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Subjective refraction

Subjective refraction is a clinical technique in optometry and ophthalmology used to determine an individual's eyeglass or contact lens prescription by assessing refractive errors through the patient's subjective feedback on lens clarity, typically employing spherical and cylindrical lenses to achieve the best-corrected visual acuity with relaxed accommodation.^[1] This method relies on patient responses during a structured examination, often using a phoropter or trial frame to present lens combinations while the individual views a visual acuity chart, such as a Snellen chart, and indicates preferences for sharper vision.^[2] The procedure generally begins with an objective refraction, like retinoscopy or autorefraction, to establish a baseline, followed by subjective refinement to account for personal visual preferences and binocular balance.^[1] Key steps include adjusting spherical power in small increments (e.g., 0.25 diopters), determining cylinder axis and power via techniques like the Jackson cross-cylinder or astigmatic fan, and verifying with tools such as the duochrome test, where patients compare red and green clarity to fine-tune the prescription.^[1] Subjective refraction is essential for prescribing corrective lenses that optimize distance and near vision, playing a critical role in preventing amblyopia in pediatric cases through timely intervention and aiding in the diagnosis of conditions like keratoconus or early cataracts by revealing discrepancies in refractive status.^[1] Its accuracy depends on patient cooperation, making it challenging for young children, non-verbal individuals, or those with cognitive impairments, where alternative objective methods may be prioritized.^[1] Historically, techniques like the Jackson cross-cylinder, developed by Edward Jackson in the early 20th century,^[3] have standardized the process, ensuring reliable outcomes within 0.25 to 0.50 diopters when performed by skilled practitioners.^[1]

Overview and Principles

Definition and Purpose

Subjective refraction is a clinical technique in optometry and ophthalmology that determines the optimal spectacle or contact lens prescription through the patient's verbal feedback on visual clarity during trials with various lens combinations. This method assesses and corrects refractive errors, including myopia (nearsightedness), hyperopia (farsightedness), astigmatism, and presbyopia (age-related loss of near focus), by systematically adjusting spherical and cylindrical lenses to find the combination yielding the best-corrected visual acuity under relaxed accommodation.^[1]^[4] The primary purpose of subjective refraction is to refine initial objective measurements, such as those from retinoscopy or autorefraction, to achieve the clearest possible distance and near vision while ensuring patient comfort and minimizing visual distortions like blur or asthenopia. By incorporating the patient's subjective perception of lens improvements—which accounts for individual factors like tolerance to over- or under-correction—this approach personalizes the prescription beyond automated or objective techniques alone, often resulting in enhanced binocular vision and reduced symptoms of refractive imbalance.^[1] Historically, subjective refraction emerged in the mid-19th century alongside advancements in trial lens sets, with the first documented trial case attributed to German physician Georg Fronmüller in 1843, enabling precise, patient-driven lens testing. This technique was further systematized by Dutch ophthalmologist Frans Cornelis Donders in his seminal 1864 publication, On the Anomalies of Accommodation and Refraction of the Eye, which classified refractive errors and emphasized subjective evaluation for accurate correction.^[5]^[6] At its core, subjective refraction relies on the patient's active responses to comparative lens choices, distinguishing it from objective methods that provide a baseline but may not fully capture perceptual nuances.^[1]

Indications and Prerequisites

Subjective refraction is indicated for patients capable of providing reliable verbal feedback, generally those aged 6 years and older, to refine spectacle or contact lens prescriptions during routine eye examinations, contact lens fittings, and postoperative assessments following cataract surgery.^[1]^[7]^[8] It serves as an essential method for correcting common refractive errors such as myopia, hyperopia, and astigmatism, as well as in conditions like keratoconus or early-stage cataracts where discrepancies exist between visual acuity and other clinical findings.^[1] Key prerequisites for performing subjective refraction include the patient's possession of adequate cognitive ability, cooperation, and steady fixation to accurately respond to inquiries about lens clarity during testing.^[1] Additionally, it must follow an initial objective refraction—typically via retinoscopy or autorefraction—to provide a baseline lens power and sphere/cylinder starting point, enhancing the precision and efficiency of the subjective refinement process.^[1]^[9] Patient selection emphasizes excluding individuals unlikely to yield reliable results, such as children under 6 years who cannot consistently follow instructions, those with cognitive impairments or developmental delays, patients facing communication barriers (e.g., language differences, deafness, or mutism), and cases involving severe ocular media opacities that prevent clear visualization of the refractive target.^[1]^[7]^[10] In these scenarios, reliance shifts to objective methods alone to determine the prescription. Within a comprehensive eye examination, subjective refraction occurs after gathering the patient's visual history and conducting preliminary objective tests, positioning it as a pivotal refinement step that informs the final prescription recommendations and ensures personalized visual optimization.^[2]^[9] This integration helps confirm refractive errors identified earlier and addresses any subjective nuances in the patient's visual experience.

Equipment and Setup

Required Equipment

Subjective refraction relies on specialized ophthalmic equipment to enable precise patient feedback during the determination of optimal lens corrections. The core instrument is the phoropter, a motorized or manual refractor that positions trial lenses directly in front of the eyes for efficient sphere, cylinder, and axis adjustments.^[1] As an alternative, particularly for pediatric or low-vision patients, a trial frame holds individual lenses from a trial lens set, offering greater comfort and peripheral vision.^[1] Visual acuity assessment requires standardized charts: a distance chart such as the Snellen or Early Treatment Diabetic Retinopathy Study (ETDRS) chart, calibrated for 6-meter (20-foot) testing to evaluate far vision clarity.^[1] For near refraction, a near vision card—typically featuring Jaeger or Snellen N5 to N48 notations—is essential to assess accommodation and presbyopia.^[1] An occluder paddle isolates monocular vision by covering one eye, preventing binocular interference, while a penlight facilitates pupil dilation checks or steady fixation targets.^[1] Lens specifications in the trial set or phoropter must cover a broad range to accommodate most refractive errors: spherical lenses from 0.12 diopters (D) to +20 D, incremented in 0.25 D steps for fine-tuning myopia, hyperopia, and presbyopia.^[11] Cylindrical lenses extend up to ±6 D in 0.25 D steps, with axis markings at 5- or 10-degree intervals to correct astigmatism orientation.^[11] Prisms, typically ranging from 0.5 to 12 prism diopters (Δ) in 0.5 Δ steps, support alignment evaluations when refractive imbalances suggest heterophoria.^[11] Key accessories include the Jackson cross-cylinder, available in ±0.25 D or ±0.50 D configurations, which uses crossed cylindrical lenses at 90-degree axes to pinpoint astigmatism power and axis with high precision.^[1] The duochrome test incorporates a chart with red and green filters or backgrounds, leveraging differential focus on wavelengths to refine spherical endpoints.^[1] To prevent measurement errors, equipment maintenance is paramount: regular cleaning of lenses and charts with manufacturer-approved, non-abrasive solutions removes contaminants that could introduce artifacts like blur or glare, compromising patient responses.^[12] Regular professional calibration (typically every 6-12 months) verifies phoropter mechanics and lens accuracies, ensuring reliable dioptric placements and avoiding prescription inaccuracies from misalignment or wear.^[13]

Patient Positioning and Environment

The patient should be seated comfortably in a chair at a standard distance of 6 meters (20 feet) from the visual acuity chart to approximate infinity focus for distance refraction, allowing for accurate assessment of refractive errors without significant accommodative demand.^[14] The head is positioned using the chin rest and forehead band of the phoropter or trial frame, with the eyes aligned horizontally to the optical center of the instrument to ensure proper pupillary alignment and minimize vertex distance errors.^[15] This setup promotes stable fixation and reduces head movement, which could otherwise introduce artifacts in the subjective responses. The examination room must be prepared with controlled lighting to optimize test reliability, featuring dim ambient illumination to reduce stray light and glare while evenly illuminating the chart at 400-600 lux for high contrast without reflections.^[16] The environment should be free from distractions, such as noise or visual clutter, to maintain patient focus; clear instructions are provided beforehand, such as asking "Which lens makes the letters clearer, number 1 or number 2?" to guide binary responses and enhance comfort during the process. Hygiene protocols are essential for patient safety, including the use of disposable occluders or thorough sanitization of shared equipment like trial lenses with alcohol wipes between uses to prevent cross-contamination.^[17] Practitioners should monitor for signs of patient fatigue, such as inconsistent responses, and incorporate brief breaks if needed to sustain accuracy.^[1] For patients with low vision, adaptations include employing larger optotype charts or shortening the testing distance to 4 meters or less, which facilitates clearer perception and more reliable subjective feedback without altering the core principles of the procedure. These modifications, often combined with trial frames for a more natural viewing experience, help accommodate reduced acuity while prioritizing patient comfort.

Procedure

Initial Assessments

Before commencing the subjective refraction procedure, initial assessments establish baseline visual function and ensure appropriate conditions for accurate patient responses. The first step involves measuring unaided visual acuity to determine the starting point of refractive error. Distance visual acuity is typically evaluated for each eye separately (OD, OS) and binocularly (OU) using a Snellen chart or equivalent at 6 meters, with overhead lighting to avoid inaccuracies from dim conditions.^[9]^[18] For patients with near vision concerns or presbyopia, near acuity is documented at 40 cm using M-notation, helping to estimate add power needs.^[9] These measurements confirm the extent of uncorrected ametropia and serve as a reference for achieving best-corrected visual acuity.^[1] A cover test is performed to assess for phorias or tropias, identifying any need for prism correction that could affect refractive outcomes. The cover-uncover test detects tropias by occluding one eye and observing refixation movement in the uncovered eye, while phorias are revealed by movement in the occluded eye upon uncovering.^[19] Conducted at distance (6 m) and near (33 cm), it uses an opaque occluder and may incorporate prisms to quantify deviations in prism diopters, serving as the gold standard for evaluating ocular alignment before proceeding.^[19] Abnormal findings, such as esophoria or exotropia, guide adjustments to avoid exacerbating misalignment during lens trials.^[19] Throughout these assessments, clear patient instructions are provided to elicit reliable feedback and ensure cooperation. Patients are oriented to the trial process, explaining that they will compare lens options and respond based on clarity, such as "which is clearer: choice one or choice two?" or if they appear equally clear.^[9] They are reminded to focus on the chart without fixating on the examiner or lights, and responses should prioritize sharpness over brightness differences.^[18] For indecisive patients, reassurance is given that subtle differences are normal, and the scale (clearer, blurrier, or equal) is reiterated to minimize confusion and optimize accuracy.^[9]

Step-by-Step Refraction Process

Subjective refraction begins with the objective refractive error obtained from prior assessments, such as retinoscopy or autorefraction, serving as a starting point for patient-driven refinements. The process relies on trial lenses in a phoropter or trial frame, with the patient providing feedback on visual clarity, typically using a Snellen chart at 20 feet or 6 meters. Adjustments are made in small increments, usually 0.25 diopters (D), to achieve the clearest vision while minimizing accommodative effort and ensuring patient comfort.^[1]^[9] Spherical refraction is typically performed first on each eye monocularly, starting with the objective spherical power. To relax accommodation, the examiner adds a fogging lens of +0.50 D to +0.75 D, which blurs vision slightly, then gradually reduces it in 0.25 D steps until the patient reports the clearest possible acuity without further improvement. For hyperopia, the goal is the maximum plus power that maintains sharp vision; for myopia, the minimum minus power is used to avoid over-correction, confirmed by asking the patient which lens option makes the letters clearer or darker. This endpoint ensures optimal spherical correction with relaxed accommodation.^[1]^[2]^[9] Following spherical adjustment, cylindrical refinement addresses astigmatism if present in the objective findings. The Jackson cross-cylinder (JCC), a ±0.25 D or ±0.50 D lens, is used to fine-tune the cylinder axis and power. For axis determination, the JCC handle is aligned parallel to the trial cylinder axis, and the patient is asked which meridian appears clearer as the cylinder is rotated in 5° to 15° increments until no preference is noted. Power is then verified by flipping the JCC with its axis perpendicular to the trial cylinder; if one position improves acuity, the cylinder power is adjusted by 0.25 D or 0.50 D while maintaining the spherical equivalent through compensatory spherical changes. Patient responses, such as "which is better, number one or number two?", guide these refinements to neutralize the astigmatic blur.^[1]^[9]^[2] Refraction proceeds monocularly for each eye before binocular integration to avoid suppression or fusion influences. Once both eyes are corrected individually, binocular balancing equalizes the accommodative demand between eyes using techniques like alternate occlusion or prism dissociation. The examiner adds +0.50 D to +0.75 D fogging to both eyes, then alternately occludes one eye while asking the patient to compare clarity; adjustments of 0.25 D are made to the less clear eye until equal vision is reported or the dominant eye is slightly preferred. This step ensures comfortable binocular vision without strain.^[1]^[9] For presbyopic patients over age 40, a near addition is determined after distance correction by presenting a near chart at 40 cm and incrementally adding plus lenses in 0.25 D or 0.50 D steps until the patient achieves clear near vision at the working distance, typically ranging from +1.00 D to +2.50 D based on age and amplitude of accommodation.^[1]^[9] The overall endpoint of the process is the lens combination yielding the best possible visual acuity—often 20/20 or better—with the least accommodative effort, verified by stable patient responses and no further gains from pinhole testing. Patient comfort is prioritized throughout, with instructions to report any strain, blur, or preference clearly, ensuring the prescription supports daily visual demands without inducing fatigue.^[1]^[2]

Duochrome Test Integration

The duochrome test, also known as the bichrome test, is integrated into subjective refraction to refine the spherical endpoint by leveraging the eye's chromatic aberration. This principle exploits the differential focusing of light wavelengths due to the refractive properties of ocular media, where shorter wavelengths like green (approximately 535 nm) focus slightly in front of the retina (about 0.20 D anterior), while longer wavelengths like red (approximately 620 nm) focus behind it (about 0.24 D posterior), relative to yellow light (570 nm) that aligns with the retina in emmetropia.^[1] Consequently, if the patient is underplussed (myopic), letters on the red background appear sharper because the red focus aligns closer to the retina; conversely, if overplussed (hyperopic), green letters appear clearer as the green focus is nearer the retina.^[20]^[21] In practice, the test is performed after the initial spherical trial lens has been tentatively determined during the refraction process. The patient, with one eye occluded and under dim illumination to minimize accommodation, views a duochrome chart—typically featuring identical lines of letters or symbols divided into red and green halves (spanning visual acuities from 20/30 to 20/20)—through the trial frame with the current correction in place.^[20] The examiner then incrementally adjusts the spherical lens in 0.25 D steps: adding plus power (+0.25 DS) if green letters predominate, or minus power (-0.25 DS) if red letters are clearer, continuing until the patient reports equal legibility across both backgrounds, indicating the neutral point where yellow light focuses on the retina.^[21] This endpoint typically requires no more than ±0.50 D adjustment for reliability.^[20] The duochrome test is particularly applied to confirm the spherical correction approaching emmetropia, especially in cases of low astigmatism where it helps balance the spherical equivalent without introducing undue accommodative effort.^[1] It proves valuable for pediatric patients or those expressing uncertainty during refraction, as the binary comparison of color backgrounds simplifies decision-making and reduces subjective bias.^[21] However, its utility is limited in the context of high astigmatism, where cylindrical corrections may distort the chromatic balance and render the test unreliable.^[20] Additionally, it should not be used in patients with color vision defects, such as congenital or acquired dyschromatopsia, as impaired discrimination between red and green wavelengths undermines the assessment.^[21]

Recording and Analysis

Documentation Techniques

Documentation of subjective refraction outcomes follows standardized sphero-cylindrical notation to ensure clarity and precision in recording refractive errors. Results are typically expressed in either plus cylinder or minus cylinder form, with optometrists commonly using minus cylinder notation and ophthalmologists preferring plus cylinder. For instance, a minus cylinder prescription might be recorded as OD -2.00 D -1.00 D × 60° to indicate a spherical correction of -2.00 diopters, a cylindrical correction of -1.00 diopter at an axis of 60 degrees for the right eye. For presbyopic patients requiring bifocal or progressive addition lenses, the near addition power is appended, such as ADD +2.50 D, to specify the additional positive power for near vision tasks. Visual acuity achieved with the final correction is always included, e.g., best-corrected visual acuity (BCVA) of 20/20, alongside uncorrected distance visual acuity (UDVA) if relevant.^[1]^[22]^[23] Tools for documentation include traditional prescription pads for handwritten entries, electronic health records (EHR) systems for digital input, or direct transcription from phoropter dials immediately following the procedure to minimize errors from memory lapse. In clinical settings, refraction findings are entered into patient charts or specialized optometry software that supports standardized fields for sphere, cylinder, axis, add power, and associated visual acuities. Immediate recording is essential, as delays can lead to inaccuracies in capturing the exact endpoint of patient responses during the refraction process.^[22]^[9] Best practices emphasize comprehensive notation of patient-specific details to support reliable follow-up care. Clinicians should document key patient responses, such as preferences during fogging or duochrome testing, and note any inconsistencies or multiple trials conducted to refine the prescription, particularly in cases of unreliable verbal feedback. The achieved visual acuity, both distance and near if applicable, must be recorded using Snellen or logMAR notation to verify the correction's efficacy. Additionally, relevant negatives, such as stable findings from prior exams, should be indicated to provide context for longitudinal monitoring.^[1]^[22]^[9] From a legal and ethical standpoint, refraction records must be clear, accurate, and legible to facilitate proper prescription dispensing and patient safety. Regulations like the U.S. Federal Trade Commission's Eyeglass Rule (as amended in 2024) mandate that prescribers provide a copy of the prescription to the patient upon completion of the exam, obtain the patient's written or electronic acknowledgment of receipt, and retain acknowledgment records for 3 years, regardless of whether eyewear is purchased on-site, ensuring access to the documented results for independent fulfillment.^[24]^[25] In jurisdictions such as the UK, compliance with data protection laws requires secure storage of records, with retention periods of at least 10 years for adults to support accountability and continuity of care. Incomplete or ambiguous documentation can lead to dispensing errors or legal liabilities, underscoring the need for standardized, verifiable entries.^[22]

Result Interpretation

Following subjective refraction, clinicians analyze the recorded results by comparing them to objective refraction measurements, such as those obtained from retinoscopy or autorefraction, to identify discrepancies and ensure alignment with the patient's refractive status.^[1] This comparison helps detect potential over-correction (excessive plus power leading to reduced acuity) or under-correction (insufficient minus power causing blur), which may necessitate fine-tuning the spherical component in 0.25 diopter increments.^[2] Additionally, binocular vision is verified through assessments like the duochrome test or fogging to confirm equal accommodative effort and comfort, addressing any imbalances that could contribute to symptoms like diplopia.^[26] Common adjustments to the refraction results include reducing cylindrical power if the axis or power appears unstable during verification, often by 0.25 to 0.50 diopters to enhance stability without compromising acuity.^[1] For detected imbalances, prism may be incorporated to support fusion and alleviate strain, particularly in cases of heterophoria.^[26] Lifestyle factors are also considered, such as prescribing slightly more plus power for patients engaged in prolonged near work to reduce accommodative demand and prevent fatigue.^[2] Validation of the results involves retesting if best-corrected visual acuity falls below 20/20 or if the patient reports dissatisfaction, such as persistent blur or discomfort, to refine the prescription iteratively.^[1] These findings are integrated with other examination elements, including fundus evaluation for retinal health or motility assessments for vergence issues, ensuring a comprehensive clinical picture.^[26] The primary outcome goal is a prescription that optimizes best-corrected visual acuity while minimizing symptoms like asthenopia (eye strain) and promoting comfortable binocular function, tailored to the patient's daily visual demands.^[2]

Advantages and Limitations

Benefits

Subjective refraction is inherently patient-centered, as it relies on the individual's feedback regarding visual clarity and comfort, allowing for customization of the prescription to align with personal preferences and daily visual demands. This approach contrasts with purely objective methods, which may overlook subjective nuances, resulting in higher patient satisfaction when prescriptions are refined through subjective input. For instance, studies indicate that relying solely on objective refraction leads to limited patient acceptance, underscoring subjective refraction's role as the gold standard for optimizing visual outcomes tailored to the user's experience.^[27] One key strength lies in its precision, enabling refinements in increments as small as 0.25 diopters (D), which allows detection of subtle refractive errors that autorefractors might miss due to their coarser resolution or inability to account for patient-specific factors. This level of accuracy is standard in clinical practice, where adjustments in 0.25 D steps progressively improve visual acuity until the patient reports optimal clarity. Research comparing subjective and objective methods shows high reliability, with intra- and inter-examiner agreement typically within 0.25 to 0.50 D, confirming its effectiveness in achieving fine-tuned corrections.^[28]^[9] Subjective refraction offers versatility, applicable across a wide range of ages—from children capable of providing reliable responses to older adults—and various ocular conditions, provided the patient can cooperate. While limitations exist for very young or non-communicative individuals, it remains suitable for most populations when combined with objective starting points. Additionally, its cost-effectiveness stems from the use of basic tools like trial lenses and a phoropter, making it accessible in diverse clinical settings without the need for expensive automated devices.^[1] Evidence from comparative studies supports these benefits, demonstrating high agreement between subjective and objective refractions, yet highlighting subjective methods' superior adaptation to real-world visual tasks, such as reading or driving, due to their incorporation of patient feedback for enhanced comfort and functionality. This alignment not only validates the technique's reliability but also its practical value in improving everyday visual performance over objective measurements alone.^[28]

Potential Drawbacks and Errors

Subjective refraction relies heavily on patient feedback, which introduces inherent subjectivity and potential inaccuracies due to factors such as patient fatigue or inconsistent responses. Prolonged testing can lead to boredom and reduced attentiveness, resulting in unreliable answers that compromise the accuracy of the final prescription.^[15]^[29] Additionally, unintended accommodation by the patient—particularly in younger individuals—can cause over-minusing, where excessive minus power is prescribed, leading to symptoms like eye strain or blurred near vision.^[9] Common errors in subjective refraction include misdetermination of the astigmatic axis, often due to subtle differences in patient perception of blur orientation, which can affect visual clarity. Without adjunct tests like the duochrome, endpoint determination for spherical power becomes ambiguous, as patients may report unclear preferences near the neutral point of focus.^[30]^[21] The method is particularly limited for non-verbal patients, such as young children or those with cognitive impairments, where cooperation is minimal and responses unreliable, necessitating reliance on objective alternatives. It is also challenging for individuals with low vision, as their ability to discern lens improvements is diminished. Furthermore, the procedure is time-intensive, typically requiring about 6 minutes per eye, which can extend to 10-20 minutes total when including binocular balancing.^[1]^[31]^[32] Emerging techniques, such as Direct Subjective Refraction (DSR) using defocus waves (as of 2021 with ongoing developments through 2025), and smartphone-based methods, aim to reduce time and improve reliability for challenging patients by minimizing subjective input dependency.^[33]^[34] To mitigate these drawbacks, subjective refraction is often combined with objective methods like retinoscopy or autorefraction to establish a baseline and reduce dependency on patient input. Modern digital phoropters further minimize errors by automating lens changes and providing faster, more precise adjustments, enhancing overall reliability.^[35]^[36]

References

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Subjective Refraction Techniques - StatPearls - NCBI Bookshelf - NIH
Subjective refraction is the assessment of refractive status by a combination of spherical and cylindrical lenses to determine the best-corrected visual acuity.
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Refraction 101: Go Forth and Refract
Jun 12, 2019 · Refraction is the measurement of the eye’s focusing characteristics, determining a prescription with sphere, cylinder, and axis components.
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Presbyopia - StatPearls - NCBI Bookshelf - NIH
Jun 2, 2025 · Typically performed during refractive lens exchange or cataract surgery, this approach uses monofocal intraocular lenses to correct one eye for ...
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[PDF] Official Publication of the Optometric Historical Society | HINDSIGHT
The availability of equipment such as trial lens sets, and later phoropters, made it possible to perform some sort of subjective refraction testing procedure.
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Frans Cornelis Donders | Ophthalmology, Eye Research, Refraction
Sep 24, 2025 · Donders summarized his studies in On the Anomalies of Accommodation and Refraction (1864), the first authoritative work in the field. This ...Missing: subjective | Show results with:subjective
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Ensuring an Accurate Refraction in Children
Nov 1, 2022 · When children are older (commonly 6 to 7 years or above) and can respond to instructions, subjective refraction can be performed. The subjective ...
[7]
Refractive Error After Cataract Surgery - EyeWiki
May 23, 2025 · Post-RK patients may take 3 months for refractive stability. Auto-refraction is not adequate and subjective refraction is necessary.
[8]
Sharpen your Subjective Refraction Technique - Review of Optometry
Jan 15, 2016 · Subjective refraction uses a standardized protocol after retinoscopy, starting with baseline visual acuities, to achieve clear binocular vision.
[9]
[PDF] Subjective Verification of Refraction- A Quality Indicator - JCDR
Jun 1, 2023 · Exclusion criteria: Difficult retinoscopy (children <10 years), ocular media opacity, small pupil, corneal ectatic conditions, mentally.
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Understanding and looking after a retinoscope and trial lens set - NIH
Spherical lenses, with a wide range of powers, both positive and negative, generally 0.12 D, 0.25 D, and then in steps of 0.25 D up to a certain point, then in ...
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May 15, 2024 · To ensure the proper operation, and to get the longest life from your refractive error devices, there are some essential practices that you should follow.
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https://pmc.ncbi.nlm.nih.gov/articles/PMC11141116/
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[PDF] General Refraction Techniques
Standard Subjective Refraction Techniques. Minus cylinder phoropter. The goal of the subjective refraction is to achieve clear and comfortable binocular vision.
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Apr 22, 2016 · Due to this, the ETDRS study protocol stated that an illumination level between 807 lux (lx) and 1345 lx [3] should be used during testing. To ...
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After completing a subjective examination, each lens and occluder is cleaned with alcohol wipes before replacing in the trial box. The trial frame is also ...
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During the subjective portion of the refraction say – “I am going to have you look through two different lenses. Although neither lens may be perfect, I want ...
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Sep 19, 2025 · The test is performed by using an opaque or translucent occluder to cover one eye.Missing: subjective refraction balance instructions
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Jul 30, 2025 · The duochrome test is not used with patients whose visual acuity is worse than 20/40, because the 0.50 D difference between the 2 sides is too ...
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Subjective Refraction Technique: Duochrome Test - StatPearls - NCBI
May 11, 2023 · Accurate refinement of endpoint subjective refraction is essential in providing an optimum optical correction.
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What to record · subjective refraction, if cycloplegic used, what drug and concentration, batch number and expiry date · distance VAs R and L · reading addition ...
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Apr 18, 2023 · A minus sign (−) next to the number means nearsightedness (you see better up close and need distance correction). A plus sign (₊) indicates you ...
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Jun 27, 2024 · If you perform an eye exam that includes a refraction, you must provide the prescription, regardless of whether you charge for the refractive ...
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None
Summary of each segment:
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The VAO subjective refraction is more accurate than VAO objective refraction and autorefraction, regardless of refractive error, age, or the presence of ocular ...
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Conclusions: The results of the reliability studies support Bannon's 1977 conclusion that conventional subjective refraction is reliable within 0.25 to 0.50D.
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Final Sale: Avoiding Glass Checks - Review of Optometry
Jun 15, 2015 · Patient fatigue can be a significant problem in the classic subjective refraction, especially for some senior and systemically ill patients.
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Sep 17, 2025 · Introduction. cross cylinder. In 1887, Edward Jackson described a method of detecting astigmatism using modified Stokes' lenses. He further ...Missing: trial | Show results with:trial
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Jun 1, 2023 · Exclusion criteria: Difﬁcult retinoscopy (children <10 years), ocular. media opacity, small pupil, corneal ectatic conditions, mentally.
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Dec 6, 2021 · For many eye care practitioners, subjective refraction represents a considerable fraction of every workday, estimated to be about 6 minutes per ...
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Jun 4, 2016 · Compare the monocular VAs with your subjective refraction result with the patient's vision or habitual VAs (as appropriate). If the VA is ...
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Enhanced accuracy: Digital technology reduces human error and ensures precise measurements. Improved patient experience: Interactive displays and faster ...