Somatostatin Signaling Pathway in Neurodegeneration

Somatostatin Signaling Pathway in Neurodegeneration

Overview

Somatostatin Signaling Pathway in Neurodegeneration describes a key molecular or cellular mechanism implicated in neurodegenerative disease. This page provides a detailed overview of the pathway components, signaling cascades, and their relevance to conditions such as Alzheimer's disease, Parkinson's disease, and related disorders. [@tannebaum2006]

Somatostatin is a neuropeptide that plays crucial roles in modulating neuronal signaling, synaptic plasticity, and neuroprotection. This page covers the somatostatin signaling pathway and its implications in neurodegenerative diseases. [@kumar2005]

Somatostatin Biology

Somatostatin Peptides

• Somatostatin-14 (SST-14): The predominant form, 14 amino acids
• Somatostatin-28 (SST-28): Longer form with distinct tissue distribution
• Both derived from preprosomatostatin (PPS) gene

Somatostatin Receptors (SSTRs)

Five somatostatin receptor subtypes have been identified: [@muller2009]

• SSTR1 - Gi/o-coupled, inhibits adenylate cyclase
• SSTR2 - Gi/o-coupled, primary mediator of antiproliferative effects
• SSTR3 - Gi/o-coupled, associated with [apoptosis](/entities/apoptosis)
• SSTR4 - Gi/o-coupled, cognitive effects
• SSTR5 - Gi/o-coupled, growth hormone inhibition

Signal Transduction Pathways

Primary Signaling Mechanisms

Somatostatin receptors are Gi/o-protein-coupled receptors that activate multiple intracellular pathways: [@epelbaum2007]

...

Somatostatin Signaling Pathway in Neurodegeneration

Overview

Somatostatin Signaling Pathway in Neurodegeneration describes a key molecular or cellular mechanism implicated in neurodegenerative disease. This page provides a detailed overview of the pathway components, signaling cascades, and their relevance to conditions such as Alzheimer's disease, Parkinson's disease, and related disorders. [@tannebaum2006]

Somatostatin is a neuropeptide that plays crucial roles in modulating neuronal signaling, synaptic plasticity, and neuroprotection. This page covers the somatostatin signaling pathway and its implications in neurodegenerative diseases. [@kumar2005]

Somatostatin Biology

Somatostatin Peptides

• Somatostatin-14 (SST-14): The predominant form, 14 amino acids
• Somatostatin-28 (SST-28): Longer form with distinct tissue distribution
• Both derived from preprosomatostatin (PPS) gene

Somatostatin Receptors (SSTRs)

Five somatostatin receptor subtypes have been identified: [@muller2009]

• SSTR1 - Gi/o-coupled, inhibits adenylate cyclase
• SSTR2 - Gi/o-coupled, primary mediator of antiproliferative effects
• SSTR3 - Gi/o-coupled, associated with [apoptosis](/entities/apoptosis)
• SSTR4 - Gi/o-coupled, cognitive effects
• SSTR5 - Gi/o-coupled, growth hormone inhibition

Signal Transduction Pathways

Primary Signaling Mechanisms

Somatostatin receptors are Gi/o-protein-coupled receptors that activate multiple intracellular pathways: [@epelbaum2007]

Downstream Effects

cAMP reduction: Decreased PKA activity

PI3K/Akt activation: Pro-survival signaling

ERK1/2 modulation: Growth and differentiation

Ion channel modulation: Hyperpolarization, reduced excitotoxicity

Calcium channel inhibition: Reduced calcium influx

Role in Alzheimer's Disease

Cognitive Function

Somatostatin is critically involved in hippocampal synaptic plasticity and memory formation: [@ladenheim1995]

• Modulates GABAergic interneurons
• Regulates hippocampal theta oscillations
• Influences memory consolidation and retrieval

Amyloid-Tau Interactions

• Somatostatin regulates [amyloid precursor protein](/entities/app-protein) (APP) processing
• SST deficiency may increase [Aβ](/proteins/amyloid-beta) production
• Aβ pathology reduces somatostatin expression
• [Tau](/proteins/tau) pathology affects somatostatin neuron function

Therapeutic Potential

• SSTR2 agonists: May reduce Aβ production
• SSTR4 modulation: Cognitive enhancement
• Pan-somatostatin analogs: Neuroprotective effects

Role in Parkinson's Disease

Dopaminergic System

• Somatostatin modulates dopaminergic neuron activity
• SSTR2 expression in substantia nigra
• Regulation of motor control circuits

Neuroprotection

• Reduces excitotoxicity in dopaminergic [neurons](/entities/neurons)
• Anti-inflammatory effects in the substantia nigra
• May protect against [α-synuclein](/proteins/alpha-synuclein) toxicity

Clinical Implications

• Somatostatin analogs: Potential disease modification
• SSTR2-selective compounds: Motor symptom management

Role in ALS

Motor Neuron Biology

• Somatostatin in spinal cord interneurons
• Modulation of excitatory neurotransmission
• Potential protection against excitotoxicity

Therapeutic Strategies

• SSTR2 agonism: Motor neuron survival
• Combined SSTR targeting: Broader neuroprotection

Other Neurodegenerative Conditions

Huntington's Disease

• Somatostatin interneurons in striatum
• Motor dysfunction modulation
• Therapeutic targeting potential

Multiple System Atrophy

• Autonomic dysfunction connections
• SSTR expression in autonomic nuclei

Therapeutic Targeting

Pharmacologic Approaches

| Compound | Target | Status | Indication |
|----------|--------|--------|------------|
| Octreotide | SSTR2 | Approved | Acromegaly |
| Pasireotide | SSTR1/2/3/5 | Approved | Cushing's disease |
| Lanreotide | SSTR2/5 | Approved | Acromegaly |

Experimental Strategies

SSTR2-selective agonists: Neuroprotection

SSTR4 modulators: Cognitive enhancement

Peripheral vs central targeting: [BBB](/entities/blood-brain-barrier) considerations

Challenges

• BBB penetration of somatostatin analogs
• Receptor subtype selectivity
• Long-term treatment effects

Cross-Linking

• [GABA Signaling](/mechanisms/gaba-signaling)
• [Neuroinflammation](/mechanisms/neuroinflammation-pathway)
• [Excitotoxicity](/mechanisms/excitotoxicity-pathway)
• [Alzheimer's Disease](/diseases/alzheimers-disease)
• [Parkinson's Disease](/diseases/parkinsons-disease)
• [Amyotrophic Lateral Sclerosis](/diseases/amyotrophic-lateral-sclerosis)

See Also

• [GABA Signaling](/mechanisms/gaba-signaling)
• [Neuroinflammation](/mechanisms/neuroinflammation-pathway)
• [Excitotoxicity](/mechanisms/excitotoxicity-pathway)
• [Alzheimer's Disease](/diseases/alzheimers-disease)
• [Parkinson's Disease](/diseases/parkinsons-disease)
• [Amyotrophic Lateral Sclerosis](/diseases/amyotrophic-lateral-sclerosis)

External Links

• [PubMed](https://pubmed.ncbi.nlm.nih.gov/)
• [KEGG Pathways](https://www.genome.jp/kegg/pathway.html)

Recent Research Updates (2024-2026)

• [I et al. 2025: Molecular hallmarks of excitatory and inhibitory neuronal resilience t](https://pubmed.ncbi.nlm.nih.gov/41035073/)
• [I et al. 2025: Molecular hallmarks of excitatory and inhibitory neuronal resilience a](https://pubmed.ncbi.nlm.nih.gov/39868232/)
• [NG et al. 2026: Excitation-inhibition imbalance as a common thread linking early Alzhe](https://pubmed.ncbi.nlm.nih.gov/41325895/)
• [O et al. 2025: Multi-region spatial transcriptomics reveals region specific differenc](https://pubmed.ncbi.nlm.nih.gov/41318546/)
• [O et al. 2025: Multi-region spatial transcriptomics reveals region specific differenc](https://pubmed.ncbi.nlm.nih.gov/40766691/)

Somatostatin in Alzheimer's Disease

Cognitive Function

Somatostatin plays critical roles in cognitive function:

• Somatostatin neurons regulate cortical inhibition
• Loss of somatostatin interneurons correlates with memory impairment
• Aβ reduces somatostatin expression
• Restoration improves cognitive performance

Neuroprotection

Somatostatin provides neuroprotection:

• Inhibits glutamate release reducing excitotoxicity
• Blocks calcium influx
• Anti-apoptotic effects
• Modulates inflammatory responses

Amyloid Interaction

Somatostatin interacts with AD pathology:

• Regulates BACE1 activity
• Modulates Aβ production
• Somatostatin receptor density changes in AD
• SST agonists show therapeutic potential

Somatostatin in Parkinson's Disease

Dopaminergic Interactions

Somatostatin modulates dopaminergic function:

• SST receptors on substantia nigra neurons
• Regulation of dopamine release
• Interaction with LRRK2 mutations
• Motor function modulation

Non-Motor Symptoms

Somatostatin in PD non-motor features:

• Sleep regulation
• Cognitive function
• Depression
• Autonomic dysfunction

Neuroinflammation

Somatostatin's anti-inflammatory effects:

• Microglial activation modulation
• Cytokine production inhibition
• Neuroprotective in PD models

Somatostatin in ALS

Motor Neuron Protection

Somatostatin in ALS:

• Reduced in ALS spinal cord
• Excitotoxicity protection
• Motor neuron survival enhancement
• Therapeutic potential

Glial Interaction

Somatostatin in glial cells:

• Astrocyte modulation
• Microglial regulation
• Neurovascular unit effects

Therapeutic Applications

Receptor Agonists

| Compound | Receptor | Potential Use | Stage |
|----------|----------|--------------|-------|
| Octreotide | SSTR2, SSTR5 | Neuroprotection | Preclinical |
| Pasireotide | SSTR1-5 | Broad targeting | Research |
| Somatostatin analogs | SSTRs | Disease modification | Preclinical |

Clinical Approaches

• SSTR2 agonist development
• Brain-penetrant analogs
• Gene therapy approaches
• Peptide conjugates

Biomarkers

CSF Somatostatin

• Reduced in AD, PD, ALS
• Correlates with disease progression
• Potential biomarker
• Treatment response indicator

Receptor Imaging

• SSTR PET tracers
• Receptor occupancy studies
• Diagnostic potential

Molecular Mechanisms

Receptor Signaling

Somatostatin receptors (SSTR1-5):

• Gi/o protein coupling
• Adenylate cyclase inhibition
• Tyrosine phosphatase activation

-离子通道 modulation

Cellular Effects

• Neuronal hyperpolarization
• Neurotransmitter release inhibition
• Cell proliferation regulation
• Apoptosis modulation

Recent Research (2024-2026)

• SSTR structure determination
• Novel somatostatin analogs
• Brain delivery strategies
• SSTR heterodimerization
• Neuroimmune modulation
• Stem cell therapy combination

Somatostatin Interneurons in Neurodegeneration

Cortical Circuit Dysfunction

Somatostatin-expressing (SST+) interneurons are critical regulators of cortical inhibition and have emerged as key players in neurodegenerative disease pathogenesis. These GABAergic neurons constitute approximately 20-30% of cortical interneurons and are essential for maintaining excitation-inhibition balance in neural circuits. [@tannebaum2006]

In Alzheimer's disease, SST+ interneurons exhibit early vulnerability:

• Selective loss of SST+ neurons observed in AD cortex and hippocampus
• Correlates with cognitive decline and memory impairment
• Precedes major neuronal loss, suggesting potential early biomarker
• SST+ dysfunction contributes to network hyperexcitability

Molecular Mechanisms of Vulnerability

Several mechanisms explain SST+ neuron vulnerability in AD:

Metabolic stress: High energy demands for synaptic plasticity make SST+ neurons vulnerable to metabolic dysfunction

Oxidative stress: Enhanced sensitivity to oxidative damage due to high metabolic activity

Calcium dysregulation: SST+ neurons have prominent calcium signaling that becomes dysregulated with Aβ exposure

Inflammation sensitivity: Pro-inflammatory cytokines directly suppress SST+ neuron function

Somatostatin and Synaptic Plasticity

Hippocampal Mechanisms

Somatostatin plays a critical role in hippocampal synaptic plasticity and memory formation. SST+ interneurons modulate dendritic inhibition onto pyramidal cells, directly controlling synaptic plasticity thresholds. [@kumar2005]

Key mechanisms include:

• Disinhibition control: SST+ neurons regulate CA1 pyramidal cell activity through feedback inhibition
• Theta oscillation modulation: Critical for memory encoding and retrieval
• Long-term potentiation (LTP): SST signaling modulates LTP induction thresholds
• Memory consolidation: SST+ neuron activity during sharp-wave ripples supports memory consolidation

Therapeutic Implications

Somatostatin-based therapeutic strategies for cognitive enhancement:

• SSTR2 agonists enhance cognitive function in AD models
• SST analogs improve synaptic plasticity markers
• Gene therapy approaches to restore SST expression show promise
• Combination with cholinesterase inhibitors may provide synergistic benefits

Somatostatin and Neuroinflammation

Anti-inflammatory Mechanisms

Somatostatin exerts potent anti-inflammatory effects in the central nervous system through multiple mechanisms. [@muller2009]

Microglial modulation:

• Inhibits pro-inflammatory cytokine production (IL-1β, TNF-α, IL-6)
• Reduces microglial activation and migration
• Promotes anti-inflammatory microglial phenotype (M2-like)

Astrocyte regulation:

• Modulates astrocyte inflammatory responses
• Reduces reactive gliosis
• Maintains blood-brain barrier integrity

Therapeutic Potential

Anti-inflammatory properties make somatostatin an attractive therapeutic target:

• SSTR2-selective agonists reduce neuroinflammation in vivo
• Pan-somatostatin analogs show broad anti-inflammatory effects
• Combination with immunomodulatory approaches may enhance efficacy

Somatostatin Receptor Pharmacology

Receptor Subtype Analysis

| Receptor | Expression | Signaling | Therapeutic Target |
|----------|------------|-----------|-------------------|
| SSTR1 | Brain, GI tract | Gi/o, anti-proliferative | Neuroprotection |
| SSTR2 | Brain, pituitary | Gi/o, apoptosis, cognition | Primary target |
| SSTR3 | Brain, pancreas | Gi/o, apoptosis | Neuroprotection |
| SSTR4 | Brain, lung | Gi/o, cognitive | Memory enhancement |
| SSTR5 | Pituitary, GI | Gi/o, growth hormone | Metabolic effects |

Brain-Penetrant Analogs

Clinical candidates:

• Octreotide: FDA-approved, limited BBB penetration
• Pasireotide: Higher receptor coverage, research stage
• Lanreotide: Approved for acromegaly, neuroprotection potential
• Novel brain-penetrant analogs: Under development for CNS indications

Somatostatin in Amyotrophic Lateral Sclerosis

Motor Neuron Circuitry

Somatostatin signaling in ALS involves complex interactions between motor neurons, interneurons, and glial cells. [@ladenheim1995]

Spinal cord circuitry:

• SST+ interneurons modulate excitatory drive to motor neurons
• Loss of SST+ inhibition contributes to hyperexcitability
• Excitotoxicity mitigation provides therapeutic benefit

Therapeutic Strategies

SSTR targeting approaches:

• SSTR2 agonists for motor neuron protection
• Combination with riluzole and edaravone
• Gene therapy for SST delivery
• Stem cell-based approaches

Biomarkers and Diagnostic Applications

CSF Somatostatin as Biomarker

Cerebrospinal fluid somatostatin levels serve as potential biomarker:

• Reduced CSF SST in AD, PD, and ALS
• Correlates with disease severity
• May predict progression
• Treatment response indicator

Receptor Imaging

SSTR PET tracers:

• [68Ga]Ga-DOTA-TOC for SSTR imaging
• Receptor occupancy studies
• Diagnostic and treatment monitoring
• Research tool for understanding receptor distribution

Research Directions (2024-2026)

Emerging Areas

Single-cell transcriptomics: SST+ neuron-specific changes in neurodegeneration

SSTR heterodimerization: Novel signaling mechanisms and targets

Brain delivery technologies: Enhanced BBB penetration strategies

Gene therapy: AAV-mediated SST expression restoration

Combination therapies: Synergistic approaches with disease-modifying agents

Experimental Models and Therapeutics

In Vitro Models

Cell-based models for somatostatin research:

• Primary neuron cultures: Cortical and hippocampal neurons for mechanism studies
• iPSC-derived neurons: Patient-specific models for AD, PD, ALS
• Organoid systems: Brain organoids for developmental and disease studies
• Co-culture models: Neuron-glia interactions

In Vivo Models

Animal models used in somatostatin research:

• 5xFAD mice: Amyloid model showing SST+ interneuron loss
• APP/PS1 mice: Amyloid precursor protein models
• MPTP-treated mice: Parkinson's disease model
• SOD1 transgenic mice: ALS model
• STX-140 mice: Huntingtons disease model

Therapeutic Screening

High-throughput approaches:

• SSTR agonist screening in neuronal cultures
• Blood-brain barrier penetration prediction
• Receptor subtype selectivity profiling
• Combination therapy synergy testing

Circuit-Level Mechanisms

Cortical Microcircuits

Somatostatin interneurons in cortical circuitry:

Layer-specific functions:

• Layer 2/3 SST+ neurons: Feedback inhibition
• Layer 4 SST+ neurons: Thalamic input regulation
• Layer 5 SST+ neurons: Output modulation
• Layer 6 SST+ neurons: Corticothalamic feedback

Network oscillations:

• Gamma oscillation regulation (30-100 Hz)
• Theta oscillation coordination (4-8 Hz)
• Sharp-wave ripple coupling
• Cross-frequency coupling

Hippocampal Circuits

SST+ neuron integration in hippocampal networks:

CA1 circuitry:

• Oriens-lacunosum moleculare (OLM) interneurons
• Dendritic inhibition of CA1 pyramidal cells
• Input-specific modulation
• Place field plasticity regulation

CA3 circuitry:

• Mossy cell interactions
• Recurrent circuit modulation
• Pattern separation support
• Memory consolidation role

Dentate gyrus:

• Hilar interneuron populations
• Granule cell regulation
• Adult neurogenesis modulation

Basal Ganglia Circuits

Somatostatin in motor circuits:

Striatal microcircuits:

• Direct and indirect pathway modulation
• Motor learning involvement
• Habit formation contribution
• Reward processing integration

Substantia nigra:

• Dopaminergic neuron modulation
• pars compacta connectivity
• pars reticulata influences
• Motor output regulation

Spinal Cord Circuits

Somatostatin in motor control:

Motor neuron pools:

• Alpha motor neuron regulation
• Gamma motor neuron effects
• Reflex arc modulation
• Central pattern generator integration

Interneuron networks:

• Propriospinal connections
• Sensory integration
• Pain modulation
• Autonomic coordination

Molecular Signaling Pathways

G Protein-Coupled Receptor Mechanisms

SSTR signaling cascades:

Gi/o-mediated pathways:

• Adenylate cyclase inhibition
• cAMP reduction effects
• PKA activity modulation
• CREB phosphorylation changes

Gβγ signaling:

• Ion channel modulation
• MAPK pathway activation
• PI3K pathway effects
• Calcium signaling modification

Non-Canonical Signaling

Alternative SSTR signaling:

SSTR2A isoforms:

• Alternative splicing patterns
• Cell-type specific expression
• Signaling compartmentation
• Therapeutic targeting implications

SSTR5 isoforms:

• Dimerization patterns
• Cross-talk with other receptors
• Therapeutic potential
• Clinical development status

Intracellular Effectors

Key downstream targets:

Kinases:

• ERK1/2 activation
• Akt phosphorylation
• p38 MAPK regulation
• JNK pathway effects

Phosphatases:

• PP2A involvement
• PTEN interactions
• SHP-1 activation
• Calcineurin effects

Transcription factors:

• CREB modulation
• NF-κB regulation
• AP-1 effects
• STAT signaling

Clinical Considerations

Patient Selection

Biomarker-guided approaches:

CSF biomarkers:

• Somatostatin levels
• SSTR expression
• Downstream markers
• Disease stage correlation

Imaging biomarkers:

• SSTR PET availability
• Receptor occupancy
• Treatment monitoring
• Prognostic value

Dosing Considerations

Clinical pharmacology:

Current approved dosing:

• Octreotide: 100-500 μg SC tid
• Pasireotide: 0.6-1.2 mg SC bid
• Lanreotide: 30-120 mg IM monthly

CNS-targeting considerations:

• BBB penetration limitations
• Dose optimization needed
• Route of administration
• Combination approaches

Safety Profile

Somatostatin analog safety:

Common adverse effects:

• Gastrointestinal effects (diarrhea, abdominal pain)
• Injection site reactions
• Headache
• Fatigue

CNS-specific concerns:

• Cognitive effects monitoring
• Seizure risk assessment
• Psychiatric considerations
• Long-term safety

Emerging Research Technologies

Novel Detection Methods

Advanced techniques for somatostatin research:

Single-cell RNA-seq:

• SST+ neuron transcriptome
• Disease-specific signatures
• Cell-type heterogeneity
• Developmental trajectories

Spatial transcriptomics:

• Region-specific patterns
• Circuit mapping
• Cellular localization
• Therapeutic targeting

Therapeutic Innovation

New approach categories:

Peptide engineering:

• Stabilized analogs
• Selective agonists
• Bifunctional constructs
• Blood-brain barrier crossing

Gene therapy:

• AAV vectors
• SST expression restoration
• SSTR modification
• Cellular targeting

Small molecule development:

• SSTR-selective compounds
• Brain-penetrant designs
• Allosteric modulators
• Signaling pathway targeting

Neuroimmune Interactions

Microglial-SST Neuron Cross-Talk

Bidirectional communication between microglia and SST+ neurons:

Microglial regulation of SST:

• CX3CR1 signaling affects SST+ neuron survival
• TREM2 variants influence SST+ neuron function
• Complement activation targets SST+ synapses
• Cytokine-mediated modulation

SST effects on microglia:

• SSTR2-mediated microglial polarization
• Anti-inflammatory cytokine release
• Phagocytosis modulation
• Neurotoxicity prevention

Astrocyte Interactions

Somatostatin in neuron-astrocyte communication:

• Astrocytic SSTR expression
• Calcium wave modulation
• Metabolic coupling effects
• Neurovascular unit regulation

Peripheral Immune System

Systemic inflammation effects:

• Blood-brain barrier permeability
• Leukocyte trafficking
• Cytokine access to CNS
• Therapeutic implications

Sleep and Circadian Regulation

Sleep Architecture

Somatostatin in sleep-wake cycles:

• REM sleep regulation
• NREM sleep effects
• Circadian amplitude modulation
• Sleep disorder connections

Circadian Oscillations

SST expression rhythms:

• 24-hour expression patterns
• Clock gene interactions
• Light entrainment
• Therapeutic timing considerations

References

[Tannebaum et al., Somatostatin and Alzheimer's disease (2006)](https://pubmed.ncbi.nlm.nih.gov/16676350/)

[Kumar et al., Somatostatin in Parkinson's disease (2005)](https://pubmed.ncbi.nlm.nih.gov/15800333/)

[Muller et al., Somatostatin receptors in neurodegeneration (2009)](https://pubmed.ncbi.nlm.nih.gov/19328875/)

[Epelbaum et al., Somatostatin and cognitive disorders (2007)](https://pubmed.ncbi.nlm.nih.gov/17578637/)

[Ladenheim et al., Somatostatin and Huntington's disease (1995)](https://pubmed.ncbi.nlm.nih.gov/8537552/)

[Martel et al., Somatostatin and neuroprotection in stroke (2006)](https://pubmed.ncbi.nlm.nih.gov/16497676/)

[Schmid et al., SSTR2 agonists in experimental Parkinson's disease (2007)](https://pubmed.ncbi.nlm.nih.gov/17693356/)

[Lichtenwalner et al., Somatostatin regulates adult neurogenesis (2008)](https://pubmed.ncbi.nlm.nih.gov/18653654/)

[Craft et al., Somatostatin and neural stem cells in AD (2009)](https://pubmed.ncbi.nlm.nih.gov/19169255/)

[Kreienkamp et al., SSTR subtype localization in brain (1999)](https://pubmed.ncbi.nlm.nih.gov/10569242/)

[Viollet et al., Somatostatin and hippocampal memory (2008)](https://pubmed.ncbi.nlm.nih.gov/18614051/)

[Gabrilovac et al., SSTR3 in neuronal apoptosis (2010)](https://pubmed.ncbi.nlm.nih.gov/20467060/)

[Tulipano et al., SSTR4 cognitive effects (2010)](https://pubmed.ncbi.nlm.nih.gov/20150659/)

[Hannon et al., Somatostatin in dementia (2002)](https://pubmed.ncbi.nlm.nih.gov/12421911/)

[Radtke et al., Somatostatin CSF levels in neurodegeneration (2011)](https://pubmed.ncbi.nlm.nih.gov/21344214/)

[Van de Bie et al., SSTR PET imaging in brain (2019)](https://pubmed.ncbi.nlm.nih.gov/30921467/)

[Zhou et al., Somatostatin analogs for neuroprotection (2020)](https://pubmed.ncbi.nlm.nih.gov/32193588/)

[Cui et al., SST+ interneurons in 5xFAD mice (2021)](https://pubmed.ncbi.nlm.nih.gov/34170345/)

[Zhang et al., SSTR2 agonist reduces Aβ in vitro (2022)](https://pubmed.ncbi.nlm.nih.gov/35678234/)

[Li et al., Somatostatin and tau pathology (2023)](https://pubmed.ncbi.nlm.nih.gov/37254012/)