Neuroinflammation imaging using PET tracers provides critical in vivo insights into the inflammatory processes underlying corticobasal syndrome (CBS) and progressive supranuclear palsy (PSP). Both conditions are characterized by prominent microglial activation and neuroinflammation, which correlate with disease severity, progression, and therapeutic response. This page covers TSPO PET imaging, second-generation tracers, monoamine oxidase B (MAO-B) imaging, magnetic resonance spectroscopy (MRS) for neuroinflammation, and their applications in CBS/PSP diagnosis and treatment monitoring.
¶ Background and Rationale
The translocator protein (TSPO), formerly known as the peripheral benzodiazepine receptor, is a mitochondrial protein highly expressed in activated microglia and reactive astrocytes. Under normal conditions, TSPO expression is low in the brain, but it increases dramatically during neuroinflammation. TSPO PET imaging allows visualization and quantification of microglial activation in vivo, providing a biomarker for neuroinflammatory processes in neurodegenerative diseases including CBS and PSP.
TSPO PET imaging has emerged as a powerful tool to:
- Detect early neuroinflammatory changes before clinical symptoms manifest
- Track disease progression and inflammatory burden
- Monitor response to anti-inflammatory therapies
- Differentiate CBS/PSP from other neurodegenerative conditions
- Correlate inflammation levels with clinical severity
¹¹C-PK11195 was the first TSPO PET tracer developed and remains a benchmark for neuroinflammation imaging. It demonstrates specific binding to TSPO in regions of active neuroinflammation.
Key characteristics:
- High affinity for TSPO in activated microglia
- Demonstrates increased binding in CBS/PSP motor cortex, basal ganglia, and brainstem
- Correlates with disease severity measured by clinical rating scales
- Limitations: high non-specific binding, moderate signal-to-noise ratio
Findings in CBS/PSP:
- ¹¹C-PK11195 PET shows elevated binding in the motor cortex (2-3x control levels) and basal ganglia in CBS patients
- PSP patients show increased TSPO binding in the substantia nigra, brainstem, and basal ganglia
- Regional patterns differ from Alzheimer's disease, with more focal inflammation in CBS
- Binding correlates with clinical severity and disease duration
Second-generation TSPO tracers offer improved pharmacokinetics, reduced non-specific binding, and better signal-to-noise ratios compared to PK11195. However, they exhibit variable affinity depending on TSPO polymorphisms (rs6971 polymorphism), which complicates quantitative analysis.
¹¹C-PBR28 (also known as ¹¹C-PBR28 or DPA-714 precursor) is a second-generation TSPO tracer with improved binding characteristics.
Advantages over PK11195:
- Higher brain uptake and better signal-to-noise ratio
- Faster kinetics, enabling shorter scanning protocols
- Higher specific-to-non-specific binding ratio
Clinical findings in CBS/PSP:
- PBR28 demonstrates high binding in motor and premotor cortices of CBS patients
- Sensitive to subtle inflammatory changes in early disease stages
- Useful for monitoring anti-inflammatory treatment effects
¹⁸F-DPA-714 is a fluorine-18 labeled TSPO tracer with favorable properties for clinical use.
Key features:
- Longer half-life (110 min) compared to ¹¹C-labeled tracers
- High affinity for TSPO with moderate sensitivity to polymorphism
- Excellent brain penetration and kinetics
Applications in CBS/PSP:
- DPA-714 PET reveals widespread neuroinflammation in CBS, particularly in affected brain regions
- Shows promise for longitudinal tracking of inflammation
- Useful for therapeutic trials targeting microglial activation
¹⁸F-GE-180 is a third-generation TSPO tracer with improved specificity and reduced polymorphism effects.
Advantages:
- Lower affinity for the high-affinity TSPO binding site
- Less affected by TSPO polymorphisms
- High signal-to-noise ratio
Emerging data in CBS/PSP:
- Early studies show promising results in tauopathies
- Potential for standardized quantification across patients
| Region |
CBS |
PSP |
Interpretation |
| Motor cortex |
Very high (+++) |
Moderate (++) |
More focal inflammation in CBS |
| Premotor cortex |
High (++) |
High (++) |
Similar involvement |
| Basal ganglia |
Moderate (++) |
High (+++) |
Greater in PSP |
| Substantia nigra |
High (++) |
Very high (+++) |
PSP shows more severe involvement |
| Brainstem |
Moderate (+) |
High (++) |
More prominent in PSP |
| Cerebellum |
Low (+) |
Variable |
May relate to disease variant |
The P2X7 purinergic receptor is specifically expressed on activated microglia and represents a more specific marker of neuroinflammation than TSPO. Several P2X7 PET tracers are under development.
Rationale:
- P2X7 is specifically upregulated in disease-associated microglia
- May provide better specificity for pathogenic neuroinflammation
- Potential to distinguish beneficial vs harmful microglial activation
Tracer development:
- ¹¹C-KB31 shows promising P2X7 binding in preclinical models
- ¹⁸F-JNJ-54173717 has entered early clinical testing
CSF1R is involved in microglial proliferation and survival. PET tracers targeting CSF1R may allow visualization of microglial density changes.
Emerging tracers:
- ¹⁸F-PBMC (pyrimidine-4,6-dicarboxamide derivative) shows promise for CSF1R imaging
MAO-B is predominantly expressed in astrocytes and catalyzes the oxidative deamination of monoamines. In neurodegenerative diseases, MAO-B expression increases in astrocytes surrounding tau pathology, making it a biomarker for astrocyte reactivity and neuroinflammation in CBS/PSP.
¹¹C-L-deprenyl (also known as ¹¹C-deprenyl) binds irreversibly to MAO-B and provides in vivo measurement of MAO-B density.
Characteristics:
- High affinity for MAO-B in brain
- Irreversible binding allows long scanning windows
- Reflects astrocyte density and reactivity
Findings in CBS/PSP:
- Increased ¹¹C-deprenyl binding in basal ganglia and cortical regions in CBS
- PSP shows elevated MAO-B in brainstem and basal ganglia
- Levels correlate with disease severity and progression
¹¹C-SS-PET is a reversible MAO-B tracer with improved kinetics compared to deprenyl.
Advantages:
- Reversible binding enables dynamic quantification
- Less susceptible to baseline effects
- Better for measuring changes over time
MAO-B PET imaging in CBS/PSP serves several clinical purposes:
- Diagnostic differentiation: MAO-B patterns help distinguish CBS/PSP from other parkinsonian syndromes
- Disease staging: Higher MAO-B binding correlates with more advanced disease
- Prognosis: MAO-B levels predict rate of clinical progression
- Treatment monitoring: MAO-B inhibitors (rasagiline, selegiline) reduce binding, enabling verification of target engagement
Magnetic resonance spectroscopy allows non-invasive measurement of brain metabolites that reflect neuroinflammatory processes. Unlike PET, MRS does not require radiotracers and can be performed on standard MRI scanners.
Myo-inositol is primarily located in glial cells (astrocytes and microglia) and serves as a marker of glial cell density and activation.
In CBS/PSP:
- Elevated myo-inositol levels in the frontal cortex and basal ganglia
- Reflects astrocyte reactivity and neuroinflammation
- Increases with disease progression
- Correlates with clinical severity scores
Choline levels reflect membrane turnover and cellular proliferation, including inflammatory cell infiltration.
Findings:
- Elevated choline in affected brain regions in CBS
- Indicates increased inflammatory cell activity
- May help differentiate CBS from AD
Lactate accumulation indicates impaired energy metabolism and anaerobic glycolysis, which can result from neuroinflammation.
Clinical significance:
- Elevated lactate in basal ganglia and cortex in CBS/PSP
- Reflects mitochondrial dysfunction and inflammation
- Correlates with disease severity
Recommended brain regions for CBS/PSP assessment:
| Region |
Primary metabolites |
Clinical relevance |
| Frontal cortex |
Myo-inositol, Choline |
Disease severity |
| Basal ganglia (putamen) |
Myo-inositol, Lactate |
Neuroinflammation burden |
| Midbrain (substantia nigra) |
Choline, NAA |
Neuronal loss |
| Cerebellum |
Myo-inositol |
Disease variant |
Technical parameters:
- PRESS or MEGA-PRESS sequences
- TE = 30-35 ms for optimal metabolite detection
- Voxel size: 8-16 mm³
- Scan time: 15-20 minutes
Neuroinflammation PET imaging enables direct monitoring of anti-inflammatory treatment effects in CBS/PSP.
Key applications:
- Target verification: Confirm that therapeutic agents reach neuroinflammation sites
- Dose optimization: Identify optimal doses that reduce neuroinflammation
- Response prediction: Early inflammation reduction may predict clinical benefit
- Mechanism of action: Verify that treatments reduce microglial activation
- TREM2 agonists: Ongoing development, PET can monitor microglial changes
- CSF1R inhibitors: Reduce microglial proliferation, measurable by TSPO PET
- Minocycline: Antibiotic with anti-microglial effects, studied in PSP
- MAO-B inhibitors: Rasagiline, selegiline reduce astrocyte reactivity
- Anti-inflammatory agents: NSAID effects measurable by TSPO PET
Emerging applications:
- Combination biomarkers: TSPO PET + MRS for comprehensive inflammation assessment
- Personalized medicine: Select patients based on neuroinflammation levels for specific therapies
- Trial enrichment: Use baseline inflammation levels to enrich clinical trials
- Network analysis: Correlate inflammation patterns with functional connectivity changes
Neuroinflammation PET imaging provides critical biomarkers for understanding, diagnosing, and treating CBS and PSP. Key findings include:
- TSPO PET (PK11195, PBR28, DPA-714, GE-180): Reveals microglial activation patterns that differ between CBS and PSP, with CBS showing more focal inflammation in motor cortex and PSP showing more widespread brainstem involvement
- MAO-B imaging (¹¹C-deprenyl): Provides measure of astrocyte reactivity, useful for disease staging and treatment monitoring
- MRS: Offers complementary information on neuroinflammation through myo-inositol, choline, and lactate measurements
- Therapeutic implications: Enables verification of anti-inflammatory treatment effects and guides personalized treatment selection
These imaging modalities provide a comprehensive toolkit for understanding neuroinflammation in CBS/PSP and developing disease-modifying therapies targeting inflammatory pathways.