In anatomy a chiasm is the spot where two structures cross, forming an X-shape (). Examples of chiasms are:
A tendinous chiasm, the spot where two tendons cross. For example, the tendon of the flexor digitorum superficialis muscle, and the tendon of the flexor digitorum longus muscle which even forms two chiasms.
In neuroanatomy, the crossing of fibres of a nerve or the crossing of two nerves.
Different types of crossings of nerves are referred to as chiasm:
Type I: Two nerves can cross one over the other (sagittal plane) without fusing, e.g., the trochlear nerve (see figure).
Type II: Two nerves can merge while at least part of the fibres cross the midline (see figure 2).
Type III: The fibres within a single nerve cross, such that the order of the functional map is reversed, e.g., the optic chiasms of various invertebrates such as insects and cephalopods.
Type IV: A torsion or loop by 180 degrees of a nerve can also reverse the order of the functional map. This type is usually not referred to as chiasm.
Note that in the third type there is no crossing of the mid sagittal plane. Only in the first type, the crossing is complete.
There are other kinds of crossings of nerve fibres. The chiasm is distinguished from a decussation, which is a crossing of nerve fibres inside the central nervous system. A chiasm also differs from a ganglion in that axons run through it without making any synapses. A chiasm is thus not a nervous processing centre.
optic chiasm
By far the most widely known chiasm is the optic chiasm in vertebrate animals, including humans.
Chiasms are found in vertebrates but also in invertebrates. The optic chiasm in vertebrates can be of type I or II. However, an optic chiasm of type III is found in many insects and in cephalopods.
In vertebrates three of the cranial nerves show a chiasm.
The Optic chiasm of the optic tract (type I or II)
The chiasm of the Trochlear nerve (type I)
The decussation of part of the Oculomotor nerve (type I)
The optic chiasm of vertebrates involves the optic tract.
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The contralateral organization of the forebrain (Latin: contra‚ against; latus‚ side; lateral‚ sided) is the property that the hemispheres of the cerebrum and the thalamus represent mainly the contralateral side of the body. Consequently, the left side of the forebrain mostly represents the right side of the body, and the right side of the brain primarily represents the left side of the body. The contralateral organization involves both executive and sensory functions (e.g., a left-sided brain lesion may cause a right-sided hemiplegia).
Decussation is used in biological contexts to describe a crossing (due to the shape of the Roman numeral for ten, an uppercase 'X' (decussis), ). In Latin anatomical terms, the form decussatio is used, e.g. decussatio pyramidum. Similarly, the anatomical term chiasma is named after the Greek uppercase 'Χ' (chi). Whereas a decussation refers to a crossing within the central nervous system, various kinds of crossings in the peripheral nervous system are called chiasma.
In neuroanatomy, the optic chiasm, or optic chiasma (pronQptIk_kaIaezəm; , ), is the part of the brain where the optic nerves cross. It is located at the bottom of the brain immediately inferior to the hypothalamus. The optic chiasm is found in all vertebrates, although in cyclostomes (lampreys and hagfishes), it is located within the brain. This article is about the optic chiasm of vertebrates, which is the best known nerve chiasm, but not every chiasm denotes a crossing of the body midline (e.g.
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