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continuing_education_activitystatpearls· Continuing Education Activity· item NBK560716

Hyperopia is a very common refractive condition of childhood and adults. Proper assessment and treatment can prevent multiple complications in the future. Adult hyperopia is associated with some complications which must be assessed at regular interval. This activity reviews the evaluation and management of hyperopia with the prevention of long term complications. Objectives: Identify the etiology of hyperopia and their associations. Review the process for performing an ocular evaluation of hyperopia. Summarize the treatment options available for hyperopia according to age and degree of hyperopia. Describe some interprofessional team strategies for improving care coordination and communication to treat hyperopia and improve outcomes. Access free multiple choice questions on this topic.

introductionstatpearls· Introduction· item NBK560716

The most common refractive error in childhood is hyperopia.[1] The term hyperopia refers to the refractive condition of the eye where parallel light rays coming from the infinity are focussed behind the neurosensory retina (after refraction through the ocular media ) when accommodation is at rest. The spontaneous accommodative effort of the human eye, by increasing the anterior curvature and converging power of the crystalline lens, usually tries to overcome this situation. So, accommodative rest is mandatory to elicit total hyperopia, specifically in young individuals.[2] By birth, human beings are predominantly hyperopic, and as the age progresses, hyperopic eyeballs grow to become emmetropic or even myopic.[3][4] Positive family history plays a crucial role in the development of hyperopia in the next generations.[5] If left untreated after diagnosis, sequelae such as amblyopia and tropia may develop.[6][7][6]

etiologystatpearls· Etiology· item NBK560716

Conventionally the hyperopia is etiologically classified into: Axial hyperopia (most common - simple hyperopia): It is due to anterior-posterior axial shortening of the eyeball. Genetic predisposition plays an important role. Retinal edema can cause a hyperopic shift. 1 mm decrease in axial length leads to 3 diopters of hyperopia.[8] Curvature hyperopia: It is due to flattening of the cornea or the lens or both. A radius of curvature increase in 1 mm leads to 6 diopters of hyperopia. Index hyperopia: It is due to the change in the refractive index of the crystalline lens, which occurs in old age or diabetics. The refractory index gradually increases from the center to the periphery. Positional hyperopia or absence of the lens (aphakia) or ocular pathologic conditions: This condition occurs due to malposition or absence of the crystalline lens (congenital or acquired) or intraocular lens owing to the creation of an aphakic zone in refractive media. Post-traumatic or post-surgical aphakia is not an uncommon cause of hyperopia. Few ocular pathologies, e.g., nanophthalmos, microphthalmos, aniridia, may cause hyperopia. No unanimous causative factor is identified to date. Though sporadic, few genetic factors have been identified in association with hyperopia. Apart from genetic and environmental factors, few acquired conditions are also responsible, specifically in aged persons.[9] The following are a few identified conditions leading to hyperopia: 16p11.2 microdeletion[10] Myelin regulatory factor gene (MYRF) mutation[11] Family history of squint, and a history of maternal smoking during pregnancy[12] Cortical cataract (index hyperopia) Aphakia (congenital or acquired)[13] Hyperglycemia[14] Diabetes mellitus and after prompt control of hyperglycemia in diabetes mellitus[15][16] Prolonged space mission due to retina and optic nerve head edema[17] Peripapillary pachychoroid syndrome (PPS)[18] Heimler syndrome[19] Kenny syndrome[20] Accommodation loss due to complete CN III nerve palsy or internal ophthalmoplegia or paralysis by cycloplegic drops, lorazepam (functional hyperopia)[21][22][21] After silicone oil injection in phakic and pseudophakic eyes. In aphakic eyes, the amount of hyperopia reduces, but the eye remains hyperopic Loeys-Dietz syndrome, Larsen syndrome.[23] Leber congenital amaurosis X-linked retinoschisis and senile retinoschisis

epidemiologystatpearls· Epidemiology· item NBK560716

Axial hyperopia, being the commonest, is usually present from birth.[3] The prevalence of moderate hyperopia, i.e., ≥ +2 diopter at 6 and 12 years of age, is 13.2% and 5.0%, respectively, and it is more in White race individuals than in other ethnic groups.[24] The prevalence of hyperopia ≥+4 diopter was 3.2% in the worse eye, with both eyes involved in 64.4% of cases in a study.[12] For United States participants, non-Hispanic, and Hispanic White races have a significantly higher risk of hyperopia in 6 to 72 months of age group.[12] In 15 years or less age group, and ≥30 years age group, hyperopia prevalence was higher in females.[25] A systematic review of refractive error revealed that the prevalence of hyperopia is 4% (less than myopia) in the population with more prevalence in school going boys than girls.[26] In the United States, for the ≥20 years age group, hyperopia is the least common refractive error while it was the most common refractive error with astigmatism in the ≥60 years age group.[27] In Polish immigrants in Chicago, a study found that hyperopia is a more common refractive error overall and in the >45 years age group.[28] In the 6 to 15 years age group in Cameroon, hyperopia is the most common refractive error.[29] Hyperopia is unrelated to posterior subcapsular cataracts but is related to incident nuclear and cortical cataract.[30] The intelligence quotient score in hyperopic patients was lower than that of myopic in a study conducted in the United Kingdom.[31] A higher prevalence of hyperopia is seen in people living in rural areas compared to urban areas.[32] Hyperopia is more prevalent in families with a history of accommodative esotropia and hyperopia, and 20% of the hyperopic individuals in infancy develop strabismus.[5]

pathophysiologystatpearls· Pathophysiology· item NBK560716

The axial shortening of the eyeball or decreased converging potential of the cornea or crystalline lens due to flattening are common responsible factors for simple hyperopia. Congenital or acquired absence of the crystalline lens resulting in loss of converging capacity leads to the pathological hyperopia. Senile changes in cortical lens fibers lead to change in the refractive index causing index hyperopia. Paralysis of accommodation (by cycloplegic drugs) and loss of accommodation due to complete third nerve palsy or internal ophthalmoplegia cause functional hyperopia.[22][21] Accommodation is a dynamic factor in controlling the state of refraction, specifically in hyperopia. Depending on the accommodation, manifest hyperopia may subdivide into: Absolute hyperopia, which can not be overcome by accommodative effort When a patient can not see 20/20 without glasses, absolute hyperopia is denoted by the weakest plus lens with which the patient can see 20/20. Facultative hyperopia which can be overcome by accommodation The manifest hyperopia is the sum of absolute and facultative hyperopia. Clinically, it is measured by the strongest plus (or convex) lens with which the patient can still maintain the maximum vision (20/20). Latent hyperopia is due to the inherent ciliary muscle tone. Usually, the magnitude of latent hyperopia is 1D, but it is higher at an early age and gradually decreases as age progresses. Cycloplegic agents like atropine unmask this condition. This latent hyperopia causes asthenopic symptoms without dimness of distant vision. Cycloplegia is a must to elicit the amount of latent hyperopia in children. Total hyperopia = Latent hyperopia + manifest hyperopia Manifest hyperopia = Absolute hyperopia + facultative hyperopia

history_and_physicalstatpearls· History and Physical· item NBK560716

Depending on the age of presentation and the degree of hyperopia, clinical presentation varies from no symptom to a wide range of complaints. Age is an important factor not only due to the ability to express but also the accommodative effort of the patient. Asymptomatic: The patient's inherent ciliary muscle tone and accommodative effort can overcome some degree of hyperopia without creating any difficulty. Symptomatic: Deviation of eyes (noted by the parents) [33] [34] : Parents sometimes note deviation of either or both eyes (simultaneous or alternative) in very young children with hyperopia. The commonest type is an inward deviation (esotropia). Asthenopia: With total accommodative effort, the patient's hyperopia is corrected here. In these cases, asthenopia (i.e., varied amount of tiredness of eyes with localized frontal/frontotemporal headache) is a very common symptom due to prolonged accommodative effort. Sometimes it may be associated with photophobia and watering. Usually, asthenopia increases after near activity of long-duration. Dimness of vision: There will be dimness of vision if existing hyperopia is not corrected with total accommodative effort. In hyperopia, infinity focuses beyond the neurosensory retina. So, nearer objects focus behind the retina. Characteristically the defective vision affects near vision more than distant vision. Thus, the objects appear more blurred as they come closer. This dimness may (small amount of hyperopia) or may not (a large amount of hyperopia or after 40 years of age when accommodation is lost) be associated with asthenopia. A significant difference in uncorrected hyperopia may predispose the worse eye to develop amblyopia. Uncorrected hyperopia of both the eyes may develop ametropic amblyopia bilaterally. Sudden blurring of vision (intermittent)[35]: Due to prolonged accommodative effort (e.g., during reading), there may be an episode of accommodative spasm leading to a sudden blurring of vision, often termed as pseudomyopia. It is commonly found in teenagers with uncorrected hyperopia.

history_and_physicalstatpearls· History and Physical· item NBK560716

Dimness of vision: There will be dimness of vision if existing hyperopia is not corrected with total accommodative effort. In hyperopia, infinity focuses beyond the neurosensory retina. So, nearer objects focus behind the retina. Characteristically the defective vision affects near vision more than distant vision. Thus, the objects appear more blurred as they come closer. This dimness may (small amount of hyperopia) or may not (a large amount of hyperopia or after 40 years of age when accommodation is lost) be associated with asthenopia. A significant difference in uncorrected hyperopia may predispose the worse eye to develop amblyopia. Uncorrected hyperopia of both the eyes may develop ametropic amblyopia bilaterally. Sudden blurring of vision (intermittent)[35]: Due to prolonged accommodative effort (e.g., during reading), there may be an episode of accommodative spasm leading to a sudden blurring of vision, often termed as pseudomyopia. It is commonly found in teenagers with uncorrected hyperopia. Recurrent Internal/External Hordeolum or Conjunctivitis: The exact mechanism of the recurrent eyelid or conjunctival inflammation is unrevealed. The proposed theory is the frequent rubbing of the eyes with unhygienic hands, which leads to recurrent inflammatory episodes. Proper treatment of recurrent inflammation helps to get good best-corrected visual acuity in the future and vice-versa.[36] A sensation of Crossed Eye: Prolonged sustained accommodation is sometimes felt as a crossed eye. The patient may complain that the eyes are crossing each other (due to convergence) without any diplopia. Ignorance towards this symptom in the pre-school age group may lead to amblyopia in the future.[37] Premature Presbyopia: As the age progresses, obvious receding of the near point becomes apparent. It occurs earlier (earlier than the 40s) in hyperope than emmetrope. The progressive accommodation loss with age is more frustrating to the patient as the near vision was already compromised earlier due to hyperopia.

evaluationstatpearls· Evaluation· item NBK560716

A thorough clinical evaluation not only helps to diagnose hyperopia but also points out significant related events. Visual Acuity: It depends on the age at presentation, degree of accommodation, and status of the crystalline lens and posterior segment. In children, the vision may not be affected due to a full accommodative effort to focus the image on the retina. As the status of the eye is usually not complicated by cataract and retinal diseases in children, distant vision may be affected with high hyperopia, which can not be corrected by the full range of accommodation. There may be a gross reduction of vision if amblyopia develops in unilateral or bilateral high hyperopia cases. Near vision may also be diminished in children with high hyperopia or in aged where accommodation is partially or fully lost. An age-related hyperopic shift can make near vision more difficult. Diffuse light examination: Eyeball and cornea may appear smaller, especially in high hyperopia and in unilateral cases. Sometimes it may simulate enophthalmos. Anterior chamber (both central and peripheral) appears shallow, and the angle of the anterior chamber may appear narrow with a small pupil. Gonioscopy is indicated in all cases to rule out possible angle closure. Cortical cataracts may also be present in aged persons or young individuals with diabetes. Fundoscopy: Fundoscopy reveals a small optic disc with a very small cup. Disc margins become blurred with overcrowding of blood vessels, sometimes termed as "pseudopapillitis" or "pseudo-papilledema" if bilateral. Choroidal folds may be present.[38][39] An increased reflex of retina named as "shot-silk appearance" is seen along with crowding of the nerve fiber layer.[40] Examination of Latent / Manifest strabismus: In children having uncorrected hyperopia for a long duration, strabismus may be present: latent (-phoria) or manifest (-tropia). Extraocular movement is usually full in all directions of gazes. Breaking the fusion by Alternate Cover-Uncover test with occluder and asking the patient to focus at a point light source may reveal latent strabismus, mainly in children and young. Alternate and sequential shifting of the occluder to cover either eye is done. The presence of latent strabismus is confirmed if the covered eye deviates, which is noted during refixation when uncovered.

evaluationstatpearls· Evaluation· item NBK560716

Breaking the fusion by Alternate Cover-Uncover test with occluder and asking the patient to focus at a point light source may reveal latent strabismus, mainly in children and young. Alternate and sequential shifting of the occluder to cover either eye is done. The presence of latent strabismus is confirmed if the covered eye deviates, which is noted during refixation when uncovered. In manifest strabismus, the deviated eye takes fixation after occlusion of the fellow orthophoric eye. Manifest strabismus must be examined by Hirschberg corneal reflex test (HCRT) and with a prism bar to note the degree of deviation. HCRT reveals the approximate degree of deviation i.e., corneal light reflex on the pupillary border and the corneal border corresponds to approximately 15 degrees and 45 degrees of deviation, respectively. Prisms can also serve to keep the apex towards the deviation to bring the corneal light reflex at the center and note that deviation in prism-diopter. Retinoscopy/Refraction: In the modern era of automated refraction, retinoscopy has its importance while examining young children and bed-ridden patients. It's a good practice to evaluate a child with suspected any refractive error with cycloplegic retinoscopy[41] from a 1-meter distance as routine. Cycloplegia abolishes ciliary muscle tone and accommodation to reveal the actual status of refraction. With a streak retinoscope, under cycloplegia, different powered-spherical lenses are used to reach a neutralization point (full illumination of the fundus with no movement) both in the horizontal and vertical axis. Existing refractive error (in horizontal/vertical axis) = Retinoscopic findings (in both axis) - the value of distance in meter (1 for 1 meter, 1.5 for 2/3rd meter) - tonus allowance for the particular cycloplegic drug (For atropine ointment 1% it is 1, cyclopentolate drops 1% it is 0.75, and for homatropine drops 2% it is 0.5) If both the axis and the power (after deduction) are equal, then that is considered as the spherical refractive power of the eye. If it is unequal, then the extra power (in one axis) is denoted as the astigmatic power in the other axis.