Summary
In this paper, we report a detailed study of the dynamic properties of horizontal, vertical and oblique saccades. These eye movements were measured with an improved version of the double-magnetic induction method in two rhesus monkeys. We found that onsets of orthogonal components of oblique saccades are so well synchronized in the monkey that a common initiation system seems likely. Saccade vectors obeyed a nonlinear peakvelocity/amplitude relationship in all directions. The peak-velocity/duration/amplitude relationship for components was not fixed, but depended on the relative size of the orthogonal component: for a component with a given size, its duration increased and its peak velocity decreased, as the saccade vector to which it contributed turned away from the component direction under consideration. This stretching effect, which reflects a nonlinearity in the system, was negligible for small saccade vectors but became very pronounced in large oblique saccades. These experimental data were confronted with quantitative predictions derived from two different models for the generation of saccades in two dimensions. It appears that a model which assumes the existence of synchronized, but otherwise independent, pulse generators for horizontal and vertical components must be rejected. An alternative model, featuring a nonlinear vectorial pulse generator followed by a decomposition stage which generates component velocity command signals from the vectorial eye velocity signal, provides good fit with the data. According to this common-source model, the two nonlinear phenomena observed, viz., the curvilinear peak-velocity/amplitude relationship of saccades in all directions and component stretching in large oblique saccades, are due to a single nonlinearity in the proposed vectorial pulse generator. A possible neural basis for the common-source model is discussed.
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References
Bahill AT, Stark L (1975) Neurological control of horizontal and vertical components of oblique saccadic eye movements. Math Biosci 27: 287–298
Bahill AT, Clark MR, Stark L (1975) The main sequence, a tool for studying human eye movements. Math Biosci 24: 191–204
Bahill AT, Stark L (1977) Oblique saccadic eye movements. Arch Ophthal 95: 1258–1261
Bahill AT, Kallman JS, Lieberman JE (1982) Frequency limitations of the two-point central difference differentiation algorithm. Biol Cybern 45: 1–4
Baloh RW, Stills AW, Kumley WE, Honrubia V (1975) Quantitative measurement of saccade amplitude, duration and velocity. Neurology 25: 1065–1070
Bour LJ, Van Gisbergen JAM, Bruijns J, Ottes FP (1984) The double magnetic induction method for measuring eye movement: results in monkey and man. IEEE Trans Bio-Med Eng BME 31: 419–427
Büttner U, Büttner-Ennever JA, Henn V (1977) Vertical eye movement related unit activity in the rostral mesencephalic reticular formation of the alert monkey. Brain Res 130: 239–252
Evinger C, Fuchs AF (1978) Saccadic, smooth pursuit and optokinetic eye movements of the trained cat. J Physiol (Lond) 285: 209–229
Evinger C, Kaneko CRS, Fuchs AF (1981) Oblique saccadic eye movements of the cat. Exp Brain Res 41: 370–379
Fuchs AF (1967) Saccadic and smooth pursuit eye movements in the monkey. J Physiol (Lond) 191: 609–631
Guitton D, Mandl G (1980) Oblique saccades of the cat: a comparison between the durations of horizontal and vertical components. Vision Res 20: 875–881
Hepp K, Henn V (1982) Physiology of horizontal gaze. In: Lennerstrand G, Zee DS, Keller EL (eds) Functional basis of ocular motility disorders. Pergamon Press, Oxford, pp 247–255
Hepp K, Henn V (1983) Spatio-temporal recoding of rapid eye movement signals in the monkey paramedian pontine reticular formation (PPRF). Exp Brain Res 52: 105–120
Keller EL (1974) Participation of medial pontine reticular formation in eye movement generation in the monkey. J Neurophysiol 37: 316–332
Keller EL (1980) Oculomotor specificity within subdivisions of the brain stem reticular formation. In: Hobson JA, Brazier MAB (eds) The reticular formation revisited. Raven Press, New York, pp 227–240
King WM, Fuchs AF (1979) Reticular control of vertical saccadic eye movements by mesencephalic burst neurons. J Neurophysiol 42: 861–876
King WM, Lisberger SG, Fuchs AF (1983) Horizontal and vertical components of oblique saccades are temporally coupled in humans and monkeys. Soc Neurosci Abstr 9 (part 1): 68
Luschei ES, Fuchs AF (1972) Activity of brain stem neurons during eye movements of alert monkeys. J Neurophysiol 35: 445–461
Marmarelis PZ, Marmarelis VZ (1978) Analysis of physiological systems. Plenum Press, New York
Mays LE, Sparks DL (1980) Dissociation of visual and saccaderelated responses in superior colliculus neurons. J Neurophysiol 43: 207–232
Optican LM, Robinson DA (1980) Cerebellar-dependent adaptive control of primate saccadic system. J Neurophysiol 44: 1058–1076
Rabiner LR, Gold B, McGonegal CA (1970) An approach to the approximation problem for nonrecursive digital filters. IEEE Trans on Audio and Electroacoustics AU-18: 83–106
Raybourn MS, Keller EL (1977) Colliculoreticular organization in primate oculomotor system. J Neurophysiol 40: 861–878
Reulen JPH, Bakker L (1982) The measurement of eye movement using double magnetic induction. IEEE Trans Bio-Med Eng BME-29: 740–744
Robinson DA (1970) Oculomotor unit behavior in the monkey. J Neurophysiol 33: 393–404
Robinson DA (1975) Oculomotor control signals. In: Lennerstrand G, Bach-y-Rita P (eds) Basic mechanisms of ocular motility and their clinical implications. Pergamon Press, Oxford, pp 337–374
Robinson DA (1981) The use of control systems analysis in the neurophysiology of eye movements. Ann Rev Neurosci 4: 463–503
Schiller PH, True SD, Conway JL (1980) Deficits in eye movements following frontal eye field and superior colliculus ablations. J Neurophysiol 44: 1175–1189
Sparks DL, Mays LE (1983) Spatial localization of saccade targets. I. Compensations for stimulation-induced perturbations in eye position. J Neurophysiol 49: 45–63
Van Gisbergen JAM, Robinson DA, Gielen S (1981) A quantitative analysis of generation of saccadic eye movements by burst neurons. J Neurophysiol 45: 417–442
Van Gisbergen JAM, Ottes FP, 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. Dr W Junk Publ, The Hague, pp 313–318
Viviani P, Berthoz A, Tracey D (1977) The curvature of oblique saccades. Vision Res 17: 661–664
Wurtz RH, Albano JE (1980) Visual-motor function of the primate superior colliculus. Ann Rev Neurosci 3: 189–226
Yarbus AL (1967) Eye movements and vision. Plenum Press, New York
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van Gisbergen, J.A.M., van Opstal, A.J. & Schoenmakers, J.J.M. Experimental test of two models for the generation of oblique saccades. Exp Brain Res 57, 321–336 (1985). https://doi.org/10.1007/BF00236538
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DOI: https://doi.org/10.1007/BF00236538