The functions of the proprioceptors of the eye muscles

Donaldson, I M L

doi:10.1098/rstb.2000.0732

Cited by 173 publications

(145 citation statements)

References 233 publications

(526 reference statements)

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“…These observations would fit with a model where proprioception, although not used for visual localization, calibrates over the long term the forward model which estimates the consequences of the oculomotor command (Steinbach, 1986). Because these two sets of experiments were performed in different species with known differences in the eye proprioceptive system (e.g., extraocular muscle spindles are absent in the monkey but present in humans; Donaldson, 2000), interspecies differences could have been responsible for the apparent contradiction between their conclusions. Another possible source of discrepancy is the concern that in the experiment by Lewis et al (1998), despite the bilateral section of the trigeminal nerves, sufficient proprioceptive input could reach the CNS via the oculomotor nuclei, which have recently been suggested to receive sensory input from the pallisade endings (Lienbacher et al, 2011).…”

Section: Discussionmentioning

confidence: 99%

Eye Proprioception Used for Visual Localization Only If in Conflict with the Oculomotor Plan

Balslev¹,

Himmelbach²,

Karnath³

et al. 2012

Journal of Neuroscience

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Both the corollary discharge of the oculomotor command and eye muscle proprioception provide eye position information to the brain. Two contradictory models have been suggested about how these two sources contribute to visual localization: (1) only the efference copy is used whereas proprioception is a slow recalibrator of the forward model, and (2) both signals are used together as a weighted average. We had the opportunity to test these hypotheses in a patient (R.W.) with a circumscribed lesion of the right postcentral gyrus that overlapped the human eye proprioceptive representation. R.W. was as accurate and precise as the control group (n ϭ 19) in locating a lit LED that she viewed through the eye contralateral to the lesion. However, when the task was preceded by a brief (Ͻ1 s), gentle push to the closed eye, which perturbed eye position and stimulated eye proprioceptors in the absence of a motor command, R.W.'s accuracy significantly decreased compared with both her own baseline and the healthy control group. The data suggest that in normal conditions, eye proprioception is not used for visual localization. Eye proprioception is, however, continuously monitored to be incorporated into the eye position estimate when a mismatch with the efference copy of the motor command is detected. Our result thus supports the first model and, furthermore, identifies the limits for its operation.

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Section: Discussionmentioning

confidence: 99%

Eye Proprioception Used for Visual Localization Only If in Conflict with the Oculomotor Plan

Balslev¹,

Himmelbach²,

Karnath³

et al. 2012

Journal of Neuroscience

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“…Thus, our data show that our bipolar EMG recordings were sufficiently selective to exclude picking up responses of non-extraocular muscles. In addition, reflex reactions of non-extraocular muscles to eye rotations are reported to occur when the latter are combined with some other stimulation such as passive rotation of the head (Donaldson 2000), which was not the case in our experiments-our animals were anesthetized and immobilized in a stereotaxic frame. Therefore, it is also doubtful that reflex responses of neck or jaw muscles to eye rotations occurred in our animals.…”

Section: Discussionmentioning

confidence: 99%

“…Although interesting, such an experiment faces theoretical and technical challenges. Indeed, the pathway of EOM afferents has been a matter of extensive debate (for review see Donaldson 2000). When these afferent signals leave the EOM through the oculomotor nerves, they become intermixed with motor fibers (Cooper et al 1955).…”

Section: Discussionmentioning

confidence: 99%

“…It is known that stretching eye muscles evokes a sensory stimulus that could produce a synchronized response in neck or jaw muscles (Donaldson 2000;Ruskell 1999). It could be suggested that our electrodes were not sufficiently selective and picked up EMG signals from non-extraocular muscles-a "cross talk" phenomenon.…”

Section: Discussionmentioning

confidence: 99%

“…They are absent in rat EOM, sparse, absent or diminutive in EOM of non-human primates (Maier et al 1974) and present in EOM of humans (Merrillees et al 1950). Although afferent signals evoked by EOM stretching are transmitted to the central nervous system (Cooper et al 1953;Fillenz 1955;Donaldson and Long 1980;Donaldson 2000), some studies have failed to demonstrate an effect of these signals on EOM motoneurons (McCouch and Adler 1932;Keller and Robinson 1971;Carpenter 1988). This has led to the conclusion that EOM have no SRs (Keller and Robinson 1971).…”

Section: Introductionmentioning

confidence: 99%

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A stretch reflex in extraocular muscles of species purportedly lacking muscle spindles

et al. 2007

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It is generally assumed that proprioceptive feedback plays a crucial role in limb posture and movement. However, the role of afferent signals from extraocular muscles (EOM) in the control of eye movement has been a matter of continuous debate. These muscles have atypical sensory receptors in several species and it has been proposed that they are not supported by stretch reXexes. We recorded electromyographic activity of EOM during passive rotations of the eye in sedated rats and squirrel monkeys and observed typical stretch reXexes in these muscles. Results suggest that there is a similarity in the reXexive control of limb and eye movement, despite substantial differences in their biomechanics and sensory receptors. Like in some limb skeletal muscles, the stretch reflex in EOM in the investigated species might be mediated by other lengthsensitive receptors, rather than muscle spindles.

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Proprioceptive Sensory Feedback

Grey

2010

Encyclopedia of Life Sciences

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Proprioceptors are sensors that provide information about orientation of the body relative to the body's orientation with respect to gravity, movement of the body relative to the external medium and movements and forces in localised regions of the body. Muscle spindles are primarily responsible for position and movement sense, Golgi tendon organs provide the sense of force and the vestibular system provides the sense of balance. Feedback from proprioceptors feedback is essential for the accurate execution of movement execution. For voluntary limb movements in primates, proprioceptive feedback can regulate the generation of motor command by correcting errors using negative feedback loops; providing timing cues about an ongoing movement to initiate commands required at a later time within a movement sequence; and by providing signals used in the planning of movements by providing information about starting limb position to set parameters of feedforward commands. Proprioceptive feedback is also required to modify motor commands slowly in response to alterations in the biomechanical properties of the limbs. Key Concepts: Proprioception is a peripherally derived kinaesthetic sense. Position and movement sense is provided by muscle spindles. Muscle tension is sensed by Golgi tendon organs. The centrally derived sense of effort gives information about force and heaviness of objects. Proprioceptors project to the motor cortex via the dorsal columns and to the cerebellum via spinocerebellar tracts. Proprioceptive information is used in the spinal regulation of rhythmic movements.

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The functions of the proprioceptors of the eye muscles

Cited by 173 publications

References 233 publications

Eye Proprioception Used for Visual Localization Only If in Conflict with the Oculomotor Plan

Eye Proprioception Used for Visual Localization Only If in Conflict with the Oculomotor Plan

A stretch reflex in extraocular muscles of species purportedly lacking muscle spindles

Proprioceptive Sensory Feedback

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