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Macula

December 15, 2023

This article is about the macula of the eye. For other uses, see Macula (disambiguation).

The macula (/ˈmakjʊlə/)[1] or macula lutea is an oval-shaped pigmented area in the center of the retina of the human eye and in other animals. The macula in humans has a diameter of around 5.5 mm (0.22 in) and is subdivided into the umbo, foveola, foveal avascular zone, fovea, parafovea, and perifovea areas.[2]

Macula
The macula is the central part of the retina of the human eye, its center slightly shifted to the temporal side. (The location in the image is misleading: it looks as if the macula were far removed from the center which is not the case.) .
Details
Part ofRetina of human eye
SystemVisual system
Identifiers
Latinmacula lutea
MeSHD008266
TA98A15.2.04.021
TA26784
FMA58637
Anatomical terminology
[edit on Wikidata]

The anatomical macula at a size of 5.5 mm (0.22 in) is much larger than the clinical macula which, at a size of 1.5 mm (0.059 in), corresponds to the anatomical fovea.[3][4][5]

The macula is responsible for the central, high-resolution, color vision that is possible in good light; and this kind of vision is impaired if the macula is damaged, for example in macular degeneration. The clinical macula is seen when viewed from the pupil, as in ophthalmoscopy or retinal photography.

The term macula lutea comes from Latin macula, "spot", and lutea, "yellow".

Structure edit

 
Photograph of the retina of the human eye, with overlay diagrams showing the positions and sizes of the macula, fovea, and optic disc
 
Schematic diagram of the macula lutea of the retina, showing perifovea, parafovea, fovea, and clinical macula

The macula is an oval-shaped pigmented area in the center of the retina of the human eye and other animal eyes. Its center is shifted slightly away from the optical axis (laterally, by 5°=1.5 mm).[6] The macula in humans has a diameter of around 5.5 mm (0.22 in) and is subdivided into the umbo, foveola, foveal avascular zone, fovea, parafovea, and perifovea areas.[2] An even smaller central region of highest receptor density (40–80 μm) is sometimes referred to as the foveal bouquet.[7][8][9][10] The anatomical macula at 5.5 mm (0.22 in) is much larger than the clinical macula which, at 1.5 mm (0.059 in), corresponds to the anatomical fovea.[3][4][5]

The clinical macula is seen when viewed from the pupil, as in ophthalmoscopy or retinal photography. The anatomical macula is defined histologically in terms of having two or more layers of ganglion cells.[11] The umbo is the center of the foveola which in turn is located at the center of the fovea.

The fovea is located near the center of the macula. It is a small pit that contains the largest concentration of cone cells. The retina's receptor layer contains two types of photosensitive cells, the rod cells and the cone cells.

Color edit

Because the macula is yellow in color, it absorbs excess blue and ultraviolet light that enter the eye and acts as a natural sunblock (analogous to sunglasses) for this area of the retina. The yellow color comes from its content of lutein and zeaxanthin, which are yellow xanthophyll carotenoids, derived from the diet. Zeaxanthin predominates at the macula, while lutein predominates elsewhere in the retina. There is some evidence that these carotenoids protect the pigmented region from some types of macular degeneration. A formulation of 10 mg lutein and 2 mg zeaxanthin has been shown to reduce the risk of age-related macular degeneration progressing to advanced stages, although these carotenoids have not been shown to prevent the disease.[12]

After death or enucleation (removal of the eye), the macula appears yellow, a color that is not visible in the living eye except when viewed with light from which red has been filtered.[13]

Regions edit

Function edit

Structures in the macula are specialized for high-acuity vision. Within the macula are the fovea and foveola that both contain a high density of cones, which are nerve cells that are photoreceptors with high acuity.

In detail, the normal human eye contains three different types of cones, with different ranges of spectral sensitivity. The brain combines the signals from neighboring cones to distinguish different colors. There is only one type of rod, but the rods are more sensitive than the cones, so in dim light, they are the dominant photoreceptors active, and without information provided by the separate spectral sensitivity of the cones it is impossible to discriminate colors. In the fovea centralis, cones predominate and are present at high density. The macula is thus responsible for the central, high-resolution, color vision that is possible in good light; and this kind of vision is impaired if the macula is damaged, for example in macular degeneration.[14]

Clinical significance edit

 
 
Fundus photographs of the right eye (left image) and left eye (right image), seen from front so that left in each image is to the person's right. The gaze is into the camera, so in each picture the macula is in the center of the image, and the optic disc is located towards the nose.

The clinical macula is seen when viewed from the pupil, as in ophthalmoscopy or retinal photography.

Whereas loss of peripheral vision may go unnoticed for some time, damage to the macula will result in loss of central vision, which is usually immediately obvious. The progressive destruction of the macula is a disease known as macular degeneration and can sometimes lead to the creation of a macular hole. Macular holes are rarely caused by trauma, but if a severe blow is delivered it can burst the blood vessels going to the macula, destroying it.[14]

Visual input from the macula occupies a substantial portion of the brain's visual capacity. As a result, some forms of visual field loss that occur without involving the macula are termed macular sparing. (For example, visual field testing might demonstrate homonymous hemianopsia with macular sparing.)

In the case of occipitoparietal ischemia owing to occlusion of elements of either posterior cerebral artery, patients may display cortical blindness (which, rarely, can involve blindness that the patient denies having, as seen in Anton's Syndrome), yet display sparing of the macula. This selective sparing is due to the collateral circulation offered to macular tracts by the middle cerebral artery.[15] Neurological examination that confirms macular sparing can go far in representing the type of damage mediated by an infarct, in this case, indicating that the caudal visual cortex (which is the principal recipient of macular projections of the optic nerve) has been spared. Further, it indicates that cortical damage rostral to, and including, lateral geniculate nucleus is an unlikely outcome of the infarction, as too much of the lateral geniculate nucleus is, proportionally, devoted to macular-stream processing.[16]

Additional images edit

  •  

    A fundus photograph showing the macula as a spot to the left. The optic disc is the area on the right where blood vessels converge. The grey, more diffuse spot in the centre is a shadow artifact.

  •  

    Time-Domain OCT of the macular area of a retina at 800 nm, axial resolution 3 µm

  •  

    Spectral-Domain OCT macula cross-section scan.

  •  

    macula histology (OCT)

See also edit

This article uses anatomical terminology.

References edit

  1. ^ . Lexico.com. Archived from the original on 3 August 2020. Retrieved 24 August 2022.
  2. ^ a b . Project Orbis International. Archived from the original on 19 December 2014. Retrieved 11 October 2014.
  3. ^ a b Yanoff, Myron (2009). Ocular Pathology. Elsevier Health Sciences. p. 393. ISBN 978-0-323-04232-1. Retrieved 7 November 2014.
  4. ^ a b Small, R.G. (1994). The Clinical Handbook of Ophthalmology. CRC Press. p. 134. ISBN 978-1-85070-584-0. Retrieved 7 November 2014.
  5. ^ a b Peyman, Gholam A.; Meffert, Stephen A.; Chou, Famin; Mandi D. Conway (2000). Vitreoretinal Surgical Techniques. CRC Press. p. 6. ISBN 978-1-85317-585-5. Retrieved 7 November 2014.
  6. ^ le Grand, Yves (1957). Light, colour and vision. London: Chapman & Hall. p. 52.
  7. ^ Oesterberg, G. (1935). "Topography of the layer of rods and cones in the human retina". Acta Ophthalmologica Supplement. 6–10: 11–96.
  8. ^ Polyak, S. L. (1941). The Retina. Chicago: University of Chicago Press.
  9. ^ Tyler, C.W.; Hamer, R.D. (1990). "Analysis of visual modulation sensitivity. IV. Validity of the Ferry-Porter law". Journal of the Optical Society of America A. 7 (4): 743–758. Bibcode:1990JOSAA...7..743T. doi:10.1364/JOSAA.7.000743. PMID 2338596.
  10. ^ Strasburger, Hans (2020). "Seven myths on crowding and peripheral vision". i-Perception. 11 (2): 1–45. doi:10.1177/2041669520913052. PMC 7238452. PMID 32489576.
  11. ^ Remington, Lee Ann (2011). Clinical Anatomy of the Visual System. Elsevier Health Sciences. pp. 314–315. ISBN 978-1-4557-2777-3. Retrieved 7 November 2014.
  12. ^ Hobbs RP, Bernstein PS (2014). "Nutrient Supplementation for Age-related Macular Degeneration, Cataract, and Dry Eye". Journal of Ophthalmic and Vision Research. 9 (4): 487–493. doi:10.4103/2008-322X.150829. PMC 4329711. PMID 25709776.
  13. ^ Britton, George; Liaaen-Jensen, Synnove; Pfander, Hanspeter (2009). Carotenoids Volume 5: Nutrition and Health. Springer Science & Business Media. p. 301. ISBN 978-3-7643-7501-0. Retrieved 7 November 2014.
  14. ^ a b "Macular Degeneration". The Lecturio Medical Concept Library. 6 October 2020. Retrieved 9 August 2021.
  15. ^ Helseth, Erek. "Posterior Cerebral Artery Stroke". Medscape Reference. Medscape. Retrieved 23 October 2011.
  16. ^ Siegel, Allan; Sapru, Hreday N. (2006). Betty Sun (ed.). Essential Neuroscience (First Revised ed.). Baltimore, Maryland: Lippincott Williams & Wilkins. ISBN 978-0-7817-9121-2.

External links edit

December 15, 2023
macula, this, article, about, macula, other, uses, disambiguation, macula, ˈmakjʊlə, macula, lutea, oval, shaped, pigmented, area, center, retina, human, other, animals, macula, humans, diameter, around, subdivided, into, umbo, foveola, foveal, avascular, zone. This article is about the macula of the eye For other uses see Macula disambiguation The macula ˈmakjʊle 1 or macula lutea is an oval shaped pigmented area in the center of the retina of the human eye and in other animals The macula in humans has a diameter of around 5 5 mm 0 22 in and is subdivided into the umbo foveola foveal avascular zone fovea parafovea and perifovea areas 2 MaculaThe macula is the central part of the retina of the human eye its center slightly shifted to the temporal side The location in the image is misleading it looks as if the macula were far removed from the center which is not the case DetailsPart ofRetina of human eyeSystemVisual systemIdentifiersLatinmacula luteaMeSHD008266TA98A15 2 04 021TA26784FMA58637Anatomical terminology edit on Wikidata The anatomical macula at a size of 5 5 mm 0 22 in is much larger than the clinical macula which at a size of 1 5 mm 0 059 in corresponds to the anatomical fovea 3 4 5 The macula is responsible for the central high resolution color vision that is possible in good light and this kind of vision is impaired if the macula is damaged for example in macular degeneration The clinical macula is seen when viewed from the pupil as in ophthalmoscopy or retinal photography The term macula lutea comes from Latin macula spot and lutea yellow Contents 1 Structure 1 1 Color 1 2 Regions 2 Function 3 Clinical significance 4 Additional images 5 See also 6 References 7 External linksStructure edit nbsp Photograph of the retina of the human eye with overlay diagrams showing the positions and sizes of the macula fovea and optic disc nbsp Schematic diagram of the macula lutea of the retina showing perifovea parafovea fovea and clinical maculaThe macula is an oval shaped pigmented area in the center of the retina of the human eye and other animal eyes Its center is shifted slightly away from the optical axis laterally by 5 1 5 mm 6 The macula in humans has a diameter of around 5 5 mm 0 22 in and is subdivided into the umbo foveola foveal avascular zone fovea parafovea and perifovea areas 2 An even smaller central region of highest receptor density 40 80 mm is sometimes referred to as the foveal bouquet 7 8 9 10 The anatomical macula at 5 5 mm 0 22 in is much larger than the clinical macula which at 1 5 mm 0 059 in corresponds to the anatomical fovea 3 4 5 The clinical macula is seen when viewed from the pupil as in ophthalmoscopy or retinal photography The anatomical macula is defined histologically in terms of having two or more layers of ganglion cells 11 The umbo is the center of the foveola which in turn is located at the center of the fovea The fovea is located near the center of the macula It is a small pit that contains the largest concentration of cone cells The retina s receptor layer contains two types of photosensitive cells the rod cells and the cone cells Color edit Because the macula is yellow in color it absorbs excess blue and ultraviolet light that enter the eye and acts as a natural sunblock analogous to sunglasses for this area of the retina The yellow color comes from its content of lutein and zeaxanthin which are yellow xanthophyll carotenoids derived from the diet Zeaxanthin predominates at the macula while lutein predominates elsewhere in the retina There is some evidence that these carotenoids protect the pigmented region from some types of macular degeneration A formulation of 10 mg lutein and 2 mg zeaxanthin has been shown to reduce the risk of age related macular degeneration progressing to advanced stages although these carotenoids have not been shown to prevent the disease 12 After death or enucleation removal of the eye the macula appears yellow a color that is not visible in the living eye except when viewed with light from which red has been filtered 13 Regions edit Fovea 1 55 mm 0 061 in Foveal avascular zone FAZ 0 5 to 0 6 mm 0 020 to 0 024 in Foveola 0 35 mm 0 014 in Umbo 0 15 mm 0 0059 in Function editStructures in the macula are specialized for high acuity vision Within the macula are the fovea and foveola that both contain a high density of cones which are nerve cells that are photoreceptors with high acuity In detail the normal human eye contains three different types of cones with different ranges of spectral sensitivity The brain combines the signals from neighboring cones to distinguish different colors There is only one type of rod but the rods are more sensitive than the cones so in dim light they are the dominant photoreceptors active and without information provided by the separate spectral sensitivity of the cones it is impossible to discriminate colors In the fovea centralis cones predominate and are present at high density The macula is thus responsible for the central high resolution color vision that is possible in good light and this kind of vision is impaired if the macula is damaged for example in macular degeneration 14 Clinical significance edit nbsp nbsp Fundus photographs of the right eye left image and left eye right image seen from front so that left in each image is to the person s right The gaze is into the camera so in each picture the macula is in the center of the image and the optic disc is located towards the nose The clinical macula is seen when viewed from the pupil as in ophthalmoscopy or retinal photography Whereas loss of peripheral vision may go unnoticed for some time damage to the macula will result in loss of central vision which is usually immediately obvious The progressive destruction of the macula is a disease known as macular degeneration and can sometimes lead to the creation of a macular hole Macular holes are rarely caused by trauma but if a severe blow is delivered it can burst the blood vessels going to the macula destroying it 14 Visual input from the macula occupies a substantial portion of the brain s visual capacity As a result some forms of visual field loss that occur without involving the macula are termed macular sparing For example visual field testing might demonstrate homonymous hemianopsia with macular sparing In the case of occipitoparietal ischemia owing to occlusion of elements of either posterior cerebral artery patients may display cortical blindness which rarely can involve blindness that the patient denies having as seen in Anton s Syndrome yet display sparing of the macula This selective sparing is due to the collateral circulation offered to macular tracts by the middle cerebral artery 15 Neurological examination that confirms macular sparing can go far in representing the type of damage mediated by an infarct in this case indicating that the caudal visual cortex which is the principal recipient of macular projections of the optic nerve has been spared Further it indicates that cortical damage rostral to and including lateral geniculate nucleus is an unlikely outcome of the infarction as too much of the lateral geniculate nucleus is proportionally devoted to macular stream processing 16 Additional images edit nbsp A fundus photograph showing the macula as a spot to the left The optic disc is the area on the right where blood vessels converge The grey more diffuse spot in the centre is a shadow artifact nbsp Time Domain OCT of the macular area of a retina at 800 nm axial resolution 3 µm nbsp Spectral Domain OCT macula cross section scan nbsp macula histology OCT See also editThis article uses anatomical terminology Macular degeneration Macular edema Macular pucker Cherry red spot Macular hypoplasia Photic retinopathy Intermediate uveitisReferences edit MACULA Meaning amp Definition for UK English Lexico com Archived from the original on 3 August 2020 Retrieved 24 August 2022 a b Interpretation of Stereo Ocular Angiography Retinal and Choroidal Anatomy Project Orbis International Archived from the original on 19 December 2014 Retrieved 11 October 2014 a b Yanoff Myron 2009 Ocular Pathology Elsevier Health Sciences p 393 ISBN 978 0 323 04232 1 Retrieved 7 November 2014 a b Small R G 1994 The Clinical Handbook of Ophthalmology CRC Press p 134 ISBN 978 1 85070 584 0 Retrieved 7 November 2014 a b Peyman Gholam A Meffert Stephen A Chou Famin Mandi D Conway 2000 Vitreoretinal Surgical Techniques CRC Press p 6 ISBN 978 1 85317 585 5 Retrieved 7 November 2014 le Grand Yves 1957 Light colour and vision London Chapman amp Hall p 52 Oesterberg G 1935 Topography of the layer of rods and cones in the human retina Acta Ophthalmologica Supplement 6 10 11 96 Polyak S L 1941 The Retina Chicago University of Chicago Press Tyler C W Hamer R D 1990 Analysis of visual modulation sensitivity IV Validity of the Ferry Porter law Journal of the Optical Society of America A 7 4 743 758 Bibcode 1990JOSAA 7 743T doi 10 1364 JOSAA 7 000743 PMID 2338596 Strasburger Hans 2020 Seven myths on crowding and peripheral vision i Perception 11 2 1 45 doi 10 1177 2041669520913052 PMC 7238452 PMID 32489576 Remington Lee Ann 2011 Clinical Anatomy of the Visual System Elsevier Health Sciences pp 314 315 ISBN 978 1 4557 2777 3 Retrieved 7 November 2014 Hobbs RP Bernstein PS 2014 Nutrient Supplementation for Age related Macular Degeneration Cataract and Dry Eye Journal of Ophthalmic and Vision Research 9 4 487 493 doi 10 4103 2008 322X 150829 PMC 4329711 PMID 25709776 Britton George Liaaen Jensen Synnove Pfander Hanspeter 2009 Carotenoids Volume 5 Nutrition and Health Springer Science amp Business Media p 301 ISBN 978 3 7643 7501 0 Retrieved 7 November 2014 a b Macular Degeneration The Lecturio Medical Concept Library 6 October 2020 Retrieved 9 August 2021 Helseth Erek Posterior Cerebral Artery Stroke Medscape Reference Medscape Retrieved 23 October 2011 Siegel Allan Sapru Hreday N 2006 Betty Sun ed Essential Neuroscience First Revised ed Baltimore Maryland Lippincott Williams amp Wilkins ISBN 978 0 7817 9121 2 External links edit nbsp Media related to Macula lutea at Wikimedia Commons MedlinePlus Encyclopedia 002252 Retrieved from https en wikipedia org w index php title Macula amp oldid 1181068200, wikipedia, wiki, book, books, library,

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