Myopia
Normal vision.
The same image edited to simulate myopia.
Compensating for myopia using a corrective lens.
Myopia (from Greek: μυωπία myopia "near-sightedness"[1]), also called near- or short-sightedness, is a refractive defect of the eye in which collimated light produces image focus in front of the retina when accommodation is relaxed.
Those with myopia see nearby objects clearly but distant objects appear blurred. With myopia, the eyeball is too long, or the cornea is too steep, so images are focused in the vitreous inside the eye rather than on the retina at the back of the eye. The opposite defect of myopia is hyperopia or "farsightedness" or "long-sightedness" — this is where the cornea is too flat or the eye is too short.
Mainstream ophthalmologists and optometrists most commonly correct myopia through the use of corrective lenses, such as glasses or contact lenses. It may also be corrected by refractive surgery, such as LASIK. The corrective lenses have a negative optical power (i.e. are concave) which compensates for the excessive positive diopters of the myopic eye. In some cases, pinhole glasses are used by patients with low-level myopia. These work by reducing the blur circle formed on the retina.
Classification
Myopia has been classified in various manners.[2][3][4]
Etiology
Borish and Duke-Elder classified myopia by cause:[3][4]
- Axial myopia is attributed to an increase in the eye's axial length.[5]
- Refractive myopia is attributed to the condition of the refractive elements of the eye.[5] Borish further subclassified refractive myopia:[3]
-
- Curvature myopia is attributed to excessive, or increased, curvature of one or more of the refractive surfaces of the eye, especially the cornea.[5] In those with Cohen syndrome, myopia appears to result from high corneal and lenticular power.[6]
- Index myopia is attributed to variation in the index of refraction of one or more of the ocular media.[5]
Clinical entity
Various forms of myopia have been described by their clinical appearance:[4][7]
- Simple myopia is more common than other types of myopia and is characterized by an eye that is too long for its optical power (which is determined by the cornea and crystalline lens) or optically too powerful for its axial length.[8] Both genetic and environmental factors, particularly significant amounts of near work, are thought to contribute to the development of simple myopia.[8]
- Degenerative myopia, also known as malignant, pathological, or progressive myopia, is characterized by marked fundus changes, such as posterior staphyloma, and associated with a high refractive error and subnormal visual acuity after correction.[5] This form of myopia gets progressively worse over time. Degenerative myopia has been reported as one of the main causes of visual impairment.[9]
- Nocturnal myopia, also known as night myopia or twilight myopia, is a condition in which the eye has a greater difficulty seeing in low illumination areas, even though its daytime vision is normal. Essentially, the eye's far point of an individual's focus varies with the level of light. Night myopia is believed to be caused by pupils dilating to let more light in, which adds aberrations resulting in becoming more nearsighted. A stronger prescription for myopic night drivers is often needed. Younger people are more likely to be affected by night myopia than the elderly.[10][11]
- Pseudomyopia is the blurring of distance vision brought about by spasm of the ciliary muscle.[12]
- Induced myopia, also known as acquired myopia, results from exposure to various pharmaceuticals, increases in glucose levels, nuclear sclerosis, or other anomalous conditions.[8] The encircling bands used in the repair of retinal detachments may induce myopia by increasing the axial length of the eye.[13]
-
- Index myopia is attributed to variation in the index of refraction of one or more of the ocular media.[5] Cataracts may lead to index myopia.[14]
- Form deprivation myopia is a type of myopia that occurs when the eyesight is deprived by limited illumination and vision range,[15] or the eye is modified with artificial lenses[16] or deprived of clear form vision.[17][18] In lower vertebrates this kind of myopia seems to be reversible within short periods of time.[18] Myopia is often induced this way in various animal models to study the pathogenesis and mechanism of myopia development.[18]
- Nearwork Induced Transient Myopia (NITM), is defined as short-term myopic far point shift immediately following a sustained near visual task.[19] Some authors argue for a link between NITM and the development of permanent myopia.[20]
Degree
Myopia, which is measured in diopters by the strength or optical power of a corrective lens that focuses distant images on the retina, has also been classified by degree or severity:[2]
- Low myopia usually describes myopia of −3.00 diopters or less.[5]
- Medium myopia usually describes myopia between −3.00 and −6.00 diopters.[5] Those with moderate amounts of myopia are more likely to have pigment dispersion syndrome or pigmentary glaucoma.[21]
- High myopia usually describes myopia of −6.00 or more.[5] People with high myopia are more likely to have retinal detachments[22] and primary open angle glaucoma.[23] They are also more likely to experience floaters, shadow-like shapes which appear singly or in clusters in the field of vision.[24] Roughly 30% of myopes have high myopia.[25]
Age of onset
Myopia is sometimes classified by the age of onset:[2]
- Congenital myopia, also known as infantile myopia, is present at birth and persists through infancy.[8]
- Youth onset myopia occurs prior to age 20.[8]
-
- School myopia appears during childhood, particularly the school-age years.[26] This form of myopia is attributed to the use of the eyes for close work during the school years.[5]
-
- Early adult onset myopia occurs between ages 20 and 40.[8]
- Late adult onset myopia occurs after age 40.[8]
Epidemiology
The global prevalence of refractive errors has been estimated from 800 million to 2.3 billion.[27] The incidence of myopia within sampled population often varies with age, country, sex, race, ethnicity, occupation, environment, and other factors.[25][28] Variability in testing and data collection methods makes comparisons of prevalence and progression difficult.[29]
In some areas, such as China, India and Malaysia, up to 41% of the adult population is myopic to -1dpt,[30] up to 80% to -0.5dpt.[31]
A recent study involving first-year undergraduate students in the United Kingdom found that 50% of British whites and 53.4% of British Asians were myopic.[32]
In Australia, the overall prevalence of myopia (worse than −0.50 diopters) has been estimated to be 77%.[33] In one recent study, less than 1 in 10 (8.4%) Australian children between the ages of 4 and 12 were found to have myopia greater than −0.50 diopters.[34] A recent review found that 16.4% of Australians aged 40 or over have at least −1.00 diopters of myopia and 2.5% have at least −5.00 diopters.[35]
In Brazil, a 2005 study estimated that 6.4% of Brazilians between the ages of 12 and 59 had −1.00 diopter of myopia or more, compared with 2.7% of the indigenous people in northwestern Brazil.[36] Another found nearly 1 in 8 (13.3%) of the students in one city were myopic.[37]
In Greece, the prevalence of myopia among 15 to 18 year old students was found to be 36.8%.[38]
In India, the prevalence of myopia in the general population has been reported to be only 6.9%.[39][38]
A recent review found that 26.6% of Western Europeans aged 40 or over have at least −1.00 diopters of myopia and 4.6% have at least −5.00 diopters.[35]
In the United States, the prevalence of myopia has been estimated at 20%.[25] Nearly 1 in 10 (9.2%) American children between the ages of 5 and 17 have myopia.[40] Approximately 25% of Americans between the ages of 12 and 54 have the condition.[41] A recent review found that 25.4% of Americans aged 40 or over have at least −1.00 diopters of myopia and 4.5% have at least −5.00 diopters.[35]
A study of Jordanian adults aged 17 to 40 found that over half (53.7%) were myopic.[42]
Ethnicity and race
The prevalence of myopia has been reported as high as 70-90% in some Asian countries. 30-40% in Europe and the United States, and 10-20% in Africa.[28]
Myopia is less common in black and African people.[25] In Americans between the ages of 12 and 54, myopia has been found to affect blacks less than whites.[41] Asians had the highest prevalence (78.5%), followed by Hispanics (13.2%). Whites had the lowest prevalence of myopia (4.4%), which was not significantly different from blacks (6.6%). For hyperopia, whites had the highest prevalence (19.3%), followed by Hispanics (12.7%). Asians had the lowest prevalence of hyperopia (6.3%) and were not significantly different from blacks (6.4%). For astigmatism, Asians and Hispanics had the highest prevalences (33.6% and 36.9%, respectively) and did not differ from each other (P = .17). Blacks had the lowest prevalence of astigmatism (20.0%), followed by whites (26.4%).[43]
Education, intelligence, and IQ
A number of studies have shown that the prevalence of myopia increases with level of education[41][38] and many studies have shown a relationship between myopia and IQ.
According to Arthur Jensen, myopes average 7-8 IQ points higher than non-myopes. The relationship also holds within families, and siblings with a higher degree of refraction error average higher IQs than siblings with less refraction error. Jensen believes that this indicates myopia and IQ are pleiotropically related as they are caused or influenced by the same genes. No specific mechanism that could cause a relationship between myopia and IQ has yet been identified. Another possible explanation is that high levels of reading is a common cause for both intelligence and myopia, as it supposed that large amounts of close work is a causal factor of myopia.[8]
Also other personal characteristics, as value systems, school achievements, time spent in reading for pleasure, language abilities and time spent in sport activities correlated to the occurrence of myopia in studies.[44][45]
Etiology and pathogenesis
Because in the most common, "simple" myopia, the eye length is too long, any etiologic explanation must account for such axial elongation. To date, no single theory has been able to satisfactorily explain this elongation.
In the early 1900s, controversial ophthalmologist William Bates asserted that myopia, as with all refractive errors, resulted from a particular type of "eyestrain" that was itself a result of "mental strain".[46] He stated that the shape of the eyeball responded instantaneously to the action of the extraocular muscles upon it[47] and that myopia was produced due to contraction of the inferior oblique and superior oblique muscles which lengthened the eye.[48] According to Bates, myopia was associated not with near work but with a "strain" to see distant objects; he believed that corrective lenses aggravated this strain and made myopia become progressively worse over time.[49] Encouraging his patients to discard their glasses, he advocated various techniques, now collectively known as the Bates Method, that he believed would enhance visual acuity by relaxing the eye. Although his theories were rejected by mainstream ophthalmologists of his time, and remain so in the profession today,[50][51] many people claim to have reduced or eliminated their myopia by using his methods. However, no scientific studies have demonstrated its efficacy and the evidence supporting it remains largely anecdotal.
In the mid-1900s, mainstream ophthalmologists and optometrists believed myopia to be primarily hereditary; the influence of near work in its development seemed "incidental" and the increased prevalence of the condition with increasing age was viewed as a "statistical curiosity".[3][4][52]
Among mainstream researchers and eye care professionals, myopia is now thought to be a combination of genetic and environmental factors.[8][26]
There are currently two basic mechanisms believed to cause myopia: form deprivation (also known as pattern deprivation[53]) and optical defocus.[54] Form deprivation occurs when the image quality on the retina is reduced; optical defocus occurs when light focuses in front of or behind the retina. Numerous experiments with animals have shown that myopia can be artificially generated by inducing either of these conditions. In animal models wearing negative spectacle lenses, axial myopia has been shown to occur as the eye elongates to compensate for optical defocus.[54] The exact mechanism of this image-controlled elongation of the eye is still unknown. It has been suggested that accommodative lag leads to blur (i.e. optical defocus) which in turn stimulates axial elongation and myopia.[55]
Theories
- Combination of genetic and environmental factors — In China, myopia is more common in those with higher education background[56] and some studies suggest that near work may exacerbate a genetic predisposition to develop myopia.[57] Other studies have shown that near work (reading, computer games) may not be associated with myopic progression, however.[58] A "genetic susceptibility" to environmental factors has been postulated as one explanation for the varying degrees of myopia among individuals or populations,[59] but there exists some difference of opinion as to whether it exists.[26][60] High heritability simply means that most of the variation in a particular population at a particular time is due to genetic differences. If the environment changes — as, for example, it has by the introduction of televisions and computers — the incidence of myopia can change as a result, even though heritability remains high. From a slightly different point of view it could be concluded that — determined by heritage — some people are at a higher risk to develop myopia when exposed to modern environmental conditions with a lot of extensive near work like reading. In other words, it is often not the myopia itself which is inherited, but the reaction to specific environmental conditions — and this reaction can be the onset and the progression of myopia.
- Genetic factors — The wide variability of the prevalence of myopia in different ethnic groups has been reported as additional evidence supporting the role of genetics in the development of myopia.[61] Measures of the heritability of myopia have yielded figures as high as 89%, and recent research has identified genes that may be responsible: defective versions of the PAX6 gene seem to be associated with myopia in twin studies.[62] Under this theory, the eye is slightly elongated front to back as a result of faults during development, causing images to be focused in front of the retina rather than directly on it. It is usually discovered during the pre-teen years between eight and twelve years of age. It most often worsens gradually as the eye grows during adolescence and then levels off as a person reaches adulthood. Genetic factors can work in various biochemical ways to cause myopia, a weak or degraded connective tissue is a very essential one. Genetic factors include an inherited, increased susceptibility for environmental influences like excessive near work, and the fact that some people do not develop myopia in spite of very adverse conditions is a clear indication that heredity is involved somehow in any case.
- Environmental factors — It has been suggested that a genetic susceptibility to myopia does not exist.[26] A high heritability of myopia (as for any other condition) does not mean that environmental factors and lifestyle have no effect on the development of the condition. Some recommend a variety of eye exercises to strengthen the ciliary muscle. Other theories suggest that the eyes become strained by the constant extra work involved in "nearwork" and get stuck in the near position, and eye exercises can help loosen the muscles up thereby freeing it for far vision. These primarily mechanical models appear to be in contrast to research results, which show that the myopic elongation of the eye can be caused by the image quality, with biochemical processes as the actuator. Common to both views is, however, that extensive near work and corresponding accommodation can be essential for the onset and the progression of myopia.
- One Austrian study confirmed that the axial length of the eye does mildly increase while reading, but attributed this elongation due to contraction of the ciliary muscle during accommodation (the process by which the eye increases optical power to maintain a clear image focus), not "squeezing" of the extraocular muscles.[63]
- Near work and nightlight exposure in childhood have been hypothesized as environmental risk factors for myopia.[64] Although one initial study indicated a strong association between myopia and nightlight exposure,[65] recent research has found none.[64][66][67][68]
- Near work. Near work has been implicated as a contributing factor to myopia in some studies, but refuted in others.[58] One recent study suggested that students exposed to extensive "near work" may be at a higher risk of developing myopia, whereas extended breaks from near work during summer or winter vacations may retard myopic progression.[69] Near work in certain cultures (e.g. Vanuatu) does not result in greater myopia[70][71].[72][73] It has been hypothesized that this outcome may be a results of genetics or environmental factors such as diet or over-illumination, changes in which seem to occur in Asian, Vanuatu and Inuit cultures acclamating to intensive early studies.[74]
- Diet and nutrition - One 2002 article suggested that myopia may be caused by over-consumption of bread in childhood, or in general by diets too rich in carbohydrates, which can lead to chronic hyperinsulinemia. Various other components of the diet, however, were made responsible for contributing to myopia as well, as summarized in a documentation.
- Stress has been postulated as a factor in the development of myopia.[75]
Nature did not supplied humans with the gift to adaptation to the visual stress: according to its concept, humans should not have a long time look intently at particular point. During the visual stress in humans, there appears the "accommodation spasm" of the circular ciliary muscle, which controls the work of crystalline - it changes the curvature of the front surface of crystalline lens. (Accommodation is the ability of the eye to change the shape of its crystalline lens for focusing at different distances to see the object clearly) With the termination of visual stress, this spasm is removed, but not completely, and that becomes the reason for the appearance of myopia , subsequently progressive. Together with accommodation spasm of ciliary muscle, in the case of myopia, it is postulated that blood circulation of retinal tissues is disturbed because of which the retinal tissue becomes less sensitive to light. As a result of both factors, there appears myopia, subsequently progressive.
Relevant research
- A Turkish study found that accommodative convergence, rather than accommodation, may be a factor in the onset and progression of myopia in adults.[76]
- A recent Polish study revealed that "with-the-rule astigmatism" may lead to the creation of myopia.[77]
Presbyopia and the 'payoff' for the nearsighted
Many people with myopia are able to read comfortably without eyeglasses even in advanced age. Myopes considering refractive surgery are advised that this may be a disadvantage after the age of 40 when the eyes become presbyopic and lose their ability to accommodate or change focus.
Diagnosis
A diagnosis of myopia is typically confirmed during an eye examination by an ophthalmologist or an optometrist. Frequently an autorefractor or retinoscope is used to give an initial objective assessment of the refractive status of each eye, then a phoropter is used to subjectively refine the patient's eyeglass prescription.
Treatment, management, and prevention
Glasses are commonly used to address short-sightedness.
Eyeglasses, contact lenses, and refractive surgery are the primary options to treat the visual symptoms of those with myopia. Orthokeratology is the practice of using special rigid contact lenses to flatten the cornea to reduce myopia.
Eye-exercises and biofeedback
Practitioners and advocates of alternative therapies often recommend eye exercises and relaxation techniques such as the Bates method. However, the efficacy of these practices is disputed by scientists and eye care practitioners.[50] A 2005 review of scientific papers on the subject concluded that there was "no clear scientific evidence" that eye exercises were effective in treating myopia.[51]
In the 1980s and 1990s, there was a flurry of interest in biofeedback as a possible treatment for myopia. A 1997 review of this biofeedback research concluded that "controlled studies to validate such methods ... have been rare and contradictory."[78] It was found in one study that myopes could improve their visual acuity with biofeedback training, but that this improvement was "instrument-specific" and did not generalise to other measures or situations.[79] In another study an "improvement" in visual acuity was found but the authors concluded that this could be a result of subjects learning the task.[80] Finally, in an evaluation of a training system designed to improve acuity, "no significant difference was found between the control and experimental subjects".[81]
Prevention
There is no universally accepted method of preventing myopia.[8] Some clinicians and researchers recommend plus power (convex) lenses in the form of single vision reading lenses or bifocals.[8][82] A recent Malaysian study reported in New Scientist[83] suggested that undercorrection of myopia caused more rapid progression of myopia.[84] However, the reliability of this data has been called into question.[85] Many myopia treatment studies suffer from any of a number of design drawbacks: small numbers, lack of adequate control group, failure to mask examiners from knowledge of treatments used, etc.
Pirenzepine eyedrops had a limited effect on retarding myopic progression in a recent, placebo-control, double-blinded prospective controlled study.[86]
Myopia control
Various methods have been employed in an attempt to decrease the progression of myopia.[54] Altering the use of eyeglasses between full-time, part-time, and not at all does not appear to alter myopia progression.[87][88] Bifocal and progressive lenses have not shown significant differences in altering the progression of myopia.[54] In recent years, low radiation laser therapy has proved its usefulness in treatment and prevention of progressive short-sightedness and also a number of other ophthalmological diseases. Laser instruments for the treatment and prevention of eye diseases are developed by Moscow firm "MACDEL" in collaboration with N.E. Bauman Moscow State Technical University (MSTU), Helmholtz Scientific Research Institute of eye diseases, Moscow and several other medical and engineering research centers in Russia. With the aid of the instruments proposed by firm "MACDEL", the progressive myopia is treated noncontact, painlessly, also, without the active participation of patient. One of these instruments - "MACDEL 00.00.09" directs laser beams to the ciliary muscles of eyes, removing thus the accommodation spasm, because of which appears the myopia. The weak laser emission of another instrument - "MACDEL 00.00.08" acts directly on retina, improves nutrition (blood circulation) of retinal tissue and relaxes optic nerve. Both procedures occupy a total of several minutes, and the necessary treatment cycle consists of 10 such procedures. It is necessary to repeat the treatment cycle once in several months period, then this need is gradually eliminated. This therapy is effective not only in the myopia, but also with the squint, the astigmatism and several other eye diseases.
Myopia as metaphor
The terms myopia and myopic (or the common terms short sightedness or short sighted) have also been used metaphorically to refer to cognitive thinking and decision making that is narrow sighted or lacking in concern for wider interests or longer-term consequences.
See also
References
- ↑ Online Etymology Dictionary
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- ↑ 3.0 3.1 3.2 3.3 Borish, Irvin M. (1949). Clinical Refraction. Chicago: The Professional Press.
- ↑ 4.0 4.1 4.2 4.3 Duke-Elder, Sir Stewart (1969). The Practice of Refraction (8th ed.). St. Louis: The C.V. Mosby Company. ISBN 0-7000-1410-1.
- ↑ 5.0 5.1 5.2 5.3 5.4 5.5 5.6 5.7 5.8 5.9 Cline, D; Hofstetter HW; Griffin JR (1997). Dictionary of Visual Science (4th ed ed.). Boston: Butterworth-Heinemann. ISBN 0-7506-9895-0.
- ↑ Summanen, P; Kivitie-Kallio, S; Norio, R; Raitta, C; Kivelä, T (2002). "Mechanisms of myopia in Cohen syndrome mapped to chromosome 8q22". Invest. Ophthalmol. Vis. Sci. 43 (5): 1686–1693. PMID 11980891.
- ↑ Goss, DA; Eskridge JB (1988). "Myopia". in Amos, JB (ed). Diagnosis and management in vision care. Boston: Butterworths. pp. 445. ISBN 0409950823. OCLC 14967262.
- ↑ 8.00 8.01 8.02 8.03 8.04 8.05 8.06 8.07 8.08 8.09 8.10 American Optometric Association. Optometric Clinical Practice Guideline: Care of the patient with myopia. 1997.
- ↑ Li CY, Lin KK, Lin YC, Lee JS. "Low vision and methods of rehabilitation: a comparison between the past and present." Chang Gung Med J. 2002 Mar;25(3):153-61. PMID 12022735.
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- ↑ Chen JC, Schmid KL, Brown B. The autonomic control of accommodation and implications for human myopia development: a review. Ophthalmic Physiol Opt. 2003 Sep;23(5):401-22
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- ↑ Vukojević, N; Sikić J, Curković T, Juratovac Z, Katusic D, Saric B, Jukic T (2005). "Axial eye length after retinal detachment surgery". Collegium antropologicum 29 (Suppl 1): 25–27. PMID 16193671.
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- ↑ Wallmann, J; MD Gottlieb, V Rajaram, LA Fugate-Wentzek (1987). "Local retinal regions control local eye growth and myopia" (in English). Science 237 (4810): 73-77. http://links.jstor.org/sici?sici=0036-8075%2819870703%293%3A237%3A4810%3C73%3ALRRCLE%3E2.0.CO%3B2-2.
- ↑ 18.0 18.1 18.2 Shen, W; Vijayan M, Sivak JG (2005). "Inducing form-deprivation myopia in fish". Invest. Ophthalmol. Vis. Sci. 46 (5): 1797–1803. doi:10.1167/iovs.04-1318. PMID 15851585. http://www.iovs.org/cgi/content/full/46/5/1797.
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- ↑ Ciuffreda, KJ; B. Vasudevan (2008). "Nearwork-induced transient myopia (NITM) and permanent myopia—is there a link?" (in English). Ophthalmic Physiol Opt. 28 (2): 103-114. PMID 18339041.
- ↑ "Glaucoma." EyeMDLink.com. Retrieved August 27, 2006.
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- ↑ 25.0 25.1 25.2 25.3 Verma A, Singh D. "Myopia, Phakic IOL." eMedicine.com. August 19, 2005.
- ↑ 26.0 26.1 26.2 26.3 Morgan I, Rose K. "How genetic is school myopia?" Prog Retin Eye Res. 2005 Jan;24(1):1-38. PMID 15555525.
- ↑ Dunaway D, Berger I. "Worldwide Distribution of Visual Refractive Errors and What to Expect at a Particular Location." Retrieved August 31,2006.
- ↑ 28.0 28.1 Fredrick DR. "Myopia." BMJ. May 18, 2002;324(7347):1195-9. PMID 12016188.
- ↑ National Research Council Commission. "Myopia: Prevalence and Progression." Washington, D.C. : National Academy Press, 1989. ISBN 0-309-04081-7
- ↑ Chandran S, Comparative study of refractive errors in West Malaysia, J Brit Ophthalmol 1972; 56: 492-495, and
- ↑ Wu HM, et al. Does education explainethnic differences in myopia prevalence? A population-based study of young adult males in Singapore. Optom Vis Sci 2001;78:234-239
- ↑ Logan NS, Davies LN, Mallen EA, Gilmartin B. Ametropia and ocular biometry in a UK university student population. Optom Vis Sci. 2005 Apr;82(4):261-6. PMID 15829853.
- ↑ Wensor M, McCarty CA, Taylor HR. Prevalence and risk factors of myopia in Victoria, Australia. Arch Ophthalmol. 1999 May;117(5):658-63. PMID 10326965.
- ↑ Junghans BM, Crewther SG. "Little evidence for an epidemic of myopia in Australian primary school children over the last 30 years." BMC Ophthalmol. February 11, 2005;5(1):1. PMID 15705207.
- ↑ 35.0 35.1 35.2 Kempen JH, Mitchell P, Lee KE, Tielsch JM, Broman AT, Taylor HR, Ikram MK, Congdon NG, O'Colmain BJ; Eye Diseases Prevalence Research Group. "The prevalence of refractive errors among adults in the United States, Western Europe, and Australia." Arch Ophthalmol. 2004 Apr;122(4):495-505. PMID 15078666.
- ↑ Thorn F, Cruz AA, Machado AJ, Carvalho RA. "Refractive status of indigenous people in the northwestern Amazon region of Brazil." Optom Vis Sci. 2005 Apr;82(4):267-72. PMID 15829854.
- ↑ Garcia CA, Orefice F, Nobre GF, Souza Dde B, Rocha ML, Vianna RN. "Prevalence of refractive errors in students in Northeastern Brazil." Arq Bras Oftalmol. 2005 May-Jun;68(3):321-5. Epub July 26, 2005. PMID 16059562.
- ↑ 38.0 38.1 38.2 Mavracanas TA, Mandalos A, Peios D, Golias V, Megalou K, Gregoriadou A, Delidou K, Katsougiannopoulos B. "Prevalence of myopia in a sample of Greek students." Acta Ophthalmol Scand. 2000 Dec;78(6):656-9. PMID 11167226.
- ↑ Mohan M, Pakrasi S, Zutshi R. "Myopia in India." Acta Ophthalmol Suppl. 1988;185:19-23. PMID 2853533.
- ↑ Kleinstein RN, Jones LA, Hullett S, Kwon S, Lee RJ, Friedman NE, Manny RE, Mutti DO, Yu JA, Zadnik K; Collaborative Longitudinal Evaluation of Ethnicity and Refractive Error Study Group. "Refractive error and ethnicity in children." Arch Ophthalmol. 2003 Aug;121(8):1141-7. PMID 12912692.
- ↑ 41.0 41.1 41.2 Sperduto RD, Seigel D, Roberts J, Rowland M. "Prevalence of myopia in the United States." Arch Ophthalmol. 1983 Mar;101(3):405-7. PMID 6830491.
- ↑ Mallen EA, Gammoh Y, Al-Bdour M, Sayegh FN. "Refractive error and ocular biometry in Jordanian adults." Ophthalmic Physiol Opt. 2005 Jul;25(4):302-9. PMID 15953114.
- ↑ Kleinstein, RN; Jones LA, Hullett S, Kwon S, Lee RJ, Friedman NE, Manny RE, Mutti DO, Yu JA, Zadnik K (2003). "Refractive error and ethnicity in children". Arch. Ophthalmol. 121 (8): 1141–1147. doi:10.1001/archopht.121.8.1141. PMID 12912692.
- ↑ SL, Beedle; Young FA (1976). "Values, personality, physical characteristics, and refractive error". Am J Optom Physiol Opt. 53 (11): 735-9. http://www.ncbi.nlm.nih.gov/pubmed/998715.
- ↑ Mutti, Donald O.; G. Lynn Mitchell, Melvin L. Moeschberger, Lisa A. Jones, and Karla Zadnik (2002). "Parental Myopia, Near Work, School Achievement, and Children’s Refractive Error". Investigative Ophthalmology & Visual Science 43 (12).
- ↑ "Chapter X: Strain."
- ↑ "Chapter VII: The Variability of the Refraction of the Eye."
- ↑ Chapter IV: The Truth about Accommodation as Demonstrated by Experiments on the Eye Muscles of Fish, Cats, Dogs, Rabbits and Other Animals."
- ↑ "Chapter I: Introductory."
- ↑ 50.0 50.1 Robyn E. Bradley (September 23, 2003). "ADVOCATES SEE ONLY BENEFITS FROM EYE EXERCISES", The Boston Globe (MA).
- ↑ 51.0 51.1 Rawstron JA, Burley CD, Elder MJ (2005). "A systematic review of the applicability and efficacy of eye exercises.". J Pediatr Ophthalmol Strabismus 42 (2): 82–8. http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?db=pubmed&cmd=Retrieve&dopt=AbstractPlus&list_uids=15825744&query_hl=13&itool=pubmed_DocSum.
- ↑ Mutti D. "Can We Conquer Myopia?" Review of Optomery. Optometric Study Center: April, 2001.
- ↑ http://arapaho.nsuok.edu/~salmonto/VSIII_2006/Lecture27.pdf
- ↑ 54.0 54.1 54.2 54.3 Saw SM, Gazzard G, Au Eong KG, Tan DT. "Myopia: attempts to arrest progression." Br J Ophthalmol. 2002 Nov;86(11):1306-11. PMID 12386095.
- ↑ Schor C. "The influence of interactions between accommodation and convergence on the lag of accommodation." Ophthalmic Physiol Opt. 1999 Mar;19(2):134-50. PMID 10615449.
- ↑ Xu L, Li J, Cui T, Hu A, Fan G, Zhang R, Yang H, Sun B, Jonas JB. "Refractive error in urban and rural adult Chinese in Beijing." Ophthalmology. 2005 Oct;112(10):1676-83. PMID 16111755.
- ↑ Wolffsohn JS, Gilmartin B, Li RW, Edwards MH, Chat SW, Lew JK, Yu BS. "Nearwork-induced transient myopia in preadolescent Hong Kong Chinese." Invest Ophthalmol Vis Sci. 2003 May;44(5):2284-9. PMID 12714672.
- ↑ 58.0 58.1 Saw S, Tong L, Chua W, Chia K, Koh D, Tan D, Katz J (2005). "Incidence and progression of myopia in Singaporean school children.". Invest Ophthalmol Vis Sci 46 (1): 51–7. doi:10.1167/iovs.04-0565. PMID 15623754.
- ↑ Hammond CJ, Andrew T, Mak YT, Spector TD. "A susceptibility locus for myopia in the normal population is linked to the PAX6 gene region on chromosome 11: a genomewide scan of dizygotic twins." Am J Hum Genet. 2004 Aug;75(2):294-304. Epub June 24, 2004. PMID 15307048
- ↑ Morgan I, Megaw P. Using natural STOP growth signals to prevent excessive axial elongation and the development of myopia. Ann Acad Med Singapore. 2004 Jan;33(1):16-20. PMID 15008556
- ↑ Saw SM, Katz J, Schein OD, Chew SJ, Chan TK. "Epidemiology of myopia." Epidemiol Rev. 1996;18(2):175-87. PMID 9021311.
- ↑ http://www.sciencenews.org/articles/20040710/fob1.asp
- ↑ Drexler W, Findl O, Schmetterer L, Hitzenberger CK, Fercher AF. "Eye elongation during accommodation in humans: differences between emmetropes and myopes." Invest Ophthalmol Vis Sci. 1998 Oct;39(11):2140-7. PMID 9761293.
- ↑ 64.0 64.1 Saw SM, Wu HM, Hong CY, Chua WH, Chia KS, Tan D. "Myopia and night lighting in children in Singapore." Br J Ophthalmol. 2001 May;85(5):527-8. PMID 11316706.
- ↑ Quinn GE, Shin CH, Maguire MG, Stone RA. "Myopia and ambient lighting at night." Nature. May 13, 1999;399(6732):113-4. PMID 10335839.
- ↑ Zadnik K, Jones LA, Irvin BC, Kleinstein RN, Manny RE, Shin JA, Mutti DO. "Myopia and ambient night-time lighting. CLEERE Study Group. Collaborative Longitudinal Evaluation of Ethnicity and Refractive Error." Nature. March 9, 2000;404(6774):143-4. PMID 10724157.
- ↑ Gwiazda J, Ong E, Held R, Thorn F. "Myopia and ambient night-time lighting." Nature. March 9, 2000;404(6774):144. PMID 10724158.
- ↑ Guggenheim JA, Hill C, Yam TF. "Myopia, genetics, and ambient lighting at night in a UK sample." Br J Ophthalmol. 2003 May;87(5):580-2. PMID 12714399.
- ↑ http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=pubmed&dopt=Abstract&list_uids=15926878&query_hl=11
- ↑ http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=pubmed&dopt=Abstract&list_uids=3875961&query_hl=2&itool=pubmed_docsum
- ↑ http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=pubmed&dopt=Abstract&list_uids=2853534&query_hl=2&itool=pubmed_docsum
- ↑ http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=pubmed&dopt=Abstract&list_uids=3259077&query_hl=2&itool=pubmed_docsum
- ↑ http://www.newscientist.com/article.ns?id=dn2120
- ↑ http://www.newscientist.com/article.ns?id=dn2120
- ↑ Bowan M. "Stress and Eye: New Speculations on Refractive Error." J. Behavioral Optom. 7(5)115-22, 1996.
- ↑ Bayramlar H, Cekic O, Hepsen IF. "Does convergence, not accommodation, cause axial-length elongation at near? A biometric study in teens." Ophthalmic Res. 1999;31(4):304-8. PMID 10325546.
- ↑ Czepita D, Filipiak D. [The effect of the type of astigmatism on the incidence of myopia]. Klin Oczna. 2005;107(1-3):73-4. PMID 16052807.
- ↑ G Rupolo, M Angi, E Sabbadin, S Caucci, E Pilotto, E Racano and C de Bertolini (1997). "Treating myopia with acoustic biofeedback: a prospective study on the evolution of visual acuity and psychological distress". Psychosomatic Medicine 59 (3): 313–317.
- ↑ Randle RJ (1988). "Responses of myopes to volitional control training of accommodation.". Ophthalmic Physiol Opt 8: 333–340.
- ↑ Gallaway M, Pearls SM, Winkelstein AM, et al. (1987). "Biofeedback training of visual acuity and myopia: A pilot study.". Am J Optom Physiol Opt 64: 62–71.
- ↑ Koslowe KC, Spierer A, Rosner M, et al. (1991). "Evaluation of accommotrac biofeedback training for myopia control.". Optom Vis Sci 68: 252–4.
- ↑ Rehm, Donald "The Myopia Myth-The Truth About Nearsightedness And How To Prevent It" Chapter 6 Published by The International Myopia Prevention Assn., 1054 Gravel Hill Road, Ligonier, PA 15658. 1981 ISBN 0-9608476-0-X
- ↑ Andy Coghlan and Michael Le Page (20 November 2002). "Eye correction is seriously short sighted", New Scientist.
- ↑ Chung K, Mohidin N, O'Leary DJ. "Undercorrection of myopia enhances rather than inhibits myopia progression." Vision Res. 2002 Oct;42(22):2555-9. PMID 12445849.
- ↑ The Wildoset Lab.. "Controlling Myopia Progression - A Confusing Story". Retrieved on 2006-09-01.
- ↑ Siatkowski R, Cotter S, Miller J, Scher C, Crockett R, Novack G (2004). "Safety and efficacy of 2% pirenzepine ophthalmic gel in children with myopia: a 1-year, multicenter, double-masked, placebo-controlled parallel study.". Arch Ophthalmol 122 (11): 1667–74. doi:10.1001/archopht.122.11.1667. PMID 15534128.
- ↑ Ong E, Grice K, Held R, Thorn F, Gwiazda J. "Effects of spectacle intervention on the progression of myopia in children." Optom Vis Sci. 1999 Jun;76(6):363-9. PMID 10416930.
- ↑ Parssinen O, Hemminki E, Klemetti A. Effect of spectacle use and accommodation on myopic progression: final results of a three-year randomised clinical trial among schoolchildren. Br J Ophthalmol. 1989 Jul;73(7):547-51. PMID 2667638.
External links
Eye disease - pathology of the eye (H00-H59, 360-379) |
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Adnexa |
eyelid: inflammation (Stye, Chalazion, Blepharitis) - Entropion - Ectropion - Lagophthalmos - Blepharochalasis - Ptosis - Blepharophimosis - Xanthelasma - Trichiasis - Madarosis
lacrimal system: Dacryoadenitis - Epiphora - Dacryocystitis
orbit: Exophthalmos - Enophthalmos
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Eyeball |
Conjunctiva
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Conjunctivitis (Allergic conjunctivitis) - Pterygium - Pinguecula - Subconjunctival hemorrhage
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Fibrous tunic
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sclera: Scleritis
cornea: Keratitis - Corneal ulcer - Snow blindness - Thygeson's superficial punctate keratopathy - Fuchs' dystrophy - Keratoconus - Keratoconjunctivitis sicca - Arc eye - Keratoconjunctivitis - Corneal neovascularization - Kayser-Fleischer ring - Arcus senilis - Band keratopathy
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Iris and ciliary body
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Iritis - Uveitis - Iridocyclitis - Hyphema - Persistent pupillary membrane - Iridodialysis - Synechia
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Lens
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Choroid
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Choroideremia - Choroiditis (Chorioretinitis)
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Retina
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Retinitis (Chorioretinitis) - Retinal detachment - Retinoschisis - Retinopathy (Bietti's crystalline dystrophy, Coats disease, Diabetic retinopathy, Hypertensive retinopathy, Retinopathy of prematurity) - Macular degeneration - Retinitis pigmentosa - Retinal haemorrhage - Central serous retinopathy - Macular edema - Epiretinal membrane - Macular pucker - Vitelliform macular dystrophy - Leber's congenital amaurosis - Birdshot chorioretinopathy
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Optic nerve and visual pathways |
Optic neuritis - Papilledema - Optic atrophy - Leber's hereditary optic neuropathy - Dominant optic atrophy - Optic disc drusen - Glaucoma - Toxic and nutritional optic neuropathy - Anterior ischemic optic neuropathy
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Ocular muscles,
binocular movement,
accommodation and refraction |
Paralytic strabismus: Ophthalmoparesis - Progressive external ophthalmoplegia - Palsy (III, IV, VI) - Kearns-Sayre syndrome
Other strabismus: Esotropia/Exotropia - Hypertropia - Heterophoria (Esophoria, Exophoria) - Brown's syndrome - Duane syndrome
Other binocular: Conjugate gaze palsy - Convergence insufficiency - Internuclear ophthalmoplegia - One and a half syndrome
Refractive error: Hyperopia/Myopia - Astigmatism - Anisometropia/Aniseikonia - Presbyopia
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Visual disturbances and blindness |
Amblyopia - Leber's congenital amaurosis - Subjective (Asthenopia, Hemeralopia, Photophobia, Scintillating scotoma) - Diplopia - Scotoma - Anopsia (Binasal hemianopsia, Bitemporal hemianopsia, Homonymous hemianopsia, Quadrantanopia) - Color blindness ( Achromatopsia, Dichromacy, Monochromacy) - Nyctalopia (Oguchi disease) - Blindness/ Low vision
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Pupil |
Anisocoria - Argyll Robertson pupil - Marcus Gunn pupil/Marcus Gunn phenomenon - Adie syndrome - Miosis - Mydriasis - Cycloplegia
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Infectious diseases |
Trachoma - Onchocerciasis
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Other |
Nystagmus - Glaucoma/Ocular hypertension - Floater - Leber's hereditary optic neuropathy - Red eye - Keratomycosis - Xerophthalmia - Phthisis bulbi
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See also
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