This observational study investigates retinal changes in Progressive Supranuclear Palsy (PSP) using advanced ophthalmic imaging techniques, seeking to identify potential biomarkers for diagnosis and disease tracking. The retina, as a direct extension of the central nervous system, offers a unique window into neurodegenerative processes, and this study leverages cutting-edge optical technologies to characterize pathological changes that may mirror brain pathology in PSP 1.
- NCT Number: NCT07000851
- Status: Recruiting
- Study Type: Observational
- Conditions: Progressive Supranuclear Palsy (PSP), Parkinson's Disease (PD)
- Sponsor: Major academic medical center with neuro-ophthalmology program
- Enrollment: Target 200 participants
¶ Background and Rationale
The retina represents a unique opportunity in neurodegenerative disease research because it is the only part of the central nervous system that can be directly visualized non-invasively 2. The retina develops from the optic vesicle, making it neuroectodermally derived, and shares many properties with the brain including:
- Similar blood-retinal barrier: Analogous to the blood-brain barrier, controlling molecular exchange
- Shared neuronal biology: Retinal ganglion cells, amacrine cells, and bipolar cells share molecular pathways with CNS neurons
- Transparent tissue architecture: Allows high-resolution imaging without surgical intervention
- Direct axonal projection: The retinal ganglion cell axons form the optic nerve, which is directly continuous with the brain
In Parkinson's disease, studies have documented:
- Reduced retinal layer thickness, particularly in the inner retinal layers
- Changes in retinal vasculature and blood flow
- Altered electroretinogram (ERG) responses
- Accumulation of alpha-synuclein in retinal tissue
In PSP, the tau pathology that affects subcortical structures also manifests in retinal neurons, making retinal imaging particularly relevant 3.
Optical Coherence Tomography (OCT) has revolutionized retinal imaging by providing cross-sectional images with micrometer resolution:
Spectral-domain OCT (SD-OCT): Standard technology with ~5 μm axial resolution, allowing measurement of individual retinal layers
Swept-source OCT (SS-OCT): Newer technology with deeper penetration and faster scanning, better for imaging choroid and deeper structures
Enhanced Depth Imaging (EDI-OCT): Technique for visualizing deeper structures including choroid and lamina cribrosa
Angiography (OCT-A): Non-invasive visualization of retinal and choroidal blood flow without dye injection
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Characterize Retinal Layer Thickness: Quantify changes in individual retinal layers in PSP compared to healthy controls and PD patients
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Evaluate OCT Findings: Document specific patterns of retinal pathology including:
- Ganglion cell-inner plexiform layer (GCIPL) thickness
- Peripapillary retinal nerve fiber layer (pRNFL) thickness
- Inner retinal layer volumes
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Clinical Correlation: Establish relationships between retinal measures and:
- PSP Rating Scale scores
- Disease duration
- Specific symptom severity (gaze palsy, postural instability)
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Biomarker Utility: Assess the potential of retinal imaging as:
- Diagnostic biomarker (differentiating PSP from PD)
- Disease progression marker
- Treatment response indicator
- Develop standardized imaging protocols for PSP
- Create reference databases for normative data
- Validate imaging biomarkers against CSF and blood biomarkers
- Establish genotype-phenotype correlations with retinal findings
¶ Imaging Modalities and Techniques
¶ Spectral-Domain OCT (SD-OCT)
The study employs Cirrus HD-OCT (Zeiss) and Spectralis OCT (Heidelberg) platforms for:
Macular Scans:
- 200x200 raster scans centered on fovea
- Automated segmentation of individual layers
- GCIPL thickness mapping
- Volume calculations
Optic Nerve Head Scans:
- Circle scan (3.4mm diameter) around optic disc
- RNFL thickness measurement
- Rim and disc parameters
- Bruch's membrane opening measurements
Enhanced Depth Imaging:
- Deeper focus into choroid
- Lamina cribrosa visualization
- Scleral canal measurements
Standardized color fundus photography documents:
- Optic disc appearance
- Retinal vascular patterns
- Macular pigment distribution
- Any incidental findings
Advanced adaptive optics (AO) provides:
- Wavefront correction for cellular-level imaging
- Individual photoreceptor visualization
- Ganglion cell counting in selected areas
- Microvascular analysis
- Fluorescein Angiography: For selected cases with suspected vascular involvement
- Confocal Scanning Laser Ophthalmoscopy (cSLO): For autofluorescence patterns
- Electroretinography (ERG): Functional assessment of retinal responses
PSP Rating Scale: Comprehensive assessment including:
- Ocular motor subdomain (vertical gaze, saccadic velocities)
- Gait and balance subdomain (falls, gait stability)
- Bulbar function subdomain (speech, swallowing)
- Motor subdomain (rigidity, bradykinesia)
- Cognitive subdomain (executive function, fluency)
MDS-UPDRS: Parkinson's disease rating scale applied for comparison with PD cohort:
- Part I: Non-motor experiences of daily living
- Part II: Motor experiences of daily living
- Part III: Motor examination
- Part IV: Motor complications
- Montreal Cognitive Assessment (MoCA)
- Trail Making Test (Parts A and B)
- Digit Symbol Substitution Test
- Verbal fluency tests
- Best-corrected visual acuity
- Contrast sensitivity
- Color vision testing
- Visual field testing (automated perimetry)
- Stereoacuity
- Clinical diagnosis of PSP (any variant) or Parkinson's Disease
- PSP variants: Richardson's syndrome (PSP-RS), PSP with parkinsonism (PSP-P), PSP-pure akinesia with gait freezing (PSP-PAGF), PSP-corticobasal syndrome (PSP-CBS)
- Age 50-85 years
- Ability to undergo OCT imaging (fixation sufficient)
- No significant media opacity (cataract, vitreous hemorrhage)
- Informed consent from participant or legally authorized representative
- Prior ocular surgery within 3 months
- Significant retinal disease (diabetic retinopathy, age-related macular degeneration, retinal vein occlusion)
- Glaucoma with significant visual field loss
- History of optic neuropathy (except in PSP)
- Inability to cooperate with imaging
- Contraindication to any imaging modality
¶ Significance and Implications
Retinal biomarkers could revolutionize PSP diagnosis:
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Early Detection: Retinal changes may precede clinical diagnosis, enabling earlier identification
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Differential Diagnosis: Specific patterns may help distinguish:
- PSP from PD (different pattern of thinning)
- PSP from other atypical parkinsonisms (MSA, CBS)
- PSP subtypes from each other
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Supportive Biomarker: Can provide objective evidence supporting clinical diagnosis
Retinal imaging offers unique advantages for disease tracking:
- Non-invasive: No need for lumbar puncture or blood draws for biomarker monitoring
- Quantitative: Objective, reproducible measurements
- Frequent: Can be performed as often as needed without risk
- Automated: Analysis can be standardized and automated
For therapeutic trials, retinal biomarkers can:
- Patient Selection: Identify patients with specific retinal phenotypes
- Outcome Measures: Serve as objective endpoints
- Response Monitoring: Track treatment effects on retinal parameters
- Mechanistic Insights: Provide evidence of target engagement
¶ Emerging Research and 2024-2025 Advances
GCIPL Thinning Patterns: Studies published in 2024 demonstrate that PSP patients show a characteristic pattern of superior-temporal GCIPL thinning that correlates with disease severity and is distinct from PD patterns 4.
pRNFL Changes: Progressive thinning of the retinal nerve fiber layer, particularly in the superior quadrant, correlates with disease progression and may predict cognitive decline in PSP 5.
Choroidal Changes: New research reveals altered choroidal thickness in PSP, potentially reflecting underlying vascular dysfunction and providing additional biomarker candidates 6.
Artificial Intelligence: Machine learning algorithms now enable automated segmentation and analysis of retinal layers with human-level accuracy, reducing operator dependence and improving reproducibility 7.
Deep Learning Models: New deep learning approaches can classify PSP vs. PD with high accuracy using OCT-derived features, demonstrating the potential for clinical adoption 8.
Multimodal Integration: Combining retinal imaging with other biomarkers (CSF NfL, genetic markers) improves diagnostic accuracy and provides comprehensive disease profiling 9.
This study contributes to broader initiatives:
- PROSPECT-MRI Consortium: PSP neuroimaging and biomarker study
- 4-Repeat Tauopathy Neuroimaging Initiative: Multi-center tauopathy imaging
- International PSP Genetics Consortium: Genetic and phenotypic correlations
- ** CurePSP Research Network**: Foundation for PSP and related disorders