Biology:Brodmann area 15
| Brodmann area 15 | |
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| Anatomical terms of neuroanatomy |
Brodmann Area 15 is one of Brodmann's subdivisions of the cerebral cortex in the brain.
Area 15 was defined by Brodmann in the guenon monkey, but he found no equivalent structure in humans. However, functional imaging experiments have found structures that may be homologous.
Anatomy
Gross Anatomy
Area 15 is located in the part of the insula nearest the temporal lobe and part of the anterior temporal lobe facing the insula.[1] It is buried in the Sylvian Fissure and thus not visible on the surface of the brain without dissection.
Cytoarchitecture
Area 15, like all Brodmann areas, is defined on the basis of cytoarchitecture of the region of cortex. The cortex in area 15 is thinner than in the rest of the insula and temporal lobe. The molecular layer (I) is unusually wide; the external granular layer (II) and the external pyramidal layer (III) are less dense, and the internal granular layer (IV) is totally absent, so that the medium-sized pyramidal cells of layer III and the internal pyramidal layer (V) merge with a few isolated granular cells scattered at their boundary. The multiform layer (VI) divides into a more densely cellular outer sublayer (VIa) and a less dense inner sublayer (VIb). As in Brodmann area 14, the sublayer VIb merges with the adjacent claustrum. The cells in all of layer VI form tangential rows similar to the formation seen in area 10 and area 11.[1]
Existence in Humans
Brodmann Area 15 is one of the areas that was not found in humans; however, at least one research group has found an area in approximately the correct anatomical location with similar functions.[2]
Function
Area 15 is the cortical target of information coming through Hering's nerves.[3] It therefore receives input from the carotid sinus relaying blood pressure and blood chemistry information to the brain.[4] The nerve gets this information from baroreceptors and chemoreceptors located in the carotid artery. This region has been shown to be active during panic attacks.[2]
See also
References
- ↑ 1.0 1.1 Brain Info Brodmann Area 15 visited 1/22/2007
- ↑ 2.0 2.1 Fischer, et Al. "Brain correlates of an unexpected panic attack: a human positron emission tomographic study". Neuroscience Letters 251(2):137-140 (1998)
- ↑ Tubbs et Al. "Cortical Representation of Hering's Nerve: A Possible Anatomical Pathway for Seizure Cessation following Electrical Stimulation." Pediatric Neurosurgery 24(5) (2002)
- ↑ whonamedit Hering's nerves visited 1/22/2007
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