Back To Search Results

Oculovestibular Reflex

Editor: Koushik Tripathy Updated: 11/7/2022 1:03:13 PM

Definition/Introduction

Precise eye movement control is necessary to obtain a fine resolution of the visual field during motion, either self–motion (translational or rotational) or object motion. These oculomotor movements are controlled at various levels, from end-organ (retinal and extraretinal sources) to supranuclear foci (motor planning stage).

Head movements during routine activities include angular rotation and linear acceleration. The oculomotor system maintains the gaze fixed in space during these head movements using the vestibulo–ocular reflex (by semicircular canals) and the ocular counter-rolling reflex (by otoliths). Vestibulo–ocular reflex is an involuntary reflex that stabilizes the visual field and retinal image during head motion by producing eye movements in a counter direction. 

Reflex arc involved in the maintenance of a stable visual field includes:

  • Extraretinal signals about head motion
  • Retinal signals
  • Neurocontrol of stabilization reflexes
  • Motor apparatus - extraocular muscles

Extraretinal Signals

The vestibular system consists of semicircular canals that transduce angular motion as occurs during rotation of the head and otoliths (utricle and saccule), which transduce linear motion of the head as during head tilt and roll.[1]

Angular acceleration of the head stimulates the hair cells of semicircular canals and results in eye rotations that are roughly equal and opposite the head's motion; this stabilization reflex has a brief latency of 7 to 15 msec and is accurate for head turns at velocities over 300 deg/sec.[2] Head rotations about the horizontal, vertical, and nasal–occipital axes produce vestibulo–ocular reflexes with horizontal, vertical, and torsional counter-rotations of the eye, seen as the slow phase of the nystagmus.[3]

These reflex eye movements must maintain a stable retinal image to be effective. However, the axis of rotation of the head is the neck and not the center of the eye; hence, the eye rotates and translates as well. This is exacerbated during near vision; hence, the gain of the vestibulo-ocular reflex increases with convergence, leading to more eye movement than head movement.[4]

However, the vestibulo–ocular reflexes are far from perfect, and yet the objects appear stable during head rotation without oscillopsia. This indicates that supranuclear foci of the visual system anticipate residual retinal image motion occurring due to the inaccuracy of the compensatory eye movements during head rotation and correct for it.

Retinal Signals

Head rotation also produces retinal image motion of the visual field, stimulating reflex eye movements with a slow phase following the moving field interrupted by resetting saccades. This reflex is known as optokinetic nystagmus, which complements the vestibulo–ocular reflex during low-velocity sustained head movements such as walking.[5]

Neuro-control of Stabilization Reflexes

The 3 semicircular canals are the end organs converting the head motion signals into a neural stimulus driving vestibulo–ocular reflex. The hair cells in the horizontal canals undergo depolarization when the endolymph moves toward the ampulla and vice versa in vertical canals. One side's anterior semicircular canal pairs with the other's posterior semicircular canal. They act as opponent pairs such that stimulation of 1 canal causes inhibition of the opponent canal. The 3 semicircular canals lie in the same plane as the extraocular muscles. Thus, the horizontal semicircular canals lie in the plane of the lateral and medial recti; the left anterior semicircular canal and right posterior semicircular canal are parallel to the muscle planes of the left eye vertical recti and the right eye obliques and vice versa.[6] Each canal excites a pair of muscles and inhibits a pair of muscles in its plane; its partner excites the muscles it inhibits and vice versa.

For example, impulses from the left medial vestibular nucleus pass via the right abducens nucleus, causing abduction of the right eye and the left eye's medial rectus via the oculomotor nucleus (via the interneuron connecting the abducens and oculomotor nucleus), causing left eye adduction, leading to conjugate eye movements.

Motor Apparatus

The 4 recti muscles and 2 oblique muscles perform eyeball movements depending on the stimulation of semicircular canals and otoliths. 

Issues of Concern

Register For Free And Read The Full Article
Get the answers you need instantly with the StatPearls Clinical Decision Support tool. StatPearls spent the last decade developing the largest and most updated Point-of Care resource ever developed. Earn CME/CE by searching and reading articles.
  • Dropdown arrow Search engine and full access to all medical articles
  • Dropdown arrow 10 free questions in your specialty
  • Dropdown arrow Free CME/CE Activities
  • Dropdown arrow Free daily question in your email
  • Dropdown arrow Save favorite articles to your dashboard
  • Dropdown arrow Emails offering discounts

Learn more about a Subscription to StatPearls Point-of-Care

Issues of Concern

Since there is fine involuntary head motion even when the person is still, there is a required reflex eye movement to maintain a stable visual field and maximize visual potential. This occurs using various involuntary reflexes, such as vestibulo–ocular reflex and optokinetic nystagmus. This accommodation is of particular importance in high-demand situations such as sports-related activities.

Clinical Significance

Disruption of vestibulo–ocular reflex results in symptoms such as nausea, head tilt, imbalance during walking and other daily life activities, dizziness, oscillopsia, and blurred vision during motion. The vestibulo–ocular reflex is testable using various examinations, including head impulse testing, rotational chair testing, velocity step test, impulse angular acceleration, and caloric reflex test. In the caloric reflex test, the examiner irrigates the external auditory canal with 20 to 40 ml of ice water, leading to slow movements of the eyes towards the ear irrigated and corrective horizontal nystagmus towards the contralateral ear under normal physiological conditions.[7] This reflex, however, becomes damaged in brain stem injury.

Nursing, Allied Health, and Interprofessional Team Interventions

Any patient presenting with dizziness or imbalance requires evaluation, looking at both systemic conditions such as hypoglycemia, transient ischemic attack, or end-organ damage such as vestibular damage or trauma to limbs etc. Simple bedside tests such as the caloric reflex test and auditory symptoms such as tinnitus or hearing defects act as a pointer towards a defect in the vestibulo-ocular reflex. Vestibular rehabilitation, with or without medication, can help the patient depending on the underlying condition.[8] The examiner should direct proper attention to history taking, particularly in eliciting medication use such as aminoglycosides, macrolides, etc.[9]

References


[1]

Khan S, Chang R. Anatomy of the vestibular system: a review. NeuroRehabilitation. 2013:32(3):437-43. doi: 10.3233/NRE-130866. Epub     [PubMed PMID: 23648598]

Level 3 (low-level) evidence

[2]

Keller EL. Gain of the vestibulo-ocular reflex in monkey at high rotational frequencies. Vision research. 1978:18(3):311-5     [PubMed PMID: 96591]

Level 3 (low-level) evidence

[3]

Seidman SH, Leigh RJ. The human torsional vestibulo-ocular reflex during rotation about an earth-vertical axis. Brain research. 1989 Dec 18:504(2):264-8     [PubMed PMID: 2598028]


[4]

Snyder LH,King WM, Effect of viewing distance and location of the axis of head rotation on the monkey's vestibuloocular reflex. I. Eye movement responses. Journal of neurophysiology. 1992 Apr;     [PubMed PMID: 1588387]

Level 3 (low-level) evidence

[5]

Cheng M, Outerbridge JS. Optokinetic nystagmus during selective retinal stimulation. Experimental brain research. 1975 Aug 14:23(2):129-39     [PubMed PMID: 1183500]


[6]

Cox PG, Jeffery N. Geometry of the semicircular canals and extraocular muscles in rodents, lagomorphs, felids and modern humans. Journal of anatomy. 2008 Nov:213(5):583-96. doi: 10.1111/j.1469-7580.2008.00983.x. Epub     [PubMed PMID: 19014365]

Level 3 (low-level) evidence

[7]

Shepard NT, Jacobson GP. The caloric irrigation test. Handbook of clinical neurology. 2016:137():119-31. doi: 10.1016/B978-0-444-63437-5.00009-1. Epub     [PubMed PMID: 27638067]


[8]

Han BI,Song HS,Kim JS, Vestibular rehabilitation therapy: review of indications, mechanisms, and key exercises. Journal of clinical neurology (Seoul, Korea). 2011 Dec;     [PubMed PMID: 22259614]


[9]

Bisht M, Bist SS. Ototoxicity: the hidden menace. Indian journal of otolaryngology and head and neck surgery : official publication of the Association of Otolaryngologists of India. 2011 Jul:63(3):255-9. doi: 10.1007/s12070-011-0151-8. Epub 2011 Feb 23     [PubMed PMID: 22754805]