[Objective and subjective indexes of auditory motion processing].

The study focused at the objective and subjective indexes of human hearing system sensitivity towards different types of moving sound stimuli. The experiment employed two methods: electrophysiological (MMN recording) and psychophysical method (two-alternative forced choice). Two types of spatial sound stimuli simulated gradual and abrupt sound motion from the head midline. MMN as an objective index of spatial discrimination has been obtained in response to the subthreshold and the suprathreshold stimuli. An increase of trajectory length of the moving stimuli resulted in an increase of the MMN amplitude and of subjective discrimination as well, although their correlation remained below the significance level. The results obtained are discussed from the point of view of preconscious perception of auditory spatial information.

[Perceptual categories for auditory motion as reflected in mismatch negativity].

Auditory evoked response and mismatch negativity potential have been studied using the reversed odd-ball paradigm of standard and deviant stimulus presentation. In the experiments, three types of spatial sound stimuli (stationary and moving either gradually or abruptly from the head midline) were presented in three configurations. Each configuration employed one stimulus type as standard and the other two types as deviants. It was demonstrated that the configuration reversals influenced significantly the evoked response and mismatch negativity. The results obtained are discussed as the possible evidence of the categorical perception of auditory motion revealed at the earlier stages of sound processing in the hearing system.

[Event-related potentials of human brain in spatial hearing].

The review presents the data concerning auditory event-related potentials and their "mismatch negativity" component under conditions of stationary and moving sound source localization. Both free-field and dichotic experimental conditions are considered. The interhemispheric asymmetry of the brain responses elicited by the sound sources of various spatial properties is also discussed.

[Forecast ability of the auditory system during perception of gradually or abruptly moving short sound images].

The ability to localize endpoints of sound image trajectories was studied in comparison with stationary sound image positions. Sound images moved either gradually or abruptly to the left or right from the head midline. Different types of sound image movement were simulated by manipulating the interaural time delay. Subjects were asked to estimate the position of the virtual sound source, using the graphic tablet. It was revealed that the perceived endpoints of the moving sound image trajectories, like stationary stimulus positions, depended on the interaural time delay. The perceived endpoints of the moving sound images simulated by stimuli with the final interaural time delay lower than 200 micros were displaced further from the head midline as compared to stationary stimuli of the same interaural time delays. This forward displacement of the perceived position of the moving target can be considered as "representational momentum" and can be explained by mental extrapolation of the dynamic information, which is necessary for successive sensorimotor coordination. For interaural time delays above 400 micros, final positions of gradually and abruptly moving sound sources were closer to the head midline than corresponding stationary sound image position. When comparing the results of both duration conditions, it was shown that in case of longer stimuli the endpoints of gradually moving sound images were lateralized further from the head midline for interaural time delays above 400 micros.

[Auditory perception sluggishness during short moving sound image localization].

Displacement of the perceived position of the starting points relative to the objective one during the moving sound source localization is an example of the auditory perception sluggishness. The ability to localize starting and end points of sound image trajectories was studied in comparison with stationary sound image positions. Sound images moved gradually or abruptly to the left or right from the head midline. The subjects were asked to estimate the position of the virtual sound source, using the graphic tablet. It was revealed that the starting points shifted systematically in the direction of the sound image movement. This tendency was stronger for the gradual movement then for the abrupt shift, and for shorter stimuli (100 ms) in comparison with longer ones (200 ms). The starting point displacement magnitude depended on the final value of the interaural time delay. The findings are discussed in view of the "snapshort" and "movement detectors" theories. The representational momentum and anticipation ability of the auditory perception were also considered.

Interhemisphere asymmetry of auditory evoked potentials in humans and mismatch negativity during sound source localization.

Results of studies in humans of long-latency auditory evoked potentials and mismatch negativity in conditions of dichotic stimulation during presentation of deviant stimuli producing instantaneous changes in stimulus azimuth from the null to +22.5 degrees or movement at rates of 11.25-112.5 degrees/sec from the midline of the head across the left and right hemispheres towards each ear are presented. These studies showed that the total amplitude of the components of the N1-P2 complex of auditory evoked potentials in the frontal lead of the right hemisphere was greater than that in the left hemisphere. Mismatch negativity parameters showed significant relationships with the spatial position of the sound source, namely, its displacement into the right hemisphere from the position of the sound image of the standard signal. Questions of the involvement of the right hemisphere in discriminating the spatial characteristics of sound sources are discussed.

[Discrimination of the dynamic properties of sound source spatial location in humans (electrophysiology and psychophysics)].

The spatial resolution of human auditory system has been studied while the localization of sound source has been changed according to the different temporal patterns of interaural time delay. Two experimental procedures have been run in the same group of subjects: psychophysical procedure (the transformed staircase method) and electrophysiological one (which requires recording of mismatch negativity, the auditory evoked response component). It has been established that 1) the magnitude of the mismatch negativity reflects the extent of spatial deviance of the sound source 2) the mismatch negativity is elicited even at minimal (20 micros) interaural time delays under both temporal patterns (abrupt azimuth change and gradual sound movement at various velocities) 3) the abrupt change of the sound source azimuth results in greater mismatch negativity than the gradual sound movement does, if the interaural time delay exceeds 40 micros 4) the discrimination threshold values of the interaural delay obtained in the psychophysical procedure are greater than the minimal interaural delays that elicit the mismatch negativity, with the exception of the expert listeners who has shown no significant difference.

[Interhemispheric asymmetry of the auditory evoked potentials and mismatch negativities during sound source localization].

The long-latency auditory evoked potentials and mismatch negativities were studied in humans using dichotic stimulation. Deviant stimuli either changed their azimuth abruptly from zero to +/- 22.5 degrees or moved gradually to the left/right from the head midline at different velocities ranging from 11.25 degrees per second to 112.5 degrees per second. It was demonstrated that the amplitude of N1-P2 wave of the evoked potential was higher when recorded from the right frontal sites than from the left sites. The mismatch negativity depended significantly on the spatial location of the deviant stimulus: the right deviants elicited greater and earlier mismatch negativities than the left deviants. The involvement of the right hemisphere in the auditory spatial discrimination is discussed.

[Mismatch negativity in the auditory event-related potentials in response to abrupt and smooth displacements of virtual sound source].

The work investigated event-related potentials, mismatch negativity (MMN), and P3a component under dichotic stimulation with deviant stimuli simulating abrupt or smooth displacement of auditory images to the left or to the right from the head midline by means of interaural time delay introduced into the deviant stimuli. Repetitive standard stimuli were localized near the head midline. All deviant stimuli elicited mismatch negativity and P3a component. It was shown the MMN for smooth deviant motion was lower than that for the abrupt deviant displacement. MMN amplitude for both deviant types obviously depended on interaural time delay, which confirms that MMN might be considered as a measure of the auditory system spatial discriminative ability. The P3a component demonstrated the same amplitude dependences as the MMN. The results obtained are discussed in respect to manifestation of the processes underlying the auditory motion detection in the event-related potentials.

Effects of the azimuthal position of stationary and moving sound images on the mismatch negativity phenomenon.

This report presents results obtained from studies of the phenomenon of mismatch negativity in conditions of dichotic stimulation with presentation of deviant stimuli modeling movement of a sound image towards or away from a standard stimulus and on presentation of stationary deviants located at an angle of 90 degrees to the standard. Standard stimuli were located close to the left or right ear or in the midline of the head. All deviant stimuli induced mismatch negativity. Movement of the deviant stimulus from the standard was found to induce mismatch negativity with the longest latency and smallest amplitude for all azimuthal positions of the standard stimulus. In addition, it was only in this direction of movement that there was a relationship between measures of mismatch negativity and the azimuth of the standard. It was suggested that the process of the recognition of differences between interaural delay times is significantly dependent on the nature of changes in this parameter at the moment at which the deviant stimulus is presented.

[Tendencies in auditory physiology].

Main tendencies in studying of human and animals auditory system with psychoacoustical and electrophysiologycal methods are considered. Concerning psychoacoustical studies some basic data are presented as well as contemporary tendencies in hearing physiology in analysis of the intensity, frequency, temporal characteristics of the sound signals and data related to such phenomena as masking and adaptation. Data concerning directional hearing are presented in detail as a basis of auditory virtual reality. In electrophysiological studies of the auditory system detailed analysis of mapping in auditory centers and mechanisms concerning localization of unmoved and moving auditory stimuli was performed. Special attempt was paid to consider the reflection of different types of auditory signals in human evoked potentials.

The role of phase changes in sound signals in localization of sound sources.

The auditory system in humans and animals makes virtually no discrimination of phase changes in the structure of monaurally presented sound signals. However, electrophysiological studies have demonstrated marked changes in the responses of the central parts of the auditory system when the phase structure of the signal changes during presentation of the same type of stimulation. We have suggested that this inconsistency is due to the preparative role of phase effects during monaural stimulation for subsequent operations in the auditory system involved in determining the location of a sound source in space. This report presents experimental data on defined changes (increases in amplitude) in the electrical responses of the midbrain center of the auditory system (inferior colliculus) in antiphase binaural presentation of series of sound impulses (comparison with synphase presentation). These changes may be part of the mechanism underlying the interference resistance of the auditory system during determination of the location of a sound source (binaural release from masking). Neuronal cortical activity is sensitive and selective to dynamic interaural changes in the phase spectrum of the signal, which may provide the basis of the mechanism for locating a moving sound source. Auditory evoked potentials in humans demonstrate memorizing of the direction of movement of a sound image, as shown by the changes in parameters on presentation of stimuli of different locations (deviant stimuli) differing from the standard parameters of mismatch negativity.

[A mismatch negativity elicited with stationary and moving auditory images of different azimuth positions]. / Vliianie azimutal'nogo polozheniia nepodvizhnykh i dvizhshchikhsia zvukovykh obrazov na fenomen negativnosti rassoglasovaniia.

Characteristics of mismatch negativity elicited by dichotic stimulation were examined using deviant stimuli simulating movement of fused auditory images towards the standard stimuli or in the reverse direction. The effect of stationary deviants localized at 90 degrees in respect to standards was also measured. The standard stimuli were localized near either of ears or along the head midline. The spatial locations were produced by introducing interaural time differences into the click trains. All deviant stimuli evoked the mismatch negativity. The deviants moving from standards seem to evoke the lowest mismatch negativity with the longest latency at all azimuthal locations of standard stimuli. Besides, the deviant shift from standards proved to be the only direction at which the characteristics of mismatch negativity depended upon the standard's azimuth. It is seems that the discrimination of interaural time delay is essentially dependent on the pattern of interaural delay changes at the moment when the deviant occurs.

Changes in evoked potentials during the action of sound signals with different localizing characteristics.

This report presents results of studies of the phenomenon of mismatch negativity (MMN) during exposure to four blocks of sound stimuli each containing identical standards creating an immobile sound image located along the midline of the head and one of a set of deviants, creating a sound image located either by the left ear or moving from the midline of the head towards the left ear or in the opposite direction. All deviants induced mismatch negativity; the minimal amplitude and longest latent period were seen in the mismatch negativity produced by the deviant modeling movement of the sound image from the midline of the head to the left ear. The question of the appearance of mismatch negativity as a criterion for the accurate discrimination of signals with different localizing characteristics is discussed.

[Role of phasic changes in sound signal in localization of auditory image]. / Rol' fazovykh izmenenii v zvukovom signale pri lokalizatsii zvukovogo obraza.

The work presents experimental data on certain changes in electrical responses of the auditory system's midbrain centre in a contraphasic binaural presentation of sound impulse series. Neuronal cortical activity is selective in respect to dynamic interaural changes of signals' phasic spectre which may serve as a basis for the mechanisms of localising a moving source of sound. Human auditory evoked potentials reveal a manifestation of memorizing the auditory image movement direction as shown by appearance of stimuli deviant from standard mismatch negativity.

[Changes of evoked potentials caused by sound signals with different localization characteristics]. / Izmenenie vyzvannykh potentsialov pri deistvii zvukovykh signalov s raznymi lokalizatsionnymi kharakteristikami.

Characteristics of the mismatch negativity (MMN) were studied by presenting the subjects with four blocks of stimuli containing standard series of clicks (90%) simulating a stationery sound image located in the head midline, and one of three different deviant series of clicks (10%) simulating either a stationary sound image located near the left ear or a moving sound image which shifted from the head midline to the left ear or in the opposite direction. All the deviant stimuli elicited the MMN with the minimal peak amplitude and the greatest latency evoked by the deviant series of clicks simulating the sound image moving from the head midline to the left ear. These findings suggest that the MMN may be considered as a pre-perceptual physiological measure of the discrimination accuracy for the sound signals with various spatial locations.

Comparison of binaural release from forward masking in animals and humans. Electrophysiological studies.

Evoked potentials in the inferior colliculus and auditory areas of the cortex were studied in anesthetized guinea pigs and long-latency auditory evoked potentials (LAEP) were studied in waking humans using sequential binaural presentation of pairs of clicks--the masker and the masked signal--with a variable interval between them, to provide the conditions needed for the psychophysical phenomenon of direct forward masking. Introduction of phase differences between the masker and the masked signal led to decreases in suppression of responses to the masked signal and to faster recovery of the reaction types recorded. The greatest relative differences between response magnitudes to antiphase and synphase masked signals were seen at the beginning of the recovery process, and were 1.6, 1.5, and 1.4 respectively for responses from the inferior colliculus, auditory area of the cortex, and LAEP at stimulus intensities of 50-65 dB sound pressure level, differences subsequently decreasing to zero. There was a positive correlation between this measure and the stimulus intensity. The greatest differences between the time at which the recovery process ended for responses to antiphase and synphase masked signals were 4, 250, and about 2000 msec respectively for the inferior colliculus, auditory area of the cortex, and LAEP.