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Refractive error

October 20, 2023

Refractive error, also known as refraction error, is a problem with focusing light accurately on the retina due to the shape of the eye and or cornea.[1] The most common types of refractive error are near-sightedness, far-sightedness, astigmatism, and presbyopia.[1] Near-sightedness results in far away objects being blurry, far-sightedness and presbyopia result in close objects being blurry, and astigmatism causes objects to appear stretched out or blurry.[1] Other symptoms may include double vision, headaches, and eye strain.[1]

Refractive error
Other namesRefraction error
A correctly-focused eye (top), and two showing refractive error: in the middle image, the light is focused too far forward; in the bottom image, the focal point is behind the eye
SpecialtyOphthalmology, optometry
SymptomsBlurry vision, double vision, headaches, eye strain[1]
ComplicationsBlindness, amblyopia[2][3]
TypesNear-sightedness, far-sightedness, astigmatism, presbyopia[1]
CausesEyeball length, problems with cornea shape, aging of the lens[1]
Diagnostic methodEye examination[1]
TreatmentEyeglasses, contact lenses, refractive surgery[1]
Frequency~1.5 billion[4]

Near-sightedness is due to the length of the eyeball being too long, far-sightedness the eyeball too short, astigmatism the cornea being the wrong shape, and presbyopia aging of the lens of the eye such that it cannot change shape sufficiently.[1] Some refractive errors occur more often among those whose parents are affected.[1] Diagnosis is by eye examination.[1]

Refractive errors are corrected with eyeglasses, contact lenses, or surgery.[1] Eyeglasses are the easiest and safest method of correction.[1] Contact lenses can provide a wider field of vision; however they are associated with a risk of infection.[1] Refractive surgery permanently changes the shape of the cornea.[1]

The number of people globally with refractive errors has been estimated at one to two billion.[4] Rates vary between regions of the world with about 25% of Europeans and 80% of Asians affected.[4] Near-sightedness is the most common disorder.[5] Rates among adults are between 15-49% while rates among children are between 1.2-42%.[6] Far-sightedness more commonly affects young children and the elderly.[7][8] Presbyopia affects most people over the age of 35.[1]

The number of people with refractive errors that have not been corrected was estimated at 660 million (10 per 100 people) in 2013.[9] Of these 9.5 million were blind due to the refractive error.[9] It is one of the most common causes of vision loss along with cataracts, macular degeneration, and vitamin A deficiency.[10]

Classification Edit

 
Top: farsighted corrected using convex lens Bottom: nearsighted corrected using concave lens.

An eye that has no refractive error when viewing distant objects is said to have emmetropia or be emmetropic meaning the eye is in a state in which it can focus parallel rays of light (light from distant objects) on the retina, without using any accommodation. A distant object, in this case, is defined as an object located beyond 6 meters, or 20 feet, from the eye, since the light from those objects arrives as essentially parallel rays when considering the limitations of human perception.[11]

An eye that has refractive error when viewing distant objects is said to have ametropia or be ametropic. This eye cannot focus parallel rays of light (light from distant objects) on the retina, or needs accommodation to do so.[citation needed]

The word "ametropia" can be used interchangeably with "refractive error". Types of ametropia include myopia, hyperopia and astigmatism. They are frequently categorized as spherical errors and cylindrical errors:

  • Cylindrical errors cause astigmatism, when the optical power of the eye is too powerful or too weak across one meridian, such as if the corneal curvature tends towards a cylindrical shape. The angle between that meridian and the horizontal is known as the axis of the cylinder.
    • Astigmatism: A person with astigmatic refractive error sees lines of a particular orientation less clearly than lines at right angles to them. This defect can be corrected by refracting light more in one meridian than the other. Cylindrical lenses serve this purpose.
  • Spherical errors occur when the optical power of the eye is either too large or too small to focus light on the retina. People with refractive error frequently have blurry vision.
    • Farsightedness: When the optics are too weak for the length of the eyeball, one has hyperopia or farsightedness. This can arise from a cornea or crystalline lens with not enough curvature (refractive hyperopia) or an eyeball that is too short (axial hyperopia). This can be corrected with convex lenses, which cause light rays to converge prior to hitting the cornea.
    • Nearsightedness: When the optics are too powerful for the length of the eyeball one has myopia or nearsightedness. This can arise from a cornea or crystalline lens with too much curvature (refractive myopia) or an eyeball that is too long (axial myopia). Myopia can be corrected with a concave lens, which causes the divergence of light rays before they reach the cornea.
    • Presbyopia: When the flexibility of the lens declines, typically due to age. The individual would experience difficulty in near vision, often relieved by reading glasses, bifocal, or progressive lenses.

Other terminology include anisometropia, when the two eyes have unequal refractive power,[12] and aniseikonia which is when the magnification power between the eyes differ.[13]

Refractive error may be quantified as the error of a wavefront arising from a person's far point, compared with a plane, or zero vergence, wavefront compared at an appropriate reference plane. The reference plane may be a real plane such as the spectacle plane or the corneal plane, or an imaginary plane such as the first principal plane or the entrance pupil plane. In diopters, spherical refractive errors can be expressed as K=1/k, where k is the distance in meters from the reference plane to an eye's far point, and K is the refractive error in diopters.[14][15] Thus, a person with myopia would have a negative refractive error, a person with emmetropia would have zero refractive error and a person with hyperopia would have a positive refractive error. In the case of regular astigmatism, refractive error needs to be expressed as 3 values: classically as sphere, cylinder and axis. However, it can also be expressed in vector terms, for example, M (mean sphere), J0 (With the rule/Against the rule astigmatism), J45 (oblique astigmatism).[16] Refractive errors containing higher order aberrations (sometimes referred to as irregular astigmatism) can be expressed for a given pupil size using wavefront errors or optical path differences, often as coefficients for Zernike polynomials.[17] A more subjective quantity visual acuity (expressed as a fraction) may be used, but there is no direct or exact conversion between the two.[18]

Risk factors Edit

Genetics Edit

 
Fundus of person with retinitis pigmentosa, early stage

There is evidence to suggest genetic predilection for refractive error. Individuals that have parents with certain refractive errors are more likely to have similar refractive errors.[1]

The Online Mendelian Inheritance in Man (OMIM) database has listed 261 genetic disorders in which myopia is one of the symptoms.[19] Myopia may be present in heritable connective tissue disorders such as: Knobloch syndrome (OMIM 267750); Marfan syndrome (OMIM 154700); and Stickler syndrome (type 1, OMIM 108300; type 2, OMIM 604841).[20] Myopia has also been reported in X-linked disorders caused by mutations in loci involved in retinal photoreceptor function (NYX, RP2, MYP1) such as: autosomal recessive congenital stationary night blindness (CSNB; OMIM 310500); retinitis pigmentosa 2 (RP2; OMIM 312600); Bornholm eye disease (OMIM 310460).[21] Many genes that have been associated with refractive error are clustered into common biological networks involved in connective tissue growth and extracellular matrix organization.[20] Although a large number of chromosomal localisations have been associated with myopia (MYP1-MYP17), few specific genes have been identified.[19]

Environmental Edit

In studies of the genetic predisposition of refractive error, there is a correlation between environmental factors and the risk of developing myopia.[22] Myopia has been observed in individuals with visually intensive occupations.[21] Reading has also been found to be a predictor of myopia in children. It has been reported that children with myopia spent significantly more time reading than non-myopic children who spent more time playing outdoors.[21] Socioeconomic status and higher levels of education have also been reported to be a risk factor for myopia.[citation needed] Blepharoptosis can also induce refractive errors.[23]

Diagnosis Edit

 
A doctor uses a trial frame and trial lenses to measure the person's refractive error.

Blurry vision may result from any number of conditions not necessarily related to refractive errors. The diagnosis of a refractive error is usually confirmed by an eye care professional during an eye examination using a large number of lenses of different optical powers, and often a retinoscope (a procedure entitled retinoscopy) to measure objectively in which the person views a distant spot while the clinician changes the lenses held before the person's eye and watches the pattern of reflection of a small light shone on the eye. Following that "objective refraction" the clinician typically shows the person lenses of progressively higher or weaker powers in a process known as subjective refraction. Cycloplegic agents are frequently used to more accurately determine the amount of refractive error, particularly in children[22]

An automated refractor is an instrument that is sometimes used in place of retinoscopy to objectively estimate a person's refractive error.[24] Shack–Hartmann wavefront sensor and its inverse[25] can also be used to characterize eye aberrations in a higher level of resolution and accuracy.

Vision defects caused by refractive error can be distinguished from other problems using a pinhole occluder, which will improve vision only in the case of refractive error.[citation needed]

Management Edit

The management of refractive error is done post-diagnosis of the condition by either optometrists, ophthalmologists, refractionists, or ophthalmic medical practitioners.[26]

How refractive errors are treated or managed depends upon the amount and severity of the condition. Those who possess mild amounts of refractive error may elect to leave the condition uncorrected, particularly if the person is asymptomatic. For those who are symptomatic, glasses, contact lenses, refractive surgery, or a combination of the three are typically used.[citation needed]

Glasses Edit

These are the most effective ways of correcting the refractive error. However, the availability and affordability of eye glasses can present a difficulty for people in many low income settings of the world. Glasses also pose a challenge to children to whom they are prescribed to, due to children's tendency to not wear them as consistently as recommended.[27]

As mentioned earlier refractive errors are because of the improper focusing of the light in the retina. Eyeglasses work as an added lens of the eye serving to bend the light to bring it to focus on the retina. Depending on the eyeglasses, they serve many functions.[28]

Reading glasses
These are general over-the-counter glasses which can be worn for easier reading, especially for defective vision due to aging called presbyopia.
Single vision prescription lenses
They can correct only one form of defective vision, either far-sightedness or near-sightedness.
Multifocal lenses
The multifocal lenses can correct defective vision in multiple focus, for example: near-vision as well as far-vision. This are particularly beneficial for presbyobia.[29]

Contact lenses Edit

Alternatively, many people choose to wear contact lenses. One style is hard contact lenses, which can distort the shape of the cornea to a desired shape. Another style, soft contact lenses, are made of silicone or hydrogel. Depending on the duration they are designed for, they may be worn daily or may be worn for an extended period of time, such as for weeks.[26]

There are a number of complication associated with contact lenses. Typically the ones that are used daily.

Complications of contact lens wear Description
Conjunctivitis (giant papillary form) Caused in response to the allergen present in the material from which the contact lens is made from. There is often discomfort in the eye after wearing and vision may be affected. Choosing the right lens material and changing it regularly might prevent conjunctivitis.
Corneal abrasion Caused by a foreign body, dust, sand, or grit trapped under the lens.
Corneal edema Caused by decreased oxygen delivery to the tissue compressed by the lens. Usually resolved after the removal of the lenses. Discomfort upon lens removal may be seen.
Neovascularization New blood vessels may form in the iris region and the limbus. This may impair vision.
Infections Various viral, bacterial, and fungal infection may be seen in the eye post-contact-lens wear, if proper lens hygiene is not maintained. Acanthamoeba are the most common infections in the people using contact lenses.

If redness, itching, and difficulty in vision develops, the use of the lenses should be stopped immediately and the consultation of ophthalmologists may be sought.

Surgery Edit

Laser in situ keratomileusis (LASIK) and photo-refractive keratectomy (PRK) are popular procedures; while use of laser epithelial keratomileusis (LASEK) is increasing. Other surgical treatments for severe myopia include insertion of implants after clear lens extraction (refractive lens exchange). Full thickness corneal graft may be a final option for patients with advanced kerataconus although currently there is interest in new techniques that involve collagen crosslinking. As with any surgical procedure complications may arise post-operatively Post-operative monitoring is normally undertaken by the specialist ophthalmic surgical clinic and optometry services. Patients are usually informed pre-operatively about what to expect and where to go if they suspect complications. Any patient reporting pain and redness after surgery should be referred urgently to their ophthalmic surgeon.[citation needed]

Medical treatment Edit

Atropine has believed to slow the progression of near-sightedness and is administered in combination with multifocal lenses. These, however, need further research.[30][31]

Prevention Edit

Strategies being studied to slow worsening include adjusting working conditions, increasing the time children spend outdoors,[21] and special types of contact lenses.[32] In children special contact lenses appear to slow worsening of nearsightedness.[32][33]

A number of questionnaires exist to determine quality of life impact of refractive errors and their correction.[34][35]

Epidemiology Edit

 
DALYs per 100,000 people due to refractive errors in 2004.[36]
  No data
  Less than 100
  100-170
  170-240
  240-310
  310-380
  380-450
  450-520
  520-590
  590-660
  660-730
  730-800
  More than 800

The number of people globally with refractive errors that have not been corrected was estimated at 660 million (10 per 100 people) in 2013.[9]

Refractive Errors are the first common cause of Visual Impairment and second most common cause of visual loss .[37] The assessment of Refractive Error is now done in DALY (Disability Adjusted Life Years) which showed an 8% increase from 1990 to 2019.[38][unreliable source]

The number of people globally with significant refractive errors has been estimated at one to two billion.[4] Rates vary between regions of the world with about 25% of Europeans and 80% of Asians affected.[4] Near-sightedness is one of the most prevalent disorders of the eye.[5] Rates among adults are between 15-49% while rates among children are between 1.2-42%.[6] Far-sightedness more commonly affects young children, whose eyes have yet to grow to their full length, and the elderly, who have lost the ability to compensate with their accommodation system.[7][8] Presbyopia affects most people over the age of 35, and nearly 100% of people by the ages of 55-65.[1] Uncorrected refractive error is responsible for visual impairment and disability for many people worldwide.[9] It is one of the most common causes of vision loss along with cataracts, macular degeneration, and vitamin A deficiency.[10]

Cost Edit

The yearly cost of correcting refractive errors is estimated at 3.9 to 7.2 billion dollars in the United States.[39]

References Edit

  1. ^ a b c d e f g h i j k l m n o p q r s "Facts About Refractive Errors". NEI. October 2010. from the original on 28 July 2016. Retrieved 29 July 2016.
  2. ^ "Care of the Patient with Amblyopia" (PDF). Retrieved 17 February 2020.
  3. ^ Dandona, R; Dandona, L (2001). "Refractive error blindness". Bulletin of the World Health Organization. 79 (3): 237–43. PMC 2566380. PMID 11285669.
  4. ^ a b c d e Denniston, Alastair; Murray, Philip (2018). Oxford Handbook of Ophthalmology (4 ed.). OUP Oxford. p. 926. ISBN 9780198816751.
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  6. ^ a b Pan, CW; Ramamurthy, D; Saw, SM (January 2012). "Worldwide prevalence and risk factors for myopia". Ophthalmic & Physiological Optics. 32 (1): 3–16. doi:10.1111/j.1475-1313.2011.00884.x. PMID 22150586. S2CID 32397628.
  7. ^ a b Castagno, VD; Fassa, AG; Carret, ML; Vilela, MA; Meucci, RD (23 December 2014). "Hyperopia: a meta-analysis of prevalence and a review of associated factors among school-aged children". BMC Ophthalmology. 14: 163. doi:10.1186/1471-2415-14-163. PMC 4391667. PMID 25539893.
  8. ^ a b Grosvenor, Theodore (2007). Primary care optometry (5 ed.). St. Louis (Miss.): Butterworth Heinemann, Elsevier. p. 70. ISBN 9780750675758. from the original on 2016-08-15.
  9. ^ a b c d Vos, Theo; Barber, Ryan M; Bell, Brad; Bertozzi-Villa, Amelia; Biryukov, Stan; Bolliger, Ian; et al. (Global Burden of Disease Study 2013 Collaborators) (22 August 2015). "Global, regional, and national incidence, prevalence, and years lived with disability for 301 acute and chronic diseases and injuries in 188 countries, 1990-2013: a systematic analysis for the Global Burden of Disease Study 2013". Lancet. 386 (9995): 743–800. doi:10.1016/s0140-6736(15)60692-4. PMC 4561509. PMID 26063472.
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  11. ^ Bope, Edward T.; Kellerman, Rick D. (2015). Conn's Current Therapy 2016. Elsevier Health Sciences. p. 354. ISBN 9780323355353.
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  13. ^ "Aniseikonia - EyeWiki". eyewiki.aao.org. Retrieved 10 February 2020.
  14. ^ Millodot M. In: Dictionary of Optometry and Vision Science 8th ed: Elsevier, 2017. pp. 291.
  15. ^ Atchison DA, Smith G. Chapter 7 - Refractive anomalies. In: Optics of the Human Eye (Atchison DA, Smith G, editors). Edinburgh: Butterworth-Heinemann, 2000. pp. 57-66.
  16. ^ Thibos LN, Wheeler W, Horner D. Power vectors: an application of Fourier analysis to the description and statistical analysis of refractive error. Optom Vis Sci. 1997;74(6):367-75. Epub 1997/06/01.
  17. ^ Thibos LN, Applegate RA, Schwiegerling JT, Webb R. Standards for reporting the optical aberrations of eyes. Journal of refractive surgery (Thorofare, NJ : 1995). 2002;18(5):S652-60. Epub 2002/10/04
  18. ^ "Converting Vision Between Diopters and 20/xx". www.iblindness.org. Retrieved 2020-05-13.
  19. ^ a b Morgan, Ian; Kyoko Ohno-Matsui (May 2012). "Myopia". The Lancet. 379 (9827): 1739–1748. doi:10.1016/S0140-6736(12)60272-4. PMID 22559900. S2CID 208793136.
  20. ^ a b Wojciechowski, Robert (April 2011). "Nature and Nurture: the complex genetics of myopia and refractive error". Clin Genet. 79 (4): 301–320. doi:10.1111/j.1399-0004.2010.01592.x. PMC 3058260. PMID 21155761.
  21. ^ a b c d Wojcienchowski, Robert (April 2011). "Nature and Nurture: the complex genetics of myopia and refractive error". Clinical Genetics. 79 (4): 301–320. doi:10.1111/j.1399-0004.2010.01592.x. PMC 3058260. PMID 21155761.
  22. ^ a b Barnes, Katherine (Feb 2013). "Genome-wide meta-analyses of multiancestry cohorts identify multiple new susceptibility loci for refractive error and myopia". Clinical Genetics. 45 (3): 314–8. doi:10.1111/j.1399-0004.2010.01592.x. PMC 3740568. PMID 23396134.
  23. ^ Owji, N; Khalili, MR; Bazrafkan, H; Heydari, M (September 2022). "Long-term outcome of refractive errors in patients with congenital blepharoptosis who have undergone ptosis surgery". Clinical & experimental optometry. 105 (7): 715–720. doi:10.1080/08164622.2021.1973344. PMID 34538220.
  24. ^ "Frequently Asked Questions: How do you measure refractive errors?". The New York Eye And Ear Infirmary. from the original on 2006-09-01. Retrieved 2006-09-13.
  25. ^ . Vitor F. Pamplona, Ankit Mohan, Manuel M. Oliveira, Ramesh Raskar. Archived from the original on 2011-12-21. Retrieved 2011-12-13.
  26. ^ a b Cochrane, Gillian M.; Toit, Rènée du; Mesurier, Richard T. Le (2010-04-12). "Management of refractive errors". BMJ. 340: c1711. doi:10.1136/bmj.c1711. ISSN 0959-8138. PMID 20385718. S2CID 8240093.
  27. ^ Wedner, S.; Masanja, H.; Bowman, R.; Todd, J.; Bowman, R.; Gilbert, C. (2008-01-01). "Two strategies for correcting refractive errors in school students in Tanzania: randomised comparison, with implications for screening programmes". British Journal of Ophthalmology. 92 (1): 19–24. doi:10.1136/bjo.2007.119198. ISSN 0007-1161. PMID 18156372. S2CID 2157969.
  28. ^ "Pediatric Ophthalmology, Optometry and Orthoptics". Asian Eye Institute. Retrieved 2022-08-03.
  29. ^ "Eyeglasses for Refractive Errors | National Eye Institute". www.nei.nih.gov. Retrieved 2021-06-29.
  30. ^ Shih, Yung-Feng; Hsiao, C. Kate; Chen, Chien-Jen; Chang, Ching-Wei; Hung, Por T.; Lin, Luke L.-K. (June 2001). "An intervention trial on efficacy of atropine and multi-focal glasses in controlling myopic progression". Acta Ophthalmologica Scandinavica. 79 (3): 233–236. doi:10.1034/j.1600-0420.2001.790304.x. ISSN 1395-3907. PMID 11401629.
  31. ^ Lee, Jong-Jer; Fang, Po-Chiung; Yang, I-Hui; Chen, Chih-Hsin; Lin, Pei-Wen; Lin, Sue-Ann; Kuo, Hsi-Kung; Wu, Pei-Chang (February 2006). "Prevention of Myopia Progression with 0.05% Atropine Solution". Journal of Ocular Pharmacology and Therapeutics. 22 (1): 41–46. doi:10.1089/jop.2006.22.41. ISSN 1080-7683. PMID 16503774.
  32. ^ a b Li, X; Friedman, IB; Medow, NB; Zhang, C (1 May 2017). "Update on Orthokeratology in Managing Progressive Myopia in Children: Efficacy, Mechanisms, and Concerns". Journal of Pediatric Ophthalmology and Strabismus. 54 (3): 142–148. doi:10.3928/01913913-20170106-01. PMID 28092397.
  33. ^ Walline, JJ (January 2016). "Myopia Control: A Review". Eye & Contact Lens. 42 (1): 3–8. doi:10.1097/ICL.0000000000000207. PMID 26513719. S2CID 24069302.
  34. ^ Kandel H, Khadka J, Goggin M, Pesudovs K (2017). "Patient-reported outcomes for assessment of quality of life in refractive error: a systematic review". Optometry and Vision Science. 94 (12): 1102–1119. doi:10.1097/OPX.0000000000001143. PMID 29095758. S2CID 21512136.
  35. ^ Kandel H, Khadka J, Lundström M, Goggin M, Pesudovs K (2017). "Questionnaires for measuring refractive surgery outcomes". Journal of Refractive Surgery. 33 (6): 416–424. doi:10.3928/1081597X-20170310-01. PMID 28586503.
  36. ^ "WHO Disease and injury country estimates". World Health Organization. 2009. from the original on 2009-11-11. Retrieved Nov 11, 2009.
  37. ^ Hashemi, Hassan; Fotouhi, Akbar; Yekta, Abbasali; Pakzad, Reza; Ostadimoghaddam, Hadi; Khabazkhoob, Mehdi (2017-09-27). "Global and regional estimates of prevalence of refractive errors: Systematic review and meta-analysis". Journal of Current Ophthalmology. 30 (1): 3–22. doi:10.1016/j.joco.2017.08.009. ISSN 2452-2325. PMC 5859285. PMID 29564404.
  38. ^ (PDF). Archived from the original (PDF) on 2021-06-24. Retrieved 2023-03-21.
  39. ^ Kuryan J, Cheema A, Chuck RS (2017). "Laser-assisted subepithelial keratectomy (LASEK) versus laser-assisted in-situ keratomileusis (LASIK) for correcting myopia". Cochrane Database Syst Rev. 2017 (2): CD011080. doi:10.1002/14651858.CD011080.pub2. PMC 5408355. PMID 28197998.

External links Edit

October 20, 2023
refractive, error, also, known, refraction, error, problem, with, focusing, light, accurately, retina, shape, cornea, most, common, types, refractive, error, near, sightedness, sightedness, astigmatism, presbyopia, near, sightedness, results, away, objects, be. Refractive error also known as refraction error is a problem with focusing light accurately on the retina due to the shape of the eye and or cornea 1 The most common types of refractive error are near sightedness far sightedness astigmatism and presbyopia 1 Near sightedness results in far away objects being blurry far sightedness and presbyopia result in close objects being blurry and astigmatism causes objects to appear stretched out or blurry 1 Other symptoms may include double vision headaches and eye strain 1 Refractive errorOther namesRefraction errorA correctly focused eye top and two showing refractive error in the middle image the light is focused too far forward in the bottom image the focal point is behind the eyeSpecialtyOphthalmology optometrySymptomsBlurry vision double vision headaches eye strain 1 ComplicationsBlindness amblyopia 2 3 TypesNear sightedness far sightedness astigmatism presbyopia 1 CausesEyeball length problems with cornea shape aging of the lens 1 Diagnostic methodEye examination 1 TreatmentEyeglasses contact lenses refractive surgery 1 Frequency 1 5 billion 4 Near sightedness is due to the length of the eyeball being too long far sightedness the eyeball too short astigmatism the cornea being the wrong shape and presbyopia aging of the lens of the eye such that it cannot change shape sufficiently 1 Some refractive errors occur more often among those whose parents are affected 1 Diagnosis is by eye examination 1 Refractive errors are corrected with eyeglasses contact lenses or surgery 1 Eyeglasses are the easiest and safest method of correction 1 Contact lenses can provide a wider field of vision however they are associated with a risk of infection 1 Refractive surgery permanently changes the shape of the cornea 1 The number of people globally with refractive errors has been estimated at one to two billion 4 Rates vary between regions of the world with about 25 of Europeans and 80 of Asians affected 4 Near sightedness is the most common disorder 5 Rates among adults are between 15 49 while rates among children are between 1 2 42 6 Far sightedness more commonly affects young children and the elderly 7 8 Presbyopia affects most people over the age of 35 1 The number of people with refractive errors that have not been corrected was estimated at 660 million 10 per 100 people in 2013 9 Of these 9 5 million were blind due to the refractive error 9 It is one of the most common causes of vision loss along with cataracts macular degeneration and vitamin A deficiency 10 Contents 1 Classification 2 Risk factors 2 1 Genetics 2 2 Environmental 3 Diagnosis 4 Management 4 1 Glasses 4 2 Contact lenses 4 3 Surgery 4 4 Medical treatment 4 5 Prevention 5 Epidemiology 6 Cost 7 References 8 External linksClassification Edit nbsp Top farsighted corrected using convex lens Bottom nearsighted corrected using concave lens An eye that has no refractive error when viewing distant objects is said to have emmetropia or be emmetropic meaning the eye is in a state in which it can focus parallel rays of light light from distant objects on the retina without using any accommodation A distant object in this case is defined as an object located beyond 6 meters or 20 feet from the eye since the light from those objects arrives as essentially parallel rays when considering the limitations of human perception 11 An eye that has refractive error when viewing distant objects is said to have ametropia or be ametropic This eye cannot focus parallel rays of light light from distant objects on the retina or needs accommodation to do so citation needed The word ametropia can be used interchangeably with refractive error Types of ametropia include myopia hyperopia and astigmatism They are frequently categorized as spherical errors and cylindrical errors Cylindrical errors cause astigmatism when the optical power of the eye is too powerful or too weak across one meridian such as if the corneal curvature tends towards a cylindrical shape The angle between that meridian and the horizontal is known as the axis of the cylinder Astigmatism A person with astigmatic refractive error sees lines of a particular orientation less clearly than lines at right angles to them This defect can be corrected by refracting light more in one meridian than the other Cylindrical lenses serve this purpose Spherical errors occur when the optical power of the eye is either too large or too small to focus light on the retina People with refractive error frequently have blurry vision Farsightedness When the optics are too weak for the length of the eyeball one has hyperopia or farsightedness This can arise from a cornea or crystalline lens with not enough curvature refractive hyperopia or an eyeball that is too short axial hyperopia This can be corrected with convex lenses which cause light rays to converge prior to hitting the cornea Nearsightedness When the optics are too powerful for the length of the eyeball one has myopia or nearsightedness This can arise from a cornea or crystalline lens with too much curvature refractive myopia or an eyeball that is too long axial myopia Myopia can be corrected with a concave lens which causes the divergence of light rays before they reach the cornea Presbyopia When the flexibility of the lens declines typically due to age The individual would experience difficulty in near vision often relieved by reading glasses bifocal or progressive lenses Other terminology include anisometropia when the two eyes have unequal refractive power 12 and aniseikonia which is when the magnification power between the eyes differ 13 Refractive error may be quantified as the error of a wavefront arising from a person s far point compared with a plane or zero vergence wavefront compared at an appropriate reference plane The reference plane may be a real plane such as the spectacle plane or the corneal plane or an imaginary plane such as the first principal plane or the entrance pupil plane In diopters spherical refractive errors can be expressed as K 1 k where k is the distance in meters from the reference plane to an eye s far point and K is the refractive error in diopters 14 15 Thus a person with myopia would have a negative refractive error a person with emmetropia would have zero refractive error and a person with hyperopia would have a positive refractive error In the case of regular astigmatism refractive error needs to be expressed as 3 values classically as sphere cylinder and axis However it can also be expressed in vector terms for example M mean sphere J0 With the rule Against the rule astigmatism J45 oblique astigmatism 16 Refractive errors containing higher order aberrations sometimes referred to as irregular astigmatism can be expressed for a given pupil size using wavefront errors or optical path differences often as coefficients for Zernike polynomials 17 A more subjective quantity visual acuity expressed as a fraction may be used but there is no direct or exact conversion between the two 18 Risk factors EditGenetics Edit nbsp Fundus of person with retinitis pigmentosa early stageThere is evidence to suggest genetic predilection for refractive error Individuals that have parents with certain refractive errors are more likely to have similar refractive errors 1 The Online Mendelian Inheritance in Man OMIM database has listed 261 genetic disorders in which myopia is one of the symptoms 19 Myopia may be present in heritable connective tissue disorders such as Knobloch syndrome OMIM 267750 Marfan syndrome OMIM 154700 and Stickler syndrome type 1 OMIM 108300 type 2 OMIM 604841 20 Myopia has also been reported in X linked disorders caused by mutations in loci involved in retinal photoreceptor function NYX RP2 MYP1 such as autosomal recessive congenital stationary night blindness CSNB OMIM 310500 retinitis pigmentosa 2 RP2 OMIM 312600 Bornholm eye disease OMIM 310460 21 Many genes that have been associated with refractive error are clustered into common biological networks involved in connective tissue growth and extracellular matrix organization 20 Although a large number of chromosomal localisations have been associated with myopia MYP1 MYP17 few specific genes have been identified 19 Environmental Edit In studies of the genetic predisposition of refractive error there is a correlation between environmental factors and the risk of developing myopia 22 Myopia has been observed in individuals with visually intensive occupations 21 Reading has also been found to be a predictor of myopia in children It has been reported that children with myopia spent significantly more time reading than non myopic children who spent more time playing outdoors 21 Socioeconomic status and higher levels of education have also been reported to be a risk factor for myopia citation needed Blepharoptosis can also induce refractive errors 23 Diagnosis Edit nbsp A doctor uses a trial frame and trial lenses to measure the person s refractive error Blurry vision may result from any number of conditions not necessarily related to refractive errors The diagnosis of a refractive error is usually confirmed by an eye care professional during an eye examination using a large number of lenses of different optical powers and often a retinoscope a procedure entitled retinoscopy to measure objectively in which the person views a distant spot while the clinician changes the lenses held before the person s eye and watches the pattern of reflection of a small light shone on the eye Following that objective refraction the clinician typically shows the person lenses of progressively higher or weaker powers in a process known as subjective refraction Cycloplegic agents are frequently used to more accurately determine the amount of refractive error particularly in children 22 An automated refractor is an instrument that is sometimes used in place of retinoscopy to objectively estimate a person s refractive error 24 Shack Hartmann wavefront sensor and its inverse 25 can also be used to characterize eye aberrations in a higher level of resolution and accuracy Vision defects caused by refractive error can be distinguished from other problems using a pinhole occluder which will improve vision only in the case of refractive error citation needed Management EditThe management of refractive error is done post diagnosis of the condition by either optometrists ophthalmologists refractionists or ophthalmic medical practitioners 26 How refractive errors are treated or managed depends upon the amount and severity of the condition Those who possess mild amounts of refractive error may elect to leave the condition uncorrected particularly if the person is asymptomatic For those who are symptomatic glasses contact lenses refractive surgery or a combination of the three are typically used citation needed Glasses Edit These are the most effective ways of correcting the refractive error However the availability and affordability of eye glasses can present a difficulty for people in many low income settings of the world Glasses also pose a challenge to children to whom they are prescribed to due to children s tendency to not wear them as consistently as recommended 27 As mentioned earlier refractive errors are because of the improper focusing of the light in the retina Eyeglasses work as an added lens of the eye serving to bend the light to bring it to focus on the retina Depending on the eyeglasses they serve many functions 28 Reading glasses These are general over the counter glasses which can be worn for easier reading especially for defective vision due to aging called presbyopia Single vision prescription lenses They can correct only one form of defective vision either far sightedness or near sightedness Multifocal lenses The multifocal lenses can correct defective vision in multiple focus for example near vision as well as far vision This are particularly beneficial for presbyobia 29 Contact lenses Edit Alternatively many people choose to wear contact lenses One style is hard contact lenses which can distort the shape of the cornea to a desired shape Another style soft contact lenses are made of silicone or hydrogel Depending on the duration they are designed for they may be worn daily or may be worn for an extended period of time such as for weeks 26 There are a number of complication associated with contact lenses Typically the ones that are used daily Complications of contact lens wear DescriptionConjunctivitis giant papillary form Caused in response to the allergen present in the material from which the contact lens is made from There is often discomfort in the eye after wearing and vision may be affected Choosing the right lens material and changing it regularly might prevent conjunctivitis Corneal abrasion Caused by a foreign body dust sand or grit trapped under the lens Corneal edema Caused by decreased oxygen delivery to the tissue compressed by the lens Usually resolved after the removal of the lenses Discomfort upon lens removal may be seen Neovascularization New blood vessels may form in the iris region and the limbus This may impair vision Infections Various viral bacterial and fungal infection may be seen in the eye post contact lens wear if proper lens hygiene is not maintained Acanthamoeba are the most common infections in the people using contact lenses If redness itching and difficulty in vision develops the use of the lenses should be stopped immediately and the consultation of ophthalmologists may be sought Surgery Edit Laser in situ keratomileusis LASIK and photo refractive keratectomy PRK are popular procedures while use of laser epithelial keratomileusis LASEK is increasing Other surgical treatments for severe myopia include insertion of implants after clear lens extraction refractive lens exchange Full thickness corneal graft may be a final option for patients with advanced kerataconus although currently there is interest in new techniques that involve collagen crosslinking As with any surgical procedure complications may arise post operatively Post operative monitoring is normally undertaken by the specialist ophthalmic surgical clinic and optometry services Patients are usually informed pre operatively about what to expect and where to go if they suspect complications Any patient reporting pain and redness after surgery should be referred urgently to their ophthalmic surgeon citation needed Medical treatment Edit Atropine has believed to slow the progression of near sightedness and is administered in combination with multifocal lenses These however need further research 30 31 Prevention Edit Strategies being studied to slow worsening include adjusting working conditions increasing the time children spend outdoors 21 and special types of contact lenses 32 In children special contact lenses appear to slow worsening of nearsightedness 32 33 A number of questionnaires exist to determine quality of life impact of refractive errors and their correction 34 35 Epidemiology Edit nbsp DALYs per 100 000 people due to refractive errors in 2004 36 No data Less than 100 100 170 170 240 240 310 310 380 380 450 450 520 520 590 590 660 660 730 730 800 More than 800The number of people globally with refractive errors that have not been corrected was estimated at 660 million 10 per 100 people in 2013 9 Refractive Errors are the first common cause of Visual Impairment and second most common cause of visual loss 37 The assessment of Refractive Error is now done in DALY Disability Adjusted Life Years which showed an 8 increase from 1990 to 2019 38 unreliable source The number of people globally with significant refractive errors has been estimated at one to two billion 4 Rates vary between regions of the world with about 25 of Europeans and 80 of Asians affected 4 Near sightedness is one of the most prevalent disorders of the eye 5 Rates among adults are between 15 49 while rates among children are between 1 2 42 6 Far sightedness more commonly affects young children whose eyes have yet to grow to their full length and the elderly who have lost the ability to compensate with their accommodation system 7 8 Presbyopia affects most people over the age of 35 and nearly 100 of people by the ages of 55 65 1 Uncorrected refractive error is responsible for visual impairment and disability for many people worldwide 9 It is one of the most common causes of vision loss along with cataracts macular degeneration and vitamin A deficiency 10 Cost EditThe yearly cost of correcting refractive errors is estimated at 3 9 to 7 2 billion dollars in the United States 39 References Edit a b c d e f g h i j k l m n o p q r s Facts About Refractive Errors NEI October 2010 Archived from the original on 28 July 2016 Retrieved 29 July 2016 Care of the Patient with Amblyopia PDF Retrieved 17 February 2020 Dandona R Dandona L 2001 Refractive error blindness Bulletin of the World Health Organization 79 3 237 43 PMC 2566380 PMID 11285669 a b c d e Denniston Alastair Murray Philip 2018 Oxford Handbook of Ophthalmology 4 ed OUP Oxford p 926 ISBN 9780198816751 a b Foster PJ Jiang Y February 2014 Epidemiology of myopia Eye 28 2 202 8 doi 10 1038 eye 2013 280 PMC 3930282 PMID 24406412 a b Pan CW Ramamurthy D Saw SM January 2012 Worldwide prevalence and risk factors for myopia Ophthalmic amp Physiological Optics 32 1 3 16 doi 10 1111 j 1475 1313 2011 00884 x PMID 22150586 S2CID 32397628 a b Castagno VD Fassa AG Carret ML Vilela MA Meucci RD 23 December 2014 Hyperopia a meta analysis of prevalence and a review of associated factors among school aged children BMC Ophthalmology 14 163 doi 10 1186 1471 2415 14 163 PMC 4391667 PMID 25539893 a b Grosvenor Theodore 2007 Primary care optometry 5 ed St Louis Miss Butterworth Heinemann Elsevier p 70 ISBN 9780750675758 Archived from the original on 2016 08 15 a b c d Vos Theo Barber Ryan M Bell Brad Bertozzi Villa Amelia Biryukov Stan Bolliger Ian et al Global Burden of Disease Study 2013 Collaborators 22 August 2015 Global regional and national incidence prevalence and years lived with disability for 301 acute and chronic diseases and injuries in 188 countries 1990 2013 a systematic analysis for the Global Burden of Disease Study 2013 Lancet 386 9995 743 800 doi 10 1016 s0140 6736 15 60692 4 PMC 4561509 PMID 26063472 a b Pan CW Dirani M Cheng CY Wong TY Saw SM March 2015 The age specific prevalence of myopia in Asia a meta analysis Optometry and Vision Science 92 3 258 66 doi 10 1097 opx 0000000000000516 PMID 25611765 S2CID 42359341 Bope Edward T Kellerman Rick D 2015 Conn s Current Therapy 2016 Elsevier Health Sciences p 354 ISBN 9780323355353 Anisometropia American Association for Pediatric Ophthalmology and Strabismus aapos org Retrieved 10 February 2020 Aniseikonia EyeWiki eyewiki aao org Retrieved 10 February 2020 Millodot M In Dictionary of Optometry and Vision Science 8th ed Elsevier 2017 pp 291 Atchison DA Smith G Chapter 7 Refractive anomalies In Optics of the Human Eye Atchison DA Smith G editors Edinburgh Butterworth Heinemann 2000 pp 57 66 Thibos LN Wheeler W Horner D Power vectors an application of Fourier analysis to the description and statistical analysis of refractive error Optom Vis Sci 1997 74 6 367 75 Epub 1997 06 01 Thibos LN Applegate RA Schwiegerling JT Webb R Standards for reporting the optical aberrations of eyes Journal of refractive surgery Thorofare NJ 1995 2002 18 5 S652 60 Epub 2002 10 04 Converting Vision Between Diopters and 20 xx www iblindness org Retrieved 2020 05 13 a b Morgan Ian Kyoko Ohno Matsui May 2012 Myopia The Lancet 379 9827 1739 1748 doi 10 1016 S0140 6736 12 60272 4 PMID 22559900 S2CID 208793136 a b Wojciechowski Robert April 2011 Nature and Nurture the complex genetics of myopia and refractive error Clin Genet 79 4 301 320 doi 10 1111 j 1399 0004 2010 01592 x PMC 3058260 PMID 21155761 a b c d Wojcienchowski Robert April 2011 Nature and Nurture the complex genetics of myopia and refractive error Clinical Genetics 79 4 301 320 doi 10 1111 j 1399 0004 2010 01592 x PMC 3058260 PMID 21155761 a b Barnes Katherine Feb 2013 Genome wide meta analyses of multiancestry cohorts identify multiple new susceptibility loci for refractive error and myopia Clinical Genetics 45 3 314 8 doi 10 1111 j 1399 0004 2010 01592 x PMC 3740568 PMID 23396134 Owji N Khalili MR Bazrafkan H Heydari M September 2022 Long term outcome of refractive errors in patients with congenital blepharoptosis who have undergone ptosis surgery Clinical amp experimental optometry 105 7 715 720 doi 10 1080 08164622 2021 1973344 PMID 34538220 Frequently Asked Questions How do you measure refractive errors The New York Eye And Ear Infirmary Archived from the original on 2006 09 01 Retrieved 2006 09 13 NETRA Inverse Shack Hartmann Wavefront Sensor using High Resolution Mobile Phone Display Vitor F Pamplona Ankit Mohan Manuel M Oliveira Ramesh Raskar Archived from the original on 2011 12 21 Retrieved 2011 12 13 a b Cochrane Gillian M Toit Renee du Mesurier Richard T Le 2010 04 12 Management of refractive errors BMJ 340 c1711 doi 10 1136 bmj c1711 ISSN 0959 8138 PMID 20385718 S2CID 8240093 Wedner S Masanja H Bowman R Todd J Bowman R Gilbert C 2008 01 01 Two strategies for correcting refractive errors in school students in Tanzania randomised comparison with implications for screening programmes British Journal of Ophthalmology 92 1 19 24 doi 10 1136 bjo 2007 119198 ISSN 0007 1161 PMID 18156372 S2CID 2157969 Pediatric Ophthalmology Optometry and Orthoptics Asian Eye Institute Retrieved 2022 08 03 Eyeglasses for Refractive Errors National Eye Institute www nei nih gov Retrieved 2021 06 29 Shih Yung Feng Hsiao C Kate Chen Chien Jen Chang Ching Wei Hung Por T Lin Luke L K June 2001 An intervention trial on efficacy of atropine and multi focal glasses in controlling myopic progression Acta Ophthalmologica Scandinavica 79 3 233 236 doi 10 1034 j 1600 0420 2001 790304 x ISSN 1395 3907 PMID 11401629 Lee Jong Jer Fang Po Chiung Yang I Hui Chen Chih Hsin Lin Pei Wen Lin Sue Ann Kuo Hsi Kung Wu Pei Chang February 2006 Prevention of Myopia Progression with 0 05 Atropine Solution Journal of Ocular Pharmacology and Therapeutics 22 1 41 46 doi 10 1089 jop 2006 22 41 ISSN 1080 7683 PMID 16503774 a b Li X Friedman IB Medow NB Zhang C 1 May 2017 Update on Orthokeratology in Managing Progressive Myopia in Children Efficacy Mechanisms and Concerns Journal of Pediatric Ophthalmology and Strabismus 54 3 142 148 doi 10 3928 01913913 20170106 01 PMID 28092397 Walline JJ January 2016 Myopia Control A Review Eye amp Contact Lens 42 1 3 8 doi 10 1097 ICL 0000000000000207 PMID 26513719 S2CID 24069302 Kandel H Khadka J Goggin M Pesudovs K 2017 Patient reported outcomes for assessment of quality of life in refractive error a systematic review Optometry and Vision Science 94 12 1102 1119 doi 10 1097 OPX 0000000000001143 PMID 29095758 S2CID 21512136 Kandel H Khadka J Lundstrom M Goggin M Pesudovs K 2017 Questionnaires for measuring refractive surgery outcomes Journal of Refractive Surgery 33 6 416 424 doi 10 3928 1081597X 20170310 01 PMID 28586503 WHO Disease and injury country estimates World Health Organization 2009 Archived from the original on 2009 11 11 Retrieved Nov 11 2009 Hashemi Hassan Fotouhi Akbar Yekta Abbasali Pakzad Reza Ostadimoghaddam Hadi Khabazkhoob Mehdi 2017 09 27 Global and regional estimates of prevalence of refractive errors Systematic review and meta analysis Journal of Current Ophthalmology 30 1 3 22 doi 10 1016 j joco 2017 08 009 ISSN 2452 2325 PMC 5859285 PMID 29564404 Global Disease Burden of Uncorrected Refractive Error Among Adolescents From 1990 to 2019 PDF Archived from the original PDF on 2021 06 24 Retrieved 2023 03 21 Kuryan J Cheema A Chuck RS 2017 Laser assisted subepithelial keratectomy LASEK versus laser assisted in situ keratomileusis LASIK for correcting myopia Cochrane Database Syst Rev 2017 2 CD011080 doi 10 1002 14651858 CD011080 pub2 PMC 5408355 PMID 28197998 External links Edit Retrieved from https en wikipedia org w index php title Refractive error amp oldid 1178926431, wikipedia, wiki, book, books, library,

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