Effect of noise masking on the brain-stem and middle-latency auditory evoked potentials: central and peripheral components

Brain-stem (BAEP) and middle-latency (MLAEP) auditory evoked potentials were recorded in zero noise and in 3 levels of continuous ipsilateral broadband noise. New information is presented on the effects of noise on BAEP wave I. Latency of wave I was not changed by increasing noise, but wave V latency linearly increased. Amplitude of waves I and V decreased non-linearly. The amplitude decrease was equivalent for both waves and occurred only at the higher noise levels. The dissociation of latency effects for waves I and V indicates a central component for the effect of noise on latency. The parallel amplitude change for waves I and V suggests a largely peripheral component. The MLAEP Pa latency also increased with increasing noise further supporting a central mechanism.     

Short- and middle-latency auditory evoked potentials in abstinent chronic alcoholics: preliminary findings.

Short- and middle-latency auditory evoked potentials (BAEPs and MAEPs) were studied in 15 chronic alcoholic patients after 1 month's abstinence and compared with those of 15 healthy controls, matching the patients pairwise for sex and age. Most of the parameters studied varied more within the alcoholic group than within the control group. The BAEP results agree with previous reports; in the alcoholic group, BAEP peak V was significantly delayed and the inter-peak intervals, III-V and I-V, were lengthened. The latencies of the MAEP components Na and Pa, on the other hand, were significantly shortened. These findings suggest that chronic abusive consumption of alcohol may bring about structural and/or neurochemical alterations at various levels in the auditory pathway.     

Human auditory evoked potentials: Reliability of intensity functions

This investigation assessed the relative reliability of the human auditory evoked potential (AEP) amplitude-intensity and latency-intensity functions. Averaged AEP waveforms to 10 levels of stimulus magnitude were obtained from bipolar recordings. Variability and slope of group functions were constant, as indicated by nonsignificant differences in day-to-day residual variances and intersession regression coefficients. Periodic change in amplitude or latency thus indicated a shift of the entire function. Individual N1–P2 amplitude-intensity functions Were similarly reliable, while individual P2–N2 amplitude and latency measures tended to be more variable. No significant differences were obtained across sessions for regression coefficients based on either group or individual data. Intersession AEP amplitude and latency apparently varied systematically with stimulus intensity.     

Human auditory evoked potentials recorded using maximum length sequences.

A maximum length sequence (MLS) is a specially constructed pseudorandom binary sequence that can be used to control the presentation of sensory stimuli. The evoked potentials to such a sequence of stimuli can be analyzed to give the response to one stimulus in the sequence. This procedure allows auditory evoked potentials to be recorded at stimulus rates that would cause a confusing overlap of responses with regular averaging. The MLS technique can be used with auditory evoked potentials at all latencies although it is most effective for the brain-stem and middle-latency responses. By demonstrating different refractory periods for different parts of the response, the technique may help delineate the component structure of the evoked potential. As well, an MLS analysis can disentangle the auditory brain-stem response from overlapping middle-latency responses during evoked potential audiometry.     

Human slow auditory evoked potentials during natural and drug-induced sleep.

The alterations of human slow auditory evoked potential (SAEP) were studied during the sleep-waking cycle. Simultaneous recording of the mean square and standard error curves proved helpful in obtaining more information on the EEG samples used for averaging. In both natural and drug-induced sleep the earlier SAEP components decreased or disappeared, while the later components increased. A significant lengthening of all SAEP peak latencies was found in all sleep stages during tone-burst stimulation. With click stimulation the peak latencies of most SAEP components remained constant. Due to the variability of individual SAEPs, the interpretation of averaged SAEPs was commonly more difficult in sleep as compared with wakefulness. The alterations of SAEPs during sleep are considered from the point of view of their exrralemniscal origin. The hypothesis is put forward that the activating (desynchronizing) and depressing (synchronizing) systems participate in the generation of the earlier and later SAEP components, respectively.     

Human auditory steady-state evoked potentials during selective attention

The human auditory steady-state evoked potentials were examined during several different tasks requiring attention. Both Fourier analysis and signal averaging were used to measure the responses at stimulus rates between 37 and 41/sec. There was no effect of attention on the amplitude and phase of the steady-state evoked potentials when subjects either counted successive increments in stimulus intensity or read a book. In a dichotic listening task, there were clear changes in the late transient evoked potentials with selective attention but no changes in the steady-state responses. Furthermore, the steady-state potentials recorded during reading were not different from those obtained while the subjects were selectively attending to the auditory stimuli in one ear. There is therefore no evidence that the auditory steady-state responses are affected by attention.     

Effects of aging and sex on middle-latency somatosensory evoked potentials: normative data.

OBJECTIVES: To investigate the exact relationship of middle-latency somatosensory evoked potential (SEP) components (in particular the third negative component N60) to age and sex in a normal population. Middle-latency SEPs are believed to show a considerable inter-individual variability and there is little published information on normative data of these components. METHODS: Eighty-three healthy subjects aged 13-80 years were investigated using a standard SEP procedure. RESULTS: Both latency and amplitude of N60 increased substantially with age. Least square polynomial regression analysis showed that a quadratic curve best described its relationship (r2=0.67 for the latency, r2=0.18 for the amplitude). Data did not differ significantly with reference to sex or side of stimulation. CONCLUSIONS: The use of polynomial regression analysis for the determination of the normal range of N60 latencies and amplitudes has to be highly recommended. It might improve the accuracy with which abnormal results are detected in studies investigating the value of middle-latency SEPs in various diseases.     

Dissociation of formal and temporal predictability in early auditory evoked potentials

Perceived regularity among events in the environment allows predictions regarding the “when” and the “what” dimensions of future events. In this context, one crucial question concerns the impact and the potentially optimizing effect, of regular temporal structure on the processing of “what”, or formal, information. The current study addresses this issue by investigating whether temporal and formal structure interact during early stages of sensory processing, and by relating the respective findings to the concept of a predictive bias in brain function. Analyses were performed on two components of the auditory event-related-potential of the electroencephalogram, namely the P50 and the N100. Oddball sequences consisting of frequent standard and infrequent deviant sinusoidal tones were presented with either regular or irregular temporal structure in pre-attentive and attentive experimental settings (Schwartze, Rothermich, Schmidt-Kassow, & Kotz, 2011). Temporal regularity effects on pre-attentive and attentive processing of deviance. Biological Psychology, 87, 146–151). The results confirm that the P50 and the N100 amplitudes reliably encode formal and temporal predictability. Similar patterns of results obtained with pre-attentive and attentive task instructions, as well as the absence of a significant interaction of formal and temporal structure suggest that the P50 response may be interpreted as an automatic marker of predictability, whereas the N100 may represent a more complex marker, in which formal and temporal structure start interacting as a function of attention.     

Brainstem auditory evoked potentials and middle latency auditory evoked potentials in young children

Measurements of brainstem auditory evoked potentials (BAEP) and middle latency auditory evoked potentials (MLAEP) are readily available neurophysiologic assessments. The generators for BAEP are believed to involve the structures of cochlear nerve, cochlear nucleus, superior olive complex, dorsal and rostral pons, and lateral lemniscus. The generators for MLAEP are assumed to be located in the subcortical area and auditory cortex. BAEP are commonly used in evaluating children with autistic and hearing disorders. However, measurement of MLAEP is rarely performed in young children. To explore the feasibility of this procedure in young children, we retrospectively reviewed our neurophysiology databank and charts for a 3-year period to identify subjects who had both BAEP and MLAEP performed. Subjects with known or identifiable central nervous system abnormalities from the history, neurologic examination and neuroimaging studies were excluded. This cohort of 93 children up to 3 years of age was divided into 10 groups based on the age at testing (upper limits of: 1 week; 1, 2, 4, 6, 8, 10 and 12 months; 2 years; and 3 years of age). Evolution of peak latency, interpeak latency and amplitude of waveforms in BAEP and MLAEP were demonstrated. We concluded that measurement of BAEP and MLAEP is feasible in children, as early as the first few months of life. The combination of both MLAEP and BAEP may increase the diagnostic sensitivity of neurophysiologic assessment of the integrity or functional status of both the peripheral (acoustic nerve) and the central (brainstem, subcortical and cortical) auditory conduction systems in young children with developmental speech and language disorders.     

The effects of anterior temporal lobectomy (ATL) on the middle-latency auditory evoked potential (MLAEP).

The anatomical and physiological origins of the middle-latency auditory evoked potential (MLAEP) are not well understood. The present investigation was conducted to determine whether the MLAEP derives its origins in part from the anterior temporal lobe. Twelve subjects with intractable seizures were evaluated with the MLAEP pre and post excision of the anterior-mesial temporal lobe (ATL) unilaterally. In our study, component Pa latency was unaffected by the ATL. The Na latency and the Na/Pa amplitude showed significant increases after ATL. The results we interpreted as being consistent with currently held beliefs regarding the origins of Pa. The changes in Na latency and Na/Pa amplitude are hypothesized to reflect a loss of the modulating influence of the cortex on the subcortical generators of Na.     

Brain-stem auditory evoked potentials and brain death.

BAEP records were obtained from 30 brain-dead patients. Three BAEP patterns were observed: (1) no identifiable waves (73.34%), (2) an isolated bilateral wave I (16.66%), and (3) an isolated unilateral wave I (10%). When wave I was present, it was always significantly delayed. Significant augmentation of wave I amplitude was present bilaterally in one case and unilaterally in another. On the other hand, in serial records from 3 cases wave I latency tended to increase progressively until this component disappeared. During the same period, wave I amplitude fluctuations were observed. A significant negative correlation was found for wave I latency with heart rate and body temperature in 1 case. Two facts might explain the progressive delay and disappearance of wave I in brain-dead patients: a progressive hypoxic-ischaemic dysfunction of the cochlea and the eighth nerve plus hypothermia, often present in brain-dead patients. Then the incidence of wave I preservation reported by different authors in single BAEP records from brain-dead patients might depend on the moment at which the evoked potential study was done in relation to the onset of the clinical state. It is suggested that, although BAEPs provide an objective electrophysiological assessment of brain-stem function, essential for BD diagnosis, this technique could be of no value for this purpose when used in isolation.     

Late auditory evoked potentials asymmetry revisited.

OBJECTIVE: To investigate brain asymmetries of the auditory evoked potential (AEP) N100, T-complex, and P200 in response to monaural stimulation. METHODS: Electroencephalographic (EEG) recordings from 68 channels were used to record auditory cortex responses to monaural stimulation from normal hearing participants (N=16). White-noise stimuli and 1000Hz tones were repeatedly presented to either the left or right ear. Source localization of the AEP N100 response was carried out with two symmetric regional sources placed into left and right auditory cortex. Regional source waveform amplitude and latency asymmetries were analyzed for tangential and radial activity explaining the N100, T-complex and P200 AEP components. RESULTS: Regional source waveform analysis showed that early tangential activity in the N100 latency range exhibited larger contralateral amplitudes and shorter latencies for both tone and noise monaural stimuli. Lateralized activity was significantly greater when tones or noise was presented to the left compared to the right ear (p<.001). The ear difference in the degree of lateralization arose due to hemispheric asymmetry. Significantly more tangential activity in the N100 latency range was recorded in the right compared to the left hemisphere in response to stimulation by either tones or noise (p<.001). Neither the radial activity modelling the T-complex, nor activity modelling the P200, showed robust ear or hemisphere differences. CONCLUSIONS: Regional source waveform analysis revealed that the extent of auditory evoked potential asymmetries depends on the ear and hemisphere examined. These findings have implications for future studies utilizing AEP asymmetries to examine normal auditory function or experience-related changes in the auditory cortex. SIGNIFICANCE: The right compared to the left auditory cortex may be more involved in processing monaurally presented tone and noise stimuli.     

Cue-induced auditory evoked potentials in alcoholism.

OBJECTIVE: Conditioning processes may convert neutral stimuli to drug-associated stimuli and create an implicit drug memory. Previous studies showed specific psychophysiological reactions to alcohol-associated stimuli differentiating alcohol-dependent subjects from healthy controls. This was shown in evoked potentials using visual and olfactory alcohol-related stimuli. METHODS: Our study examined the effects of complex alcohol-associated sounds in comparison to complex neutral sounds on electrophysiological event-related potentials and the self-report of craving. We assessed 10 detoxified alcoholics and 10 healthy controls in a cue-reactivity paradigm. RESULTS: Detoxified alcoholics demonstrated significantly higher alcohol stimulus-induced late P300 and late positive complexes. Subjective baseline craving and stimulus-induced craving only differed significantly between groups in terms of the craving dimension "relief of withdrawal symptoms". CONCLUSIONS: The results show that auditory stimuli attach importance to stimulus-induced craving in alcoholics. Therapeutic consequences will be discussed. SIGNIFICANCE: The study examined for the first time the effects of alcohol-associated auditory stimuli on alcohol craving and identifies learning processes as underlying neural mechanisms which support the assumption of an implicit addiction memory in alcoholics.     

Late slow wave components of auditory evoked potentials: Their cognitive significance and interaction

Late slow waves following auditory stimulation were studied in 20 normal subjects. The experiment was designed to determine whether there are one or many late slow waves, to investigate their relationship to the making of decisions and motor responses, and to examine their relationship to other slow wave phenomena such as the contingent negative variation (CNV).Using multi-channel averaging and subjecting the resulting wave forms to a principal components analysis revealed not one, but several independent late slow waves. Components with peak latencies at 550 msec and 1210 msec were found to have different properties following the warning and imperative stimuli in a series of warned foreperiod tasks. A further feature, with a peak latency of 375 msec, and associated with the N550 following the warning stimulus, increased in amplitude when a motor response was made. However, some components seemed to be more closely related to decision processes than to action.Most of the late components recorded were predominantly negative, but some were bipolar, being negative over some regions and positive over others. The emergence of an independent factor, recognizably linked to the whole CNV wave form, suggested that the CNV may not be simply the product of separate slow potential changes occurring ‘early’ and ‘late’ in the interstimulus interval as has sometimes been suggested. Nevertheless in many cases what is usually seen as the CNV probably represents a summation between an extended DC shift and other late slow wave processes occurring during the interstimulus interval.     

Auditory middle-latency components to fusion of speech elements forming an auditory object.

OBJECTIVE: The purpose of this study was to define early brain activity associated with fusion of speech elements to form an auditory object in the middle-latency range preceding the F-Complex. METHODS: Stimuli were binaural formant transition and base, that were presented separately or fused to form the vowel-consonant-vowel sequence /ada/. Eleven right-handed, adult, native Hebrew speakers listened to 2/s presentations, and the brain potentials from C(z) during the 250 msec following transition onset (in the responses to transition and to the fused word) or following the time it would have been presented (in the response to base alone) were recorded. The net-fusion response was extracted by subtracting the sum of potentials to the base and the formant transition from the potentials to the fused sound. RESULTS: Auditory middle-latency components, comprising of 9 peaks and troughs were recorded in response to the base, to the formant transition and to the fused /ada/. In general, the responses to the fused object were significantly smaller in peak amplitude and in total activity (area under the curve) resulting in the difference waveform of the net-fusion response that also included 9 peaks, but with opposite polarities. CONCLUSIONS: The early middle-latency components to fusion indicate that the fusion of speech elements to a word involves inhibition, occlusion or both. The results are in line with the uniqueness of speech perception and the early role of the auditory cortex in speech analysis.