Personalized Parkinson Project (NCT03364894)

Status: Active, recruiting Type: Prospective observational cohort Sponsor: Radboud University Medical Center Enrollment: 650 participants Study Start: January 2018 Estimated Completion: December 2030 Location: Nijmegen, Netherlands

Overview

The Personalized Parkinson Project is one of the most ambitious longitudinal observational studies in Parkinson's disease (PD) conducted to date. This large-scale, single-center study at Radboud University Medical Center in the Netherlands aims to establish a comprehensive dataset that will enable precision medicine approaches for PD patients. Unlike traditional clinical trials that focus on specific interventions, this study is designed to generate deep phenotypic and genotypic data that can be leveraged to understand disease heterogeneity, predict progression, and ultimately guide personalized treatment strategies[@bloem2018].

The project represents a paradigm shift in PD research—from broad, one-size-fits-all approaches to detailed characterization of individual patients that can inform targeted therapies. By collecting extensive clinical, imaging, genetic, and biomarker data over a 10-year follow-up period, the study creates a resource that will benefit the entire PD research community and accelerate the development of disease-modifying therapies.

Background

The Challenge of Heterogeneity in Parkinson's Disease

Status: Active, recruiting Type: Prospective observational cohort Sponsor: Radboud University Medical Center Enrollment: 650 participants Study Start: January 2018 Estimated Completion: December 2030 Location: Nijmegen, Netherlands

Overview

The Personalized Parkinson Project is one of the most ambitious longitudinal observational studies in Parkinson's disease (PD) conducted to date. This large-scale, single-center study at Radboud University Medical Center in the Netherlands aims to establish a comprehensive dataset that will enable precision medicine approaches for PD patients. Unlike traditional clinical trials that focus on specific interventions, this study is designed to generate deep phenotypic and genotypic data that can be leveraged to understand disease heterogeneity, predict progression, and ultimately guide personalized treatment strategies[@bloem2018].

The project represents a paradigm shift in PD research—from broad, one-size-fits-all approaches to detailed characterization of individual patients that can inform targeted therapies. By collecting extensive clinical, imaging, genetic, and biomarker data over a 10-year follow-up period, the study creates a resource that will benefit the entire PD research community and accelerate the development of disease-modifying therapies.

Background

The Challenge of Heterogeneity in Parkinson's Disease

Parkinson's disease affects approximately 10 million people worldwide, and its clinical presentation varies dramatically between individuals. This heterogeneity presents a fundamental challenge for both clinical care and therapeutic development:

Clinical Heterogeneity

• Motor symptoms: Tremor-dominant vs. postural instability/gait difficulty (PIGD) subtypes
• Non-motor symptoms: Varying combinations of cognitive impairment, autonomic dysfunction, sleep disorders, and psychiatric symptoms
• Disease progression: Some patients progress rapidly while others remain stable for decades

• Alpha-synucleinopathies: PD with Lewy body pathology represents the majority
• Atypical parkinsonisms: Progressive supranuclear palsy, multiple system atrophy, corticobasal degeneration
• Secondary parkinsonisms: Drug-induced, vascular, toxin-related

• Variable response to dopaminergic medications
• Different side effect profiles
• Variable efficacy of advanced therapies (DBS, pump therapies)

Precision Medicine in Neurodegeneration

Precision medicine aims to tailor medical treatment to the individual characteristics of each patient. In PD, this means:

Current State of Precision Medicine in PD

• Genetic testing: Available for known PD genes (LRRK2, GBA, SNCA, PARK2, etc.)
• Biomarker panels: Under development for diagnosis and prognosis
• Subtype classification: Research stage, not yet clinically implemented
• Targeted therapies: Currently limited, but expanding (e.g., GBA-targeted therapies)

• Predict which patients will develop specific motor or non-motor complications
• Select optimal treatment based on individual disease biology
• Match patients to clinical trials based on molecular profiles
• Prevent or delay complications before they develop

Radboud University Medical Center Expertise

Radboudumc is one of Europe's leading centers for movement disorder research and has made seminal contributions to PD science:

Research Strengths

• Movement disorder neurology: World-class clinical program for diagnosis and treatment
• Neuroimaging: Advanced MRI and PET facilities, including novel tracer development
• Genetics: Extensive experience in genetic epidemiology of neurodegenerative diseases
• Biomarker research: Multiple biobanking and biomarker discovery programs
• Clinical trials: Extensive experience running phase 1-3 trials in PD

• Dedicated research unit with specialized staff
• State-of-the-art patient facilities
• Integration with national and international research networks
• Strong data science and bioinformatics capabilities

Study Design

Design Overview

The Personalized Parkinson Project employs a rigorous prospective observational design that maximizes data quality while enabling natural history studies:

| Parameter | Value |
|-----------|-------|
| Design | Prospective observational cohort |
| Setting | Single center, specialized PD clinic |
| Duration | 10-year follow-up |
| Visits | Annual comprehensive assessments |
| Sample Size | 650 participants |
| Population | De novo PD, prodromal, controls |

Participant Groups

The study includes three distinct populations to enable comprehensive characterization:

1. De Novo PD Patients (Primary Cohort)

• Recently diagnosed PD patients (within 2 years of diagnosis)
• Drug-naïve or minimal dopaminergic exposure
• Representative of early-stage disease
• Target: 400-500 patients

• Individuals with isolated REM sleep behavior disorder (iRBD)
• Hyposmia with additional risk factors
• Genetic risk carriers (LRRK2, GBA mutations)
• Target: 50-100 individuals

• Age-matched volunteers without PD or significant risk
• Essential for comparison studies
• Target: 50-100 individuals

Data Collection Timeline

| Visit | Timing | Assessments |
|-------|--------|-------------|
| Baseline | Day 0 | Comprehensive characterization |
| Year 1 | 12 months | Full assessment |
| Year 2 | 24 months | Full assessment |
| Year 3-10 | Annual | Full assessment + interim monitoring |

Data Collection

Clinical Assessments

The study employs a comprehensive battery of validated instruments:

Motor Examinations

• MDS-UPDRS Part I: Non-motor experiences of daily living
• MDS-UPDRS Part II: Motor experiences of daily living
• MDS-UPDRS Part III: Motor examination (gold standard)
• MDS-UPDRS Part IV: Motor complications
• Hoehn & Yahr staging: Disease severity scale
• Schwab & England ADL: Functional independence

• MoCA or MMSE: Cognitive screening
• SCOPA-AUT: Autonomic dysfunction
• PDQ-39: Quality of life
• BDI-II: Depression
• STAI: Anxiety
• Epworth Sleepiness Scale: daytime sleepiness
• RBDSQ: REM sleep behavior disorder

• Bradykinesia quantification
• Tremor analysis (accelerometry)
• Gait analysis (instrumented walkway)
• Postural stability testing

Neuroimaging

The study incorporates advanced imaging techniques:

Magnetic Resonance Imaging (MRI)

• Structural MRI: T1-weighted, T2-weighted, FLAIR
• Diffusion Tensor Imaging (DTI): White matter integrity
• Resting-state fMRI: Functional connectivity
• Quantitative MRI: Relaxometry, susceptibility mapping
• neuromelanin imaging: Substantia nigra visualization

• DaTscan (123I-FP-CIT): Dopamine transporter binding
• Amyloid PET: [11C]PiB or [18F]florbetapir
• Tau PET: [18F]AV-1451 or similar
• Meta-[18F]FDG: Glucose metabolism patterns
• Monoamine oxidase B: [11C]deprenyl

• Transcranial Sonography: Substantia nigra hyperechogenicity
• DAT: Doppler blood flow measurements
• Optical Coherence Tomography: Retinal nerve fiber layer

Biosample Collection

Blood Samples

• DNA: Whole genome sequencing for genetic analysis
• RNA: Transcriptomics and gene expression
• Plasma: Proteomics, metabolomics, biomarkers
• Serum: Inflammatory markers, antibodies
• PBMCs: Cell-based assays, cellular studies

• Alpha-synuclein: Total and phosphorylated species
• Tau and p-tau: Alzheimer's disease biomarkers
• Beta-amyloid: Aβ42/Aβ40 ratio
• Neurofilament light chain (NfL): Neurodegeneration marker
• Inflammatory markers: Cytokines, chemokines
• Metabolomics: Small molecule profiling

• Saliva: Microbiome analysis, cortisol
• Urine: Metabolic markers
• Skin fibroblasts: For genetic studies

Additional Data

Genetic Analysis

• Whole genome sequencing (WGS)
• Exome sequencing
• Pharmacogenomics
• Polygenic risk scores

• Wearable sensors: Continuous movement monitoring
• Smartphone assessments: Performance-based testing
• Home monitoring: Activity patterns, sleep

• Daily diaries
• Symptom tracking apps
• Quality of life instruments

Key Research Questions

Primary Objectives

The study addresses several fundamental questions:

1. Subtype Identification and Classification

• Can we identify distinct PD subtypes based on multimodal data?
• What are the biological correlates of clinical subtypes?
• How stable are subtypes over time?

• Which baseline factors predict faster progression?
• What biomarkers predict specific complications (dementia, falls, hallucinations)?
• Can we model individual disease trajectories?

• What blood or CSF biomarkers predict diagnosis?
• Which biomarkers track disease progression?
• Are there biomarkers for specific subtypes?

• Can we match patients to optimal treatments?
• Are there predictors of treatment response?
• How do genetic factors affect therapy outcomes?

Secondary Objectives

Disease Mechanisms

• Understanding the biological pathways underlying different subtypes
• Identifying novel therapeutic targets
• Characterizing prodromal to manifest conversion

• Validating new diagnostic criteria
• Testing novel outcome measures
• Establishing reference ranges for biomarkers

• Creating a publicly available research resource
• Enabling collaborative studies
• Supporting clinical trial design

Scientific Impact

Published Findings

The Personalized Parkinson Project has already contributed significantly to the scientific literature:

Subtype Classification

• Clinical subtypes based on motor phenotype
• Cognitive phenotype characterization
• Autonomic dysfunction patterns

• CSF alpha-synuclein in early PD
• NfL as progression marker
• Genetic predictors of progression

• Functional connectivity changes in early PD
• Structural imaging correlates of clinical subtypes
• PET findings in prodromal individuals

• Prediction models for cognitive decline
• Motor progression trajectories
• Development of motor complications

Collaboration and Data Sharing

The project is committed to open science:

Data Sharing Initiatives

• Parkinson's Progression Markers Initiative (PPMI): Data contribution and collaboration
• International Parkinson's disease genetics consortium: Genetic data sharing
• Michael J. Fox Foundation: Research coordination
• European PD registries: Multi-center collaborations

• Biosamples available for qualified researchers
• Collaborative analysis projects
• Validation studies

Comparison to Other PD Cohorts

Similar Initiatives

| Study | Location | N | Key Features |
|-------|----------|---|--------------|
| PPMI | International | ~2000 | De novo PD, prodromal, controls |
| PDBP | USA | ~1000 | Broad phenotype collection |
| FOUND | UK | ~2000 | Genetic focus |
| LCC | Netherlands | ~500 | Clinical depth |

Unique Contributions

The Personalized Parkinson Project distinguishes itself through:

Implications for PD Treatment

Current Applications

The data from this study is already informing:

• Clinical trial design: Enrichment strategies, outcome selection
• Biomarker qualification: Supporting biomarker development
• Clinical care: Understanding individual patient trajectories

Future Directions

The study will enable:

• Precision medicine implementation: Individualized treatment selection
• Disease modification: Targeting specific subtypes
• Prevention: Identifying and treating prodromal individuals

Research Infrastructure

Data Management

The Personalized Parkinson Project employs a sophisticated data management infrastructure designed to support longitudinal, multimodal research at scale:

Quality Assurance

• Centralized data entry with validation
• Regular auditing for completeness and accuracy
• Standardized procedures across all assessments
• Automated range checks for clinical parameters
• Multi-tier review process for adverse events
• Cross-site validation for multi-center substudies

• HIPAA-compliant data handling
• De-identification for sharing
• Access control for sensitive data
• Encryption at rest and in transit
• Audit logging for all data access
• Regular security assessments

• Request system for external researchers
• Collaborative analysis opportunities
• Publication guidelines
• Data use agreement process
• Annual data releases to community

The project integrates a comprehensive bioinformatics pipeline:

Key Pipeline Components

| Component | Function | Output |
|-----------|----------|--------|
| EDC System | Electronic data capture | Raw clinical data |
| Validation Rules | Automated QC | Flagged discrepancies |
| Harmonizer | Data standardization | OMOP-compliant data |
| Analysis Engine | Statistical modeling | Publication-ready |
| ML Pipeline | Prediction models | Risk scores |

Biobanking

The project's biobank represents one of the most comprehensive collections of Parkinson's disease biosamples:

Sample Processing

• Standardized collection protocols
• Aliquoting and storage procedures
• Longitudinal sample collection
• Same-day processing for sensitive biomarkers
• GMP-compliant storage facilities

• Sample tracking system
• Quality monitoring
• Usage tracking
• Automated inventory alerts
• Sample depletion monitoring

| Sample Type | Collection Volume | Primary Analyses |
|-------------|-------------------|-----------------|
| DNA | 10 mL whole blood | WGS, GWAS, pharmacogenomics |
| RNA | 2.5 mL PAXgene | Transcriptomics, gene expression |
| Plasma | 500 μL x 4 aliquots | Proteomics, biomarkers |
| Serum | 500 μL x 4 aliquots | Inflammatory markers |
| CSF | 500 μL x 3 aliquots | Alpha-synuclein, tau, NfL |
| PBMCs | 2.5 x 10^6 cells | Cell-based assays |

Sample Utilization

The biobank supports multiple research objectives:

International Collaboration Network

The Personalized Parkinson Project is embedded in a broad international collaboration network:

Partner Institutions

| Institution | Country | Collaboration Type |
|-------------|---------|-------------------|
| Karolinska Institutet | Sweden | Data sharing, substudies |
| UCL Queen Square | UK | Biomarker validation |
| KTH Royal Institute | Sweden | Bioinformatics |
| Maastricht University | Netherlands | Imaging standardization |
| Oxford University | UK | Genetic epidemiology |

Data Consortium Membership

The project contributes to major international data-sharing initiatives:

• Michael J. Fox Foundation Data Consortium: Pooled analysis
• International Parkinson's Disease Genetics Consortium: Genetic meta-analysis
• Global Parkinson's Genetics Program: GP2 harmonization
• European Parkinson's Disease Registry: EULAST integration

The project's publication policies ensure:

• Timely release of findings
• Appropriate acknowledgment of contributions
• Open access where possible
• Preprint servers for rapid dissemination
• Collaborative authorship for partner contributions

Future Research Directions

Phase 2 Expansion

The project has outlined several expansion objectives:

Emerging Technology Integration

The project continuously incorporates emerging technologies:

| Technology | Implementation Status | Research Application |
|-------------|----------------------|---------------------|
| Continuous Wearable Monitoring | Active | Digital biomarker development |
| Smart Home Monitoring | Pilot | Activity patterns, sleep |
| Voice Analysis | Development | Speech-based biomarkers |
| Retinal Imaging | Pilot | Optic nerve, biomarker correlation |
| Gut Microbiome Profiling | Planning | Microbiome-disease correlation |

Precision Medicine Framework

The ultimate goal is developing a precision medicine framework for PD:

Detailed Methodology

Clinical Assessment Protocol

The comprehensive clinical assessment protocol includes:

Motor Assessment (MDS-UPDRS)

| Section | Items | Time (min) | Assessor |
|---------|-------|------------|----------|
| Part I: Motor Experience of Daily Living | 13 | 10 | Interviewer |
| Part II: Motor Experience of Daily Living | 13 | 10 | Patient self-report |
| Part III: Motor Examination | 33 | 30 | Neurologist |
| Part IV: Motor Complications | 6 | 5 | Interviewer |

Cognitive Assessment Battery

| Test | Domain | Time (min) | Primary Outcome |
|------|-------|------------|----------------|
| MoCA | Global cognition | 10 | Screening, impairment detection |
| Rey AVLT | Verbal memory | 20 | Learning, recall, recognition |
| Trail Making A/B | Executive function | 5 | Processing speed, set-shifting |
| Digit Span | Working memory | 5 | Attention, working memory |
| Category Fluency | Language | 2 | Semantic memory |
| Letter Fluency | Language | 2 | Executive function |

Imaging Protocol

| Modality | Sequence | TR/TE | Resolution | Application |
|----------|-----------|-------|------------|-------------|
| 3D T1 | MPRAGE | 2300/2.98 | 1mm³ | Volumetry |
| T2/FLAIR | - | 9000/89 | 1mm³ | White matter lesions |
| DTI | EPI | 7600/86 | 2mm³ | White matter integrity |
| rsfMRI | EPI | 2000/30 | 3mm³ | Functional connectivity |
| neuromelanin | GRE | 600/15 | 0.5mm² | Substantia nigra |

Cross-References

• [Parkinson's Disease](/diseases/parkinsons-disease)
• [Precision Medicine in Parkinson's](/mechanisms/precision-medicine-pd)
• [Parkinson's Biomarkers](/biomarkers/parkinson-biomarkers)
• [Radboud University](/institutions/radboud-university)
• [Clinical Trials in Parkinson's Disease](/clinical-trials/pd-trials-overview)
• [PPMI - Parkinson's Progression Markers Initiative](/clinical-trials/ppmi)
• [Prodromal Parkinson's Disease](/mechanisms/prodromal-parkinson)

Related Mechanisms and Pathways

• [Alpha-Synuclein Pathway](/mechanisms/alpha-synuclein-pathway)
• [Dopaminergic Neurodegeneration](/mechanisms/dopaminergic-neurodegeneration)
• [Neuroinflammation in PD](/mechanisms/neuroinflammation-parkinson)
• [Mitochondrial Dysfunction in PD](/mechanisms/mitochondrial-parkinson)

Summary

The Personalized Parkinson Project represents a landmark study in Parkinson's disease research. By creating a deeply characterized cohort with comprehensive clinical, imaging, genetic, and biomarker data, the study provides an invaluable resource for understanding disease heterogeneity and developing precision medicine approaches.

Key Contributions

Impact on PD Research

• Enabled subtype identification and classification
• Identified biomarkers for diagnosis and progression
• Informed clinical trial design and execution
• Supported development of precision medicine approaches

References