαν καταγράφηκαν κινητικά προκλητά δυναμικά (ΜΕΡ) από τον απαγωγό μυ του αντίχειρα μετά τον ερεθισμό του αντίπλευρου κινητικού φλοιού με ένα κυκλικό πηνίο. Μετρήθηκαν: w RMTh (resting motor threshold): Ο ουδός κινητικής ηρεμίας w SI-max (stimulus intensity for maximum MEP): Η ένταση ερεθίσματος που χρειάζεται για την καταγραφή του μέγιστου κινητικού προκλητού δυναμικού w Post-stimulus silent period: Την ανερέθιστη περίοδο που επάγεται μετά από ένα ερέθισμα που προκαλεί συγκεκριμένη μυική δραστηριότητα w MEP Latency: Λανθάνον χρόνος των κινητικών προκλητών δυναμικών MEP amplitude: Το εύρος των κινητικών προκλητών δυναμικών. Τα βασικά ευρήματα είναι η σαφώς υψηλότερη από τις φυσιολογικές τιμές, τιμή των RMTh και SI-max και τα δύο, ενδείξεις νευρωνικής ευοδωτικής δραστηριότητας στους ασθενείς σε σύγκριση με τους μάρτυρες. Ειδικότερα στην ομάδα των ασθενών που βρίσκονται σε θεραπεία με ζιπρασιδόνη παρουσιάστηκε το υψηλότερο SI-max και στα δύο ημισφαίρια και το υψηλότερο RMTh στο αριστερό ημισφαίριο. Οι ασθενείς στην ομάδα που ελάμβαναν ολανζαπίνη παρουσίασαν το χαμηλότερο RMTh για το αριστερό ημισφαίριο και αυτοί σε θεραπεία με κουατιεπίινη παρουσίασαν τιμές ανάμεσα στις τιμές των δύο προηγούμενων ομάδων. Όταν χρησιμοποιήθηκε ένταση ερεθίσματος (SI) σχετικής τιμής με το RMTh, η ανερέθιστη περίοδος βρέθηκε μεγαλύτερη στους ασθενείς από ότι στους μάρτυρες ενώ δεν παρατηρήθηκε καμία διαφορά ανάμεσα στις δύο μεγάλες ομάδες ασθενών και μαρτύρων όταν χρησιμοποιήθηκε σταθερής έντασης ερέθισμα (SI). Συμπεράναμε, ότι οι αλλαγές στις παραμέτρους που μετρήθηκαν, μπορούν να εξηγηθούν από βασικές μεταβολές της ενδοφλοιϊκής ευοδωτικής κινητικής δραστηριότητας που ακολουθείται από διαφοροποιήσεις της φλοιϊκής αναστολής, οι οποίες μπορούν να αποδοθούν είτε στην σχιζοφρένεια είτε στην φαρμακευτική αγωγή ή στην αλληλεπίδρασή τους.
Trancranial magnetic stimulation (TMS) provides a non-invasive means for exploring physiological alterations of central motor control in a variety of neuropsychiatric diseases. The present study aimed to assess the neurophysiological profile of muscle evoked responses to a standard TMS procedure in a considerable number of medicated patients with schizophrenia. Fifty-one patients with diagnosis of schizophrenia and 51 sex- and age-matched healthy subjects were enrolled in the study. Motor evoked potential (MEP) from abductor pollicis brevis muscle was elicited by stimulation of the contralateral motor cortex with a circular coil. The hot-spot was marked. Were measured: ¨ the resting motor threshold (RMTh), ¨ the stimulus intensity for maximum MEP (SI-max), ¨ the post-stimulus silent period of voluntary muscle activity and ¨ MEP latency and amplitude. The main findings were the significantly higher than normal values for RMTh and SI-max, which are both indices of neuronal excitability. In particular, patients who had ziprasidone in their therapeutic regimen demonstrated the highest SI-max for both hemispheres and highest RMTh for left hemisphere, patients receiving olanzapine demonstrated the lowest RMTh for left hemisphere and those on quetiapine showed intermediate values. Silent period was longer in the patients as opposed to controls when a RMTh-related SI was used and did not differ between the two groups when a fixed SI was used. We concluded that the observed TMS changes could be interpreted by primary alterations of intracortical motor excitability followed by defects of cortical inhibition and should be attributed to schizophrenia, antipsychotic medication or the interaction between both factors.

The variable amplitude of motor cortex is a striking aspect of the muscle response to transcranial magnetic stimulation. It is easy to produce large motor-evoked potentials (MEPs) in some healthy subjects, while others' cortico-muscular pathways seem barely excitable, even by the strongest available stimuli. MEP amplitude and other measures also vary widely within individuals over time. The factors of these differences among and within individuals are age, gross anatomy of the individuals, genetic factors, and physiological differences associated with behavioural and other traits such as personality, conditions like migraine. The MEP varies over time within individuals at rest under laboratory conditions. These variations can be short term or long term. Differences among neurologically normal individuals have important implications for research using TMS. These differences open doors to new fields of study to neurophysiologists in the treatment and etiology of brain disease.

This chapter discusses general aspects of evoked and event-related responses in MEG and EEG recordings. The earliest evoked responses occur within milliseconds from stimulus onset (for example in the auditory brainstem) and cortical responses continue for many hundreds of milliseconds poststimulus. Sustained potentials and fields can be recorded during long-duration stimuli, or during tasks involving motor planning, attention, and other cognitive operations. Interstimulus interval and physical stimulus characteristics can dramatically affect amplitudes and latencies of evoked responses. A distinction is made between transient and steady-state responses. Various nomenclatures adopted in literature for different types of evoked responses are discussed and recommendations are given for more consistency in nomenclature.