Vitreous body explained

Vitreous humor
Latin:humor vitreus
System:Visual system
Part Of:Eye

The vitreous body (vitreous meaning "glass-like";,) is the clear gel that fills the space between the lens and the retina of the eyeball (the vitreous chamber) in humans and other vertebrates. It is often referred to as the vitreous humor (also spelled humour), from Latin meaning liquid, or simply "the vitreous". Vitreous fluid or "liquid vitreous" is the liquid component of the vitreous gel, found after a vitreous detachment. It is not to be confused with the aqueous humor, the other fluid in the eye that is found between the cornea and lens.

Structure

The vitreous humor is a transparent, colorless, gelatinous mass that fills the space in the eye between the lens and the retina. It is surrounded by a layer of collagen called the vitreous membrane (or hyaloid membrane or vitreous cortex) separating it from the rest of the eye. It makes up four-fifths of the volume of the eyeball.[1] The vitreous humour is fluid-like near the centre, and gel-like near the edges.

The vitreous humour is in contact with the vitreous membrane overlying the retina. Collagen fibrils attach the vitreous at the optic nerve disc and the ora serrata (where the retina ends anteriorly), at the Wieger-band, the dorsal side of the lens. The vitreous also firmly attaches to the lens capsule, retinal vessels, and the macula, the area of the retina which provides finer detail and central vision.[2]

Aquaporin 4 in Müller cells in rats transports water to the vitreous body.[3] [4]

Anatomical features

The vitreous has many anatomical landmarks, including the hyaloid membrane, Berger's space, space of Erggelet, Wieger's ligament, Cloquet's canal and the space of Martegiani.[5] [6] [7]

Surface features:

Internal structures of the vitreous

Named tracts

Biochemical properties

Its composition is similar to that of the cornea, but the vitreous contains very few cells. It is composed mostly of phagocytes, which remove unwanted cellular debris in the visual field, and hyalocytes, which turn over the hyaluronan.

The vitreous humour contains no blood vessels, and 98–99% of its volume is water (as opposed to only 75% in the cornea). In addition to water, the vitreous consists of salts, sugars, vitrosin (a type of collagen), a network of collagen type II fibrils with glycosaminoglycan, hyaluronan, opticin, and a wide array of proteins. Despite having little solid matter, the fluid is substantial enough to fill the eye and give it its spherical shape. This contrasts with the aqueous humour, which is more fluid, and the lens, on the other hand, which is elastic in nature and is tightly packed with cells.[9] The vitreous humour has a viscosity two to four times that of water, giving it a gelatinous consistency. It has a refractive index of 1.336.[10]

Inorganic ion content of vitreous! Solute !! Mean concentration !! Units !! Reference !! Data from living humans?
146.7 mmol/L [11] Yes
5.73 mmol/L Yes
121.6 mmol/L Yes
1.13 mmol/L Yes
0.9 mmol/L Yes
0.1 to 3.3 mEq/dm3 No
1.2 to 3.0 g/kg water No
Inorganic coenzyme content of vitreous! Solute !! Mean concentration !! Units !! Reference !! Data from living humans?
0.52 μmol/L Yes
0.104 μmol/L Yes
3.11 μmol/L Yes
110.7 nmol/L [12] Yes
Organic content of vitreous! Solute !! Mean concentration !! Units !! Reference !! Data from living humans?
2.97 mmol/L Yes
3.97 mmol/L Yes
2 μg/mL No
280–1360 μg/cm3 No
42–400 μg/cm3 No
60 μg/cm3 No
300 μg/mL [13] No
293 ± 18 μg/cm3 No
33.5 ± 3 μg/cm3 No
141 ± 2.9 μg/cm3 No
4 ± 0.7 μg/cm3 No
0.094 mmol/L Yes
19.52 μg/L Yes
0.088 g/L Yes
24–172 mg/dL water No
0.3–3.0 mg/dL water No
1.9 mg/dL water No
7.3 mg/dL water No
36 mg/100g No
Physical properties of vitreous! Property !! Value !! Units !! Reference !! Data from living humans?
3.9 mL [14] No
3.9 g No
99 to 99.7 % No
7.4 to 7.52 No
289.5 mOsm/kg Yes
Osmotic pressure (Freezing-point depression) -0.554 to -0.518 °C No
1.0053 to 1.0089 g/cm3 No
3–5 × 103 cm3/g No
1.6 cP No
1.3345 to 1.337 No

Development

The vitreous fluid is not present at birth (the eye being filled with only the gel-like vitreous body), but found after age 4-5, and increases in size thereafter.

Produced by cells in the non-pigmented portion of the ciliary body, the vitreous humour is derived from embryonic mesenchyme cells, which degenerate after birth.

The nature and composition of the vitreous humour changes over the course of life. In adolescence, the vitreous cortex becomes more dense and vitreous tracts develop; and in adulthood, the tracts become better defined and sinuous. Central vitreous liquefies, fibrillar degeneration occurs, and the tracts break up (syneresis).

Coarse strands develop with ageing. The gel volume decreases with age, and the liquid volume increases.[14] The cortex may disappear at sites, allowing liquid vitreous to extrude adjacently into the potential space between vitreous cortex and retina (vitreous detachment).

Clinical significance

Injury

If the vitreous pulls away from the retina, it is known as a vitreous detachment. As the human body ages, the vitreous often liquefies and may collapse. This is more likely to occur, and occurs much earlier, in eyes that are nearsighted (myopia). It can also occur after injuries to the eye or inflammation in the eye (uveitis).

The collagen fibres of the vitreous are held apart by electrical charges. With aging, these charges tend to reduce, and the fibres may clump together. Similarly, the gel may liquefy, a condition known as synaeresis, allowing cells and other organic clusters to float freely within the vitreous humour. These allow floaters which are perceived in the visual field as spots or fibrous strands. Floaters are generally harmless, but the sudden onset of recurring floaters may signify a posterior vitreous detachment or other diseases of the eye.

Posterior vitreous detachment

Once liquid vitreous enters the sub-hyaloid space between the vitreous cortex and the retina, it may strip the vitreous cortex off the retina with each eye movement (see Saccade).

Postmortem and forensic

After death, the vitreous resists putrefaction longer than other body fluids. Within the hours, days and weeks after death, the vitreous potassium concentration rises, at such a predictable speed that vitreous potassium levels are frequently used to estimate the time since death (post-mortem interval) of a corpse.[15] [16] [17]

The metabolic exchange and equilibration between systemic circulation and vitreous humour is so slow that vitreous humour is sometimes the fluid of choice for postmortem analysis of glucose levels or substances which would be more rapidly diffused, degraded, excreted or metabolized from the general circulation.

According to Jewish religion, extracting the vitreous fluid for forensic chemical analysis is preferred to blood analysis (in case a forensic or post-mortem toxicology test is deemed necessary). This avoids the loss of even a few droplets of blood from the body prior to burial.

See also

External links

Notes and References

  1. Book: Susan Standring . Neil R. Borley . etal . Gray's anatomy: the anatomical basis of clinical practice. 2008. Churchill Livingstone. London. 978-0-8089-2371-8. 40th.
  2. Book: Retina and vitreous.. American Academy of Ophthalmology. 2017 . 9781615258185. 2017-2018. San Francisco, CA. 1003266782.
  3. Sim?. Rafael. Villarroel. Marta. Corraliza. L?dia. Hern?ndez. Cristina. Garcia-Ram?rez. Marta. The Retinal Pigment Epithelium: Something More than a Constituent of the Blood-Retinal Barrier? Implications for the Pathogenesis of Diabetic Retinopathy. Journal of Biomedicine and Biotechnology. 2010. 2010. 190724. 10.1155/2010/190724. 20182540. 2825554. free .
  4. Nagelhus. EA. Veruki. ML. Torp. R. Haug. FM. Laake. JH. Nielsen. S. Agre. P. Ottersen. OP. Aquaporin-4 water channel protein in the rat retina and optic nerve: polarized expression in Müller cells and fibrous astrocytes.. The Journal of Neuroscience. 1 April 1998. 18. 7. 2506–19. 9502811. These data suggest that Muller cells play a prominent role in the water handling in the retina and that they direct osmotically driven water flux to the vitreous body and vessels rather than to the subretinal space . 10.1523/JNEUROSCI.18-07-02506.1998. 6793100. free.
  5. http://image.slidesharecdn.com/anatomyoflens-151014144942-lva1-app6892/95/anatomy-of-lens-6-638.jpg?cb=1444834244 Anatomical relation
  6. http://www.oculist.net/downaton502/prof/ebook/duanes/graphics/figures/v7/0010/025f.jpg shaded cross-section of eye, labelling structures in the posterior capsule
  7. http://www.oculist.net/downaton502/prof/ebook/duanes/graphics/figures/v6/0510/001f.jpg line drawing cross-section of eye, with details of structures in the posterior capsule
  8. https://webeye.ophth.uiowa.edu/eyeforum/atlas/pages/mittendorf-dots.htm Mittendorf dot
  9. "eye, human" Encyclopædia Britannica -from Encyclopædia Britannica 2006 Ultimate Reference Suite DVD 2009
  10. http://retina.anatomy.upenn.edu/~lance/eye/humor_vitreous.html The Vitreous Humor
  11. Web site: Biochemical analysis of the living human vitreous. ResearchGate. 2016-03-09.
  12. Web site: Manganese in the Human Vitreous. 1 March 2016. ResearchGate.
  13. Book: Velpandian, Thirumurthy. Pharmacology of Ocular Therapeutics. 29 February 2016. Springer. Google Books. 9783319254982.
  14. Book: Handbook of Biomaterial Properties. William. Murphy. Jonathan. Black. Garth. Hastings. 11 June 2016. Springer. Google Books. 9781493933051.
  15. A new model for the estimation of time of death from vitreous potassium levels corrected for age and temperature. Forensic Science International. B.. Zilg. S.. Bernard. K.. Alkass. S.. Berg. H.. Druid. 17 July 2015. 254. 158–66. 10.1016/j.forsciint.2015.07.020. 26232848. 10616/44849. free.
  16. Antemortem vitreous potassium may strengthen postmortem interval estimates. Forensic Science International. Jan. Kokavec. San H.. Min. Mei H.. Tan. Jagjit S.. Gilhotra. Henry S.. Newland. Shane R.. Durkin. Robert J.. Casson. 19 March 2016. 263. e18. 10.1016/j.forsciint.2016.03.027. 27080618.
  17. Postmortem Vitreous Analyses: Overview, Vitreous Procurement and Pretreatment, Performable Postmortem Vitreous Analyses. 30 June 2020 . eMedicine.