Transcranial Magnetic Stimulation in Progressive Supranuclear Palsy

Transcranial Magnetic Stimulation in PSP (NCT04468932)

Overview

This Phase 2 clinical trial investigates the use of repetitive [transcranial magnetic stimulation](/mechanisms/transcranial-magnetic-stimulation) (rTMS) as a potential treatment for motor and cognitive symptoms in [Progressive Supranuclear Palsy](/diseases/progressive-supranuclear-palsy)[@stamelou_2019]. The trial represents an innovative non-pharmacological approach to addressing the significant unmet medical needs in PSP, a rapidly progressive atypical parkinsonian disorder with limited treatment options.

Transcranial Magnetic Stimulation in PSP (NCT04468932)

Overview

This Phase 2 clinical trial investigates the use of repetitive [transcranial magnetic stimulation](/mechanisms/transcranial-magnetic-stimulation) (rTMS) as a potential treatment for motor and cognitive symptoms in [Progressive Supranuclear Palsy](/diseases/progressive-supranuclear-palsy)[@stamelou_2019]. The trial represents an innovative non-pharmacological approach to addressing the significant unmet medical needs in PSP, a rapidly progressive atypical parkinsonian disorder with limited treatment options.

Progressive supranuclear palsy (PSP) is a 4R-tauopathy characterized by vertical supranuclear gaze palsy, postural instability with falls, parkinsonism, and frontal cognitive dysfunction["@litvan_2018"]. Current pharmacological treatments provide minimal benefit, making non-invasive brain stimulation an attractive therapeutic avenue.

Study Details

| Parameter | Value |
|-----------|-------|
| NCT Number | NCT04468932 |
| Status | Recruiting |
| Study Type | Interventional (Phase 2) |
| Intervention | Repetitive Transcranial Magnetic Stimulation (rTMS) |
| Conditions | Progressive Supranuclear Palsy (PSP) |
| Design | Randomized, Sham-controlled |
| Allocation | Parallel |
| Blinding | Double-blind |

Background

PSP Pathophysiology

PSP involves progressive degeneration of subcortical and cortical structures[@niccolini_2015]:

| Brain Region | Pathology | Clinical Correlate |
|--------------|-----------|-------------------|
| Substantia nigra | Tau-positive NFTs | Parkinsonism |
| Globus pallidus | Neuronal loss | Rigidity, bradykinesia |
| Superior colliculus | Tau pathology | Gaze palsy |
| Frontal cortex | Neuronal loss | Cognitive dysfunction |
| Brainstem | Tau pathology | Dysphagia, sleep issues |

Frontal Cortical Dysfunction

The frontal cortex plays a critical role in PSP pathophysiology[@barbagallo_2020]:

• Impaired planning and organization
• Reduced verbal fluency
• Poor set-shifting

• Apathy
• Disinhibition
• Personality changes

• Impaired movement selection
• Failure of motor inhibition

rTMS as Therapeutic Modality

Repetitive transcranial magnetic stimulation uses electromagnetic induction to modulate cortical excitability[@responde_2019]. Key mechanisms include:

Neurophysiological Effects

• Long-term potentiation/depression: Synaptic plasticity modulation
• Transsynaptic effects: Downstream circuit modulation
• Neurotrophic factors: BDNF expression changes
• Network effects: Distant connectivity modifications

Clinical Applications

• Depression (FDA-approved)
• Chronic pain
• Movement disorders
• Cognitive enhancement

rTMS in Parkinsonian Disorders

Multiple studies have evaluated rTMS in Parkinson's disease and related disorders[@rektorova_2019]:

Parkinson's Disease Evidence

• High-frequency rTMS: Improves motor function (Level A evidence)[@lefaucheur_2014]
• Motor cortex targeting: Primary stimulation site
• Combined approaches: Motor + prefrontal for non-motor symptoms
• Durability: Effects may persist months after treatment course

Evidence in PSP and CBS[@arranz_2019]

• Limited but promising data
• Safety established in small cohorts
• Theoretical rationale strong given cortical involvement
• Need for rigorous randomized controlled trials

Trial Design

Treatment Protocol

Stimulation Parameters

• Frequency: High-frequency (typically 5-10 Hz) or theta-burst
• Intensity: 80-120% of motor threshold
• Pulses per session: 1000-2000 pulses
• Sessions: 10-20 sessions over 2-4 weeks

Target Regions

• Primary: Prefrontal cortex (DLPFC)
• Secondary: Motor cortex (M1)
• Rationale: Frontal dysfunction contributes significantly to PSP symptoms

Sham Control

• Active sham: Minimal stimulation at same scalp location
• Procedural sham: Coil positioned without stimulation
• Importance: Essential for placebo-controlled trial

Study Objectives

Primary Endpoints

• Adverse event monitoring
• Serious adverse events
• Discontinuation rate

• PSP Rating Scale (PSPRS)
• Motor subscores
• Gait and balance measures

Secondary Endpoints

• Montreal Cognitive Assessment (MoCA)
• Trail Making Test
• Verbal fluency

• Apathy Evaluation Scale
• Frontal Assessment Battery

• PSP Quality of Life questionnaire
• Caregiver burden measures

Assessment Schedule

| Timepoint | Assessments |
|-----------|-------------|
| Baseline | Full clinical assessment |
| Mid-treatment | Safety, preliminary efficacy |
| Post-treatment | Primary endpoints |
| Follow-up | Durability assessment (1-3 months) |

Mechanism of Action in PSP

Targeting Frontal Dysfunction

rTMS may benefit PSP through several mechanisms:

1. Cortical Excitability Modulation

• Enhanced motor cortex excitability
• Restored cortical-inhibitory balance
• Improved motor output

2. Frontal Circuit Enhancement

• Prefrontal cortex activation
• Executive function improvement
• Behavioral symptom reduction

3. Network Effects

• Modulation of frontal-striatal circuits
• Thalamic relay effects
• Brainstem connections

4. Neuroplasticity

• Synaptic strengthening
• BDNF elevation
• Functional reorganization

Evidence from Related Conditions

Parkinson's Disease Meta-Analyses[@bologna_2020]

• Significant motor improvement after rTMS
• Effect size: moderate (Hedges' g = 0.4-0.6)
• Best results with high-frequency M1 stimulation

Cognitive Effects in PD[@di_giacomo_2022]

• Prefrontal rTMS improves executive function
• Working memory enhancement
• Attention benefits

Clinical Considerations

PSP Clinical Features and rTMS Potential

| PSP Symptom | rTMS Target | Expected Benefit |
|-------------|-------------|------------------|
| Bradykinesia | M1 | Improved movement initiation |
| Rigidity | M1 | Reduced muscle tone |
| Gaze palsy | Frontal eye fields | Limited direct benefit |
| Falls | DLPFC/motor | Postural control |
| Cognitive decline | DLPFC | Executive function |
| Apathy | DLPFC | Mood and motivation |

Patient Selection

Inclusion Considerations

Exclusion Considerations

• Seizure history
• Metallic implants in head
• Pacemaker
• Active epilepsy

• Severe cardiac disease
• Active psychiatric illness
• Unable to lie comfortably

Safety Profile

rTMS is generally well-tolerated[@lefaucheur_2014]:

Common (mild, transient)

• Headache (up to 30%)
• Scalp discomfort
• Transient hearing changes

Rare (serious but uncommon)

• Seizure (<0.1% with appropriate protocols)
• Mania (in vulnerable individuals)
• Local skin irritation

Significance for PSP Treatment

Unmet Medical Needs in PSP

PSP has limited treatment options[@golbe_2014]:

Pharmacological Approaches

• Limited efficacy: No disease-modifying drugs
• Symptomatic treatments: Modest benefits only
• Off-label use: Various agents with minimal evidence

Non-Pharmacological Approaches

• Physical therapy: Falls prevention, mobility
• Occupational therapy: ADL optimization
• Speech therapy: Dysphagia management
• Neuropsychology: Cognitive strategies

rTMS Advantages for PSP

Comparison to Other PSP Trials

| Trial | Intervention | Phase | Status | Outcome |
|-------|-------------|-------|--------|---------|
| NCT04468932 | rTMS | Phase 2 | Recruiting | Motor, cognitive |
| NCT05318985 | Bepranemab | Phase 2 | Active | Tau reduction |
| NCT04564555 | CoQ10 | Phase 3 | Completed | Minimal benefit |
| NCT05297202 | Lithium | Phase 2 | Completed | Negative |

Future Directions

Combination Approaches

rTMS may be combined with:

• Physical therapy: Enhanced motor recovery
• Cognitive training: Synergistic cognitive benefits
• Pharmacological: Adjunct to medications
• Other NIBS: tDCS, transcranial focused ultrasound

Biomarker Development

Future trials may incorporate:

• Neurophysiological markers (MEP, SICI)
• Neuroimaging (connectivity changes)
• Fluid biomarkers
• Clinical endpoint validation

Related Mechanisms and Pathways

PSP Pathogenesis

• [Tau Pathology](/mechanisms/tau-pathology)
• [4R-Tauopathies](/mechanisms/4r-tauopathies)
• [Frontal Cortical Dysfunction](/mechanisms/frontal-cortical-dysfunction)
• [Basal Ganglia Degeneration](/mechanisms/basal-ganglia-degeneration)

rTMS Mechanisms

• [Cortical Excitability Modulation](/mechanisms/cortical-excitability)
• [Neuroplasticity Induction](/mechanisms/neuroplasticity)
• [Network Connectivity Effects](/mechanisms/network-connectivity)

Related Clinical Trials

• [PSP Treatment Trials](/clinical-trials/progressive-supranuclear-palsy-trials)
• [Non-motor Symptoms in PSP](/clinical-trials/psp-non-motor)
• [Other NIBS Trials](/clinical-trials/transcranial-stimulation-trials)

See Also

• [Progressive Supranuclear Palsy](/diseases/progressive-supranuclear-palsy)
• [Transcranial Magnetic Stimulation](/mechanisms/transcranial-magnetic-stimulation)
• [Clinical Trials](/clinical-trials)
• [PSP Clinical Trials](/clinical-trials/psp-trials)
• [Non-invasive Brain Stimulation](/mechanisms/non-invasive-brain-stimulation)
• [Frontal Lobe Disorders](/mechanisms/frontal-lobe-disorders)

External Links

• [ClinicalTrials.gov NCT04468932](https://clinicaltrials.gov/study/NCT04468932)
• [CurePSP Foundation](https://www.psp.org)
• [International Parkinson and Movement Disorders Society](https://www.mds.org)

References