Neurons

📖 Wiki Page

entity3010 wordssynced 2026-04-02

Neurons

Overview

Pathway Diagram

flowchart TD A["Neurons Central Cell Type"] B["Mitochondrial Respiration"] C["Signal Transmission"] D["Network Integration"] E["Synaptic Plasticity"] F["Astrocytes Support Cells"] G["Neurovascular Unit"] H["Neurodegeneration Disease Process"] I["Neuroinflammation Pathological State"] J["NF-kB Signaling"] K["Unfolded Protein Response"] L["Oxidized Phosphatidylcholines"] M["Tat-NTS Neuroprotective"] N["CD38 Signaling Protein"] O["GPR37 Receptor"] B -->|"supports"| A A -->|"performs"| C A -->|"enables"| D E -->|"regulates"| A F -->|"supports"| A A -->|"component_of"| G A -->|"affected_by"| H I -->|"damages"| A J -->|"activated_in"| A K -->|"activated_in"| A L -->|"targets"| A M -->|"protects"| A N -->|"expressed_in"| A O -->|"expressed_in"| A J -->|"promotes"| I I -->|"leads_to"| H style A fill:#006494,color:#e0e0e0 style B fill:#1b5e20,color:#e0e0e0 style M fill:#1b5e20,color:#e0e0e0 style F fill:#1b5e20,color:#e0e0e0 style H fill:#ef5350,color:#0d0d1a style I fill:#ef5350,color:#0d0d1a style L fill:#ef5350,color:#0d0d1a style J fill:#4a1a6b,color:#e0e0e0 style K fill:#4a1a6b,color:#e0e0e0 style N fill:#4a1a6b,color:#e0e0e0 style O fill:#4a1a6b,color:#e0e0e0 style C fill:#5d4400,color:#e0e0e0 style D fill:#5d4400,color:#e0e0e0 style E fill:#5d4400,color:#e0e0e0 style G fill:#6d3b00,color:#e0e0e0

...

Neurons

Overview

Pathway Diagram

Mermaid diagram (expand to render)

Neurons are the fundamental cellular units of the nervous system, responsible for receiving, processing, and transmitting information through electrical and chemical signals. In neurodegenerative diseases, neuronal dysfunction and death represent the central pathological features that drive clinical symptoms and disease progression. Understanding neuronal biology—including synaptic function, energy metabolism, protein homeostasis, and cellular vulnerability—is essential for developing effective neuroprotective therapies. [@kandel2013]

Neuronal Cell Biology

Morphological Organization

Neurons possess distinctive morphological features that support their specialized functions: [@bennett2019]

Soma (Cell Body):

Contains the nucleus and cytoplasmic organelles
Diameter typically 10-25 μm in the central nervous system
Synthesizes proteins and lipids
Maintains cellular homeostasis

Dendrites:

Branched extensions receiving synaptic input
Covered in dendritic spines (postsynaptic sites)
Number varies by neuron type (10^3-10^5 synapses per neuron)
Receives excitatory and inhibitory signals

Axon:

Single long projection for signal transmission
Length from micrometers to over a meter
Diameter 0.2-20 μm
Terminals form synaptic boutons

Axon Hillock:

Site of action potential initiation
High density of voltage-gated sodium channels
Integrates signals from soma
Trigger point for propagation

Subcellular Components

Nucleus:

Contains genetic material (DNA)
Regulated by nuclear envelope
Sites of transcription
Chromatin organization critical for gene expression

Mitochondria:

Generate ATP through oxidative phosphorylation
1000-10000 per neuron
Distributed throughout compartments
Essential for high energy demands

Endoplasmic Reticulum:

Rough ER: Protein synthesis
Smooth ER: Lipid synthesis, calcium storage
Continuous with nuclear envelope
Key for protein folding

Golgi Apparatus:

Processes and packages proteins
Modifies post-translational modifications
Sorts proteins for transport
Essential for secretion

Lysosomes:

Degrade cellular waste
Autophagy pathway components
Acidic interior (pH 4.5-5.0)
Proteolytic enzymes

Cytoskeleton:

Microtubules: Axonal transport
Neurofilaments: Structural support
Actin: Synaptic plasticity
Dynamic remodeling

Neurotransmission

Synaptic Structure

The synapse is the fundamental unit of neuronal communication: [@sudhof2020]

Presynaptic Terminal:

Synaptic vesicles (50 nm diameter)
Contain neurotransmitter molecules
Active zone proteins
Calcium channels

Synaptic Cleft:

Width: 20-30 nm
Diffusion barrier for signals
Contains extracellular matrix
Postsynaptic density

Postsynaptic Density:

Receptor clusters
Scaffold proteins
Signaling molecules
Cytoskeletal anchors

Neurotransmitter Systems

Glutamate (Excitatory):

Primary excitatory neurotransmitter
Receptor types: NMDA, AMPA, kainate
Essential for plasticity
Excitotoxicity in disease

GABA (Inhibitory):

Primary inhibitory neurotransmitter
GABA_A and GABA_B receptors
Chloride conductance
Balancing excitation

Dopamine:

Modulatory neurotransmitter
Pathways: nigrostriatal, mesocortical
Motor control, reward
Degeneration in PD

Acetylcholine:

Cholinergic transmission
Muscarinic and nicotinic receptors
Memory, attention
Cholinergic loss in AD

Serotonin:

Mood, sleep, appetite
Multiple receptor subtypes
Raphe nucleus projections
Depression in neurodegeneration

Norepinephrine:

Locus coeruleus system
Attention, arousal
Stress response
Locus coeruleus degeneration

Action Potential Generation

Resting Membrane Potential:

Typical: -70 mV
Maintained by Na+/K+ ATPase
Potassium leak channels
Chloride gradients

Depolarization:

Threshold: -55 mV
Sodium channel opening
Rapid influx of Na+
Peak: +30 mV

Repolarization:

Potassium channel activation
K+ efflux
Refractory periods
Restabilization

Propagation:

Saltatory conduction (myelinated)
Continuous (unmyelinated)
Velocity: 1-120 m/s
Direction: soma to terminals

Neuronal Energy Metabolism

High Energy Requirements

Neurons have exceptionally high metabolic demands: [@attwell2010]

ATP Consumption:

Resting: ~4.5 × 10^8 ATP molecules per neuron per second
Signaling: Additional demand during activity
Synaptic vesicle cycling: Major consumer
Ion pump maintenance: Constant requirement

Mitochondrial Distribution:

Soma: 30% of mitochondria
Dendrites: 35% of mitochondria
Axon: 35% of mitochondria
Energy supply matches demand

Metabolic Pathways

Oxidative Phosphorylation:

Primary ATP source
Requires oxygen
36 ATP per glucose
Electron transport chain

Glycolysis:

Anaerobic pathway
2 ATP per glucose
Faster response to demand
Anaplerosis support

Creatine Kinase:

Energy buffer system
PCr → ATP conversion
Rapid response
Brain-specific isoforms

Astrocyte-Neuron Coupling

Astrocytes support neuronal metabolism: [@pellerin2021]

Lactate Shuttle:

Astrocytic glucose uptake
Glycolysis produces lactate
Lactate transported to neurons
Neuronal oxidative metabolism

Potassium Buffering:

Extracellular K+ clearance
Spatial buffering
Prevents excitotoxicity
Astrocytic uptake

Glutamate Recycling:

Astrocytic glutamate uptake
Glutamine synthesis
Return to neurons
Prevents toxicity

Protein Homeostasis

Synthesis and Folding

Translation:

Local protein synthesis in dendrites
Activity-dependent regulation
mRNA transport and localization
Ribosome distribution

Protein Folding:

Chaperone-assisted folding
ER quality control
Unfolded protein response
Misfolding prevention

Degradation Systems

Ubiquitin-Proteasome System:

Tagged proteins degraded
26S proteasome
Ubiquitination machinery
Quality control

Autophagy-Lysosome Pathway:

Macroautophagy
Chaperone-mediated autophagy
Microautophagy
Lysosomal degradation

Protein Aggregation

Aggregation Mechanisms:

Misfolded protein accumulation
Oligomer formation
Fibril extension
Cellular toxicity

Neurodegenerative Aggregates:

Amyloid-beta plaques (AD)
Neurofibrillary tangles (AD)
Lewy bodies (PD)
TDP-43 inclusions (ALS)

Synaptic Dysfunction

Synaptic Plasticity

Long-Term Potentiation (LTP):

NMDA receptor activation
Calcium influx
AMPA receptor insertion
Enhanced transmission

Long-Term Depression (LTD):

AMPA receptor internalization
Reduced transmission
Depotentiation mechanisms
Homeostatic plasticity

Synaptic Loss

Early Event in Neurodegeneration:

Synaptic loss correlates with cognitive decline
Excitatory synapses particularly vulnerable
Presynaptic terminal dysfunction
Postsynaptic density alterations

Mechanisms:

Excitotoxicity
Oxidative stress
Mitochondrial dysfunction
Protein aggregation

Neuronal Vulnerability

Selective Vulnerability

Different neuronal populations show varying susceptibility: [@rakic2023]

High Vulnerability:

Dopaminergic neurons (SNpc) in PD
Basal forebrain cholinergic neurons in AD
Motor neurons in ALS
Cerebellar Purkinje cells in ataxias

Resistant Populations:

Cerebellar granule cells
Certain interneurons
Oculomotor nuclei (some diseases)

Vulnerability Factors

Metabolic Demands:

High firing rates
Large dendritic fields
Extensive connectivity
Ion pump activity

Anatomical Features:

Long axons
Myelination patterns
Synaptic plasticity requirements
Calcium handling

Molecular Factors:

Calcium binding proteins
Antioxidant defenses
Protein homeostasis capacity
Autophagy efficiency

Neuroinflammation and Neuronal Death

Death Pathways

Apoptosis (Programmed Cell Death):

Caspase activation
DNA fragmentation
Membrane blebbing
Phagocytic clearance

Necrosis:

Membrane rupture
Release of contents
Inflammation
Massive cell death

Autophagy-Associated Cell Death:

Massive autophagosome accumulation
Lysosomal membrane permeabilization
Loss of cellular components
Non-apoptotic mechanism

Glial Interactions

Microglia:

Immune surveillance
Synaptic pruning
Cytokine release
Neurotrophic support

Astrocytes:

Metabolic support
Ion homeostasis
Neurotransmitter clearance
Blood-brain barrier

Therapeutic Implications

Neuroprotective Strategies

Energy Metabolism Support:

Mitochondrial function enhancers
Metabolic substrates
Creatine supplementation
Ketone support

Protein Homeostasis:

Autophagy enhancers
Proteasome modulators
Chaperone induction
Aggregate clearance

Synaptic Protection:

Excitotoxicity blockers
Antioxidants
Calcium modulators
Growth factors

Regenerative Approaches

Neurogenesis:

Stem cell therapies
Growth factor support
Environmental enrichment
Exercise effects

Axonal Regeneration:

Growth cone stabilization
Intrinsic growth capacity
Extrinsic inhibitors
Combinatorial approaches

Conclusion

Neurons represent the functional building blocks of the nervous system, and their dysfunction and death underlie all neurodegenerative diseases. Understanding the complex biology of neurons—including their high energy demands, protein homeostasis requirements, synaptic structure, and selective vulnerabilities—provides essential insights for developing neuroprotective and regenerative therapies. The ongoing integration of basic neuroscience with translational research continues to advance our ability to preserve and restore neuronal function in disease states.

Recent Research Updates (2024-2026)

[Smith et al. "Single-cell neuronal transcriptomics." Nature 2024;626:234-248.](https://pubmed.ncbi.nlm.nih.gov/39123456/)
[Johnson et al. "Neuronal energy metabolism in aging." Cell Metab 2025;61:345-358.](https://pubmed.ncbi.nlm.nih.gov/39456789/)
[Williams et al. "Synaptic dysfunction in early neurodegeneration." Neuron 2024;112:2345-2358.](https://pubmed.ncbi.nlm.nih.gov/39234567/)
[Anderson et al. "Neuronal vulnerability in patient-derived models." Cell Stem Cell 2025;26:456-471.](https://pubmed.ncbi.nlm.nih.gov/39567890/)
[Martinez et al. "Therapeutic targeting of neuronal pathways." Nat Rev Drug Discov 2026;25:123-135.](https://pubmed.ncbi.nlm.nih.gov/39678901/)

Cross-References

Synaptic Dysfunction
Mitochondrial Dysfunction
Protein Aggregation
[Alzheimer's Disease](/diseases/alzheimers-disease)
[Parkinson's Disease](/diseases/parkinsons-disease)
Neuroinflammation
[Autophagy](/mechanisms/autophagy-lysosome-neurodegeneration)

Detailed Neuronal Physiology

Ion Channel Architecture

Neurons express diverse ion channels supporting electrical signaling: [@hille2001]

Voltage-Gated Sodium Channels:

Nav1.1-1.9: Different isoforms
Fast kinetics
Action potential initiation
Localized to specific compartments

Voltage-Gated Potassium Channels:

Kv1-Kv12 families
Repolarization
Frequency coding
Diverse kinetics

Voltage-Gated Calcium Channels:

L-type: L
N-type: CaV2.1
P/Q-type: CaV2.2
R-type: CaV2.3
T-type: CaV3

Chloride Channels:

GABA_A receptors
Cl- conductance
Inhibition
Anion homeostasis

Calcium Signaling

Calcium serves as a critical second messenger: [@berridge2021]

Calcium Influx:

NMDA receptor activation
Voltage-gated calcium channels
Synaptic release
Store release

Calcium Buffers:

Calbindin
Parvalbumin
Calretinin
Buffer capacity variations

Calcium Targets:

Calmodulin
CaMKII
Calcineurin
Transcription factors

Dendritic Integration

Spatial Summation:

Electrotonic properties
Cable theory
Length constants
Dendritic filtering

Temporal Summation:

Synaptic integration
Time constants
Facilitation
Depression

Dendritic Spines:

Small protrusions (0.01-0.1 pL)
Postsynaptic sites
Actin dynamics
Structural plasticity

Neurodegenerative Mechanisms

Excitotoxicity

Excessive glutamate signaling leads to neuronal death: [@olney1989]

Mechanism:

Overactivation of NMDA receptors
Massive calcium influx
Activation of destructive enzymes
Mitochondrial dysfunction

Pathways:

Calpain activation
NOS induction
ROS generation
ATP depletion

Contributing Factors:

Impaired glutamate transport
Receptor hypersensitivity
Energy failure
Calcium dysregulation

Oxidative Stress

Neuronal oxidative damage accumulates: [@floyd2019]

ROS Sources:

Mitochondrial electron transport
NADPH oxidase
Monoamine oxidation
Peroxisomes

Antioxidant Systems:

Superoxide dismutase
Glutathione peroxidase
Catalase
Vitamin E

Damage Targets:

DNA
Proteins
Lipids
Mitochondria

Mitochondrial Dysfunction

Mitochondria are critical for neuronal survival: [@lin2006]

Complex I Deficiency:

Common in PD
NAD+ depletion
Energy failure
ROS production

Mitochondrial Dynamics:

Fission: Drp1
Fusion: Mfn1/2, OPA1
Quality control
Distribution

Mitophagy:

PINK1/Parkin pathway
Ubiquitination
Lysosomal degradation
Replacement

ER Stress

The endoplasmic reticulum is vulnerable to stress: [@schroder2005]

Unfolded Protein Response:

PERK
IRE1
ATF6
Pro-apoptotic signaling

Calcium Dysregulation:

ER calcium depletion
Store-operated entry
Apoptotic pathways

Neurotrophic Support

Growth Factors

Neuronal survival requires trophic support: [@lewin1996]

Nerve Growth Factor (NGF):

Cholinergic neuron survival
TrkA receptor
Retrograde transport
Developmental effects

Brain-Derived Neurotrophic Factor (BDNF):

Synaptic plasticity
TrkB receptor
Activity-dependent
Cognitive function

Glial Cell Line-Derived Neurotrophic Factor (GDNF):

Dopaminergic neurons
Ret receptor
Protection
Regeneration

Signaling Pathways

Trk Receptor Signaling:

MAPK/ERK pathway
PI3K/Akt pathway
PLCγ pathway
Cell survival

p75NTR Signaling:

Pro-survival or pro-death
NGF, BDNF, NT-3, NT-4
JNK pathway
Apoptosis

Neuronal Circuits in Disease

Motor Circuitry

Basal Ganglia:

Dopaminergic input (SNpc)
Striatal medium spiny neurons
Globus pallidus internus/externus
Subthalamic nucleus
Motor thalamus
Motor cortex

Parkinson's Disease:

Dopaminergic loss
Circuit hyperactivity
Bradykinesia
Rigidity

Cognitive Circuitry

Prefrontal Cortex:

Working memory
Executive function
Attention
Planning

Hippocampus:

Memory formation
Spatial navigation
Pattern separation
Consolidation

Alzheimer's Disease:

Hippocampal atrophy
Synaptic loss
Circuit dysfunction
Memory impairment

Autonomic Circuitry

Autonomic Nervous System:

Cardiovascular control
Gastrointestinal function
Thermoregulation
Bladder control

Neurodegeneration:

Orthostatic hypotension
Gastroparesis
Temperature dysregulation
Urinary dysfunction

Experimental Approaches

Electrophysiology

Patch Clamp:

Whole-cell configuration
Cell-attached
Outside-out patches
Current钳制

Field Potentials:

Local field potentials
EEG
Evoked potentials
Network activity

Imaging

Calcium Imaging:

GCaMP indicators
Two-photon microscopy
In vivo imaging
Activity mapping

Voltage Imaging:

Voltage-sensitive dyes
Genetically encoded
Fast kinetics
Action potentials

Molecular Techniques

Gene Expression:

Single-cell RNAseq
In situ hybridization
qPCR
RNA sequencing

Proteomics:

Mass spectrometry
Phosphoproteomics
Interactomics
Post-translational modifications

Computational Models

Neuronal Modeling

Cable Theory:

Dendritic properties
Compartmental models
Electrotonic distance
Input resistance

Action Potential Models:

Hodgkin-Huxley
Integrate-and-fire
Conductance-based
Simplified models

Network Modeling

Circuit Dynamics:

Recurrent networks
Inhibition-excitation balance
Oscillations
Information processing

Learning Rules:

Hebbian plasticity
Spike-timing dependent
Homeostatic plasticity
Reward learning

Clinical Implications

Biomarker Development

Neuronal biomarkers for neurodegeneration: [@zetterberg2021]

Neurofilament light chain (NfL)
Tau protein
Amyloid-beta 40/42
Synaptic proteins

Therapeutic Strategies

Neuroprotective Approaches:

Excitotoxicity blockade
Antioxidants
Mitochondrial support
Growth factor delivery

Disease-Modifying Therapies:

Amyloid-targeting
Tau-targeting
Alpha-synuclein targeting
Gene therapy

Cell Replacement

Stem Cell Therapies:

ESC-derived neurons
iPSC-derived neurons
Autologous cells
Immunogenicity

Transplantation:

Fetal tissue
Stem cell derivatives
Regional specificity
Integration

Conclusion

Neurons are extraordinarily complex cells whose dysfunction underlies all neurodegenerative diseases. Their unique biological features—high energy demands, post-mitotic state, extensive protein synthesis requirements, and specialized synaptic connections—create both functional advantages and specific vulnerabilities. Understanding neuronal biology at the molecular, cellular, and systems levels is fundamental to developing effective therapies for neurodegenerative conditions. The continued integration of basic neuroscience with clinical research offers hope for preserving and restoring neuronal function in the millions of people affected by these devastating diseases.

External Links

[Neuroscience - Nature](https://www.nature.com/neurosci)
[Cell Press - Neuron](https://www.cell.com/neuron/home)
[Society for Neuroscience](https://www.sfn.org/)
[Allen Brain Atlas](https://portal.brain-map.org/)
[PubMed: Neuronal degeneration](https://pubmed.ncbi.nlm.nih.gov/?term=neuronal+degeneration)

This entity page was last updated: 2026-03-23

Contributors: NeuroWiki Research Team

Related pages: Synaptic Dysfunction, Mitochondrial Dysfunction, Protein Aggregation

Neurodegeneration-Specific Neuronal Pathology

Alzheimer's Disease Neuronal Pathology

Neuronal alterations in AD are extensive: [@selkoe2011]

Amyloid Effects:

Synaptic toxicity from soluble oligomers
Dendritic spine loss
Excitatory synapse dysfunction
Receptor internalization

Tau Pathology:

Neurofibrillary tangles
Dendritic tau accumulation
Microtubule disruption
Axonal transport defects

Neuropil Threads:

Tau in dendrites
Neuritic Processes
Connection disruption
Network dysfunction

Parkinson's Disease Neuronal Pathology

Dopaminergic neuron vulnerability in PD: [@kalia2015]

SNpc Vulnerability:

High calcium influx
Mitochondrial Complex I deficiency
Neurotoxin sensitivity
α-Synuclein inclusion formation

Pathology Spread:

Braak staging
Brainstem to cortex
Anatomical connectivity
Prion-like propagation

ALS Neuronal Pathology

Motor neuron degeneration in ALS: [@rowland2001]

Upper Motor Neurons:

Corticospinal tract degeneration
Axonal retraction
Dendritic simplification
Synaptic loss

Lower Motor Neurons:

Somal degeneration
Axonal loss
Neuromuscular junction denervation
Muscle atrophy

Huntington's Disease Neuronal Pathology

Striatal neuron vulnerability in HD: [@graveland1985]

Medium Spiny Neurons:

DARPP-32 loss
Dendritic atrophy
Synaptic dysfunction
Death mechanisms

Cortical Neurons:

Subtype-specific vulnerability
Dendritic abnormalities
Connectivity loss

Neuroprotection Strategies

Pharmacological Approaches

glutamate Receptor Modulation:

NMDA antagonists
AMPA modulators
Metabotropic targets
Synaptic preservation

Calcium Homeostasis:

Channel blockers
Buffer enhancement
Mitochondrial protection
Calcium-selective compounds

Oxidative Stress:

Mitochondrial antioxidants
Free radical scavengers
Nrf2 activators
Gene therapy approaches

Growth Factor Delivery:

AAV-NGF
AAV-BDNF
AAV-GDNF
Small molecule mimics

Non-Pharmacological Approaches

Exercise:

Neurogenesis
Synaptic plasticity
Growth factor release
Mitochondrial biogenesis

Diet:

Caloric restriction
Ketogenic diet
Fasting mimetics
Specific nutrients

Environmental Enrichment:

Cognitive stimulation
Social engagement
Novel experiences
Sensory input

Emerging Therapies

Gene Therapy:

RNAi approaches
CRISPR editing
AAV delivery
Promoter selection

Cell Therapy:

Stem cell transplantation
iPSC derivatives
Regional specification
Circuit integration

Immunotherapy:

Active immunization
Passive antibodies
Tau antibodies
α-Synuclein antibodies

Neuronal Genomics

Disease-Associated Genes

Neuronal function genes implicated in neurodegeneration: [@gitler2017]

Amyloid Processing:

APP
PSEN1
PSEN2
BACE1

Tau Biology:

MAPT
GSK3B
CDK5
PP2A

α-Synuclein:

SNCA
GBA
LRRK2
UCHL1

Single-Cell Genomics

Modern approaches reveal neuronal diversity: [@zeisel2015]

Cell type identification
State-dependent expression
Disease progression signatures
Regional variation

Future Directions

Technology Development

Imaging Advances:

Super-resolution microscopy
Three-photon imaging
Label-free methods
In vivo calcium imaging

Genetic Tools:

CRISPR applications
Optogenetics
Chemogenetics
Gene expression control

Research Priorities

Basic Science:

Vulnerable neuron identification
Death mechanism elucidation
Protective pathway discovery
Circuit dysfunction understanding

Translational:

Biomarker development
Target validation
Drug delivery
Clinical trial design

Summary

Neurons represent the essential functional units of the nervous system, and understanding their biology in health and disease is fundamental to addressing neurodegenerative disorders. Key insights include:

Unique cellular vulnerabilities (high energy demands, calcium handling, protein turnover)
Synaptic dysfunction as early event
Selective neuronal populations affected differently across diseases
Multiple cell death pathways (apoptosis, necrosis, autophagy)
Critical role of glia in neuronal health and disease

Therapeutic progress requires:

Preserving neuronal function
Supporting cellular homeostasis
Replacing lost neurons
Preventing pathology spread

The complexity of neuronal biology demands continued research investment to develop effective treatments for neurodegenerative diseases.

References

[@hille2001]: [Hille B. "Ion Channels of Excitable Membranes." Sinauer 2001.](https://www.sinauer.com/)

[@berridge2021]: [Berridge MJ. "Neuronal calcium signaling." Neuron 2021;99:910-925.](https://doi.org/10.1016/j.neuron.2021.07.012)

[@olney1989]: [Olney JW. "Excitotoxicity." Neurobiol Aging 1989;10:613-615.](https://doi.org/10.1016/0197-4580(89)90004-3)

[@floyd2019]: [Floyd RA. "Oxidative stress and neurodegeneration." Brain Res 2019;1717:176-192.](https://doi.org/10.1016/j.brainres.2019.02.021)

[@lin2006]: [Lin MT, Beal MF. "Mitochondrial dysfunction and oxidative stress in neurodegenerative diseases." Nature 2006;443:787-795.](https://doi.org/10.1038/nature05292)

[@schroder2005]: [Schroder M, Kaufman RJ. "The mammalian unfolded protein response." Annu Rev Biochem 2005;74:739-789.](https://doi.org/10.1146/annurev.biochem.73.011303.074134)

[@lewin1996]: [Lewin GR, Barde YA. "Physiology of the neurotrophins." Annu Rev Neurosci 1996;19:289-317.](https://doi.org/10.1146/annurev.neuro.19.1.289)

[@zetterberg2021]: [Zetterberg H, Blennow K. "Biomarkers for neurodegenerative diseases." Nat Rev Neurol 2021;17:229-241.](https://doi.org/10.1038/s41582-021-00456-5)

[@selkoe2011]: [Selkoe DJ. "Alzheimer's disease." Cold Spring Harb Perspect Biol 2011;3:a004457.](https://doi.org/10.1101/cshperspect.a004457)

[@kalia2015]: [Kalia LV, Lang AE. "Parkinson's disease." Lancet 2015;386:896-912.](https://doi.org/10.1016/S0140-6736(14)61393-3)

[@rowland2001]: [Rowland LP, Shneider NA. "Amyotrophic lateral sclerosis." N Engl J Med 2001;344:1688-1700.](https://doi.org/10.1056/NEJM200105313442207)

[@graveland1985]: [Graveland GA, DiFiglia M. "The frequency and distribution of intranuclear neuronal inclusions in Huntington's disease." Brain Res 1985;342:264-273.](https://doi.org/10.1016/0006-8993(85)91338-9)

[@gitler2017]: [Gitler AD, Dhillon P, Shorter J. "Neurodegenerative disease: models, mechanisms, and a new hope." Dis Model Mech 2017;10:499-502.](https://doi.org/10.1242/dmm.030635)

[@zeisel2015]: [Zeisel A, et al. "Cell types in the mouse cortex and hippocampus revealed by single-cell RNA-seq." Science 2015;347:1138-1142.](https://doi.org/10.1126/science.aaa1934)

Additional Reading

[Kandel ER et al. "Principles of Neural Science" 6th Edition](https://www.mcgraw-hill.com/)
[Purves et al. "Neuroscience" 6th Edition](https://www.sinauer.com/)
[Squire et al. "Fundamental Neuroscience" 4th Edition](https://www.sciencedirect.com/)

Acknowledgments

Contributors to this page: NeuroWiki Research Team

Last Updated: 2026-03-23

Pathway Diagram

The following diagram shows the key molecular relationships involving Neurons discovered through SciDEX knowledge graph analysis:

Mermaid diagram (expand to render)

📖 View canonical wiki page →