Nigrostriatal pathway

The nigrostriatal pathway is shown here in solid blue, connecting the substantia nigra with the dorsal striatum.

The nigrostriatal pathway or the nigrostriatal bundle (NSB), is a dopaminergic pathway that connects the substantia nigra with the dorsal striatum (i.e., the caudate nucleus and putamen). It is one of the four major dopamine pathways in the brain, and is particularly involved in the production of movement, as part of a system called the basal ganglia motor loop. Dopaminergic neurons of this pathway synapse onto GABAergic neurons.^[1]

Loss of dopamine neurons in the substantia nigra is one of the main pathological features of Parkinson's disease,^[2] leading to a marked reduction in dopamine function in this pathway. Depletion of neurons in this pathway lead to the symptomatic motor deficits of Parkinson's disease including tremors, rigidity, and postural imbalance.

Anatomy

The following are considered part of the nigrostriatal pathway.

Substantia nigra

The substantia nigra is located in the midbrain. It has two distinct parts, the pars compacta and the pars reticulata. The pars compacta is part of the nigrostriatal pathway and relays information to the basal ganglia by supplying dopamine to the striatum. The pars reticulata in conjunction with the Globus pallidus in the basal ganglia allows for inhibition of the thalamus.

Dorsal striatum

The dorsal striatum is located in the subcortical region of the forebrain. It is divided by a white matter tract called the internal capsule into two parts: the putamen and the caudate nucleus. The putamen and caudate both input information from the cerebral cortex, thalamus, and substantia nigra.

Function

The nigrostriatal pathway connects the substantia nigra with the dorsal striatum. It is one of the four major dopamine pathways in the brain, and is particularly involved in modulation of the extrapyramidal system. Dopaminergic neurons in the nigrostriatal pathway synapse onto GABAergic neurons in the basal ganglia.^[1] and in part make up the basal ganglia motor loop. Along with the other dopaminergic pathways, it is also partially involved in reward and in the reinforcement of memory consolidation.^[3]

The nigrostriatal pathway influences two other pathways, the direct pathway of movement and the indirect pathway of movement.

Direct pathway of movement

The direct pathway is involved in facilitation of wanted movements. The projections of the caudate, putamen, internal segment of the globus pallidus, and the substantia nigra pars compacta create an excitatory effect on the thalamus by decreasing the GABA released by the striatum. This inhibitory effect decreases inhibitory projections from the thalamus, creating an overall net excitatory effect.

Indirect pathway of movement

The indirect pathway is involved in preventing unwanted movement. The projections of the caudate, putamen, external segment of the globus pallidus, and substantia nigra pars reticula create an inhibitory effect on the thalamus through the release of GABA. This inhibitory effect decreases the excitatory projections from the thalamus, creating an overall net inhibitory effect on movement.

Parkinson's disease

Parkinson's disease is characterized by severe motor problems, mainly hypokinsia, rigidity, tremors, and postural imbalance.^[4] Loss of dopamine neurons in the nigrostriatal pathway is one of the main pathological features of Parkinson's disease.^[5] Degeneration of dopamine producing neurons in the substantia nigra pars compacta and the putamen-caudate complex leads to diminished concentrations of dopamine in the nigrostriatal pathway, leading to reduced function and the characteristic symptoms.^[6] The symptoms of the disease typically do not show themselves until 80-90% of dopamine function has been lost.

Levodopa-induced dyskinesia

Levodopa-induced dyskinesias (LID) is a complication associated with long-term use of the Parkinson's treatment L-DOPA characterized by involuntary movement and muscle contractions. This disorder occurs in up to 90% of patients after 9 years of treatment. The use of L-DOPA in patients can lead to interruption of nigrostriatal dopamine projections as well as changes in the post-synaptic neurons in the basal ganglia.^[7]

Other dopamine pathways

Other major dopamine pathways include:

References

1 2 Tritsch, NX; Ding, JB; Sabatini, BL (Oct 2012). "Dopaminergic neurons inhibit striatal output through non-canonical release of GABA". Nature. 490 (7419): 262–6. doi:10.1038/nature11466. PMC 3944587. PMID 23034651.
↑ Diaz, Jaime. How Drugs Influence Behavior. Englewood Cliffs: Prentice Hall, 1996.
↑ Wise, RA (October 2009). "Roles for nigrostriatal--not just mesocorticolimbic--dopamine in reward and addiction.". Trends Neuroscience. 32 (10): 517–524. doi:10.1016/j.tins.2009.06.004. PMC 2755633. PMID 19758714.
↑ Cenci, Angela M (2006). "Post- versus presynaptic plastic ity in L-DOPA-induced dyskinesia". Journal of Neurochemistry. 99 (2): 381–92. doi:10.1111/j.1471-4159.2006.04124.x. PMID 16942598.
↑ Deumens, Ronald (21 June 2002). "Modeling Parkinson's Disease in Rats: An Evaluation of 6-OHDA Lesions of the Nigrostriatal Pathway". Experimental Neurology. 175 (2): 303–17. doi:10.1006/exnr.2002.7891. PMID 12061862.
↑ Groger, Adraine (8 January 2014). "Dopamine Reduction in the Substantia Nigra of Parkinson's Disease Patients Confirmed by In Vivo Magnetic Resonance Spectroscopic Imaging". PLoS ONE. 9: e84081. doi:10.1371/journal.pone.0084081.
↑ Niethammer, Martin (May 2012). "Functional Neuroimaging in Parkinson's Disease". Cold Spring Harbors Perspect in Medicin. 2 (5): a009274. doi:10.1101/cshperspect.a009274. PMC 3331691. PMID 22553499.

External links

ancil-491 at NeuroNames
Diagram

Neurotransmitter systems

Acetylcholine

Nucleus basalis of Meynert → Neocortex

Septal nuclei (Medial septal nucleus) → Fornix → Hippocampus

Striatum

BA/M

Dopaminergic pathways	Mesocortical pathway: Ventral tegmental area → Prefrontal cortices Mesolimbic pathway: Ventral tegmental area → Nucleus accumbens Nigrostriatal pathway: Substantia nigra pars compacta → Caudate nucleus and putamen Tuberoinfundibular pathway: Hypothalamus (Infundibular nucleus) → Pituitary gland (Median eminence)

Norepinephrine	Locus coeruleus Lateral tegmental field

Serotonin pathways	Raphe nuclei Anterior raphespinal tract Lateral raphespinal tract

Aspartate	Climbing fibers

GABA	Globus pallidus Rostromedial tegmental nucleus

Glycine	Renshaw cells

Glutamate	Thalamus Subthalamic nucleus Globus pallidus

Brain and spinal cord: neural tracts and fasciculi

Sensory/
ascending

PCML

1°:	Pacinian corpuscle/Meissner's corpuscle → Posterior column (Gracile fasciculus/Cuneate fasciculus) → Gracile nucleus/Cuneate nucleus

2°:	→ sensory decussation/arcuate fibers (Posterior external arcuate fibers, Internal arcuate fibers) → Medial lemniscus/Trigeminal lemniscus → Thalamus (VPL, VPM)

3°:	→ Posterior limb of internal capsule → Postcentral gyrus

Anterolateral/
pain

Fast/lateral	1° (Free nerve ending → A delta fiber) → 2° (Anterior white commissure → Lateral and Anterior Spinothalamic tract → Spinal lemniscus → VPL of Thalamus) → 3° (Postcentral gyrus) → 4° (Posterior parietal cortex) 2° (Spinomesencephalic tract → Superior colliculus of Midbrain tectum)

Slow/medial	1° (Group C nerve fiber → Spinoreticular tract → Reticular formation) → 2° (MD of Thalamus) → 3° (Cingulate cortex)

Motor/
descending

Pyramidal

flexion: Primary motor cortex → Posterior limb of internal capsule → Decussation of pyramids → Corticospinal tract (Lateral, Anterior) → Neuromuscular junction

Extrapyramidal

flexion:	Primary motor cortex → Genu of internal capsule → Corticobulbar tract → Facial motor nucleus → Facial muscles

flexion:	Red nucleus → Rubrospinal tract

extension:	Vestibulocerebellum → Vestibular nuclei → Vestibulospinal tract

extension:	Vestibulocerebellum → Reticular formation → Reticulospinal tract

Midbrain tectum → Tectospinal tract → muscles of neck

Basal ganglia

direct:	1° (Motor cortex → Striatum) → 2° (GPi) → 3° (Lenticular fasciculus/Ansa lenticularis → Thalamic fasciculus → VL of Thalamus) → 4° (Thalamocortical radiations → Supplementary motor area) → 5° (Motor cortex)

indirect:	1° (Motor cortex → Striatum) → 2° (GPe) → 3° (Subthalamic fasciculus → Subthalamic nucleus) → 4° (Subthalamic fasciculus → GPi) → 5° (Lenticular fasciculus/Ansa lenticularis → Thalamic fasciculus → VL of Thalamus) → 6° (Thalamocortical radiations → Supplementary motor area) → 7° (Motor cortex)

nigrostriatal pathway:	Pars compacta → Striatum

Cerebellar

Afferent

Vestibular nuclei → Vestibulocerebellar tract → ICP → Cerebellum → Granule cell

Pontine nuclei → Pontocerebellar fibers → MCP → Deep cerebellar nuclei → Granule cell

Inferior olivary nucleus → Olivocerebellar tract → ICP → Hemisphere → Purkinje cell → Deep cerebellar nuclei

Efferent

Dentate nucleus in Lateral hemisphere/pontocerebellum → SCP → Dentatothalamic tract → Thalamus (VL) → Motor cortex

Interposed nucleus in Intermediate hemisphere/spinocerebellum → SCP → Reticular formation, or → Cerebellothalamic tract → Red nucleus → Thalamus (VL) → Motor cortex

Fastigial nucleus in Flocculonodular lobe/vestibulocerebellum → Vestibulocerebellar tract → Vestibular nuclei

Bidirectional:
Spinocerebellar

Unconscious proprioception	lower limb → 1° (muscle spindles → DRG) → 2° (Posterior thoracic nucleus → Dorsal/posterior spinocerebellar tract → ICP → Cerebellar vermis) upper limb → 1° (muscle spindles → DRG) → 2° (Accessory cuneate nucleus → Cuneocerebellar tract → ICP → Anterior lobe of cerebellum)

Reflex arc	lower limb → 1° (Golgi tendon organ) → 2° (Ventral/anterior spinocerebellar tract→ SCP → Cerebellar vermis) upper limb → 1° (Golgi tendon organ) → 2° (Rostral spinocerebellar tract → ICP → Cerebellum)

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