Zona incerta

Zona incerta
Identifiers
NeuroNames hier-421
NeuroLex ID Zona incerta
TA A14.1.08.707
FMA 62038

Anatomical terms of neuroanatomy

The zona incerta is a horizontally elongated region of gray matter cells in the subthalamus below the thalamus. Its connections project extensively over the brain from the cerebral cortex down into the spinal cord.

Its function is unknown, though several potential functions related to "limbic–motor integration" have been proposed, such as controlling visceral activity and pain; gating sensory input and synchronizing cortical and subcortical brain rhythms. Its dysfunction may play a role in central pain syndrome. It has also been identified as a promising deep brain stimulation therapy target for treating Parkinsons Disease.

Its existence was first described by Auguste Forel in 1877 as a "region of which nothing certain can be said".[1][2] A hundred and thirty years later in 2007, Nadia Urbain and Martin Deschênes of Université Laval noted that the "zona incerta is among the least studied regions of the brain; its name does not even appear in the index of many textbooks."[3]

Structure

This nucleus is located medially to the internal capsule, ventral to the thalamus, and is contiguous with the thalamic reticular nucleus. The nucleus separates the lenticular fasciculus from the thalamic fasciculus (also known as the "field H1 of Forel") . Its cells are very heterogeneous differing widely in their shape and size. Its chemoarchitecture is also diverse containing up to 20 different types of neurochemically defined cells. It has been noted that "There are few diencephalic regions that have as much cellular and neurochemical diversity".[2]

In rats four areas are usually identified.[4][5][6]

These areas lack clear cell-free borders and merge into each other.[2]

Zona incerta neurons have dendrites with a wide span 0.8 mm and their axons give off collaterals that arborized locally within the zona incerta providing a means for lateral inhibition. The ventral area of the zona incerta has been described as having "a network of GABAergic cells with widespread interconnections, so that cells in one subsector may influence the activity of cells in a different subsector".[3]

The zona incerta together with the hypothalamus is one of the two areas of the brain that produces the neuropeptide melanin concentrating hormone.[8] Dopaminergic ones are also more prevalent.[6] There are in addition populations of cells producing somatostatin, angiotensin II and melanocyte stimulating hormone.[6]

Connections

The zona incerta has connections to the cerebral cortex, diencephalon, basal ganglia, brainstem and spinal cord.

Cerebral cortex

Projections to the zona incerta arise across the cortical mantel from the frontal to the occipital lobes. The heaviest projections are from cingulate cortex, frontal and parietal areas. The head area of the body seems from these areas to have the largest representation in the zona incerta. These projections preferentially go to cortical layer I neurons.[9] There are projections from the zona incerta back to the cerebral cortex.[10]

Diencephalon

Projections with the diencephalon are reciprocal and mainly to the thalamus such as the intralaminar nucleus (parafascicular nucleus and central lateral nucleus) and higher-order nuclei such as the lateral posterior nucleus. The zona incerta avoids the thalamus nuclei of the primary sensory areas such as the ventral posterior nucleus of the somatosensory system and the lateral geniculate of the visual system.[11]

Hypothalamus

Projections to the hypothalamus go mainly to the paraventricular nucleus areas in the anterior hypothalamus, lateral hypothalamus, lateral preoptic area, horizontal diagonal band of Broca, and the parvocellular region of the paraventricular nucleus.[12]

Basal ganglia

Zona incerta is connected in the basal ganglia to the substantia nigra (both pars compacta and pars reticulata) and pedunculopontine tegmental nucleus (but only its pars dissipata area). It also has less important connections to the entopeduncular nucleus and globus pallidus. These projections are glutamatergic and excitatory rather than GABAergic and inhibitory.[13] The zona incerta also receives input from these areas.

Cerebellum

The cerebellum sends a significant number of fibers to the zona incerta. [14] These projections originate from various cerebellar nuclei and are gabaergic. Given the cererebellar contributions to motor learning, timing and coordination, the interactions between the cerebellum with the zona incerta are likely to have profound influence on motor functions.

Brainstem

Zona incerta receives input from many parts of the brainstem nuclei including the periaqueductal gray, raphe nuclei, thalamic reticular nucleus, and the deep layers of the superior colliculus. It is regulated by inputs from brainstem cholinergic nuclei such as the Laterodorsal tegmental nucleus and pedunculopontine nucleus upon its neuron’s muscarinic receptors.[15]

Spinal cord

Zona incerta afferents terminate within the spinal cord gray matter, particularly the anterior horn, while spinal projections back to the zona incerta arise from cells located across the posterior horn and intermediate gray.

Other

Zona incerta also has connections to the amygdala, basal forebrain, the osmoreceptors in the subfornical organ, olfactory bulb, posterior pituitary and habenula.

Some of these projections appear in register; the representation of the same body part in cortex and spinal cord connect to the same areas in the zona incerta.[16] This is possibly so with the superior colliculus.[17]

Function

The function of the Zona incerta is unknown, "To this day, we are still not certain of the precise function of this 'zone of uncertainty'"[2] However it is suggested to have possible roles in "limbic–motor integration".[2]

Visceral survival activities.

Zona incerta controls such activities as water and food intake, sexuality and cardiovascular activity. This control is related to its effects upon the nearby posterior hypothalamus with which it shares similar connections and neurochemically defined cell types.[2]

The zona incerta receives pain input through the spinothalamic tract and this has been shown to control the activity of the pain transmission pathway in the posterior thalamus.[11]

Electrical or chemical stimulation of the zona incerta creates limbic-related movements, such as those associated with defense orientation and copulation.[18]

Sensory-motor activities.

At rest sensory input to the higher sensory areas of the cerebral cortex is gated through the thalamus. It has moreover been proposed that the zona incerta provides a top-down disinhibitory mechanism of this gating when there is sensory-motor activity such as the tactile use of whiskers.[3][19]

This has also been linked to sensory gating changes between sleep and waking. In this occurs a zona incerta mediated inhibition of thalamic nuclei such the somatosensory posterior medial thalamus. This is most strong when cholinergic input to the zona incerta is reduced as during slow-wave sleep and during anesthesia. The consequence of this has been explained upon information processing:

As a result, posterior medial thalamus neurons fail to respond to ascending sensory inputs, and function primarily in "higher-order" mode, concerned with relaying trans-cortical information. By contrast, increased cholinergic activity during wakefulness and enhanced vigilance suppresses zona incerta -mediated inhibition, thereby ungating posterior thalamus responses to ascending inputs.[15]

The zona incerta projects to the superior colliculus and these link to the initiation of orientating eye and head movements. In monkeys for example neuronal activity in the zona incerta "pauses" before the start of a saccade and resumes at the end of a saccade.[20]

Synchronizing cortical and subcortical brain rhythms and integration.

The GABAergic input received from the cerebral cortex has been suggested to synchronize thalamocortical and brainstem rhythms by providing a link between basal ganglia output and the cerebello-thalamo cortical loop.[7][21] This allows it to synchronize oscillations generate by the basal ganglia during the preparation and execution of intended movements. One function of the loop is to carry movement instructions to the motor cortex through zona incerta output to the ventral lateral nucleus neurons in the cerebello-thalamocortical loop and to brainstem motor neurons in the medial reticular formation and midbrain extrapyramidal area. This acts to synchronize the basal ganglia areas involved in planning and execution of the movement with those in the brainstem controlling axial and proximal limb muscles with those areas in the motor cortex that control distal limb movements.[7]

Synthesis

John Mitrofanis at the University of Sydney has proposed a general theory that might underlie some of the above.

The zona incerta is in a position to form a primal synaptic interface of the diencephalon, linking diverse sensory channels to appropriate visceral, arousal, attention and posture-locomotion responses. The different sensory inputs, whether exteroreceptive (somatic) or interoreceptive (visceral), influence these activities by driving zona incerta cells with different projection patterns and functions; each of these cells may be located in different sectors of the zone… In essence, it is suggested that the zona incerta has the pathways to integrate both exteroreceptive (e.g. somatosensory) and interoreceptive (e.g. thirst) sensory challenges, so that visceral activity, arousal, attention and/or posture locomotion are altered and/or generated. The zona incerta could form a neural niche in the thalamus from where these responses are "recruited" immediately, as to give an instant response.[2]

Clinical significance

Parkinson's disease

Parkinson's disease might disrupt the zona incerta as it is hyperactive in parkinsonian experimental animals.[22] In humans with Parkinson's disease, surgical lesion of the zona incerta alleviates their parkinsonian motor symptoms.

Deep brain stimulation of the subthalamic nucleus in those with Parkinson's disease has identified the zona incerta as a promising target area for effective therapy.[23] Unlike deep bilateral stimulation of the ventral lateral nucleus such stimulation of the zona incerta improves all aspects of tremor including both the distal and proximal parts of limbs and the body more generally.[7] This also occurs without dysarthria and disequilibrium as this stimulation does not interrupt proprioceptive sensation and the processing of the fine motor skill movements of vocal cords.

Researchers observed that "The ventral lateral nucleus has long been established as an effective surgical target for controlling distal limb tremor, including Parkinson Disease tremor. However, because it receives predominantly cerebellar afferents and no direct basal ganglia afferents, the reason why it is effective in controlling Parkinson Disease tremor has remained a paradox. The conduction of abnormal oscillations generated in the basal ganglia in Parkinson Disease to the ventral lateral nucleus via zona incerta would therefore explain this paradox and also explain why we observed such a potent anti-tremor effect from stimulating zona incerta in our patients with Parkinson Disease"[7]

The study further noted that deep brain stimulation upon the zona incerta "is effective in suppressing all components of tremor affecting both the distal and proximal part of the body. These results, if replicated in larger randomised controlled studies, have important implications for our current surgical management of patients with tremor and point to a more promising target area than the ventral lateral nucleus of the thalamus."[7]

Central pain syndrome

Central pain syndrome is pain initiated or caused by injury or dysfunction in the central nervous system. Recent research suggests that the development and maintenance of such pain could link to abnormal inhibitory regulation by the zona incerta of the posterior thalamus.[11] It has been suggested that there exists

a significant suppression of both spontaneous and evoked activity in inhibitory neurons in zona incerta and abnormally high spontaneous and evoked activity of neurons in posterior thalamus in animals with central pain syndrome. The positive association between behavioral and neurophysiological thresholds in rats with central pain syndrome is consistent with a causal role for suppressed incerto-thalamic inputs in central pain syndrome.[11]

References

  1. Forel, A. (1877). "Untersuchungen über die Haubenregion und ihre oberen Verknüpfungen im Gehirne des Menschen und einiger Säugethiere, mit Beiträgen zu den Methoden der Gehirnuntersuchung". Archiv für Psychiatrie und Nervenkrankheiten. 7 (3): 393–495. doi:10.1007/BF02041873.
  2. 1 2 3 4 5 6 7 Mitrofanis, J. (2005). "Some certainty for the "zone of uncertainty"? Exploring the function of the zona incerta". Neuroscience. 130 (1): 1–15. doi:10.1016/j.neuroscience.2004.08.017. ISSN 0306-4522. PMID 15561420.
  3. 1 2 3 Urbain, N.; Deschênes, M. (Nov 2007). "Motor cortex gates vibrissal responses in a thalamocortical projection pathway". Neuron. 56 (4): 714–725. doi:10.1016/j.neuron.2007.10.023. ISSN 0896-6273. PMID 18031687.
  4. Kolmac, C.; Mitrofanis, J. (1999). "Distribution of various neurochemicals within the zona incerta: an immunocytochemical and histochemical study". Anatomy and Embryology. 199 (3): 265–280. doi:10.1007/s004290050227. PMID 10068092.
  5. Kawana, E; Watanabe, K (1981). "A cytoarchitectonic study of zona incerta in the rat". Journal für Hirnforschung. 22 (5): 535–41. ISSN 0021-8359. PMID 7328309.
  6. 1 2 3 Mitrofanis, J.; Ashkan, K.; Wallace, A.; Benabid, L. (Jul 2004). "Chemoarchitectonic heterogeneities in the primate zona incerta: clinical and functional implications". Journal of neurocytology. 33 (4): 429–440. doi:10.1023/B:NEUR.0000046573.28081.dd. ISSN 0300-4864. PMID 15520528.
  7. 1 2 3 4 5 6 7 Plaha, P.; Khan, S.; Gill, S. (May 2008). "Bilateral stimulation of the caudal zona incerta nucleus for tremor control". Journal of Neurology, Neurosurgery, and Psychiatry. 79 (5): 504–513. doi:10.1136/jnnp.2006.112334. ISSN 0022-3050. PMID 18037630.
  8. Bittencourt, J. C.; Presse, F.; Arias, C.; Peto, C.; Vaughan, J.; Nahon, J. -L.; Vale, W.; Sawchenko, P. E. (May 1992). "The melanin-concentrating hormone system of the rat brain: an immuno- and hybridization histochemical characterization" (Free full text). The Journal of Comparative Neurology. 319 (2): 218–245. doi:10.1002/cne.903190204. ISSN 0021-9967. PMID 1522246.
  9. Lin, CS; Nicolelis, MA; Schneider, JS; Chapin, JK. (1990). "A major direct GABAergic pathway from zona incerta to neocortex". Science. 248 (4962): 1553–6. doi:10.1126/science.2360049. PMID 2360049.
  10. Nicolelis, M.; Chapin, J. K.; Lin, R. C. (1992). "Somatotopic maps within the zona incerta relay parallel GABAergic somatosensory pathways to the neocortex, superior colliculus, and brainstem". Brain Research. 577 (1): 134–141. doi:10.1016/0006-8993(92)90546-L. PMID 1521138.
  11. 1 2 3 4 Masri, R.; Quiton, L.; Lucas, M.; Murray, D.; Thompson, M.; Keller, A. (Jul 2009). "Zona incerta: a role in central pain". Journal of Neurophysiology. 102 (1): 181–191. doi:10.1152/jn.00152.2009. ISSN 0022-3077. PMC 2712264Freely accessible. PMID 19403748.
  12. Wagner, C.; Eaton, M.; Moore, K.; Lookingland, K. (1995). "Efferent projections from the region of the medial zona incerta containing A13 dopaminergic neurons: a PHA-L anterograde tract-tracing study in the rat". Brain Research. 677 (2): 229–997. doi:10.1016/0006-8993(95)00128-D. PMID 7552247.
  13. Heise, C. E.; Mitrofanis, J. (Jan 2004). "Evidence for a glutamatergic projection from the zona incerta to the basal ganglia of rats". The Journal of Comparative Neurology. 468 (4): 482–495. doi:10.1002/cne.10971. ISSN 0021-9967. PMID 14689481.
  14. Teune, T. M.; Van Der Burg, J.; Van Der Moer, J.; Voogd, J.; Ruigrok, T. J. H. (2000). "Topography of cerebellar nuclear projections to the brain stem in the rat". Cerebellar modules: Molecules, morphology and function. Progress in Brain Research. 124. pp. 141–172. doi:10.1016/S0079-6123(00)24014-4. ISBN 9780444501080. PMID 10943123.
  15. 1 2 Trageser, C.; Burke, A.; Masri, R.; Li, Y.; Sellers, L.; Keller, A. (Sep 2006). "State-dependent gating of sensory inputs by zona incerta" (Free full text). Journal of Neurophysiology. 96 (3): 1456–1463. doi:10.1152/jn.00423.2006. ISSN 0022-3077. PMC 1764852Freely accessible. PMID 16775205.
  16. Shaw, V. E.; Mitrofanis, J. (2001). "Lamination of spinal cells projecting to the zona incerta of rats.". Journal of Neurocytology. 30 (8): 695–704. doi:10.1023/A:1016529817118. PMID 12118157.
  17. Shaw, V.; Mitrofanis, J. (Dec 2002). "Anatomical evidence for somatotopic maps in the zona incerta of rats". Anatomy and embryology. 206 (1–2): 119–130. doi:10.1007/s00429-002-0280-7. ISSN 0340-2061. PMID 12478373.
  18. Edwards, DA; Isaacs, S (1991). "Zona incerta lesions: effects on copulation, partner-preference and other socio-sexual behaviors.". Behavioural Brain Research. 44 (2): 145–50. doi:10.1016/S0166-4328(05)80019-1. PMID 1751005.
  19. Lavallée, P.; Urbain, N.; Dufresne, C.; Bokor, H.; Acsády, L.; Deschênes, M. (Aug 2005). "Feedforward inhibitory control of sensory information in higher-order thalamic nuclei" (Free full text). Journal of Neuroscience. 25 (33): 7489–7498. doi:10.1523/JNEUROSCI.2301-05.2005. ISSN 0270-6474. PMC 2670454Freely accessible. PMID 16107636.
  20. Ma, T. P. (Nov 1996). "Saccade-related omnivectoral pause neurons in the primate zona incerta". NeuroReport. 7 (15–17): 2713–2716. doi:10.1097/00001756-199611040-00061. ISSN 0959-4965. PMID 8981453.
  21. Barthó, P.; Slézia, A.; Varga, V.; Bokor, H.; Pinault, D.; Buzsáki, G.; Acsády, L. (Feb 2007). "Cortical control of zona incerta" (Free full text). Journal of Neuroscience. 27 (7): 1670–1681. doi:10.1523/JNEUROSCI.3768-06.2007. ISSN 0270-6474. PMC 2670453Freely accessible. PMID 17301175.
  22. Périer, C; Vila, M; Féger, J; Agid, Y; Hirsch, EC (2000). "Functional activity of zona incerta neurons is altered after nigrostriatal denervation in hemiparkinsonian rats.". Experimental neurology. 162 (1): 215–24. doi:10.1006/exnr.1999.7331. PMID 10716902.
  23. Sun, A.; Yu, H.; Spooner, J.; Tatsas, D.; Davis, T.; Abel, W.; Kao, C.; Konrad, E. (August 2008). "Postmortem analysis following 71 months of deep brain stimulation of the subthalamic nucleus for Parkinson disease". Journal of Neurosurgery. 109 (2): 325–329. doi:10.3171/JNS/2008/109/8/0325. ISSN 0022-3085. PMID 18671648.
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