Brain: Choroid plexus
Scheme of roof of fourth ventricle. The arrow is in the foramen of Magendie. 1: inferior medullary velum 2: Choroid plexus 3: Cerebellomedullary cistern of subarachnoid cavity 4: Central canal 5: Corpora quadrigemina 6: Cerebral peduncle 7: Superior medullary velum 8: Ependymal lining of ventricle 9: Pontine cistern of subarachnoid cavity
Coronal section of lateral and third ventricles.
Latin	plexus choroideus
Gray's	subject #187 798
NeuroNames	ancil-456
MeSH	Choroid+Plexus

The choroid plexus (from Latin: chorion - delicate, plexus knot) is the area on the ventricles of the brain where cerebrospinal fluid (CSF) is produced by modified ependymal cells.

Contents 1 Locations 2 Structure of the choroid plexus 3 Pathology 4 See also 5 Additional images 6 References 7 External links

[edit] Locations

Choroid plexus is present in all components of the ventricular system except for the cerebral aqueduct and the occipital and frontal horns of the lateral ventricles.

It is found in the superior part of the inferior horn of the lateral ventricles. It follows up along this boundary, continuous with the inferior of the body of the lateral ventricles. It passes into the interventricular foramen, and is present at the top of the third ventricle.

There is also choroid plexus on the fourth ventricle, on the section closest to the bottom half of the cerebellum.

[edit] Structure of the choroid plexus

The choroid plexus (CP) consists of many capillaries, separated from the ventricles by choroid epithelial cells. Liquid filters through these cells from blood to become cerebrospinal fluid. There is also much active transport of substances into, and out of, the CSF as it is made.

There are four choroid plexus in the brain, one in each of the ventricles. The CP consist of a layer of cuboidal epithelial cells surrounding a core of capillaries and loose connective tissue. The CP epithelial layer is continuous with the ependymal cell layer that lines the ventricles, but unlike the ependyma the CP epithelial layer has tight junctions in between the cells on the side facing the ventricle (apical surface). These tight junctions prevent the majority of substances from crossing the cell layer into the CSF; thus the CP acts as a blood-CSF barrier. The CP folds into many villi around each capillary, creating frond-like processes that project into the ventricles. The villi, along with a brush border of microvilli, greatly increases the surface area of the CP. CSF is formed as plasma is filtered from the blood through the epithelial cells. CP epithelial cells actively transport sodium, chloride and bicarbonate ions into the ventricles and water follows the resulting osmotic gradient.

In addition to CSF production, the CP act as a filtration system, removing metabolic waste, foreign substances, and excess neurotransmitters from the CSF. In this way the CP have a very important role in helping to maintain the delicate extracellular environment required by the brain to function optimally.

[edit] Pathology

During embryological development, some fetuses may form choroid plexus cysts. These fluid-filled cysts can be detected by a level II ultrasound (18–20 weeks gestation). The finding is relatively common, with a prevalence of ~1%. Choroid plexus cysts (CPC) can be an isolated finding, which confers a 1-12% (variable based on population studied) risk of fetal aneuploidy. The risk of aneuploidy increases to 10.5-12% if other risk factors or ultrasound findings are noted. The idioma size, bilaterality, disappearance/progression of the CPC, and position of the CPC do not have any effect on the risk of aneuploidy. 44-50% of trisomy 18 cases will present with CPC, and 1.4% of trisomy 21 (Down syndrome) cases will present with CPC. ~75% of abnormal karyotypes (obtained by chorionic villus sampling or amniocentesis) associated with CPCs are trisomy 18, while the remainder are trisomy 21. ^[1]

CPCs typically disappear later during pregnancy, and are considered soft markers. They are likely harmless, and studies have shown that they have no effect on infant and early childhood development.^[2]

[edit] See also

• Choroid plexus papilloma

[edit] Additional images

Velum interpositum.	Mesal aspect of a brain sectioned in the median sagittal plane.	Coronal section of brain immediately in front of pons.	Coronal section of brain through intermediate mass of third ventricle.
Median sagittal section of brain.	Posterior and inferior cornua of left lateral ventricle exposed from the side.	Coronal section of inferior horn of lateral ventricle.	Choroid Plexus Histology 40x

[edit] References

Brodbelt and Stoodley. "CSF Pathways: A Review". 2007 British Journal of Neurosurgery

Strazielle and Ghersi-Egea. "Choroid Plexus in the Central Nervous System: BIology and Physiopathology". 2000. Jouranal of Neuropathology and Experimental Neurology 59(7): 561-574.

[edit] External links

• Media related to choroid plexus at Wikimedia Commons
• University of Idaho
• 3-Dimensional images of choroid plexus (marked red)
• Roche Lexicon - illustrated navigator, at Elsevier 13048.000-3
• MedPix Images of Choroid Plexus

v • d • e Anatomy: meninges of the brain and medulla spinalis (TA A14.1.01, GA 9.749/9.872) Layers Dura mater Falx cerebri · Tentorium cerebelli · Falx cerebelli · Diaphragma sellae · Trigeminal cave Arachnoid mater Arachnoid granulation Subarachnoid cisterns: Cisterna magna · Pontine cistern · Interpeduncular cistern · Chiasmatic · Lateral cerebral fossa · Of great cerebral vein Pia mater Denticulate ligaments Tela chorioidea (Tela chorioidea of third ventricle, Tela chorioidea of fourth ventricle) · Choroid plexus Combined Filum terminale · Leptomeninges Spaces Epidural space · Subdural space · Subarachnoid space (Cerebrospinal fluid)