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The Journal of Neuroscience, January 1, 1999, 19(1):316-327
Computation of Inertial Motion: Neural Strategies to Resolve
Ambiguous Otolith Information
Dora E.
Angelaki1, 2,
M.
Quinn
McHenry2,
J. David
Dickman1, 2,
Shawn D.
Newlands1, and
Bernhard J. M.
Hess3
Departments of 1 Surgery (Otolaryngology) and
2 Anatomy, University of Mississippi Medical Center,
Jackson Mississippi 39216, and 3 Department of Neurology,
University Hospital, Zürich CH-8091, Switzerland
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ABSTRACT |
According to Einstein's equivalence principle, inertial
accelerations during translational motion are physically
indistinguishable from gravitational accelerations experienced during
tilting movements. Nevertheless, despite ambiguous sensory
representation of motion in primary otolith afferents, primate
oculomotor responses are appropriately compensatory for the correct
translational component of the head movement. The neural computational
strategies used by the brain to discriminate the two and to reliably
detect translational motion were investigated in the primate
vestibulo-ocular system. The experimental protocols consisted of either
lateral translations, roll tilts, or combined translation-tilt
paradigms. Results using both steady-state sinusoidal and transient
motion profiles in darkness or near target viewing demonstrated that
semicircular canal signals are necessary sensory cues for the
discrimination between different sources of linear acceleration. When
the semicircular canals were inactivated, horizontal eye movements
(appropriate for translational motion) could no longer be correlated
with head translation. Instead, translational eye movements totally
reflected the erroneous primary otolith afferent signals and were
correlated with the resultant acceleration, regardless of whether it
resulted from translation or tilt. Therefore, at least for frequencies in which the vestibulo-ocular reflex is important for gaze
stabilization (>0.1 Hz), the oculomotor system discriminates between
head translation and tilt primarily by sensory integration mechanisms
rather than frequency segregation of otolith afferent information.
Nonlinear neural computational schemes are proposed in which not only
linear acceleration information from the otolith receptors but also
angular velocity signals from the semicircular canals are
simultaneously used by the brain to correctly estimate the source of
linear acceleration and to elicit appropriate oculomotor responses.
Key words:
eye movements; vestibular; oculomotor; navigation; inertial; gravity; neural computation
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INTRODUCTION |
In everyday life, one often
experiences movements that involve both rotational and translational
components. In addition, most naturally occurring rotational movements
are accompanied by a concurrent change in head orientation relative to
gravity. Running and locomoting, for example, have been shown to be
characterized by high-frequency rotational and translational motion
components (Grossman et al., 1988 ; Pozzo et al., 1990). Motion
information is transduced by the vestibular system, which consists of
separate receptors that respond to either angular (semicircular canals) or linear (otolith organs) accelerations. Because tilt and translation induce inertial accelerations of the otoconia that are physically equivalent (Einstein's equivalence principle; Einstein, 1908), primary
otolith afferent neurons provide equivalent responses to both head
tilts relative to gravity and to translational movements (Loe et al.,
1973; Fernandez and Goldberg, 1976; Anderson et al., 1978; Dickman et
al., 1991; Si et al., 1997). Thus, the otolith signals transmitted to
the CNS merely encode the resultant linear acceleration ( ),
which is equal to the vectorial sum of the translational (f) and gravitational
(g) components, i.e., = f + g.
Despite indiscriminate primary otolith afferent information, motor
responses to head tilts and translations must be different. With
respect to the oculomotor system, for example, a roll tilt of the head
toward the shoulder should elicit ocular torsion, whereas a lateral
head translation should generate horizontal eye movements (Bronstein
and Gresty, 1988; Crawford and Vilis, 1991; Paige and Tomko, 1991a;
Schwarz and Miles, 1991; Haslwanter et al., 1992; Tweed et al., 1994;
Angelaki and Hess, 1996b; Telford et al., 1997; Angelaki, 1998).
Because otolith afferent information does not discriminate between
different sources of linear acceleration, it becomes the task of the
CNS to correctly differentiate the acceleration source and to elicit
functionally compensatory motor responses.
Two hypotheses have been proposed as to how the brain might solve the
tilt-translation ambiguity of otolithic receptor information. According to the "multisensory integration" hypothesis, the brain must combine information from different sensors, such as the vestibular rotation sensors (i.e., the semicircular canals) and the otolith organs, to correctly differentiate between head translation and tilt
(Guedry, 1974; Mayne, 1974; Young, 1974). Alternatively, the
"frequency-segregation" hypothesis states that the frequency content of the otolith signals determines the source of acceleration. Accordingly, high-frequency accelerations are interpreted as
translations, whereas low-frequency accelerations are interpreted as
tilts (Paige and Tomko, 1991a; Telford et al., 1997).
In the present study, predictions derived from these hypotheses were
tested. To directly investigate whether information from the
semicircular canals is used by the CNS to correctly interpret linear
accelerations, the horizontal eye movements elicited by linear
acceleration before and after canal inactivation were taken as a
measure of the capacity of the brain to encode head translation. The results refute frequency segregation as the primary computational scheme used to discern movement. Rather, functional semicircular canal
signals are critical for an appropriate discrimination of the source of
linear acceleration and the mode of head motion.
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MATERIALS AND METHODS |
Animal preparation and eye movement recording
Binocular three-dimensional (3-D) eye movements were
recorded using the magnetic search coil technique. The driver coils, which generated horizontal and vertical magnetic fields (100 and 66 kHz, respectively) were mounted on a cubic fiberglass frame of 16-inch
side length (CNC Engineering). Five rhesus monkeys (Macaca
mulatta) were implanted with a head-restraining platform and dual
search coils on each eye under gas anesthesia. Details for the surgical
procedures have been described elsewhere (Angelaki, 1998). All
surgeries were performed under sterile conditions in accordance with
the Institutional Animal Care and Use Committee and National Institutes
of Health guidelines. Anesthesia was initiated with an intramuscular
injection of ketamine (10 mg/kg), followed by administration of an
inhalative anesthesia that consisted of an O2-isoflurane
mixture. Respiration, body temperature, and heart rate were
continuously monitored. Animals were given antibiotics and analgesics
after completion of each surgery. In addition, the lumens of all six
semicircular canals were plugged in two of the animals, as described
previously (Ewald, 1892; Angelaki et al., 1996). Canal-plugged animals
showed no evidence of spontaneous nystagmus other than the normal
downbeat nystagmus that is observed also in intact animals in darkness.
After the surgery, animals were kept in complete darkness until the
next morning when they were brought to the laboratory for vestibular
testing ("acute" experimental protocol). After this acute
vestibulo-ocular reflex (VOR) testing, animals were returned to the
regular diurnal cycle.
The dual eye coil assembly that was implanted on each eye consisted of
two serially interconnected miniature coils (Sokymat, Veveyse
Switzerland) that were attached at diagonal points along the
circumference of an ~15 mm three-turn stainless steel coil (Cooner
wire). The exact orientation of the two coils relative to each other
and the orientation of the dual eye coil on the eye were precisely
determined based on both preimplantation and daily calibration
procedures (Hess 1990; Hess et al., 1992). Briefly, each dual eye coil
was calibrated before surgical implantation with a 3-D calibration jig.
Using rotations about all three axes, this calibration yielded the coil
sensitivities, as well as the angle between the two coil sensitivity
vectors. In each experimental session and protocol, pretrained animals
performed a visual fixation task. The eye coil voltages measured during
visual fixation, along with the precalibrated values for the
sensitivity vector of the torsion coil and the angle between the two
coils, were used to calculate the orientation of the dual coil on the
eye, as well as offset voltages.
3-D eye positions were expressed as rotation vectors using
straight-ahead gaze as the reference position. Angular eye velocity was
computed from these rotation vectors (cf. Angelaki and Hess, 1996a,b,c). Both eye position and angular eye velocity vectors were
expressed relative to a head-fixed right-handed coordinate system, with
the head placed in an 18° nose-down position (see below). Torsional,
vertical, and horizontal eye position and velocity were defined as the
components of the eye position and eye velocity vectors along the
naso-occipital, interaural (IA), and vertical head axes,
respectively. Positive directions were clockwise (as viewed from the
animal, i.e., rotation of the upper pole of the eye toward the right
ear), downward, and leftward for the torsional, vertical, and
horizontal components, respectively.
Experimental setup and protocols
During experimental testing, the monkeys were seated in a
primate chair, with their heads statically positioned such that the
horizontal stereotaxic plane was tilted 18° nose-down. This head
position was used to place the lateral semicircular canals approximately parallel to the earth-horizontal plane, while at the same
time keeping the vertical semicircular canals as vertically oriented as
possible. The animal's body was secured with shoulder and lap belts,
while the extremities were loosely tied to the chair. The primate chair
was then secured inside the inner frame of a vestibular turntable,
which consisted of a 3-D rotator on top of a linear sled powered by a
servo-controlled linear motor (2 m length; Acutronics Inc.). The two
inner frames of the turntable were manufactured by nonmetallic
composite materials to minimize interference with the magnetic fields.
The 3-D turntable was used to deliver roll movements, whereas the
linear sled was used to laterally translate the animals.
Experimental protocol 1. Steady-state sinusoidal
oscillations at 0.16, 0.5, and 1 Hz were delivered in complete darkness
(vergence angle of ~1 MA) (Angelaki, 1998). For each of these
frequencies, four stimulus combinations of lateral translation and/or
roll tilt were tested. The peak amplitudes during combined
tilt-translational motion profiles are provided in Table
1A.
As shown in Figure 1A for 0.5 Hz stimuli, the Translation only stimulus consisted
of translational displacements (±36.7 cm) along the animal's IA axis, with a peak IA shear acceleration of 0.37G). In Figure
1B, the Roll tilt only stimulus consisted
of earth-horizontal axis roll oscillations (±21.8°), which generated
the same IA shear acceleration of 0.37G). In Figure 1C, the
Roll tilt + Translation stimulus consisted of lateral linear
translations (sled motion, ±39.8 cm) combined with simultaneous roll
tilt oscillations (±21.8°). The translational and tilt motions were
produced in phase such that a total IA acceleration of 0.74G resulted.
The Roll tilt  Translation stimulus in Figure
1D consisted of the same combined translation and
tilt components, except that the two motions were out of phase. This produced a total IA acceleration of 0.0G.
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Figure 1.
Schematic diagram outlining the main experimental
protocol of lateral motion and/or roll tilt oscillations at 0.5 Hz.
a, Pure translation [black arrow,
gravitational acceleration (g); gray
arrow, translational acceleration
(f)]. b, Pure roll
tilt. c, Combined roll tilt and translation with
relative phases such that the translational component added to the
gravity component along the IA axis, generating a resultant IA
acceleration of 0.74G (thick arrow). d,
Combined roll tilt and translation with relative phases such that the
translational and gravitational components along the IA axis canceled
each other (i.e., IA acceleration, 0G).
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Because the roll movements were nested inside the translational
displacement, the translational acceleration along the IA axis differed
slightly from that delivered by the linear sled. Specifically, if the
roll oscillation amplitude is described by the equation
 (t) = o · sin( t), and the
translational acceleration during linear motion is described by the
equation  tr = o · sin(t +  ), where is the relative phase between the
two stimuli, then during a combined motion profile, the translational
component of the acceleration along the IA axis
(fy) and the vertical head axis
(fz) would be:
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(1a)
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(1b)
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Component y modulates sinusoidally at
frequency , whereas component z modulates
at the second harmonic (2). Vertical slow phase velocity modulation
was indeed seen in the responses of intact animals (see Fig. 2). These
vertical slow phase eye velocity components were partly
attributable to a misalignment of the roll VOR and partly
attributable to a second harmonic contribution because of the changing
head orientation relative to the translational displacement (i.e.,
z in Eqs. 1a,b). No
such vertical eye movement components were elicited during combined
tilt-translation in canal-plugged animals (see Fig. 5).
The total IA acceleration that results from simultaneous roll tilt and
translation is given by the equation:
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(2)
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Equations 1 and 2 have been used here to compute the
translational and resultant acceleration components along the IA axis (see Fig. 9).
Experimental protocol 2. In addition to the four sinusoidal
protocols described above and illustrated in Figure 1, a more extensive
tilt-translation combination battery of tests consisting of 0.5 Hz
oscillations were also delivered (Table 1B).
Specifically, (1) peak sled oscillation amplitude was kept constant
(0.40G), whereas peak roll oscillation amplitude varied between 0°
and ±21.8°; (2) peak sled oscillation amplitude was varied
(0-0.40G), whereas peak roll oscillation amplitude was kept constant
(21.8°); and finally, (3) the relative phase between the sled
oscillations (0.4G) and roll oscillations (±21.8°) was varied in
45° steps. A phase of 0° corresponded to the Roll tilt + Translation motion condition, whereas a phase of 180°
corresponded to the Roll tilt Translation motion condition.
Experimental protocol 3. The same four main protocols (i.e.,
Translation only, Roll tilt only, Roll
tilt + Translation motion, and Roll tilt Translation motion) were also tested with transient motion
profiles. For these stimuli, the angular component of the stimulus
consisted of a 15° roll tilt (angular velocity, 60°/sec; angular
acceleration, 220°/sec2). The parameters of head
translation were adjusted such that the inertial linear acceleration
profile generated during translation closely matched that induced by
the head tilt for the whole stimulus duration (~500 msec). As a
result, the Roll tilt Translation transients
exhibited nearly zero IA acceleration.
Experimental protocol 4. For comparison, earth-horizontal
and earth-vertical axis roll oscillations were also delivered in a
broader amplitude and frequency range. Specifically, the roll oscillation protocols in labyrinthine-intact animals included the
following: ±5° (1 Hz); ±22° (0.5, 0.2, and 0.1 Hz); and ±90° (0.2, 0.1, 0.05, 0.02, and 0.01 Hz). Canal-plugged animals were only
tested with the low-amplitude stimuli (5° and 22°).
All steady-state sinusoidal recordings were made in complete darkness.
Under these conditions, vergence averages were ~1 MA (Angelaki,
1998). Responses to transient stimuli were also recorded in complete
darkness, but binocular fixation was controlled, and large vergence
angles were obtained by initializing each trial only when the animal
had satisfactorily fixated a target light located approximately in
between the two eyes at a distance of 20 cm. The target light was
extinguished immediately before the onset of motion and remained off
until the animal came to a complete stop. All animals participating in
these experiments were pretrained using juice rewards to fixate targets
paired with an auditory cue for variable time periods (300-1000 msec)
and then to maintain fixation after the target was turned off, for as
long as the auditory tone was present (at least 1-2 sec). During all
fixations, the room was illuminated (through small red lights) such
that the animals could easily establish relative distance estimates of the targets. Adequate fixation was defined when both eyes were within
behavioral windows (separate for each eye) of ±1.0°. Animals were
trained to perform these fixation tasks for at least 1 month before any
experimental testing. As shown by the eye position traces of Figure 10,
animals quickly learned to maintain vergence in complete darkness for a
minimum of 500 msec, as long as the auditory tone remained on.
Responses were first obtained in animals with intact labyrinths. As
stated above, acute responses were obtained during the first day after
canal plugging (see Figs. 5, 10). Data were recorded up to 3 months
after plugging. Because no changes were observed in the horizontal
translational VOR properties after canal plugging (Angelaki, 1998, Fig.
7), data obtained at different times after plugging were included in
the average (see Figs. 4, 6-9). The adequacy of canal plugging was
physiologically verified by the lack of any response during
earth-vertical axis yaw, pitch, and roll oscillations (0.1-1 Hz).
These responses were systematically tested throughout the 3 month
period of testing.
Data analysis
All data analyses were performed on personal computers off-line.
First, calibrated 3-D eye positions were expressed as rotation vectors.
The horizontal, vertical, and torsional components of the calibrated
eye position vectors were then smoothened and differentiated with a
Savitzky-Golay quadratic polynomial filter using a 15-point forward
and backward window (Savitzky and Golay, 1964; Press et al., 1988). The
angular eye velocity vector was computed from 3-D eye position and its
derivative, as described previously (cf. Angelaki and Hess, 1996a,b,c).
For transient motion profiles, only runs without fast phases for the
first 500 msec were further analyzed. For sinusoidal stimuli, fast eye
movements were removed from the eye velocity profiles using a
semi-automated procedure based on time and amplitude windows set for
the second derivative of the magnitude of eye velocity. Subsequently,
average response cycles were computed from steady-state response
components (i.e., horizontal, vertical, and torsional) for each eye.
For each of these average response cycles, peak response amplitude and
phase were determined by fitting a sine function (including first and second harmonic, as well as a direct current offset) to both slow phase
eye velocity and stimulus (angular or linear velocity) using a
nonlinear least squares algorithm based on the Levenberg-Marquardt method. Phase was expressed as the difference (in degrees) between peak
eye velocity and peak angular velocity (for roll tilt and tilt-translation combination profiles) or linear velocity (for pure
translational motion).
The results presented here concentrate on horizontal eye movements,
because they reflect the coding of head translation. In contrast,
torsional eye movements were considered inappropriate in this regard,
because they are primarily generated by semicircular canal activation,
whereas static or otolith-induced eye torsion is known to have small
gain in primates and humans (Diamond et al., 1979; Paige and Tomko,
1991a; Haslwanter et al., 1992; Angelaki, 1998).
Statistical comparisons on the data were based on ANOVA.
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RESULTS |
Tilt-translation discrimination in
labyrinthine-intact animals
In all animals with intact labyrinths, the elicited eye movements
were compensatory for all stimulus combinations. As shown in Figure
2, for example, sinusoidal lateral
translation (Translation only), but not roll tilt
oscillations (Roll tilt only), elicited robust horizontal
eye movements in complete darkness. Moreover, during the combined
Roll tilt + Translation and Roll tilt Translation motion profiles, the elicited horizontal eye movements
were similar to those generated during Translation only
motion. Thus, the horizontal eye movements generated in
labyrinthine-intact animals totally ignored the linear accelerations
caused by changes in head orientation relative to gravity during the
roll movement. In fact, for all stimulus conditions (Translation
only, Roll tilt only, Roll tilt + Translation, and Roll tilt Translation motion
protocols), the direction and magnitude of the horizontal response
remained compensatory to the translational component of linear
acceleration and was related neither to the acceleration produced by
the roll tilt nor to the resultant IA acceleration. This was
particularly striking for the Roll tilt Translation
protocols in which robust horizontal eye movements were generated,
despite the fact that the resultant IA acceleration was zero.
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Figure 2.
Tilt-translation discrimination in a
labyrinthine-intact rhesus monkey. Torsional, vertical, and horizontal
components of eye position (Etor,
Ever, and Ehor,
respectively) and slow phase eye velocity
( tor, ver, and
hor, respectively) of the right eye during
lateral translation and/or roll tilt at 0.5 Hz in complete darkness.
Left to Right, The stimuli consisted of
Translation motion only, Roll tilt only,
Roll tilt + Translation motion, and Roll
tilt Translation motion. Dotted lines
are zero position (straight-ahead gaze) and zero eye velocity. The
stimulus traces (bottom) show sled position
(Htrans, positive direction to the left) and
roll tilt position (Hroll, positive tilt toward
right ear-down). Positive eye movement directions are leftward,
downward, and clockwise (upper pole of the eye toward the right
ear).
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As reported previously (Tweed et al., 1994; Angelaki and Hess, 1996b),
a small horizontal eye velocity modulation was often present during
roll head movements. This has been further quantified in Figure
3 in which sensitivity and phase of
horizontal eye velocity during earth-horizontal and earth-vertical axis
roll oscillations (filled and open
symbols, respectively) are compared with those generated
during lateral translation (triangles) (Angelaki, 1998, Fig.
6). The horizontal eye movements elicited during both earth-horizontal and earth-vertical roll oscillations (i.e., rotations with the animals
supine) were significantly smaller than those elicited during lateral
head translation at the same frequency.
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Figure 3.
Comparison of horizontal eye velocity elicited
during roll and translation. Mean ± SD peak horizontal eye
velocity sensitivity (expressed in degrees/second/gravity, where G = 9.81 m/sec2) and phase have been plotted separately
for earth-horizontal and earth-vertical roll oscillations
(filled and open symbols,
respectively). Roll oscillations: squares, ±90°
(0.01-0.2 Hz); circles, ±22° (0.1-0.5 Hz) and
±5° (1 Hz); lateral translations: triangles
(Angelaki, 1998, Fig. 6, average data from five animals
replotted).
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The observation that horizontal eye movements appropriately
discriminated for tilt and translation is further illustrated in Figure
4. In the frequency range tested, the
results were independent of stimulus frequency (0.16, 0.5, and 1 Hz;
F(4,23) = 0.81; p > 0.05).
Accordingly, robust horizontal eye movements were generated only in the
presence of translational motion (Fig. 4, Tran only, Roll+Tran, RollTran). In contrast, the
horizontal eye movement components elicited during Roll only
motion were significantly smaller in amplitude than those generated
during Translation only motion
(F(1,15) = 68.0; p < 0.05).
During the combined Roll tilt + Translation and Roll
tilt Translation motion profiles, the horizontal eye
movements were indistinguishable from those generated during
Translation only motion (F(2,23) = 2.1; p > 0.05). In fact, their amplitude and phase
were always appropriate for gaze compensation during head
translation.
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Figure 4.
Translational (horizontal) VOR as a function of
stimulus type in labyrinthine-intact animals. Mean ± SD peak
horizontal eye velocity from four monkeys with intact semicircular
canals, tested at 1, 0.5, and 0.16 Hz (stimulus parameters are shown in
Table 1A). Note that primate VOR correctly
discriminates between tilt and translation at all tested
frequencies.
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Tilt-translation discrimination in canal-plugged animals
As shown in Figures 5 and
6, results were different in
canal-inactivated animals. Figure 5 illustrates responses from an
animal acutely after canal plugging. Data from both
canal-plugged animals have been summarized for all tested frequencies
in Figure 6, A and B, respectively. Responses to
two stimuli were of particular interest. First, during Roll tilt
only stimulation, a robust horizontal response component was
observed in canal-plugged, but not labyrinthine-intact, animals. In
fact, the horizontal responses in canal-plugged animals were
indistinguishable during Translation only and Roll
tilt only motions (F(1,22) = 3.78;
p > 0.05). Second, horizontal responses differed for
each of the Translation only, Roll tilt + Translation, and Roll tilt Translation motion
profiles (F(2,32) = 115.5; p  0.05). Most
noticeably, in the Roll tilt Translation stimulus condition, horizontal slow phase velocity was negligible, as was the
resultant IA acceleration (Fig. 5).
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Figure 5.
Tilt-translation discrimination after all
semicircular canals were inactivated by plugging the canal lumen.
Responses, stimuli, and figure organization as in Figure 2. Note that
there is no horizontal response during Roll tilt Translation motion (IA acceleration, 0G).
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Figure 6.
Translational (horizontal) VOR as a function of
stimulus type in two canal-plugged animals. Mean ± SD peak
horizontal eye velocity elicited during lateral translation and/or roll
tilt oscillations at 1, 0.5, and 0.16 Hz. Notice the large differences
when compared with labyrinthine-intact animals (Fig. 4), particularly
during Roll only and Roll tilt Translation stimuli.
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Different tilt-translation combinations
To further corroborate these results, the tilt-translation
combination protocols were expanded at 0.5 Hz in two different ways
(Table 1B). First, peak roll oscillation amplitude
was kept constant (21.8°, corresponding to a peak gravitational
acceleration component of 0.37G along the IA axis), whereas peak sled
oscillation amplitude varied. Second, peak sled oscillation amplitude
was kept constant (0.4G), whereas peak roll oscillation amplitude varied. In both sets of protocols, the resultant IA acceleration was
identical, because it varied between 0 and 0.74G (in steps of 0.09G).
Data from all three labyrinthine-intact and the two canal-plugged
animals tested have been summarized in Figures
7 and 8,
A and B in both figures, respectively. As peak
translational acceleration increased, peak horizontal eye velocity in
labyrinthine-intact animals also increased in a linear manner, such
that it was zero when fIA,peak was 0G (and IA
acceleration was 0.37G) and maximal (minimal) when
fIA,peak was ±0.37G (Fig. 7A). In
contrast, as the peak gravitational acceleration component along the IA
axis was changed and as long as translational acceleration remained the
same, horizontal eye velocity in labyrinthine-intact animals remained
constant and independent of peak roll oscillation amplitude (Fig.
8A). These data clearly demonstrate that the
horizontal eye movements elicited during any combination of roll tilt
and translation in labyrinthine-intact primates precisely follows the
translational rather than either the resultant or gravitational component of acceleration.
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Figure 7.
Combined roll-translational motion stimuli.
Constant peak amplitude roll oscillations (o = 21.8°)
were paired with varying peak amplitude and in phase or out of phase
translational oscillations (Table 1B). As peak
translational acceleration amplitude (f)
was varied between 0 and ±0.37G, the resultant IA acceleration changed
between 0 and 0.74G. Horizontal slow phase velocity has been separately
plotted for three intact (A) and two
canal-plugged (B) animals (different
symbols are used for different animals). Open
symbols, Data obtained during pure translational motion
(0.37G).
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Figure 8.
Combined roll-translational motion stimuli.
Constant peak amplitude translational oscillations (39.4 cm; i.e.,
fo = 0.4G) were paired with varying peak
amplitude, in phase or out of phase roll oscillations (Table
1B), such that the resultant IA acceleration
varied between 0 and 0.74G. Horizontal slow phase velocity has been
separately plotted for three intact (A) and two
canal-plugged (B) animals (different
symbols are used for different animals).
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Very different observations were made in canal-plugged animals. As
illustrated when Figures 7B and 8B are
compared, horizontal eye velocity exhibited the same dependencies on
linear acceleration, independently of the nature of the stimulus. In
both combination protocols, horizontal eye velocity was zero only when
the resultant IA acceleration was zero. Furthermore, the practically
indistinguishable behavior of horizontal eye velocity in Figures
7B and 8B suggests that horizontal eye
movements in canal-plugged animals are elicited in response to the
resultant IA acceleration, with no functional distinction between tilt
and translation. There was a nonlinear dependence of horizontal eye
velocity on acceleration, exhibiting saturating characteristics at high
IA acceleration levels. Horizontal eye velocity responses generated
during pure translation (peak acceleration of 0.37G) have been
superimposed in Figure 7B (open symbols). These
data points fall approximately on the second order regression line
drawn through the combination responses.
In a third protocol, the phase () of the translation relative to the
roll tilt was varied. As shown in Figure
9B, amplitude and phase of
horizontal eye velocity as a function of was predicted to differ,
depending on whether the relevant stimulus was translational acceleration (f) or resultant IA acceleration
(Eqs. 1, 2). Comparison of the observed peak horizontal eye velocity
amplitude and phase as a function of the relative phase between tilt
and translation strongly suggests different encoding of linear
acceleration in intact and canal-plugged animals. When semicircular
canals were intact and functional, the peak horizontal eye velocity
depended on relative phase according to a relationship that resembled
the translational acceleration dependence. In contrast, horizontal eye
velocity was clearly characterized by IA acceleration-dependent behavior when the semicircular canals were inactivated (Fig.
9A).
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Figure 9.
Combined roll-translational motion
stimuli. Constant peak amplitude roll oscillations (o = 21.8°) were paired with constant peak amplitude translational
oscillations (39.8 cm; i.e., fo = 0.4G) and
variable phase. A, Mean ± SD horizontal slow phase
velocity amplitude and phase from intact animals (open
circles) are compared with data from two canal-plugged animals
(filled circles and squares).
B, Theoretical predictions of the dependence of the
resultant and the translational component of acceleration along the IA
axis, according to Equations 1 and 2 (solid and
dotted lines, respectively).
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Transient tilt-translation stimuli
These observations regarding the role of semicircular canals in
the correct discrimination of translational motion were independent of
vergence angle. In fact, responses to transient head translation-roll tilt stimuli delivered as the animals maintained large vergence angles
further corroborated these findings. Figure
10 plots binocular horizontal eye
position and velocity recorded during transient motion profiles that
were delivered immediately after fixation on a near, central visual
target located 20 cm from the eyes (vergence of ~10°). The stimulus
consisted of a quick roll tilt toward the right ear combined with a
transient lateral displacement to the right, which was associated with
a nearly zero acceleration along the IA axis (Roll tilt Translation condition) (Fig. 10). The elicited horizontal eye
movements before and after semicircular canal inactivation clearly
differed. Whereas robust leftward horizontal responses were elicited in
the intact animal, negligible horizontal eye movements were observed in
the same animal after all semicircular canals had been inactivated.
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Figure 10.
Transient Roll tilt Translation motion profiles in an animal with intact and
inactivated semicircular canals (SCC). The stimulus
consisted of a subtractive combination of a 15° roll tilt toward the
animal's right ear and linear translation to the right. Horizontal eye
position (top) and eye velocity (middle)
of both the right and left eyes (mean ± SD; left,
nine trials; right, 26 trials). Dotted
lines are zero eye position (straight-ahead gaze) and zero eye
velocity. Bottom, Translational component and resultant
IA acceleration measured as the outputs of two linear accelerometers
mounted on the linear sled and on the animal's head, respectively. The
IA acceleration trace was not measured for the Inactivated
SCC plot and is therefore duplicated from the Intact
SCC condition.
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DISCUSSION |
The problem of sensorimotor discrimination between inertial
(translational) and gravitational components of linear acceleration has
been a long-debated issue in motor control and inertial navigation. This study shows that not only otolith but also semicircular canal signals are necessary sensory cues for the appropriate discrimination between different sources of linear acceleration. Therefore, the oculomotor system discriminates between head translation and tilt primarily by sensory integration rather than frequency segregation of
otolith afferent information.
The central vestibular system correctly detects
translational motion
Because of the inherent ambiguity associated with
afferent coding of linear acceleration, it has often been implied that
the oculomotor system (and motor systems in general) is bound by
similar limitations. Based on responses obtained during translational oscillations between 0.5 and 4 Hz, for example, Paige and Tomko (1991a)
and Telford et al. (1997) proposed that horizontal and torsional
responses are always elicited simultaneously during both translation
and tilt, as if responding to the resultant acceleration. Accordingly,
otolith response ambiguity can only partially be resolved through
central parsing of linear accelerations on the basis of frequency
content. However, a direct test of this proposal was never performed.
Our results provide strong evidence in contrast to this interpretation,
at least for the frequency range important for VOR compensation during
movement (i.e., >0.1 Hz) (Angelaki, 1998). For all
tilt-translation combination protocols, the direction and magnitude of
the horizontal response of intact animals remained compensatory to the
translational component of linear acceleration and was related neither
to the acceleration produced by the roll tilt nor to the resultant IA
acceleration. This was particularly striking for the Roll
tilt Translation protocols in which the resultant IA
acceleration was zero, yet robust horizontal eye movements were generated.
Inactivation of semicircular canals compromises accurate
detection of translational motion
The multisensory integration hypothesis predicts that both
semicircular canal and otolith signals are needed for appropriate detection of the translational component of motion. In the absence of
functional semicircular canal signals, correct motion discrimination would be compromised by interpreting the resultant IA acceleration as
the translational stimulus. Conversely, if otolith signals were simply
filtered, as the frequency-segregation hypothesis predicts, elimination
of semicircular canal signals should have no effect on the ability of
the vestibulo-ocular system to detect head translation.
The results from animals with inactivated semicircular canals clearly
demonstrated that accurate discrimination between the translational and
tilt components of motion was no longer possible. In fact, the elicited
horizontal eye movements were always proportional to the resultant IA
acceleration. The need for functional semicircular canal signals in the
central processing of linear accelerations was further demonstrated by
the experiments in which the relative phase of the two stimuli and
either the translational or the gravitational component of acceleration
was varied separately (Figs. 7-9). Noticeably, a nonlinear
dependence of horizontal eye velocity on IA acceleration amplitude
was observed in the plugged animals (Figs. 7B,
8B). A similar amplitude nonlinearity has been
described in primary otolith afferents above ~0.4-0.5G
(Fernández and Goldberg, 1976). Interestingly, no such amplitude
nonlinearity was seen in animals with intact labyrinths (Fig.
7A), although it is possible that primary afferents may have
been driven into saturation.
Because translational VOR sensitivity strongly depends on viewing
distance (Paige and Tomko, 1991b; Schwarz and Miles, 1991; Telford et
al., 1997), the main stimulus combinations were also tested during
short-lasting transient motion, immediately after satisfactory fixation
on a near, centered target. The differences in the horizontal eye
movements between labyrinthine-intact and canal-plugged primates were
even more provocative when viewing distance was controlled (Fig. 10).
Despite robust horizontal eye movements during the Roll tilt Translation motion profile during near target fixation in
labyrinthine-intact animals, no horizontal translational response was
generated in canal-inactivated animals when the resultant linear
acceleration along the IA axis was zero. These results demonstrate that
in the absence of functional signals from the semicircular canals and
with all other sensory inputs essentially unchanged before and
after canal inactivation, any linear acceleration component along
the IA axis will be centrally interpreted as translational motion
and generate a horizontal (translational) VOR.
Nonlinear processing of vestibular afferent signals:
neural computations to resolve tilt-translation ambiguity
A fundamental question that arises from these results
relates to the computational mechanisms used by the brain to
discriminate the source of linear acceleration and to correctly detect
head translation. Semicircular canal signals could contribute to the discrimination of head motion according to either one of the following principles. First, central integration of head angular velocity signals
from the semicircular canals could be used to estimate the change in
angular head orientation relative to gravity. For example, the inertial
component that is caused by head translation (vector
f) during a combined sinusoidal roll tilt plus
translational motion could be extracted from the resultant otolith
signal (vector ) by estimating the roll motion via integration
of the roll velocity signal [vector = (x, 0, 0)], oriented along the head roll axis). Thus:
|
(3)
|
with
describing roll tilt (re: gravity) as a function of time. In a
more general case integration of 3-D angular velocity is more complex
(e.g., Hess and Angelaki, 1997).
Second, a similar computational scheme utilizes angular velocity
information from the semicircular canals (vector ), as well as
static and dynamic linear acceleration information from otolith afferents (vectors and  = d/dt). Based on the fact that the resultant linear acceleration is equal to the vectorial sum of translational and gravitational components, i.e., = f + g, and on the relationship
dg/dt =  = × g (where × denotes the vector cross-product), which
describes the rate of change of gravity, the translational component of
acceleration (f) can be easily computed by
solving the following differential equation (Viéville and
Faugeras, 1990; Hess and Angelaki, 1997):
|
(4)
|
Despite its apparent complexity, Equation 4 could be easily
implemented in the CNS through signal convergence between angular velocity (, from semicircular canal afferents), as well as static and dynamic linear acceleration ( and , extracted from
otolith afferents). The simplest neural network that could implement
Equation 4 has been illustrated in Figure
11 and requires a minimum of four distinct "vector" neurons. The first two perform multiplicative interaction of their inputs, and the third is assumed to linearly summate its inputs. The fourth neuron functions as a neural integrator. Such computational steps have been often proposed to occur within single neurons or assemblies of neurons (Torre and Poggio, 1978; Koch
et al., 1983; Shen, 1989). Furthermore, head angular velocity signals
(), as well as both linear acceleration () and its time derivative () signals have been shown to coexist in single
vestibular brainstem neurons (Angelaki et al., 1993).
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Figure 11.
A four-neuron network, the simplest model that
would implement the computations described by the differential Equation 4. SSC, Primary semicircular canal afferents;
, , static and dynamic
otolith signals, respectively; x,
 ,  , vector multiplication,
summation, and signal integration, respectively.
|
|
These computational schemes and the conclusions reached based on the
results of this study are only pertinent to frequencies higher than 0.1 Hz in which semicircular canal afferents can provide veridical
information about head angular velocity. Below ~0.05-0.1 Hz,
however, semicircular canal signals are no longer accurate detectors of
head velocity. Several solutions and models have been proposed to
account for low-frequency tilt-translational discrimination (e.g.,
Glasauer and Merfeld, 1997) and remain to be further tested experimentally.
Detection of inertial motion: a fundamental sensorimotor task
Living and moving in a gravitational field places particular
computational demands on inertial motion estimation. Although the
peripheral sensory transduction of motion is dictated and bound by the
laws of physics, the brain can use multisensory information to
interpret sensory afferent signals and compute inertial motion. Specifically, the issue of inertial navigation and movement control has
been long recognized as a major computational task for both biological
and man-made inertial guidance systems (Fernandez and Macomber, 1962;
Barlow, 1964; Beritoff, 1965; Mayne, 1969a,b). The vestibular
labyrinths, like inertial guidance systems, are equipped with a set of
3-D linear accelerometers (otolith organs) and a set of 3-D angular
accelerometers with built-in integrators that accurately detect head
angular velocity in a wide frequency range (semicircular canals). The
challenging computational task arises when these two independent sets
of signals get combined to compute motion in space. Accurate separation
of the resultant acceleration () into the translational and
gravitational components (f and g,
respectively) comprises only one, but perhaps the most important,
computational demand (Fig. 12).
Inertial control of movement requires that, in addition, absolute
angular motion in space be computed. Because primary semicircular canal
afferents only code for a relative, head-fixed velocity vector (),
estimation of inertial velocity (s) requires a
second processing stage that uses the gravitational estimate
(g) to transform primary semicircular canal
signals into space-referenced angular motion estimates (Fig. 12).
Indeed, inertial velocity has been shown to be computed within the
central vestibular system (Angelaki and Hess, 1994, 1995; Angelaki et
al., 1995; Hess and Angelaki, 1997).
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Figure 12.
Schematic diagram summarizing the two
main computations necessary to transform primary vestibular signals
into inertial motion parameters. Angular velocity signals from the
semicircular canals () are used to segregate the resultant linear
acceleration signals coded by primary otolith afferents () into
gravitational (g, orientation) and translational
(f) components. Gravitational estimates are
also used to transform head-fixed angular velocity signals from the
semicircular canals () into inertial velocity, i.e.,
space-referenced angular velocity (S) (Angelaki
and Hess, 1994, 1995, 1996b).
|
|
| |
FOOTNOTES |
Received July 2, 1998; revised Oct. 7, 1998; accepted Oct. 12, 1998.
This work was supported by National Institutes of Health Grant EY10851,
Air Force Office of Scientific Research Grant F49620, and Swiss
National Science Foundation Grant 31-47287.96.
Correspondence should be addressed to Dr. Dora Angelaki, Department of
Surgery (Otolaryngology), University of Mississippi Medical Center,
2500 North State Street, Jackson, MS 39216-4505.
| |
APPENDIX |
Assuming a combined tilt-translation motion in which the roll
oscillation amplitude is described as (t) = o · sin(t), and the translational
acceleration during linear motion is described as
tr = o · sin(t + ) where is the relative phase between the
two stimuli, the components of the gravitational and translation acceleration vectors in space- and head-fixed coordinates (Fig. 13) are as follows (in G units, G = 9.81 m/sec2):
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Figure 13.
Tilt-translation paradigm. x,
y, z, Head-fixed coordinates.
X, Y, Z, Space-fixed
coordinates. , Roll tilt angle (about the x-axis).
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|
Gravity vector g:
in space-fixed coordinates:
gx = 0
gy = 0
gz = 1
in head-fixed coordinates (tilted by the angle relative to
space):
gx = 0
gy = sin()
gz = cos()
Translational acceleration f:
in space-fixed coordinates:
fx = 0
fy = fo
sin(t + )
fz = 0
in head-fixed coordinates:
fx = 0
fy = fo
sin(t + )cos()
fz = fo
sin(t + )sin()
Acceleration a (in head-fixed coordinates):
ax = fx + gx = 0
ay = fy + gy = fo
sin(t + )cos() sin() (resultant IA acceleration)
az = fz + gz = fo
(t + )sin() cos()
Condition for cancellation of IA acceleration:
ay = 0 = fo
sin(t + )cos() sin()
Thus,
tan() = tan (o sin(t)) = fo sin(t + )
approximation for small o:
tan(o)  o fo
| |
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R. G. Kaptein and J. A.M. Van Gisbergen
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J Neurophysiol,
March 1, 2006;
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D. M. Merfeld, S. Park, C. Gianna-Poulin, F. O. Black, and S. Wood
Vestibular Perception and Action Employ Qualitatively Different Mechanisms. I. Frequency Response of VOR and Perceptual Responses During Translation and Tilt
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D. M. Merfeld, S. Park, C. Gianna-Poulin, F. O. Black, and S. Wood
Vestibular Perception and Action Employ Qualitatively Different Mechanisms. II. VOR and Perceptual Responses During Combined Tilt&Translation
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B. J. M. Hess, K. Jaggi-Schwarz, and H. Misslisch
Canal-Otolith Interactions After Off-Vertical Axis Rotations. II. Spatiotemporal Properties of Roll and Pitch Postrotatory Vestibuloocular Reflexes
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R. J. Peterka, C. C. Gianna-Poulin, L. H. Zupan, and D. M. Merfeld
Origin of Orientation-Dependent Asymmetries in Vestibulo-Ocular Reflexes Evoked by Caloric Stimulation
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October 1, 2004;
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A. M. Green and D. E. Angelaki
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D. E. Angelaki
Eyes on Target: What Neurons Must do for the Vestibuloocular Reflex During Linear Motion
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July 1, 2004;
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R. J. Peterka and P. J. Loughlin
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January 1, 2004;
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A. M. Green and D. E. Angelaki
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J. D. Crawford, D. B. Tweed, and T. Vilis
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L. H. Zupan and D. M. Merfeld
Neural Processing of Gravito-Inertial Cues in Humans. IV. Influence of Visual Rotational Cues During Roll Optokinetic Stimuli
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J. D. Dickman and D. E. Angelaki
Vestibular Convergence Patterns in Vestibular Nuclei Neurons of Alert Primates
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D. E. Angelaki, S. D. Newlands, and J. D. Dickman
Inactivation of Semicircular Canals Causes Adaptive Increases in Otolith-Driven Tilt Responses
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D. M. Merfeld and L. H. Zupan
Neural Processing of Gravitoinertial Cues in Humans. III. Modeling Tilt and Translation Responses
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W. P. Medendorp, J.A.M. Van Gisbergen, and C.C.A.M. Gielen
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B. J. M. Hess
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D. M. Merfeld, L. H. Zupan, and C. A. Gifford
Neural Processing of Gravito-Inertial Cues in Humans. II. Influence of the Semicircular Canals During Eccentric Rotation
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L. H. Zupan, R. J. Peterka, and D. M. Merfeld
Neural Processing of Gravito-Inertial Cues in Humans. I. Influence of the Semicircular Canals Following Post-Rotatory Tilt
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D. E. Angelaki and J. D. Dickman
Spatiotemporal Processing of Linear Acceleration: Primary Afferent and Central Vestibular Neuron Responses
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A. D. Van Beuzekom and J.A.M. Van Gisbergen
Properties of the Internal Representation of Gravity Inferred From Spatial-Direction and Body-Tilt Estimates
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D. E. Angelaki, S. D. Newlands, and J. D. Dickman
Primate Translational Vestibuloocular Reflexes. IV. Changes After Unilateral Labyrinthectomy
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D. E. Angelaki, M. Q. McHenry, and B. J. M. Hess
Primate Translational Vestibuloocular Reflexes. I. High-Frequency Dynamics and Three-Dimensional Properties During Lateral Motion
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D. E. Angelaki, M. Q. McHenry, J. D. Dickman, and A. A. Perachio
Primate Translational Vestibuloocular Reflexes. III. Effects of Bilateral Labyrinthine Electrical Stimulation
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S. I. Perlmutter, Y. Iwamoto, J. F. Baker, and B. W. Peterson
Spatial Alignment of Rotational and Static Tilt Responses of Vestibulospinal Neurons in the Cat
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Top
Abstract
Introduction
