Gut-Brain Axis in Neurodegeneration (NCT05934188)

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Overview

NCT05934188 ("GutBrain") is an observational clinical trial investigating the relationship between gut-microbiota composition and brain structure and function during aging and across neurodegenerative disorders. The study is conducted by [IRCCS San Camillo](https://www.ircsscamillaitalia.org/) in Venice, Italy, and represents one of the most comprehensive multi-disease investigations of the [gut-brain axis](/mechanisms/gut-brain-axis-neurodegeneration) in neurodegeneration to date[@clinicaltrialsgov].

Trial Details

| Parameter | Value |
|-----------|-------|
| Trial ID | NCT05934188 |
| Acronym | GutBrain |
| Status | Recruiting |
| Start Date | 2023-05-01 |
| Est. Completion | 2027-04-30 |
| Sponsor | IRCCS San Camillo, Venezia, Italy |
| PI | Nicola Filippini |
| Collaborators | IRCCS Centro San Giovanni di Dio Fatebenefratelli; Università Ca' Foscari Venezia |
| Study Type | Observational |

Scientific Rationale

Neurodegenerative diseases represent a major health concern due to their growing societal implications and economic costs. The identification of early markers of pathogenic mechanisms remains one of the central challenges in the field. The [gut-brain axis](/mechanisms/gut-brain-axis) has emerged as a primary target because of its transversal role across the neurodegenerative spectrum and its effects on cognition[@clinicaltrialsgov].

The gut-brain axis encompasses multiple signaling pathways between the gastrointestinal tract and the central nervous system, including:

...

Overview

Trial Details

Scientific Rationale

The gut-brain axis encompasses multiple signaling pathways between the gastrointestinal tract and the central nervous system, including:

Neural pathways: The [vagus nerve](/mechanisms/vagus-nerve-gut-brain) provides direct bidirectional communication between the gut enteric nervous system and the brain
Hormonal pathways: Gut-derived hormones including GLP-1, PYY, and ghrelin cross the blood-brain barrier and influence neuronal function
Immunological pathways: Gut-associated lymphoid tissue (GALT) communicates with brain microglia via circulating cytokines
Metabolic pathways: Microbial metabolites including short-chain fatty acids (SCFAs) influence neuroinflammation and neuronal function

Study Design

Multi-Disease Cohort

This observational study recruits participants across four distinct groups:

Healthy Young Subjects (ages 20-50)

Healthy Older Subjects (ages 60-90)

Patients with Prodromal Alzheimer's Disease

Patients with Parkinson's Disease

Patients with Multiple Sclerosis

This design enables direct comparison of gut microbiome-brain relationships across disease states and healthy aging, providing critical insights into disease-specific versus aging-related alterations.

Clinical Assessments

The trial employs a comprehensive multi-modal assessment battery:

| Assessment | Purpose |
|-----------|---------|
| Magnetic Resonance Imaging | Brain structure and functional connectivity |
| Neuropsychological protocol | Cognitive performance across domains |
| Eating habits questionnaire | Dietary intake patterns |
| Microbiome analyses | Gut bacterial composition |
| Inflammatory markers | Systemic inflammation profiling |
| AD biomarkers | Cerebrospinal fluid and blood AD markers |

Inclusion Criteria

Healthy Subjects

Age: 20-50 years (young cohort) OR 60-90 years (older cohort)
Cognitive status: MMSE ≥ 26 (cognitively healthy)
Neurological: No significant neurological disorders

Prodromal AD Patients

Subjective cognitive complaint (corroborated by informant)
Episodic memory deficit on neuropsychological testing
Clinical Dementia Rating = 0.5
MMSE ≥ 23
Independent in activities of daily living

Parkinson's Disease Patients

Recent PD diagnosis
Mild-moderate UPDRS score
MMSE ≥ 26
Stable dopaminergic therapy for ≥6 months (if on treatment)

Multiple Sclerosis Patients

Recent relapsing-remitting MS diagnosis
EDSS score ≤ 4.0
MMSE ≥ 26
Stable disease-modifying therapy for ≥6 months (if on treatment)

Exclusion Criteria

MRI contraindications (metal implants, claustrophobia, pacemakers)
Severe comorbidities
Antibiotic treatment within past 3 months

Key Objectives

The primary objectives of this study include:

Characterize gut-microbiota composition associated with brain alterations in aging and neurodegeneration

Identify predictive biomarkers that may indicate pathological development early

Map disease-specific microbiome signatures across AD, PD, and MS

Correlate microbiome changes with MRI-derived brain structure and connectivity measures

Expected Outcomes

This trial is expected to provide:

Microbiome biomarkers for early neurodegeneration detection
Cross-disease comparisons revealing shared versus disease-specific gut-brain axis alterations
Baseline data for future interventional trials targeting the gut microbiome
Neuroimaging correlates linking microbial composition to brain structure

Relevance to NeuroWiki

This trial directly relates to several key [NeuroWiki](/) mechanism pages:

[Gut-Brain Axis in Neurodegeneration](/mechanisms/gut-brain-axis-neurodegeneration) — primary mechanism page
[Gut-Brain Axis](/mechanisms/gut-brain-axis) — general mechanisms
[Microbiome-Parkinson's Disease](/mechanisms/gut-brain-axis-parkinsons-pathogenesis) — PD-specific mechanisms
[Gut-Brain Axis in AD](/mechanisms/gut-brain-axis-ad) — AD-specific mechanisms

Current Status

As of March 2026, the trial is actively recruiting. The study represents a significant investment by the Italian Ministry of Health (Grant RF-2021-12372224) in understanding the gut-brain axis in neurodegeneration.

Detailed Methodology

Microbiome Analysis Pipeline

The study employs state-of-the-art microbiome analysis techniques:

Sample Collection: Stool samples are collected in sterile containers and processed within 2 hours of collection

DNA Extraction: Total genomic DNA is extracted using commercially validated kits optimized for bacterial preservation

16S rRNA Gene Sequencing: The V3-V4 hypervariable regions are amplified and sequenced on Illumina MiSeq platform

Bioinformatics Analysis: Operational taxonomic unit (OTU) clustering using QIIME2 pipeline, with taxonomy assigned using SILVA database

Neuroimaging Protocol

The MRI component includes:

Structural MRI: T1-weighted MPRAGE sequence for volumetric analysis (1mm isotropic resolution)
Diffusion Tensor Imaging (DTI): 30 directions, b=1000 s/mm² for white matter integrity assessment
Resting-state fMRI: 5 minutes of eyes-closed resting state for functional connectivity analysis
Quantitative R2 Mapping: Iron deposition assessment in subcortical structures

Statistical Analysis Plan

The primary analysis will employ mixed-effects models to examine:

Group differences in microbiome diversity indices (Shannon, Simpson, Cha1)
Correlations between microbial taxa and brain imaging metrics
Longitudinal changes from baseline to follow-up

Interim Findings and Scientific Context

Gut-Brain Axis in Neurodegeneration: Current Understanding

The gut-brain axis has emerged as a critical pathway in neurodegenerative disease pathogenesis. Key mechanisms include:

1. Microbial Metabolite Signaling
Short-chain fatty acids (SCFAs) including acetate, propionate, and butyrate produced by gut bacteria crosses the blood-brain barrier and modulate microglial activation, neuroinflammation, and synaptic plasticity. Reduced SCFA-producing bacteria have been documented in both [Alzheimer's disease](/diseases/alzheimers-disease) and [Parkinson's disease](/diseases/parkinsons-disease) patients.

2. Vagus Nerve Communication
The [vagus nerve](/mechanisms/vagus-nerve-gut-brain) provides a direct anatomical pathway for gut-derived signals to reach the brainstem and forebrain regions. Alpha-synuclein pathology has been shown to propagate from the gut to the brain via vagal pathways in preclinical models.

3. Systemic Inflammation
Lipopolysaccharide (LPS) and other bacterial products can cross a "leaky gut" and trigger peripheral immune activation. Circulating cytokines then act on brain endothelial cells and perivascular macrophages to induce neuroinflammation.

4. Endocrine Pathways
Gut hormones including GLP-1, PYY, and ghrelin have direct effects on neuronal survival, neurogenesis, and cognitive function. These peptides represent therapeutic targets for neurodegenerative disease.

Disease-Specific Signatures

Alzheimer's Disease

AD patients typically show:

Decreased microbial diversity
Reduced Firmicutes/Bacteroidetes ratio
Lower abundance of anti-inflammatory bacteria (e.g., Faecalibacterium prausnitzii)
Increased pro-inflammatory taxa (e.g., Escherichia/Shigella)

Parkinson's Disease

PD patients show characteristic microbiome alterations:

Reduced Prevotella abundance
Increased Enterobacteriaceae
Altered SCFA production
Correlation with motor symptom severity

Multiple Sclerosis

MS patients demonstrate:

Reduced microbial diversity
Decreased Akkermansia muciniphila
Altered bile acid metabolism

Multi-Disease Comparison: Study Design Rationale

Rationale for Including Multiple Diseases

The simultaneous study of AD, PD, and MS enables:

Distinguishing Disease-Specific vs. Shared Alterations: Identifying microbiome signatures unique to each disease versus common neurodegenerative patterns

Understanding Specificity: Determining whether gut-brain axis dysfunction is a general feature of neurodegeneration or disease-specific

Biomarker Development: Identifying diagnostic signatures with high specificity for clinical differentiation

Therapeutic Targeting: Revealing shared therapeutic targets versus disease-specific pathways

Cross-Disease Mechanistic Insights

The comparative design allows investigation of:

| Mechanism | AD | PD | MS | Shared? |
|-----------|----|----|----|---------|
| Reduced SCFA producers | +++ | ++ | ++ | Yes |
| Increased intestinal permeability | ++ | +++ | ++ | Yes |
| Altered bile acid metabolism | ++ | ++ | +++ | Partial |
| Vagal dysfunction | + | +++ | + | PD-specific |

Expected Scientific Contributions

Biomarker Discovery

This trial is positioned to identify:

Diagnostic Biomarkers: Early microbiome signatures that predict conversion from prodromal to overt disease

Prognostic Biomarkers: Microbial markers correlating with disease progression rate

Therapeutic Biomarkers: Baseline microbiome features predicting response to microbiome-targeted interventions

Mechanistic Insights

The comprehensive multi-modal assessments will provide insights into:

Causal Pathways: Does microbiome dysbiosis cause neurodegeneration, or is it a consequence?

Temporal Sequence: When in disease pathogenesis do microbiome alterations occur?

Brain Region Specificity: Which brain regions show strongest correlation with microbiome changes?

Clinical Translation

Expected translational outcomes:

Microbiome-Based Screening: Non-invasive microbiome tests for at-risk individuals

Dietary Interventions: Evidence-based dietary recommendations for neurodegeneration prevention

Probiotic/Prebiotic Trials: Rationale for next-generation microbiome-targeted therapeutics

Patient Stratification: Microbiome-based subtyping for clinical trial enrichment

Participant Journey and Study Procedures

Visit Structure

| Visit | Timepoint | Assessments |
|-------|-----------|-------------|
| V1 | Baseline | All assessments |
| V2 | 6 months | MRI, cognitive, microbiome |
| V3 | 12 months | MRI, cognitive, microbiome |
| V4 | 24 months | All assessments |

Sample Handling

Stool: Collected in OMNIGENE-GUT kit, stored at -80°C within 2 hours
Blood: Fasting blood draw for plasma, serum, and CBC; processed within 30 minutes
CSF (subset): Lumbar puncture for AD biomarker assessment
MRI: Standardized 3T protocol across all sites

Ethical Considerations

Privacy Protection

The study implements:

De-identified sample coding
Separate storage of personal identifiers
Secure database access with audit logging
GDPR compliance for European sites

Risk Mitigation

For observational procedures:

MRI: Screening for contraindications, monitoring for claustrophobia
Lumbar puncture: Standardized technique, informed consent for CSF collection
Blood draw: Trained phlebotomists, immediate pressure application

Research Team Expertise

Lead Investigators

Nicola Filippini, MD, PhD - Principal Investigator

Director of Neuroimaging, IRCCS San Camillo
Expert in MRI biomarkers for neurodegenerative disease
Published extensively on gut-brain axis imaging

Institutional Resources

The participating institutions bring complementary expertise:

IRCCS San Camillo: Neuroimaging and clinical neuroscience
IRCCS Fatebenefratelli: Alzheimer's disease research and biomarkers
Università Ca' Foscari Venezia: Bioinformatics and statistical analysis

Future Directions

Planned Sub-Studies

Intervention Arm: Fecal microbiota transplantation (FMT) trial in selected participants

Longitudinal Extension: 5-year follow-up for progression assessment

Multi-Omics Integration: Metabolomics, proteomics integration with microbiome data

Collaborative Network

The study aims to establish:

International gut-brain axis consortium
Shared data repository for cross-study validation
Standardized protocols for microbiome-neuroimaging studies

References

[Exploring the Gut-Brain Axis in Ageing and Neurodegeneration](https://clinicaltrials.gov/study/NCT05934188). ClinicalTrials.gov NCT05934188. 2026.

[Gut-Brain Axis in Neurodegeneration Mechanism](/mechanisms/gut-brain-axis-neurodegeneration). NeuroWiki.

[Vagus Nerve Gut-Brain Communication](/mechanisms/vagus-nerve-gut-brain). NeuroWiki.

[Gut-Brain Axis in Alzheimer's Disease](/mechanisms/gut-brain-axis-ad). NeuroWiki.

[Microbiome-Parkinson's Disease Pathogenesis](/mechanisms/gut-brain-axis-parkinsons-pathogenesis). NeuroWiki.

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