Eye movement abnormalities in corticobasal syndrome (CBS) provide important diagnostic clues that help distinguish it from other parkinsonian disorders, particularly progressive supranuclear palsy (PSP) and Parkinson's disease (PD). While PSP is characterized by vertical supranuclear gaze palsy (particularly downward), CBS shows a different pattern of oculomotor dysfunction reflecting the distinct neuroanatomical involvement of cortical and subcortical structures[@chen2020].
The eye movement findings in CBS reflect:
- Cortical dysfunction — from parietal, premotor, and supplementary motor area involvement
- Basal ganglia impairment — affecting saccade selection and initiation
- Brainstem integration deficits — disrupting ocular motor nuclei coordination
- Cerebellar contributions — affecting smooth pursuit and saccade accuracy
Square wave jerks (SWJs) are the most characteristic eye movement abnormality in CBS, present in the majority of patients[@chen2020]. These are:
- Involuntary, horizontal, jerk-like saccades away from fixation
- Brief停顿 (100-200ms) after each jerk before returning to target
- Occur at a frequency of 1-3 Hz
- Most prominent during fixation on a stationary target
Prevalence in CBS: 60-80% of patients demonstrate square wave jerks, making this one of the most sensitive eye movement markers for CBS.
Mechanism: SWJs reflect impaired fixation stability due to dysfunction in:
- Superior colliculus — abnormal burst neuron activity
- Basal ganglia output — excessive facilitation of random saccades
- Cortical inhibition deficits — from parietal and frontal cortex dysfunction
Diagnostic value: While SWJs occur in other parkinsonian disorders, their severity and frequency tend to be greater in CBS than in PD, and they appear earlier in the disease course[@r2021].
CBS patients demonstrate prolonged saccade latency (the time to initiate a saccade), reflecting:
- Impaired cortical eye field function
- Reduced transmission from frontal eye fields to brainstem saccade generators
- Basal ganglia-mediated inhibition of automatic saccades
Hypermetria (overshooting the target) is common in CBS, particularly for horizontal saccades. This reflects:
- Impaired cerebellar error correction
- Reduced feedback from saccadic eye movement circuits
- Disinhibition of the superior colliculus
Hypometria (undershooting) may occur in more advanced disease stages.
Saccade velocity is generally preserved in CBS, unlike PSP where vertical saccades are markedly slowed. This helps differentiate CBS from PSP:
- CBS: Normal or near-normal saccade velocity
- PSP: Markedly reduced vertical saccade velocity (the hallmark finding)
Impaired smooth pursuit is common in CBS due to:
- Cerebellar involvement — flocculus and paraflocculus dysfunction
- Parietal lobe contributions — impaired visual motion processing
- Brainstem integration deficits — faulty sensorimotor transformation
Characteristics:
- Catch-up saccades during pursuit of moving targets
- More pronounced for horizontal than vertical pursuit
- Correlation with overall disease severity
Beyond square wave jerks, fixation abnormalities in CBS include:
- Reduced blink rate — contributing to corneal exposure
- Impaired convergence — especially with parietal involvement
- Difficulty maintaining eccentric fixation — reflecting cortical dysfunction
While square wave jerks are the most prominent fixation instability in CBS, several other saccadic intrusion patterns may be observed:
Glissades are small, quick saccades that occur at the end of a primary saccade, representing incomplete deceleration:
- Characteristics: Small amplitude (0.5-3°), horizontal, often in the direction of the primary saccade
- Prevalence: Common in CBS, present in up to 40% of patients
- Pathophysiology: Reflects impaired cerebellar-mediated saccade termination
- Clinical significance: More prominent in CBS than in PD, correlates with cerebellar involvement
Macrosaccadic oscillations are repetitive, symmetrical saccades that oscillate around the target:
- Characteristics: Large amplitude (5-15°), horizontal or vertical, occur in bursts
- Prevalence: Less common than SWJs, seen in ~20% of CBS patients
- Pathophysiology: Dysfunction in the cerebellar fastigial nucleus and oculomotor vermis
- Clinical significance: Suggests significant cerebellar pathway involvement
¶ Ocular Flutter and Opsoclonus
Ocular flutter and opsoclonus represent more severe saccadic intrusion syndromes:
- Ocular flutter: Continuous horizontal oscillations without an interposed pause (2-8 Hz)
- Opsoclonus: Multidirectional chaotic saccades (horizontal, vertical, torsional)
- Prevalence: Rare in idiopathic CBS, more common in paraneoplastic or autoimmune variants
- Pathophysiology: Brainstem burst neuron dysfunction, may involve superior colliculus
- Clinical significance: When present, warrants investigation for underlying etiology (paraneoplastic, neuroblastoma)
| Intrusion Type |
Prevalence in CBS |
Anatomical Substrate |
Clinical Correlation |
| Square wave jerks |
60-80% |
Superior colliculus, basal ganglia |
Most common, early marker |
| Glissades |
30-40% |
Cerebellar fastigial nucleus |
Cerebellar involvement |
| Macrosaccadic oscillations |
15-20% |
Cerebellar vermis |
Significant cerebellar pathology |
| Ocular flutter/opsoclonus |
<5% |
Brainstem burst neurons |
Consider paraneoplastic |
The pattern and severity of saccadic intrusions can provide insight into the underlying pathological substrate and help guide diagnostic workup, particularly when atypical features suggest alternative etiologies.
Vergence eye movements enable single, binocular vision at different viewing distances by adjusting the alignment of both eyes. CBS frequently affects these complex movements:
Convergence insufficiency is the most common vergence abnormality in CBS:
- Prevalence: Present in 50-70% of CBS patients
- Symptoms: Diplopia (double vision), especially during close work; eyestrain; headache; difficulty reading
- Findings:
- Reduced near point of convergence (NPC > 10 cm)
- Exodeviation at near (outward eye turn)
- Reduced convergence amplitudes (< 15 prism diopters)
- Pathophysiology:
- Midbrain dysfunction affecting convergence integrator
- Parietal cortex involvement in visual attention to near targets
- Basal ganglia impairment of vergence control
- Management: Prism glasses, vision therapy, botulinum toxin for severe cases
Divergence excess presents with:
- Exodeviation at distance (outward deviation) that reduces at near
- Typically less common than convergence insufficiency in CBS
- May be asymmetric, reflecting the unilateral cortical involvement typical of CBS
Even when basic vergence amplitudes are preserved, CBS patients may exhibit:
- Reduced fusional vergence ranges — inability to maintain single vision despite adequate amplitude
- Instability — fluctuating convergence during sustained near tasks
- Fatigability — worsening performance with prolonged near work
Bedside vergence testing should include:
- Near point of convergence — measure closest clear single vision
- Cover test — identify latent eye deviations
- Prism and alternate cover — quantify magnitude of deviation
- Vergence amplitudes — base-in and base-out prisms at distance and near
¶ Comparison with PSP and PD
| Feature |
CBS |
PSP |
PD |
| Square wave jerks |
Prominent (60-80%) |
Moderate (40-60%) |
Mild-moderate |
| Vertical saccade slowing |
Absent |
Marked (downward > upward) |
Absent |
| Saccade accuracy |
Hypermetria common |
Variable |
Typically normal |
| Smooth pursuit |
Impaired |
Severely impaired |
Preserved early |
| Gaze palsy |
Rare |
Vertical supranuclear gaze palsy |
None |
The absence of vertical supranuclear gaze palsy in CBS is the most important diagnostic distinction from PSP[@bjo2019]. PSP patients demonstrate:
- Inability to voluntarily move eyes vertically (especially downward)
- Reflexive eye movements are preserved (demonstrating supranuclear nature)
- "Rocket sign" — eyes fixed upward during sleep
Given that some CBS cases have AD pathology:
- CBS-AD overlap cases may show saccadic intrusions similar to AD
- Oculomotor apraxia may be present in CBS with cortical pathology
- Memory and cognitive factors may compound eye movement testing
Eye movement abnormalities in CBS reflect dysfunction at multiple anatomical levels:
Cortical Level
- Frontal eye fields (FEF) — impaired saccade planning and execution
- Supplementary motor area (SMA) — reduced antisaccade performance
- Posterior parietal cortex — disrupted visual attention and target selection
- Anterior cingulate cortex — impaired volitional saccade suppression
Subcortical Level
- Basal ganglia — abnormal output affecting saccade selection
- Thalamus — disrupted thalamocortical loops for eye movement
- Superior colliculus — enhanced excitability causing SWJs
Brainstem Level
- Pontine reticular formation — abnormal burst and pause neuron activity
- Medial longitudinal fasciculus — internuclear dysfunction
- Ocular motor nuclei — generally preserved in CBS
The pattern of eye movement abnormality varies with the underlying pathology in CBS:
| Pathology |
Eye Movement Pattern |
| CBD pathology |
Prominent SWJs, impaired antisaccades |
| PSP pathology |
Vertical gaze palsy (overlapping) |
| AD pathology |
Saccadic intrusions, cognitive因素 |
| TDP-43 pathology |
Variable, may include supranuclear gaze |
Horizontal Eye Movements
- Observe spontaneous eye movements during conversation
- Test saccades: "Look at my finger, then at that pen"
- Assess smooth pursuit: follow moving target
Vertical Eye Movements
- Assess voluntary vertical saccades: "Look up, then down"
- Test reflexive eye movements: intact in supranuclear palsy
Special Tests
- Antisaccade task: "When I move my finger to the right, look to the left"
- Stroop-like task: Cognitive interference testing
- OKN drum: Assess optokinetic nystagmus
- Video-oculography (VOG) — quantitative measurement of all eye movement types
- Electrophysiological testing — saccade latency and velocity
- Infrared oculography — high-resolution tracking
Recent neuroimaging studies in CBS reveal associations between eye movement abnormalities and structural changes[@filip2023]:
- Superior colliculus atrophy — correlates with SWJ severity
- Frontal eye field involvement — predicts saccade latency
- Parietal cortex damage — affects smooth pursuit
- Brainstem nuclei — generally preserved in pure CBS
Eye movement abnormalities in CBS have practical consequences:
- Reading difficulty — SWJs and fixation instability impair sustained reading
- Driving safety — impaired visual scanning may affect driving ability
- Fall risk — reduced visual scanning contributes to navigational deficits
- Communication — gaze avoidance affects social interaction
- Visual compensation strategies — using peripheral vision for navigation
- Environmental modifications — high-contrast targets, adequate lighting
- Prism lenses — may help with convergence insufficiency
- Speech/language therapy — for associated aphasia affecting communication
Current research areas include:
- Biomarker development — SWJs as early diagnostic markers
- Pathological correlation — relating eye movement patterns to underlying pathology
- Treatment targets — developing therapies for specific oculomotor deficits
- Machine learning — using eye tracking for automated diagnosis
- Cross-disease comparison — systematic comparison across CBS, PSP, PD
Eye movement abnormalities in CBS are clinically significant features that help differentiate this condition from PSP and PD. The prominence of square wave jerks, preserved saccade velocity, and absence of vertical supranuclear gaze palsy are key distinguishing characteristics. Understanding the neuroanatomical basis of these findings provides insight into the distinct pattern of cortical and subcortical involvement in CBS and may guide future therapeutic approaches targeting specific neural circuits.
- Chen L, Chen Y, Liu C, et al. Ocular motor abnormalities in corticobasal syndrome: a systematic review. Park Relat Disord. 2020
- Kim YE, Lee WW, Yun JY, et al. Eye movement characteristics in corticobasal syndrome compared to progressive supranuclear palsy. J Neurol Sci. 2022
- Ferman TJ, van Gerpen JA, Boeve BF, et al. Eye movement abnormalities in neurodegenerative dementias. Handb Clin Neurol. 2018
- Filip P, Tintera J, Vanacek M, et al. Neuroimaging correlates of eye movement abnormalities in corticobasal syndrome. Neuroimage Clin. 2023
- Anderson TJ, MacAskill MR. Eye movements in Parkinson's disease: what we know and what we don't. Mov Disord. 2020