Overview
The Neurovascular Unit (NVU) Dysfunction Hypothesis proposes that breakdown of the blood-brain barrier (BBB) and associated neurovascular unit components represents a critical upstream driver of Parkinson’s disease pathogenesis. This hypothesis integrates vascular, immune, and protein clearance mechanisms into a unified model explaining both early prodromal features and progressive neurodegeneration. The NVU encompasses the anatomical and functional relationship between cerebral blood vessels and neural tissue, comprising endothelial cells, pericytes, astrocytes, neurons, and the extracellular matrix—all of which may be compromised in PD1Failure of immune cell transport in neurodegenerative diseaseOpen reference.
Scientific Rationale
Evidence of BBB Dysfunction in PD
Multiple lines of evidence support BBB compromise in Parkinson’s disease:
-
Post-mortem studies show reduced expression of tight junction proteins (claudin-5, occludin, ZO-1) in PD brains2Blood-brain barrier alterations in Parkinson's diseaseOpen reference
-
Neuroimaging studies using dynamic contrast-enhanced MRI demonstrate increased BBB permeability in the substantia nigra and striatum of PD patients3Dynamic contrast-enhanced MRI evidence of BBB dysfunction in Parkinson's diseaseOpen reference
-
Cerebrospinal fluid albumin ratio is elevated in PD, indicating compromised BBB integrity4CSF albumin ratio as BBB marker in Parkinson's diseaseOpen reference
-
Pericyte degeneration has been documented in PD substantia nigra, with loss of platelet-derived growth factor receptor-β (PDGFRβ) positive pericytes5Pericyte degeneration in Parkinson's disease substantia nigraOpen reference
The Neurovascular Unit Model
The neurovascular unit comprises:
-
Endothelial cells forming the BBB with tight junctions
-
Pericytes regulating cerebral blood flow and BBB development
-
Astrocytes maintaining BBB properties via astrocyte end-feet
-
Neurons providing neurovascular coupling signals
-
Extracellular matrix forming the basement membrane
In PD, dysfunction at multiple NVU components creates a permissive environment for neurodegeneration6Neurovascular unit dysfunction in neurodegenerative diseaseOpen reference.
Mechanistic Model
Core Mechanistic Cascade
flowchart TD
subgraph Triggers
A["Genetic Risk<br/>(LRRK2, GBA, VPS35)"] --> D["NVU Dysfunction"]
B["Environmental Toxins<br/>(MPTP, rotenone)"] --> D
C["Aging-associated<br/>BBB senescence"] --> D
end
subgraph NVU_Damage
D --> E["Tight Junction<br/>Breakdown"]
D --> F["Pericyte<br/>Degeneration"]
D --> G["Astrocyte<br/>Activation"]
D --> H["Endothelial<br/>Dysfunction"]
end
subgraph Leakage
E --> I["Peripheral Molecules<br/>Enter Brain"]
F --> J["Impaired Cerebral<br/>Blood Flow"]
G --> K["Reduced Abeta/Syn<br/>Clearance"]
H --> L["Reduced NO<br/>Production"]
end
subgraph Pathogenesis
I --> M["Brain alpha-Syn<br/>Burden"]
J --> N["Hypoxia/Ischemia"]
K --> M
L --> O["Vasoconstriction"]
end
subgraph Neurotoxicity
M --> P["Microglial<br/>Activation"]
N --> P
P --> Q["Neuroinflammation<br/>(IL-1beta, TNF-alpha, IL-6)"]
Q --> R["Dopaminergic<br/>Neuron Loss"]
end
subgraph Feedforward
R --> S["Further NVU Damage"]
S --> D
end
style A fill:#01334a,stroke:#01579b
style B fill:#01334a,stroke:#01579b
style C fill:#01334a,stroke:#01579b
style M fill:#3b1114,stroke:#c62828
style R fill:#3b1114,stroke:#c62828
style P fill:#3a3000,stroke:#f57f17
style Q fill:#3a3000,stroke:#f57f17Molecular Mechanisms of NVU Breakdown
Tight Junction Disassembly
The blood-brain barrier’s selective permeability is maintained by tight junction proteins including claudin-5, occludin, and ZO-1. In PD, multiple mechanisms contribute to their degradation:
-
Matrix metalloproteinase (MMP) activation: Pro-inflammatory cytokines (TNF-α, IL-1β) upregulate MMP-9, which directly cleaves tight junction proteins
-
Oxidative stress: Reactive oxygen species (ROS) from mitochondrial dysfunction impair tight junction assembly
-
α-Synuclein toxicity: Oligomeric α-synuclein can bind to endothelial cells and cause barrier dysfunction1Failure of immune cell transport in neurodegenerative diseaseOpen reference
Pericyte Pathology
Pericytes are critical for BBB development and maintenance. In PD:
-
PDGFRβ-positive pericytes are reduced in substantia nigra5Pericyte degeneration in Parkinson's disease substantia nigraOpen reference
-
Pericyte loss leads to increased BBB permeability and reduced cerebral blood flow
-
Pericyte-derived VEGF dysregulation contributes to angiogenesis and barrier compromise
Astrocyte End-Foot Dysfunction
Astrocytes maintain BBB properties through aquaporin-4 (AQP4) channels in their end-feet. In PD:
-
AQP4 polarization is disrupted, impairing glymphatic clearance
-
Astrocyte reactivity (astrogliosis) correlates with BBB breakdown
-
Inflammatory activation of astrocytes releases cytokines that further compromise the NVU
Endothelial Cell Dysregulation
Beyond tight junction loss, endothelial cells themselves become dysregulated in PD7LRRK2-mediated BBB dysfunction through endothelial kinase activityOpen reference8Tight junction protein regulation in PD modelsOpen reference:
-
LRRK2 kinase activity: LRRK2 is highly expressed in brain endothelial cells; G2019S mutations cause increased monolayer permeability through cytoskeletal remodeling
-
eNOS dysfunction: Endothelial nitric oxide synthase is uncoupled in PD, producing superoxide instead of NO, leading to vasoconstriction and reduced cerebral blood flow2Blood-brain barrier alterations in Parkinson's diseaseOpen reference0
-
VCAM-1/ICAM-1 upregulation: Pro-inflammatory cytokines induce adhesion molecule expression, promoting leukocyte transmigration across the compromised BBB
-
P-glycoprotein dysregulation: Efflux transporters at the BBB become dysfunctional, impairing clearance of neurotoxic species including alpha-synuclein
Neurovascular Coupling Impairment
The NVU coordinates regional blood flow in response to neural activity—a process called neurovascular coupling or functional hyperemia. In PD, this coupling is severely impaired2Blood-brain barrier alterations in Parkinson's diseaseOpen reference1:
-
Neuronal dysfunction: Reduced alpha-synuclein-mediated signaling impairs perivascular neuron control of vessel diameter
-
Pericyte contractility loss: Pericytes normally act as capillary-level flow regulators; their degeneration eliminates this control
-
Astrocyte calcium dysregulation: Failed AQP4 polarization disrupts astrocyte-mediated vasodilatory signaling
-
Endothelial dysfunction: Reduced NO bioavailability prevents appropriate vasodilation in response to neural demand
The result is a “vascular hypofrontality”—insufficient blood delivery to active brain regions during task performance, contributing to cognitive as well as motor impairment in PD.
MMP-9-Mediated Tight Junction Degradation
Matrix metalloproteinase-9 (MMP9) plays a central role in NVU breakdown in PD2Blood-brain barrier alterations in Parkinson's diseaseOpen reference2:
| MMP-9 Substrate | Effect of Cleavage |
|---|---|
| Claudin-5 | Direct tight junction disruption |
| Occludin | Barrier permeability increase |
| ZO-1 | Loss of junctional anchoring |
| Pro-MMP-9 | Auto-amplification loop |
| Collagen IV (basement membrane) | Structural compromise |
MMP9 is activated by multiple PD-relevant stimuli: TNF-α, IL-1β, ROS, and alpha-synuclein oligomers. CSF levels of MMP-9 are elevated in PD patients and correlate with disease severity2Blood-brain barrier alterations in Parkinson's diseaseOpen reference3, making it both a mechanistic driver and a potential biomarker.
LRRK2-Mediated Endothelial Dysfunction
The LRRK2 G2019S mutation provides the strongest genetic link to BBB dysfunction in PD2Blood-brain barrier alterations in Parkinson's diseaseOpen reference4. LRRK2 kinase activity in endothelial cells:
-
Phosphorylates Rab proteins involved in vesicular trafficking, disrupting endothelial polarity
-
Increases monolayer permeability through cytoskeletal effects on the actin cytoskeleton
-
Promotes transendothelial migration of peripheral immune cells
-
Sensitizes endothelial cells to inflammatory cytokines
This mechanism explains why LRRK2-PD patients may have accelerated NVU dysfunction even before motor symptoms emerge2Blood-brain barrier alterations in Parkinson's diseaseOpen reference5.
Prodromal NVU Dysfunction
Recent studies have demonstrated that BBB dysfunction precedes motor symptom onset in PD2Blood-brain barrier alterations in Parkinson's diseaseOpen reference6:
-
REM sleep behavior disorder (RBD) patients: Show elevated BBB permeability on DCE-MRI, with increased CSF/serum albumin ratios comparable to manifest PD
-
LRRK2 G2019S carriers (non-manifest): Show endothelial dysfunction markers including elevated MMP-9 activity before clinical PD diagnosis
-
Olfactory dysfunction: A prodromal PD feature strongly correlates with BBB disruption in the olfactory bulb region
This temporal ordering supports NVU dysfunction as an upstream pathogenic driver rather than a secondary consequence of neurodegeneration.
Biomarker Development
| Biomarker | Source | NVU Specificity | Status |
|---|---|---|---|
| MMP-9 activity | CSF | Tight junction degradation | Clinical validation2Blood-brain barrier alterations in Parkinson's diseaseOpen reference7 |
| MMP-2 activity | CSF | Basement membrane remodeling | Research use |
| sVCAM-1 | Serum | Endothelial activation | Phase 2 biomarker |
| sICAM-1 | Serum | Endothelial activation | Research use |
| CSF/serum albumin ratio | CSF, serum | BBB permeability | Established2Blood-brain barrier alterations in Parkinson's diseaseOpen reference8 |
| PDGFRβ | Plasma | Pericyte injury | Preclinical |
| AQP4 polarization | MRI | Astrocyte end-foot | Emerging2Blood-brain barrier alterations in Parkinson's diseaseOpen reference9 |
Integration with Existing Mechanisms
flowchart LR
subgraph NVU_Hypothesis
A["NVU Dysfunction"] --> B["BBB Breakdown"]
end
subgraph Related_Mechanisms
B --> C["Glymphatic<br/>Impairment"]
C --> D["alpha-Syn<br/>Accumulation"]
B --> E["Neuroinflammation"]
E --> F["Microglial<br/>Activation"]
B --> M["Peripheral alpha-Syn<br/>Entry"]
M --> D
end
subgraph Mitochondrial_Connection
D --> G["Mitochondrial<br/>Dysfunction"]
G --> H["ROS Production"]
H --> I["Tight Junction<br/>Damage"]
I --> B
end
A -.-> C
A -.-> E
A -.-> M
A -.-> GThe NVU dysfunction hypothesis connects to multiple established mechanisms in the wiki:
-
Neuroinflammation Mechanism — inflammatory cytokines both result from and contribute to BBB breakdown
-
Glymphatic-Circadian Axis Hypothesis — impaired AQP4 polarization reduces waste clearance
-
Mitochondrial Dysfunction Pathway — ROS damages tight junctions
-
Extracellular Vesicle Synuclein Propagation — EVs may cross compromised BBB
Evidence Assessment
Confidence Level: Moderate
The NVU dysfunction hypothesis has substantial supporting evidence but remains an active area of investigation.
| Evidence Type | Level | Supporting Data |
|---|---|---|
| Genetic | Strong | LRRK2, GBA, VPS35 mutations linked to endolysosomal dysfunction affecting BBB3Dynamic contrast-enhanced MRI evidence of BBB dysfunction in Parkinson's diseaseOpen reference0 |
| Post-mortem | Strong | Consistent tight junction protein reduction in PD substantia nigra |
| Neuroimaging | Moderate | DCE-MRI shows BBB leakage in PD striatum |
| Biomarkers | Moderate | Elevated CSF albumin ratio, increased MMP-9 |
| Animal Models | Strong | MPTP, rotenone models show BBB compromise |
| Therapeutic Translation | Moderate | Multiple BBB-stabilizing approaches in development |
Key Supporting Studies
-
Gómez-González et al. (2022) — Comprehensive analysis of tight junction alterations in PD post-mortem brain tissue, demonstrating significant reductions in claudin-5, occludin, and ZO-1 expression in the substantia nigra3Dynamic contrast-enhanced MRI evidence of BBB dysfunction in Parkinson's diseaseOpen reference1
-
Goldberg et al. (2023) — Dynamic contrast-enhanced MRI showing increased BBB permeability in the substantia nigra and striatum of living PD patients3Dynamic contrast-enhanced MRI evidence of BBB dysfunction in Parkinson's diseaseOpen reference2
-
Bell et al. (2022) — PDGFRβ-positive pericyte loss in PD substantia nigra, establishing pericyte degeneration as a key NVU component3Dynamic contrast-enhanced MRI evidence of BBB dysfunction in Parkinson's diseaseOpen reference3
-
Sweeney et al. (2022) — Review of immune cell transport failures across the BBB in neurodegenerative diseases, linking peripheral immune activation to CNS pathology3Dynamic contrast-enhanced MRI evidence of BBB dysfunction in Parkinson's diseaseOpen reference4
-
Iadecola et al. (2023) — Comprehensive treatise on neurovascular unit dysfunction across neurodegenerative diseases, providing framework for understanding NVU in PD3Dynamic contrast-enhanced MRI evidence of BBB dysfunction in Parkinson's diseaseOpen reference5
-
Kim et al. (2023) — LRRK2 G2019S directly causes BBB dysfunction through endothelial kinase activity, providing mechanistic link between most common familial PD mutation and NVU breakdown3Dynamic contrast-enhanced MRI evidence of BBB dysfunction in Parkinson's diseaseOpen reference6
-
Monti et al. (2023) — First evidence of BBB disruption in prodromal PD patients (RBD), suggesting NVU dysfunction precedes motor symptoms3Dynamic contrast-enhanced MRI evidence of BBB dysfunction in Parkinson's diseaseOpen reference7
-
Park et al. (2024) — MMP-9/MMP-2 elevated in PD CSF as biomarkers of BBB dysfunction, correlating with disease severity3Dynamic contrast-enhanced MRI evidence of BBB dysfunction in Parkinson's diseaseOpen reference8
-
Zhang et al. (2024) — Glymphatic dysfunction and NVU impairment in early PD, linking AQP4 mislocalization to impaired waste clearance3Dynamic contrast-enhanced MRI evidence of BBB dysfunction in Parkinson's diseaseOpen reference9
-
Wang et al. (2024) — Comprehensive review of BBB stabilization as therapeutic strategy in PD, summarizing emerging drug candidates and delivery approaches4CSF albumin ratio as BBB marker in Parkinson's diseaseOpen reference0
Key Challenges and Contradictions
-
Species differences: Mouse models may not fully recapitulate human BBB complexity
-
Confounding factors: Post-mortem tissue may show artifacts from agonal state
-
Temporal dynamics: Unclear whether NVU dysfunction is cause or consequence
-
Therapeutic targeting: BBB penetration challenges limit drug development
-
Biomarker validation: CSF albumin ratio is non-specific; more precise markers needed4CSF albumin ratio as BBB marker in Parkinson's diseaseOpen reference1
-
Imaging resolution: Current DCE-MRI cannot resolve capillary-level changes
Testability Score: 8/10
-
Biomarker availability: CSF albumin ratio, MMP-9 levels measurable
-
Imaging capabilities: DCE-MRI, perfusion MRI available
-
Genetic stratification: Can test in LRRK2, GBA carriers
-
Therapeutic window: Multiple repurposing candidates available
Therapeutic Potential Score: 9/10
The NVU represents a highly accessible therapeutic target4CSF albumin ratio as BBB marker in Parkinson's diseaseOpen reference2:
-
BBB-penetrant drugs can be engineered
-
Pericyte recruitment strategies are emerging
-
Repurposing opportunities exist (ACE inhibitors, statins, GLP-1 agonists)
Key Proteins and Genes
| Protein/Gene | Role in NVU | Relevance to PD |
|---|---|---|
| LRRK2 | Endothelial cell function, kinase activity | G2019S mutation associated with BBB dysfunction |
| GBA | Lysosomal function, autophagy | Loss leads to endolysosomal NVU compromise |
| VPS35 | Retromer function, protein trafficking | Implicated in endothelial protein sorting |
| CLDN5 | Tight junction component | Downregulated in PD substantia nigra |
| OCLN | Tight junction component | Reduced expression in PD |
| PDGFRβ | Pericyte marker and function | Degeneration in PD SN |
| AQP4 | Astrocyte water channel | Polarization impaired in PD |
| MMP9 | Tight junction protease | Elevated in PD CSF |
| TNF-α | Pro-inflammatory cytokine | Upregulated, degrades tight junctions |
| IL-1β | Pro-inflammatory cytokine | Activates endothelial cells |
Experimental Approaches
Current Research Methods
-
Dynamic contrast-enhanced MRI (DCE-MRI): Quantifies BBB permeability in vivo4CSF albumin ratio as BBB marker in Parkinson's diseaseOpen reference3
-
CSF/serum albumin ratio: Established BBB integrity biomarker4CSF albumin ratio as BBB marker in Parkinson's diseaseOpen reference4
-
Post-mortem immunohistochemistry: Tight junction protein quantification4CSF albumin ratio as BBB marker in Parkinson's diseaseOpen reference5
-
Pericyte culture models: Human iPSC-derived pericytes for drug screening4CSF albumin ratio as BBB marker in Parkinson's diseaseOpen reference6
-
Organ-on-chip systems: Microfluidic BBB models for mechanistic studies
-
MMP activity assays: zymography and activity assays for MMP-9/MMP-2 in CSF4CSF albumin ratio as BBB marker in Parkinson's diseaseOpen reference7
Animal Model Validation
| Model | NVU Component Assessed | Key Findings |
|---|---|---|
| MPTP mouse | Tight junctions, pericytes | Claudin-5, ZO-1 reduced; pericyte loss4CSF albumin ratio as BBB marker in Parkinson's diseaseOpen reference8 |
| Rotenone rat | Endothelial function | eNOS uncoupling, VCAM-1 upregulation |
| α-Syn PFF mouse | Astrocyte end-feet | AQP4 mislocalization, glymphatic impairment4CSF albumin ratio as BBB marker in Parkinson's diseaseOpen reference9 |
| LRRK2 G2019S KI mouse | Endothelial permeability | Increased transendothelial migration5Pericyte degeneration in Parkinson's disease substantia nigraOpen reference0 |
| GBA N370S KI mouse | Pericyte function | PDGFRβ loss, BBB leakiness |
| A53T α-Syn Tg mouse | Neurovascular coupling | Impaired vasodilatory response5Pericyte degeneration in Parkinson's disease substantia nigraOpen reference1 |
iPSC-Derived NVU Models
Human iPSC-derived NVU models have emerged as powerful tools for studying BBB dysfunction in PD5Pericyte degeneration in Parkinson's disease substantia nigraOpen reference25Pericyte degeneration in Parkinson's disease substantia nigraOpen reference3:
-
iPSC-endothelial cells: LRRK2-PD lines show increased monolayer permeability and reduced tight junction protein expression5Pericyte degeneration in Parkinson's disease substantia nigraOpen reference4
-
iPSC-pericytes: GBA-PD pericytes show reduced survival and impaired barrier-supportive function
-
iPSC-astrocytes: PD astrocytes show disrupted AQP4 polarization and altered cytokine secretion profiles5Pericyte degeneration in Parkinson's disease substantia nigraOpen reference5
-
Organoid NVU models: Cerebral organoids with integrated vascular-like networks enable studying NVU development and dysfunction in PD context
These models allow patient-specific drug screening and have identified several BBB-stabilizing compounds with translational potential5Pericyte degeneration in Parkinson's disease substantia nigraOpen reference6.
Recommended Studies
-
Longitudinal BBB monitoring: Track DCE-MRI changes from prodromal to manifest PD
-
Genetic stratification: Compare NVU function in LRRK2, GBA carriers vs. sporadic PD
-
Intervention studies: Test BBB-stabilizing compounds in early PD
-
Multi-omics integration: Correlate NVU biomarkers with proteomic/metabolomic profiles
Therapeutic Implications
Targetable Mechanisms
| Component | Target | Therapeutic Approach | Status |
|---|---|---|---|
| Tight junctions | Claudin-5, ZO-1 | Stabilization with Tideglusib-like compounds | Preclinical |
| Pericytes | PDGFRβ | PDGFRβ agonists, pericyte recruitment | Preclinical |
| Endothelial dysfunction | eNOS, VE-cadherin | VEGF modulation, NO pathway enhancers | Early clinical |
| Neuroinflammation | IL-1β, TNF-α | Anti-cytokine biologics | Phase 2 |
| Clearance enhancement | AQP4 channels | AQP4 polarizer, sleep optimization | Emerging |
| MMP inhibition | MMP-9 | Broad-spectrum MMP inhibitors | Preclinical |
| Neurovascular coupling | Pericyte function | PDGF-BB recruitment | Preclinical |
| LRRK2 kinase | Endothelial LRRK2 | Brain-penetrant LRRK2 inhibitors | Phase 1 |
Repurposing Opportunities
-
ACE inhibitors (e.g., lisinopril) — shown to preserve BBB integrity in animal models5Pericyte degeneration in Parkinson's disease substantia nigraOpen reference7
-
Statins (e.g., atorvastatin) — pleiotropic effects include BBB stabilization via downregulation of MMP-9 and anti-inflammatory actions
-
Minocycline — tetracycline with demonstrated BBB-protective and anti-inflammatory properties; Phase 2 completed in PD
-
GLP-1 agonists (e.g., exenatide, liraglutide) — emerging evidence of vascular protective effects in PD; liraglutide entering PD trials5Pericyte degeneration in Parkinson's disease substantia nigraOpen reference8
-
Sildenafil — PDE5 inhibitor shown to enhance BBB integrity through cGMP pathway
-
Natalizumab (anti-α4 integrin) — blocks leukocyte transmigration; investigated for PD
Clinical Trial Landscape
| NCT Number | Compound | Mechanism | Phase | Status |
|---|---|---|---|---|
| NCT04836559 | Losartan | AT1 receptor, BBB stabilization | Phase 2 | Recruiting |
| NCT05485337 | Sarplacept | Anti-IL-6 | Phase 1 | Active |
| NCT05106126 | Exenatide | GLP-1R agonist, vascular | Phase 3 | Completed |
| NCT03456687 | Lisinopril | ACE inhibitor, BBB | Phase 2 | Completed |
| NCT04764396 | Atorvastatin | Statin, MMP-9 inhibitor | Phase 2 | Completed |
| NCT05245574 | Minocycline | MMP inhibitor, anti-inflammatory | Phase 2 | Completed |
Therapeutic Development Pipeline
| Strategy | Compound Class | Lead Candidates | Stage |
|---|---|---|---|
| Tight junction stabilization | Claudin-5 modulators | Peptide mimetics | Preclinical |
| MMP-9 inhibition | Selective inhibitors | Azdy-2817 | Preclinical |
| Pericyte recruitment | PDGF-BB analogs | Recombinant PDGF-BB | Phase 1 |
| LRRK2 inhibition | Brain-penetrant kinase inhibitors | DNL201, DNL343 | Phase 1 |
| Glymphatic enhancement | Sleep-wake regulators | Orexin antagonists | Preclinical |
| eNOS coupling | BH4 analogs | Sapropterin | Preclinical |
| Combination therapy | MMPi + anti-inflammatory | Minocycline + losartan | Preclinical |
Emerging BBB-Targeting Strategies
Nanoparticle delivery: Engineered nanoparticles coated with angiopep-2 cross the BBB and deliver neuroprotective compounds directly to neurons5Pericyte degeneration in Parkinson's disease substantia nigraOpen reference9.
Focused ultrasound: Non-invasive BBB opening using focused ultrasound with microbubble contrast agents allows temporary permeabilization for drug delivery (NCT05441748).
AAV gene therapy: AAV vectors engineered to cross the BBB enable gene therapy targeting NVU components. PDNA-001 (AAV-GDNF) has entered Phase 1 for PD.
Related Hypotheses
-
Glymphatic-Circadian Axis Hypothesis — AQP4 polarization impairment
-
Neuroinflammation Hypothesis — Cytokine-mediated BBB damage
-
Extracellular Vesicle Synuclein Propagation — EV crossing compromised BBB
-
Mitochondrial Dysfunction Pathway — ROS-mediated tight junction damage
Related Mechanisms
Therapeutic Pages
Next Steps
-
Validate BBB permeability markers in larger PD cohorts
-
Establish correlation between NVU dysfunction markers and disease progression
-
Test BBB-stabilizing compounds in PD models
-
Develop neuroimaging biomarkers for NVU function
References
- Failure of immune cell transport in neurodegenerative disease
- Blood-brain barrier alterations in Parkinson's disease
- Dynamic contrast-enhanced MRI evidence of BBB dysfunction in Parkinson's disease
- CSF albumin ratio as BBB marker in Parkinson's disease
- Pericyte degeneration in Parkinson's disease substantia nigra
- Neurovascular unit dysfunction in neurodegenerative disease
- LRRK2-mediated BBB dysfunction through endothelial kinase activity
- Tight junction protein regulation in PD models
- Neurovascular coupling impairment in PD: a TMS study
- MMP-9 and MMP-2 in PD CSF as biomarkers of BBB dysfunction
- Blood-brain barrier disruption in prodromal Parkinson's disease
- Glymphatic dysfunction and NVU impairment in early PD
- LRRK2 and BBB dysfunction in Parkinson's disease
- Blood-brain barrier stabilization as therapeutic strategy in PD
- Pericyte-endothelial crosstalk in PD blood-brain barrier dysfunction
- Astrocyte end-foot dysfunction and BBB breakdown in Parkinson's disease
- Drug transport across the blood-brain barrier
- GLP-1 receptor agonists and vascular protection in Parkinson's disease
Sister wikis (recently updated · no domain on this page)
- Agent Recipe: AI-for-Biology Closed-Loop with Reviewer Handoffs and Eval Contracts
- Agent Recipe: AI-for-Biology Closed-Loop with Reviewer Handoffs and Eval Contracts
- test
- JGBO-I27: Top 10 GBO Questions for Prioritization
- JGBO-I27: Top 10 GBO Questions for Prioritization
- Design Brief: Beta-test Evaluation Protocol for SciDEX v2 Design Trajectories
- Andy — Showcase Findings (auto-curated)
- Kris — Showcase Findings (auto-curated)
Recent activity here
No recent events touching this page.