Abstract
We investigated the properties of human saccadic eye movements evoked by acoustic stimuli in the two-dimensional frontal plane. These movements proved to be quite accurate, both in azimuth and in elevation, grovided the sound source spectrum had a broad bandwidth and a sufficiently long duration. If the acoustic target was a tone, the azimuth of the saccadic end points remained equally accurate, whereas the elevation of the response was related to the frequency of the tone, rather than to the physical position of the target. Saccade elevation accuracy also declined substantially for short-duration noise bursts, although response elevation remained highly correlated with target elevation. The latencies of auditory saccades depended on the amplitude, but not on the direction of the eye movement, suggesting a polar coordinate origin of auditory saccade initiation. We also observed that the trajectories of auditory saccades were often substantially curved. Both a qualitative and a model-based analysis showed that this curvature corrected for errors in the initial direction of the saccade. The latter analysis also suggested that the kinematic properties of auditory saccades could be described by the superposition of two overlapping saccadic eye movements, hypothesized to be based on binaural difference cues and monaural spectral cues in the auditory signal, respectively. It is argued that, although the audio-oculomotor system has to operate in a feedforward way, it must nevertheless have access to an accurate representation of actual and desired eye position. Different models underlying the generation of auditory saccades are discussed.
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References
Bahill AT, Clark MR, Stark L (1975) The main sequence: a tool for studying human eye movements. Math Biosci 24: 191–204
Butler RA, Musicant AD (1993) Binaural localization: influence of stimulus frequency and the linkage to covert peak areas. Hear Res 67: 220–229
Clarey JC, Barone P, Imig TJ (1992) Physiology of thalamus and cortex. In: Popper AN, Fay RR (eds) The mammalian auditory pathway: neurophysiology. Springer, Berlin Heidelberg New York
Collewijn H, Van der Mark F. Jansen TJ (1975) Precise recording of human eye movements. Vision Res 15: 447–450
Collewijn H, Van der Steen J, Ferman L, Jansen TC (1985) Human ocular counterroll: assessment of static and dynamic properties from electromagnetic scleral coil recordings. Exp Brain Res 59: 185–196
Findlay JM, Harris LR (1984) Small saccades to double-stepped targets moving in two dimensions. In: Gale AG, Johnson F (eds) Theoretical and applied aspects of eye movement research. Elsevier, Amsterdam, pp 71–78
Frens MA, Van Opstal AJ (1994a) Auditory-evoked saccades in two dimensions: dynamical characteristics, influence of eye position, and sound source spectrum. In: Delgado-García J, Godaux E, Vidal PP (eds) Neural mechanisms underlying gaze control. Pergamon, Oxford, pp 329–339
Frens MA, Van Opstal AJ (1994b) Dynamical properties of auditory-evoked saccades. Neurosci Abstr 20: 1402
Frens MA, Van Opstal AJ, Van der Willigen RW (1995) Spatial and temporal factors determine audio-visual interactions in human saccadic eye movements. Percept Psychophys 57: 802–816
Hess BJM, Van Opstal AJ, Straumann D, Hepp K (1992) Calibration of three-dimensional eye positions using search coil signals in the rhesus monkey. Vision Res 32: 1647–1654
Irvine DRF (1992) Physiology of the auditory brainstem. In: Popper AN, Fay RR (eds) The mammalian auditory pathway: neurophysiology. Springer, Berlin Heidelberg New York
Jay MF, Sparks DL (1987) Sensorimotor integration in the primate superior colliculus. I. Motor convergence. J Neurophysiol 57: 22–34
Jay MF, Sparks DL (1990) Localization of auditory and visual targets for the initiation of saccadic eye movements. In: Berkley MA, Stebbins WC (eds) Basic mechanisms. (Comparative perception, vol I) Wiley, New York
Kalesnykas RP, Hallett PE (1994) Retinal eccentricity and the latency of saccades. Vision Res 34: 517–531
Kistler DJ, Wightman FL (1992) A model of head-related transfer functions based on principal component analysis and minimum-phase reconstruction. J Acoust Soc Am 3: 1637–1647
Lueck CJ, Crawford TJ, Savage CJ, Kennard C (1990) Auditoryvisual interaction in the generation of saccades in man. Exp Brain Res 82: 149–157
Middlebrooks JC, Green DM (1991) Sound localization by human listeners. Ann Rev Psychol 42: 135–159
Minken AWH, Van Opstal AJ, Van Gisbergen JAM (1993) Three-dimensional analysis of strongly curved saccades elicited by double-step stimuli. Exp Brain Res 93: 521–533
Ottes FP, Van Gisbergen JA.M., Eggermont JJ (1982) Responses of the saccadic system to sudden changes in target direction. In: Roucoux A, Crommelinck M (eds) Physiological and pathological aspects of eye movements. Junk, The Hague, pp 313–318
Press WH, Flannery BP, Teukolsky SA, Vettering WT (1992) Numerical recipes in C, 2nd edn. Cambridge University Press, Cambridge
Robinson DA (1975) Oculomotor control signals. In: Lennerstrand G, Bach-y-Rita P (eds) Basic mechanisms of ocular motility and their clinical implications. Pergamon, Oxford, pp 337–374
Rogers ME, Butler AE (1992) The linkage between stimulus frequency and covert peak areas as it relates to monaural localization. Percept Psychophys 52: 536–546
Rumelhart DE, Hinton GE, Williams RJ (1986) Learning internal representations by error propagation. In: Rumelhart DE, McClelland JL (eds) Parallel distributed processing: explorations in the microstructure of cognition, vol I. MIT Press, Cambridge, Mass, pp 318–362
Smit AC, Van Opstal AJ, Van Gisbergen JAM (1990) Component stretching in fast and slow oblique saccades in the human. Exp Brain Res 81: 325–334
Tweed D, Cadera W, Vilis T (1990) Computing three-dimensional eye position quaternions and eye velocity from search coil signals. Vision Res 30: 97–110
Van Gisbergen JAM, Van Opstal AJ, Schoenmakers JJM (1985) Experimental test for the generation of oblique saccades. Exp Brain Res 57: 321–336
Van Gisbergen JAM, Van Opstal AJ, Roebroek JGH (1987) Stimulus-induced midflight modification of saccade trajectories. In: O'Regan JK,Lévy-Schoen A (eds) Eye movements: from physiology to cognition. Elsevier, Amsterdam, pp 27–36
Van Opstal AJ (1993) Representation of eye position in three dimensions. In: Berthoz A (ed) Multisensory control of movement. Oxford University Press, Oxford, pp 27–41
Whittington DA, Hepp-Reymond MC, Flood W (1981) Eye and head movements to auditory targets. Exp Brain Res 41: 385–363
Zahn JR, Abel LA, Dell'Osso LF, Daroff RB (1979) The audioocular response: intersensory delay. Sens Proc 3: 60–65
Zakarouskas P, Cynader MS (1993) A computational theory of spectral cue localization. J Acoust Soc Am 94: 1323–1331
Zambarbieri D, Schmid R, Prablanc C, Magenes G (1981) Characteristics of eye movements evoked by the presentation of acoustic targets. In: Fuchs AF, Becker W (eds) Progress in oculomotor research. Elsevier/North-Holland, Amsterdam, pp 559–566
Zambarbieri D, Schmid R, Magenes G, Prablanc C (1982) Saccadic responses evoked by presentation of visual and auditory targets. Exp Brain Res 47: 417–427
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Frens, M.A., Van Opstal, A.J. A quantitative study of auditory-evoked saccadic eye movements in two dimensions. Exp Brain Res 107, 103–117 (1995). https://doi.org/10.1007/BF00228022
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DOI: https://doi.org/10.1007/BF00228022