Macular degeneration, often age-related macular degeneration (AMD or ARMD), is a medical condition that usually affects older adults and results in a loss of vision in the center of the visual field (the macula) because of damage to the retina. It occurs in "dry" and "wet" forms. It is a major cause of blindness and visual impairment in older adults (>50 years). Macular degeneration can make it difficult or impossible to read or recognize faces, although enough peripheral vision remains to allow other activities of daily life.
Although some macular dystrophies affecting younger individuals are sometimes referred to as macular degeneration, the term generally refers to age-related macular degeneration (AMD or ARMD).
The retina is a network of visual receptors and nerves. It lies on the choroid, a network of blood vessels which supplies the retina with blood.
In the dry (nonexudative) form, cellular debris called drusen accumulates between the retina and the choroid, and the retina can become detached. In the wet (exudative) form, which is more severe, blood vessels grow up from the choroid behind the retina, and the retina can also become detached. It can be treated with laser coagulation, and with medication that stops and sometimes reverses the growth of blood vessels.
Blurred vision: Those with nonexudative macular degeneration may be asymptomatic or notice a gradual loss of central vision, whereas those with exudative macular degeneration often notice a rapid onset of vision loss (often caused by age)
Central scotomas (shadows or missing areas of vision)
Distorted vision in the form of metamorphopsia, in which a grid of straight lines appears wavy and parts of the grid may appear blank: Patients often first notice this when looking at miniblinds in their home
Trouble discerning colors, specifically dark ones from dark ones and light ones from light ones
Slow recovery of visual function after exposure to bright light
Macular degeneration by itself will not lead to total blindness. For that matter, only a very small number of people with visual impairment are totally blind. In almost all cases, some vision remains. Other complicating conditions may possibly lead to such an acute condition (severe stroke or trauma, untreated glaucoma, etc.), but few macular degeneration patients experience total visual loss. The area of the macula comprises only about 2.1% of the retina, and the remaining 97.9% (the peripheral field) remains unaffected by the disease. Interestingly, even though the macula provides such a small fraction of the visual field, almost half of the visual cortex is devoted to processing macular information.
The loss of central vision profoundly affects visual functioning. It is quite difficult, for example, to read without central vision. Pictures that attempt to depict the central visual loss of macular degeneration with a black spot do not really do justice to the devastating nature of the visual loss. This can be demonstrated by printing letters six inches high on a piece of paper and attempting to identify them while looking straight ahead and holding the paper slightly to the side. Most people find this difficult to do.
There is a loss of contrast sensitivity, so that contours, shadows, and color vision are less vivid. The loss in contrast sensitivity can be quickly and easily measured by a contrast sensitivity test performed either at home or by an eye specialist.
Aging: Approximately 10% of patients 66 to 74 years of age will have findings of macular degeneration. The prevalence increases to 30% in patients 75 to 85 years of age.
Family history: The lifetime risk of developing late-stage macular degeneration is 50% for people who have a relative with macular degeneration, versus 12% for people who do not have relatives with macular degeneration. Researchers from the University of Southampton reported they had discovered six mutations of the gene SERPING1 that are associated with AMD. Mutations in this gene can also cause hereditary angioedema.
Macular degeneration gene: The genes for the complement system proteins factor H (CFH), factor B (CFB) and factor 3 (C3) are strongly associated with a person's risk for developing AMD. CFH is involved in inhibiting the inflammatory response mediated via C3b (and the alternative pathway of complement) both by acting as a cofactor for cleavage of C3b to its inactive form, C3bi, and by weakening the active complex that forms between C3b and factor B. C-reactive protein and polyanionic surface markers such as glycosaminoglycans normally enhance the ability of factor H to inhibit complement. But the mutation in CFH (Tyr402His) reduces the affinity of CFH for CRP and probably also alters the ability of factor H to recognise specific glycosaminoglycans. This change results in reduced ability of CFH to regulate complement on critical surfaces such as the specialised membrane at the back of the eye and leads to increased inflammatory response within the macula. In two 2006 studies, another gene that has implications for the disease, called HTRA1 (encoding a secreted serine protease), was identified. The mitochondrial genome (mtDNA) in humans is contained on a single circular chromosome, 16,569 basepairs around, and each mitochondrion contains five to 10 copies of the mitochondrial chromosome. Several essential genes in mtDNA are involved in replication and translation, along with some genes that are crucial for the machinery that converts metabolic energy into ATP. These include NADH dehydrogenase, cytochrome C oxidase, ubiquinol/cytochrome C oxidoreductase, and ATP synthase, as well as the genes for unique ribosomal RNA and transfer RNA particles that are required for translating these genes into proteins. Specific diseases are associated with mutations in some of these genes. Below is one of the affected genes and the disease that arises from its mutation.
Mutation of the ATP synthase gene:Retinitis pigmentosa (RP) is a genetically linked dysfunction of the retina and is related to mutation of the adenosine triphosphate (ATP) synthase gene 615.1617.
Stargardt's disease (juvenile macular degeneration, STGD) is an autosomal recessive retinal disorder characterized by a juvenile-onset macular dystrophy, alterations of the peripheral retina, and subretinal deposition of lipofuscin-like material. A gene encoding an ATP-binding cassette transporter was mapped to the 2-cM (centiMorgan) interval at 1p13-p21 previously shown by linkage analysis to harbor this gene. This gene, ABCR, is expressed exclusively and at high levels in the retina, in rod but not cone photoreceptors, as detected by in situ hybridization. Mutational analysis of ABCR in STGD families revealed a total of 19 different mutations including homozygous mutations in two families with consanguineous parentage. These data indicate that ABCR is the causal gene of STGD/FFM.
Drusen: CMSD studies indicate drusen are similar in molecular composition to plaques and deposits in other age-related diseases such as Alzheimer's disease and atherosclerosis. While there is a tendency for drusen to be blamed for the progressive loss of vision, drusen deposits can be present in the retina without vision loss. Some patients with large deposits of drusen have normal visual acuity. If normal retinal reception and image transmission are sometimes possible in a retina when high concentrations of drusen are present, then, even if drusen can be implicated in the loss of visual function, there must be at least one other factor that accounts for the loss of vision.
Arg80Gly variant of the complement protein C3: Two independent studies published in the New England Journal of Medicine and Nature Genetics in 2007 showed a certain common mutation in the C3 gene, which is a central protein of the complement system, is strongly associated with the occurrence of AMD. The authors of both papers consider their study to underscore the influence of the complement pathway in the pathogenesis of this disease.
Oxidative stress: Age-related accumulation of low-molecular-weight, phototoxic, pro-oxidantmelanin oligomers within lysosomes in the retinal pigment epithelium may be partly responsible for decreasing the digestive rate of photoreceptor outer rod segments (POS) by the RPE. A decrease in the digestive rate of POS has been shown to be associated with lipofuscin formation - a classic sign associated with AMD.
Fibulin-5 mutation: Rare forms of the disease are caused by genetic defects in fibulin-5, in an autosomal dominant manner. In 2004, Stone et al. performed a screen on 402 AMD patients and revealed a statistically significant correlation between mutations in fibulin-5 and incidence of the disease. Furthermore, the point mutants were found in the calcium-binding sites of the cbEGF domains of the protein. There is no structural basis for the effects of the mutations.
Race: Macular degeneration is more likely to be found in Caucasians than in people of African descent.
Exposure to sunlight, especially blue light: Evidence is conflicting as to whether exposure to sunlight contributes to the development of macular degeneration. A recent study on 446 subjects found it does not. Other research, however, has shown high-energy visible light may contribute to AMD.
Vitamin D deficiency: higher vitamin D levels are associated with lower age-related macular degeneration risk in women 
Smoking: Smoking tobacco increases the risk of AMD by two to three times that of someone who has never smoked, and may be the most important modifiable factor in its prevention. A review of previous studies found "the literature review confirmed a strong association between current smoking and AMD. ... Cigarette smoking is likely to have toxic effects on the retina."
Deletion of CFHR3 and CFHR1: Deletion of the complement factor H-related genes CFHR3 and CFHR1 protects against AMD.
A practical application of AMD-associated markers is in the prediction of progression of AMD from early stages of the disease to neovascularization.
Early work demonstrated a family of immune mediators was plentiful in drusen. Complement factor H (CFH) is an important inhibitor of this inflammatory cascade, and a disease-associated polymorphism in the CFH gene strongly associates with AMD. Thus an AMD pathophysiological model of chronic low grade complement activation and inflammation in the macula has been advanced. Lending credibility to this has been the discovery of disease-associated genetic polymorphisms in other elements of the complement cascade including complement component 3 (C3).
A powerful predictor of AMD is found on chromosome 10q26 at LOC 387715. An insertion/deletion polymorphism at this site reduces expression of the ARMS2 gene though destabilization of its mRNA through deletion of the polyadenylation signal.ARMS2 protein may localize to the mitochondria and participate in energy metabolism, though much remains to be discovered about its function.
Other gene markers of progression risk includes tissue inhibitor of metalloproteinase 3 (TIMP3), suggesting a role for intracellular matrix metabolism in AMD progression. Variations in cholesterol metabolising genes such as the hepatic lipase, cholesterol ester transferase, lipoprotein lipase and the ABC-binding cassette A1 correlate with disease progression. The early stigmata of disease, drusen, are rich in cholesterol, offering face validity to the results of genome-wide association studies.
Starting from the inside of the eye and going towards the outer surface, the three main layers at the back of the eye are the retina, which is light-sensitive tissue that is considered part of the central nervous system and is actually brain tissue; the choroid, which contains the blood supply; and the sclera, which is the white, outer, layer of the eye.
Age-related macular degeneration begins with characteristic yellow deposits (drusen) in the macula, between the retinal pigment epithelium and the underlying choroid. Most people with these early changes (referred to as age-related maculopathy) have good vision. People with drusen can go on to develop advanced AMD. The risk is higher when the drusen are large and numerous and associated with disturbance in the pigmented cell layer under the macula. Large and soft drusen are related to elevated cholesterol deposits and may respond to cholesterol-lowering agents.
Central geographic atrophy, the "dry" form of advanced AMD, results from atrophy of the retinal pigment epithelial layer below the retina, which causes vision loss through loss of photoreceptors (rods and cones) in the central part of the eye. No medical or surgical treatment is available for this condition; however, vitamin supplements with high doses of antioxidants, lutein and zeaxanthin, have been suggested by the National Eye Institute and others to slow progression of the disease in people who have intermediate AMD, and those who have late AMD in one eye. AREDS formulation is not a cure. It does not help people with early AMD, and will not restore vision already lost from AMD. But it may delay the onset of late AMD. It also may help slow vision loss in people who already have late AMD. Higher beta-carotene intake was associated with an increased risk of AMD.
Neovascular or exudative AMD, the "wet" form of advanced AMD, causes vision loss due to abnormal blood vessel growth (choroidal neovascularization) in the choriocapillaris, through Bruch's membrane, ultimately leading to blood and protein leakage below the macula. Bleeding, leaking, and scarring from these blood vessels eventually cause irreversible damage to the photoreceptors and rapid vision loss if left untreated.
Only about 10% of patients suffering from macular degeneration have the wet type.
Macular degeneration is not painful, which may allow it to go unnoticed for some time.
Super resolution microscopic investigation of human eye tissue affected by AMD
In dry macular degeneration which occur in 85-90 percent of AMD cases, drusen spots can be seen in Fundus photography
In wet macular degeneration, using Angiography we can see leakage of bloodstream behind the macula
Use Electroretinogram, we can know the points in macula which response weak or absent compared to a normal eye
The visual acuity and color sensitivity should be similar for red, green and blue (RGB)
Fluorescein angiography allows for the identification and localization of abnormal vascular processes. Optical coherence tomography is now used by most ophthalmologists in the diagnosis and the follow-up evaluation of the response to treatment by using either bevacizumab (Avastin) or ranibizumab (Lucentis), which are injected into the vitreous humor of the eye at various intervals.
Recently, structured illumination light microscopy, using a specially designed super resolution microscope setup has been used to resolve the fluorescent distribution of small autofluorescent structures (lipofuscin granulae) in retinal pigment epithelium tissue sections.
The proliferation of abnormal blood vessels in the retina is stimulated by vascular endothelial growth factor (VEGF). Antiangiogenics or anti-VEGF agents can cause regression of the abnormal blood vessels and improve vision when injected directly into the vitreous humor of the eye. The injections must be repeated monthly or bimonthly. Several antiangiogenic drugs have been approved for use in the eye by the U.S. Food and Drug Administration and regulatory agencies in other countries.
The first angiogenesis inhibitor, a monoclonal antibody against VEGF-A, was bevacizumab, which is approved for use in cancer. Ranibizumab is a smaller fragment, Fab fragment, of the parent bevacizumab molecule specifically designed for eye injections. The cost of ranibizumab is approximately GB£742 per treatment in the United Kingdom. Bevacizumab is packaged and used for cancer in larger doses than the doses used in the eye. It can be administered in smaller doses in the eye, off label, at a cost of less than one-tenth that of ranibizumab per treatment. A recent randomised control trial found that bevacizumab and ranibizumab had similar efficacy, and reported no significant increase in adverse events with bevacizumab 
In the UK, NICE issued guidelines for the treatment of wet AMD in the NHS. NICE only approved use of ranibizumab for wet AMD in the NHS in England. NHS hospitals and Primary Care Trusts in England are required to follow NICE guidance.
Other approved antiangiogenic drugs for the treatment of neo-vascular AMD include pegaptanib (Macugen) and aflibercept (Eylea).
Photodynamic therapy has also been used to treat wet AMD. The drug verteporfin is administered intravenously; light of the correct wavelength is then applied to the abnormal blood vessels. This activates the verteporfin and obliterates the vessels.
A Cochrane Database Review of publications to 2012 found the use of vitamin and mineral supplements, alone or in combination, by the general population had no effect on AMD, a finding echoed by another review. A 2006 Cochrane Review of the effects of vitamins and minerals on the slowing of AMD found the positive results mainly came from a single large trial in the United States (the Age-Related Eye Disease Study), with funding from the eye care product company Bausch & Lomb, which also manufactured the supplements used in the study, and questioned the generalization of the data to any other populations with different nutritional status. The review also questioned the possible harm of such supplements, given the increased risk of lung cancer in smokers with high intakes of beta-carotene, and the increased risk of heart failure in at-risk populations who consume high levels of vitamin E supplements. A Cochrane database review published in March 2012 did not find sufficient evidence to determine the effectiveness and safety of statins for the prevention or delaying the progression of AMD.
Cell based therapies using bone marrow stem cells as well as Retinal pigment epithelial transplantation have been reported as experimental options in several patients.
Saffron (Crocus sativus) is a spice containing the antioxidant carotenoids crocin and crocetin. Saffron has been known for its antioxidant, anti-inflammatory, and cell protective effects. The most important result for eye health benefits of saffron came from a recent double blind, placebo-controlled, cross-over clinical study. Results indicated that taking oral supplementation of saffron at 20 mg/day for three months induced a short-term and significant improvement of retinal function in early AMD. In this study cone-mediated ERG in response to high-frequency flicker (focal ERG, FERG) was employed as the main outcome variable. The effects, however, disappeared when patients stopped taking the saffron pills. No adverse side effects were reported in this study. According to Professor Silvia Bisti from the University of Sydney, who carried out the research, 'Patients' vision improved after taking the saffron pill’ (Falsini et al. 2010).
In a 15-month follow up clinical study, the same researchers observed that patients continued to get the benefits of the supplement for as long as they took the saffron capsules. This study confirmed initial findings that saffron may hold the key for tackling vision loss in AMD.
According to this recent study taking long term saffron supplement led to: "improvement in contrast and colour perception, reading ability, and vision at low luminances, all ultimately leading to a substantial improvement in the patients’ quality of life.". This new study showed that taking saffron supplementation for long term presents a safe natural solution to help prevent eyesight loss in old age, and as reported “no adverse systemic side effects were recorded” (Piccardi et al. 2012). Health Canada in 2012 approved Saffron 2020 for macular degeneration and cataracts. Saffron 2020 is made based on current clinical data on effect of saffron, resveratrol, lutein, zeaxanthin and vitmins in macular degeneration.
Josef Tal, an Israeli composer who was affected by macular degeneration, checks a manuscript using a CCTV desktop unit.
Because peripheral vision is not affected, people with macular degeneration can learn to use their remaining vision to partially compensate. Assistance and resources are available in many countries and every state in the U.S. Classes for "independent living" are given and some technology can be obtained from a state department of rehabilitation.
Adaptive devices can help people read. These include magnifying glasses, special eyeglass lenses, computer screen readers, and TV systems that enlarge reading material.
^Yang Z, Camp NJ, Sun H, Tong Z, Gibbs D, Cameron DJ, Chen H, Zhao Y, Pearson E et al. (Nov 2006). "A variant of the HTRA1 gene increases susceptibility to age-related macular degeneration". Science314 (5801): 992–3. doi:10.1126/science.1133811. PMID17053109.
^Hughes, Anne E; Orr, Nick; Esfandiary, Hossein; Diaz-Torres, Martha; Goodship, Timothy; Chakravarthy, Usha (2006). "A common CFH haplotype, with deletion of CFHR1 and CFHR3, is associated with lower risk of age-related macular degeneration". Nature Genetics38 (10): 1173–1177. doi:10.1038/ng1890. PMID16998489.
^Fritsche, L. G.; Lauer, N.; Hartmann, A.; Stippa, S. et al. (2010). "An imbalance of human complement regulatory proteins CFHR1, CFHR3 and factor H influences risk for age-related macular degeneration (AMD)". Human Molecular Genetics19 (23): 4694–4704. doi:10.1093/hmg/ddq399. PMID20843825.
^Mullins RF, Russell SR, Anderson DH, Hageman GS (2000). "Drusen associated with aging and age-related macular degeneration contain proteins common to extracellular deposits associated with atherosclerosis, elastosis, amyloidosis, and dense deposit disease". FASEB J14 (7): 835–46. PMID10783137.
^Haines JL, Hauser MA, Schmidt S, Scott WK, Olson LM, Gallins P (2005). "Complement factor H variant increases the risk of age-related macular degeneration". Science308 (5720): 419–21. doi:10.1126/science.1110359. PMID15761120.
^Rohrer B, Long Q, Coughlin B, Renner B, Huang Y, Kunchithapautham K (2010). "A targeted inhibitor of the complement alternative pathway reduces RPE injury and angiogenesis in models of age-related macular degeneration". Adv Exp Med Biol. Advances in Experimental Medicine and Biology 703: 137–49. doi:10.1007/978-1-4419-5635-4_10. ISBN978-1-4419-5634-7. PMID20711712.
^Yates JR, Sepp T, Matharu BK, Khan JC, Thurlby DA, Shahid H (2007). "Complement C3 variant and the risk of age-related macular degeneration". NEJM357 (6): 553–61. doi:10.1056/NEJMoa072618. PMID17634448.
^^ Thornton J, Edwards R, Mitchell P, Harrison RA, Buchan I, Kelly SP (2005). "Smoking and age-related macular degeneration: a review of association". Eye19 (9): 935–44. doi:10.1038/sj.eye.6701978. PMID16151432.
^Tomany SC, Cruickshanks KJ, Klein R, Klein BE, Knudtson MD (2004). "Sunlight and the 10-year incidence of age-related maculopathy: the Beaver Dam Eye Study". Arch Ophthalmol122 (5): 750–7. doi:10.1001/archopht.122.5.750. PMID15136324.
^Szaflik JP, Janik-Papis K, Synowiec E, Ksiazek D, Zaras M, Wozniak K (2009). "DNA damage and repair in age-related macular degeneration". Mutat Res669 (1–2): 167–176.
^Udar N, Atilano SR, Memarzadeh M, Boyer D, Chwa M, Lu S (2009). "Mitochondrial DNA Haplogroups Associated with Age-Related Macular Degeneration". Invest Ophthalmol Vis Sci50 (6): 2966–74. doi:10.1167/iovs.08-2646. PMID19151382.
^Fritsche LG, Loenhardt T, Janssen A, Fisher SA, Rivera A, Keilhauer CN (2008). "Age-related macular degeneration is associated with an unstable ARMS2 (LOC387715) mRNA DNA damage and repair in age-related macular degeneration". NatGenet40 (7): 892–896. doi:10.1038/ng.170.
^Kenealy SJ, Schmidt S, Agarwal A, Postel EA, De La Paz MA, Pericak-Vance MA (2004). "Linkage analysis for age-related macular degeneration supports a gene on chromosome 10q26". Mol Vis26 (10): 57–61.
^ abTan JS, Wang JJ, Flood V, Rochtchina E, Smith W, Mitchell P. (February 2008). "Dietary antioxidants and the long-term incidence of age-related macular degeneration: the Blue Mountain Eye Study". Ophthalmology.115 (2): 334–41. doi:10.1016/j.ophtha.2007.03.083. PMID17664009.
^Best G, Amberger R, Baddeley D, Ach T, Dithmar S, Heintzmann R and Cremer C (2011). Structured illumination microscopy of autofluorescent aggregations in human tissue. Micron, 42, 330-335 doi:10.1016/j.micron.2010.06.016
^Evans JR, Lawrenson JG (2012). "Antioxidant vitamin and mineral supplements for preventing age-related macular degeneration". In Evans, Jennifer R. Cochrane Database Syst Rev6: CD000253. doi:10.1002/14651858.CD000253.pub3. PMID22696317.
^Evans J (June 2008). "Antioxidant supplements to prevent or slow down the progression of AMD: a systematic review and meta-analysis". Eye22 (6): 751–60. doi:10.1038/eye.2008.100. PMID18425071.
^Evans JR; Evans, Jennifer R (2006). "Antioxidant vitamin and mineral supplements for slowing the progression of age-related macular degeneration". In Evans, Jennifer R. Cochrane Database Syst Rev (2): CD000254. doi:10.1002/14651858.CD000254.pub2. PMID16625532.
^Bisti S, Falsini B (2010). "Influence of saffron supplementation on retinal flicker sensitivity in early age-related macular degeneration.". In Bisti, Falsini B. Invest Ophthalmol Vis Sci. 251 (12): 6118–24. doi:10.1167/iovs.09-4995. PMID20688744.
^Falsini B, Piccardi M (2012). "A longitudinal follow-up study of saffron supplementation in early age-related macular degeneration: sustained benefits to central retinal function.". In Falsini, Piccardi M. Evid Based Complement Alternat Med.2012: 429124. doi:10.1155/2012/429124. PMID22852021.
^Pacella, E; Pacella, F; Mazzeo, F; Turchetti, P et al. (November 2012). "Effectiveness of vision rehabilitation treatment through MP-1 microperimeter in patients with visual loss due to macular disease". Clin Ter163 (6): 163(6):e423–8. PMID23306757.