Fact-checked by Grok 2 weeks ago

Tear break-up time

Tear break-up time (TBUT), also referred to as tear film break-up time (TFBUT), is a clinical diagnostic test in that quantifies the stability of the pre-ocular tear film by measuring the interval between a complete blink and the appearance of the first dry spot on the corneal surface. This assessment, first described by Norn in 1969, typically involves the instillation of fluorescein dye and helps identify disruptions in the tear film's protective lipid layer, which prevents excessive evaporation and maintains ocular surface health. TBUT is particularly valuable for diagnosing evaporative dry eye disease, a common condition with a global prevalence ranging from 5% to 50%, where rapid tear film instability leads to symptoms such as ocular discomfort, , and surface damage. A reduced TBUT, generally less than 10 seconds, is indicative of tear film instability and is frequently associated with , deficiency, or keratoconjunctivitis sicca. Clinically, TBUT serves as a specific screening tool within the TFOS DEWS diagnostic framework, guiding treatments to restore tear film integrity. Emerging noninvasive alternatives aim to improve accuracy over traditional methods, which have reported around 75% and specificity around 60%. Its measurement underscores the multifactorial nature of dry eye, emphasizing the interplay between aqueous production, lipid evaporation barriers, and adhesion for optimal ocular surface protection.

Definition and Background

Definition

Tear break-up time (TBUT), also known as tear film break-up time (TFBUT), is a clinical metric that quantifies the stability of the preocular tear film by measuring the interval, in seconds, from the last complete blink to the first appearance of a dry spot or discontinuity in the tear film covering the corneal surface. This parameter serves as an indicator of tear film integrity, where shorter times suggest rapid destabilization leading to potential ocular surface disruption. The concept of TBUT was first introduced by Danish ophthalmologist Mogens Norn in 1969 as a straightforward, non-invasive method to assess tear film instability and its implications for corneal health. Norn's original description emphasized its utility in evaluating the process of the tear film, laying the foundation for its widespread adoption in ocular diagnostics. At its core, TBUT reflects the combined functionality of the tear film's three principal layers—the outermost lipid layer, which retards ; the middle aqueous layer, which provides ; and the innermost mucin layer, which ensures to the ocular surface—collectively maintaining and protection against environmental stressors. Disruptions in any of these layers can accelerate break-up, with TBUT values below 10 seconds generally signaling compromised stability and heightened risk of symptoms such as dryness or . Expressed solely in seconds, this scale allows for quick clinical interpretation without requiring complex equipment in its basic form.

Tear Film Physiology

The tear film is a thin, multilayered structure that coats the ocular surface, essential for maintaining eye health and function. It consists of three primary layers: an outer lipid layer, a middle aqueous layer, and an inner mucin layer. The outermost lipid layer, secreted primarily by the meibomian glands in the eyelids, forms a hydrophobic barrier approximately 40-60 nm thick that retards evaporation of the underlying aqueous components and stabilizes the overall film. The middle aqueous layer, produced by the lacrimal glands and accessory glands such as the Krause and Wolfring glands, constitutes the bulk of the tear volume (about 7-10 μm thick) and provides hydration, electrolytes, proteins, and growth factors to nourish the cornea and conjunctiva. The innermost mucin layer, derived from goblet cells in the conjunctiva and epithelial cells on the cornea, creates a hydrophilic glycocalyx that promotes adhesion of the tear film to the ocular epithelium and facilitates uniform spreading. Dynamically, the tear film is renewed and redistributed with each blink, which mechanically spreads the layers across the ocular surface and replenishes the aqueous component. Between blinks, the film thins progressively due to , primarily from the aqueous layer, at a rate influenced by environmental factors and layer integrity; instability in this process can lead to localized dry spots or breaks in the film. Complete blinks, where the eyelids fully approximate, effectively renew the tear film by mixing and redistributing its components, whereas partial or incomplete blinks fail to cover the entire , promoting uneven thinning and reduced stability. Physiologically, the tear film plays critical roles in ocular : it maintains corneal transparency by smoothing the refractive surface and preventing , defends against microbial pathogens through antimicrobial proteins and mechanical flushing, and delivers oxygen and nutrients to the avascular via from the aqueous layer. Tear break-up time serves as a key metric reflecting this stability, with disruptions indicating potential compromise in these protective functions.

Clinical Significance

Role in Dry Eye Syndrome

Tear break-up time (TBUT) is a critical diagnostic parameter in (), serving as a primary indicator of tear film instability that underpins the evaporative subtype of the condition. The Tear Film & Ocular Surface Society (TFOS) DEWS reports, including DEWS II (2017) and DEWS III (2025), classify evaporative dry eye as a major form of when TBUT is less than 10 seconds, reflecting excessive tear evaporation due to deficiencies in the lipid layer of the tear film. This subtype represents the most common manifestation of , accounting for the majority of clinical cases as recognized in epidemiological analyses. A reduced TBUT directly correlates with hallmark symptoms of , such as ocular burning, a foreign body sensation, and intermittent , which arise from discontinuous tear coverage on the ocular surface leading to epithelial exposure and irritation. These symptoms often intensify with prolonged visual tasks or environmental stressors, highlighting TBUT's value in linking objective tear film disruption to patient-reported discomfort. In clinical practice, TBUT enhances diagnostic accuracy when integrated with subjective tools like the Ocular Surface Disease Index (OSDI) questionnaire, enabling a multifaceted that captures both signs and symptom severity in . Moreover, a low TBUT identifies patients likely to benefit from lipid-based therapies, such as emulsion , which stabilize the tear and alleviate evaporative loss, with studies demonstrating significant TBUT improvements in those with baseline values under 10 seconds. Epidemiological evidence underscores the heightened relevance of abnormal TBUT in , particularly among wearers where prevalence can reach up to 50%, exacerbating tear instability and symptom burden.

Associations with Other Ocular Disorders

Tear break-up time (TBUT) is frequently reduced in (MGD), primarily due to deficient lipid secretion from the meibomian glands, which compromises the tear film's layer and accelerates . MGD is present in up to 86% of dry eye cases, often resulting in abnormal TBUT and highlighting MGD as a predominant contributor to evaporative dry eye. In patients with MGD, the instability of the tear film manifests as shortened TBUT, often accompanied by symptoms of ocular discomfort and surface damage. In , inflammation induced by allergens disrupts production and overall tear stability, resulting in a notable shortening of TBUT. Pediatric patients with exhibit significantly thinner lipid layers and reduced TBUT compared to controls, with mean values of approximately 3.7 seconds compared to 7.7 seconds in controls, indicating about a 50% reduction in stability. This ocular surface instability exacerbates symptoms like itching and redness, and the inflammatory cytokines further impair tear integrity. Contact lens wear is associated with alterations in tear film , often leading to decreased TBUT over time due to and reduced blink completeness. After six months of soft use, TBUT can decline by an average of 3 seconds, reflecting increased and lipid layer disruption. Similarly, refractive surgeries like temporarily reduce TBUT, with postoperative values dropping due to corneal nerve damage that diminishes blink rate and reflexive tear secretion; studies report TBUT reductions persisting for weeks to months in up to 20-50% of patients. This neurotrophic heightens evaporative loss and contributes to post-surgical eye symptoms. Systemically, reduced TBUT is prominent in Sjögren's syndrome, an autoimmune condition characterized by aqueous tear deficiency and glandular inflammation, leading to markedly unstable tear films. Patients with primary Sjögren's syndrome show mean TBUT values as low as 3.7 seconds, compared to over 14 seconds in healthy individuals, correlating with severe ocular surface damage. In diabetes mellitus, neuropathy affects corneal innervation and lacrimal function, resulting in shortened TBUT and overall ocular surface dysfunction; tear film instability is evident even in early-stage , with reductions linked to autonomic nerve impairment and elevated inflammatory markers. These systemic links underscore TBUT's utility as a marker for broader ocular and metabolic health impacts.

Measurement Methods

The measurement of tear break-up time (TBUT) follows guidelines from the Tear Film & Ocular Surface Society (TFOS) DEWS II Diagnostic Methodology report, which standardizes procedures for assessing tear film stability.

Fluorescein Dye Technique

The fluorescein dye technique, also known as fluorescein break-up time (FBUT), is a conventional invasive for evaluating tear film stability by observing the disruption of the fluorescein-stained tear layer under illumination. In preparation, a small volume (1-2 μL) of 1-2% preservative-free sodium fluorescein solution or a fluorescein-impregnated (containing approximately 0.6-1 mg of , wetted with non-preserved saline and excess shaken off) is instilled into the lower conjunctival of the eye to be tested. The patient is instructed to blink naturally several times to ensure even distribution of the dye, followed by a brief wait of 1-2 minutes to allow mixing with the tear film. The procedure is conducted using a slit-lamp biomicroscope equipped with a excitation filter to enhance visibility. After the final blink to spread the , the patient maintains an open-eyed gaze without blinking, while the observer monitors the corneal surface. The time interval is recorded from the completion of the last blink to the first observable break in the tear film. A tear film break is identified as the initial appearance of a dark spot, line, or irregularity against the uniformly fluorescent background, indicating localized or instability. For reliability, the measurement is repeated 3-5 times per eye, with at least a 30-second interval between trials to allow tear film recovery, and the average value is calculated. This technique is widely adopted in clinical settings due to its accessibility, low cost, and equivalence across standard instillation methods such as strips or micropipettes. Unlike non-invasive techniques, it requires dye application, which can potentially influence tear dynamics.

Non-Invasive Techniques

Non-invasive techniques for assessing tear break-up time (TBUT) represent advancements in ocular diagnostics that avoid the use of dyes, such as fluorescein, which is the traditional benchmark method. These approaches rely on optical imaging and automated analysis to evaluate tear film stability, providing objective measurements of the time from the last blink to the formation of dry spots on the ocular surface. By eliminating physical contact and chemical instillation, they minimize potential artifacts and patient discomfort. Keratography and videokeratoscopy utilize Placido disc or projection ring patterns projected onto the corneal surface to visualize tear film disruptions without dyes. These devices capture high-resolution video sequences, where software algorithms detect distortions or breaks in the reflected ring patterns, automatically calculating the non-invasive break-up time (NIBUT). For instance, the Keratograph 5M employs a color camera and Placido-ring topographer to perform fully automated NIBUT assessments, enabling evaluation of tear film stability alongside other parameters like tear height. Similarly, videokeratoscopy systems, such as those integrated into corneal topographers, project mires or rings and analyze their deformation in real-time to quantify TBUT, offering reproducible results in clinical settings. Interferometry measures tear film stability by analyzing interference patterns from reflected white light, particularly focusing on the lipid layer thickness and its role in preventing break-up. Devices like the LipiView Ocular Surface Interferometer capture specular reflections to assess lipid layer thickness (LLT) and dynamics, which contribute to tear film stability, though TBUT is typically measured separately. The Keeler TearScope-Plus, another tool, illuminates the tear film to observe color-coded interference patterns, allowing manual or semi-automated detection of break-up events without contact. These methods provide insights into the lipid-aqueous balance, with studies showing correlations between thicker layers and prolonged . The general procedure for non-invasive TBUT measurement involves the patient fixating on a central target in a controlled environment with minimal airflow and illumination to reduce external influences. The patient is instructed to blink several times—typically two or three—to evenly distribute the tear film, then maintain fixation without while the device records video footage, often lasting 20-30 seconds. Imaging captures the tear surface continuously, and built-in software processes the data to identify the first break, yielding average and minimum NIBUT values without requiring instillation or observer intervention. These techniques offer key advantages, including reduced through , high , and suitability for patients with sensitive corneas by avoiding from dyes. According to the 2024 American Academy of Ophthalmology Preferred Practice Pattern on , non-invasive methods like keratography and are preferred for their objectivity and patient comfort, positioning them as an emerging standard in dry eye evaluation.

Interpretation of Results

Normal Values and Ranges

In healthy adults, tear break-up time (TBUT) typically averages 10 to 15 seconds, with values below 10 seconds indicating abnormality and potential tear film instability. The TFOS DEWS II report establishes this threshold based on aggregated data from multiple studies using both invasive and non-invasive methods, where non-invasive TBUT ranges from 4 to 19 seconds across healthy cohorts, though fluorescein-based measurements tend to yield slightly lower values. Age-related changes contribute to a progressive decline in TBUT, primarily due to atrophy and reduced lipid layer stability. In younger adults (under 40 years), mean TBUT values often range from 12 to 14 seconds, decreasing to 8 to 10 seconds in those over 60 years, as evidenced by significant differences across age groups (P < 0.001) in population-based assessments. Gender differences show slightly lower TBUT in females compared to males, attributable to hormonal influences on function and lipid production. This disparity is supported by clinical evidence linking estrogen fluctuations to diminished lipid secretion and tear film stability in women. Population norms vary by ethnicity and measurement technique. For instance, a 2022 study of healthy Indian adults found a mean non-invasive TBUT of 10.95 ± 2.02 seconds, with no significant sex-based variation in this cohort.

Factors Influencing Measurements

Several environmental factors can significantly alter tear break-up time (TBUT) measurements by accelerating tear evaporation or disrupting film stability. Low relative humidity environments, particularly below 40%, have been shown to shorten TBUT through increased tear evaporation rates, with studies reporting reductions of approximately 17-20% in controlled dry conditions compared to normal humidity levels. Air conditioning, which often creates similar low-humidity settings (typically 20-40% RH), contributes to this effect by promoting faster tear film instability, leading to decreased TBUT and heightened ocular discomfort during prolonged exposure. Behavioral factors, such as prolonged screen use, influence TBUT by reducing the spontaneous blink rate, which normally ranges from 15 to 20 blinks per minute but can drop to 5 to 7 blinks per minute during digital tasks. This diminished blinking impairs tear film redistribution, resulting in faster break-up and instability, often exacerbating symptoms in office or digital work settings. Pharmacological agents, including certain systemic medications, can decrease aqueous tear production and thereby shorten TBUT. Antihistamines like cetirizine and loratadine have been associated with reduced TBUT, with one study noting a mean decrease of about 0.8 seconds after short-term use, alongside signs of ocular dryness such as increased staining. Systemic beta-blockers, such as metoprolol, significantly suppress tear secretion (p < 0.001), leading to lower TBUT values through diminished aqueous layer volume. Ocular surface conditions related to interventions can artifactually lower TBUT until adaptation occurs. Contact lens wear, particularly soft lenses, reduces TBUT by an average of 3 seconds after several months of use, due to lens-induced disruption of the tear film layers and increased evaporation. Similarly, following ocular surgeries like cataract extraction, TBUT remains persistently shortened in pseudophakic eyes compared to phakic ones, with stabilization often requiring weeks to months post-procedure. These effects highlight the need to consider recent ocular history when interpreting TBUT results relative to established normal ranges of 10 seconds or more.

Advanced Concepts and Applications

Ocular Protection Index

The Ocular Protection Index (OPI) is a TBUT-derived metric that evaluates the adequacy of blinking in maintaining ocular surface protection by quantifying the relationship between tear film stability and blink frequency. Defined as the ratio of tear break-up time (TBUT) to inter-blink interval (IBI), an OPI greater than 1 indicates that the tear film remains intact between blinks, providing adequate protection, while a value less than 1 signifies that tear film disruption occurs before the next blink, increasing the risk of ocular surface exposure and potential damage. To calculate the OPI, the IBI—the average duration between consecutive blinks—is first determined through videographic analysis of natural blink patterns during visual tasks, ensuring measurements reflect real-world conditions. The TBUT is then divided by this IBI; for instance, a TBUT of 8 seconds and an IBI of 5 seconds yields an OPI of 1.6, denoting sufficient ocular protection. In clinical practice, the OPI aids in assessing incomplete blinks, where partial lid closure fails to fully refresh the tear film, contributing to dry eye progression by prolonging surface exposure. Although low OPI values theoretically indicate increased risk of evaporation-induced irritation and inflammation, the index shows poor association with dry eye symptom severity. The OPI was introduced by Ousler et al. in 2002 as a tool to integrate blink dynamics with tear film metrics and was formally detailed in their 2008 publication. It has since been validated in studies.

Integration with Other Diagnostic Tests

Tear break-up time (TBUT) synergizes with the Schirmer test to differentiate dry eye subtypes by evaluating distinct aspects of tear film dynamics. TBUT primarily assesses tear film stability and evaporation rate, with values below 10 seconds indicating instability often associated with evaporative dry eye, while the Schirmer test measures aqueous tear production volume, where results under 10 mm/5 minutes suggest aqueous-deficient dry eye. Combining these tests allows clinicians to identify mixed or predominant subtypes, as low TBUT without reduced Schirmer values points to evaporative mechanisms, whereas isolated low Schirmer scores highlight aqueous deficiency. This integration enhances diagnostic precision, guiding targeted therapies like lipid-based drops for evaporative cases or anti-inflammatory agents for aqueous-deficient ones. TBUT correlates closely with ocular surface staining techniques, providing complementary insights into epithelial damage resulting from tear instability. Short TBUT durations frequently precede and contribute to corneal and conjunctival damage visible via fluorescein or lissamine green staining, as unstable tear films expose the surface to hyperosmolarity and friction. The Tear Film & Ocular Surface Society (TFOS) DEWS III report (2025) recommends performing TBUT prior to staining in a sequential protocol to minimize interference from dyes while using staining to quantify the extent of damage from prolonged instability (>5 corneal fluorescein spots or >9 conjunctival lissamine green spots). For instance, patients with TBUT under 10 seconds often exhibit moderate to severe staining scores, confirming the progression from instability to surface compromise. Integration of TBUT with tear osmolarity and meibography further refines evaporative dry eye assessment by linking film instability to underlying physiological disruptions. A TBUT below 10 seconds combined with elevated osmolarity exceeding 308 mOsm/L signals confirmed tear hyperosmolarity and instability, with inter-eye differences over 8 mOsm/L strengthening the diagnosis of moderate disease. Meibography complements TBUT by visualizing atrophy or dropout, which correlates with reduced lipid layer integrity and shortened TBUT in evaporative cases, allowing identification of as a root cause. Studies show significant negative correlations between gland loss quantified via meibography and TBUT values, underscoring their utility in subclassifying and monitoring evaporative dry eye. In the TFOS DEWS III framework (2025), TBUT serves as a core confirmatory diagnostic tool following symptom evaluation via the OSDI-6 questionnaire (cut-off ≥4), positioned as a non-invasive test alongside osmolarity and to establish tear film disruption efficiently. The protocol advocates starting with symptoms, then proceeding to one or more confirmatory signs (non-invasive TBUT <10 seconds, osmolarity ≥308 mOsm/L or inter-eye difference >8 mOsm/L, or positive ), followed by additional tests like Schirmer and meibography for comprehensive subtyping and severity grading based on etiological drivers. This staged approach ensures minimal patient discomfort while maximizing diagnostic yield, with TBUT's role in confirming instability pivotal to the overall panel.

Limitations and Safety Considerations

Contraindications

Tear break-up time (TBUT) testing, particularly when using the conventional fluorescein method, carries few absolute contraindications but several relative ones where the procedure should be approached with caution or deferred to avoid patient harm, discomfort, or unreliable results. Active or epithelial defects represent a relative due to the risk of exacerbating the injury through fluorescein instillation and the requirement for prolonged non-blinking observation, which could further irritate or damage the compromised surface. Similarly, in cases of active ocular infection such as bacterial keratitis, dye application may potentially spread pathogens or introduce contaminants into the affected area, warranting avoidance until the infection is controlled. Severe , often associated with conditions like acute anterior or infectious , contraindicates routine TBUT testing as the bright illumination from the slit-lamp biomicroscope can intensify discomfort and prevent patient cooperation during the fixation phase. Recent ocular surgery, including procedures such as cataract extraction or , within the first 1-2 weeks postoperatively, is considered a relative because of transient alterations in tear film stability and the potential for the test to interfere with ongoing epithelial healing or introduce unnecessary ocular stress. Certain patient-specific factors, including young children who are uncooperative or adults with severe anxiety disorders, preclude accurate TBUT assessment since the test demands sustained fixation and voluntary blink suppression, which may be impossible to achieve. In such scenarios, non-invasive TBUT techniques may serve as safer alternatives when feasible.

Sources of Error and Limitations

Observer variability represents a primary technical challenge in tear break-up time (TBUT) assessment, particularly with the conventional fluorescein method, where subjective detection of the first break in the tear film can lead to inter-observer differences of up to 3 seconds due to variations in experience and lighting perception. This subjectivity contributes to poor to moderate inter-observer reliability, as evidenced by coefficients () typically ranging from 0.5 to 0.85 in human comparative studies. Mitigation strategies include standardized training for examiners, which improves correlation scores, or shifting to automated non-invasive techniques that eliminate through algorithmic detection, achieving strong correlations (r > 0.89) with manual methods while reducing variability. Environmental artifacts further compromise TBUT accuracy by accelerating tear evaporation and altering film stability; for instance, low relative humidity and high air velocity (e.g., >1.0 m/s) can shorten measured times by promoting . Increased inversely correlates with TBUT duration, exacerbating apparent in uncontrolled settings. To address these, testing protocols recommend standardization to controlled conditions of 20-25°C and 40-60% relative humidity, which minimizes evaporation-related discrepancies and enhances reproducibility across sessions. Patient-related errors often arise from incomplete or infrequent blinks during the test, which expose the ocular surface excessively and artificially shorten TBUT by disrupting the tear film renewal process. Poor fixation or anxiety can also induce partial blinks, leading to underestimated stability in up to 30% of measurements if not monitored. These issues are mitigated by providing clear instructions to patients for complete, natural post-instillation and encouraging relaxation to simulate everyday conditions. Despite its utility, TBUT has inherent limitations as a diagnostic tool, particularly its insensitivity to early-stage dry eye, where some symptomatic patients may exhibit normal values (>10 seconds) due to compensatory mechanisms masking subtle instability. According to the 2023 American Academy of Ophthalmology Preferred Practice Pattern (updated in line with 2024 trends) and TFOS DEWS III guidelines, TBUT should not be used as a standalone diagnostic, as no single test adequately captures the multifactorial nature of dry eye, necessitating integration with symptom questionnaires and other objective measures for comprehensive evaluation.

References

  1. [1]
    Tear breakup time (TBUT) - Atlas Entry
    Tear breakup time (TBUT) is a clinical test used to assess for evaporative dry eye disease. To measure TBUT, fluorescein is instilled into the patient's tear ...
  2. [2]
    Dry Eye Syndrome - EyeWiki
    Feb 11, 2025 · Tear break up time (TBUT). TBUT is an indication of tear film stability. The proper method of TBUT testing is using a fluorescein-impregnated ...
  3. [3]
    NONINVASIVE TEAR FILM BREAK-UP TIME ASSESSMENT ... - NIH
    In normal eyes, TBUT values range from 3 seconds (s) to 132 s, with an average of 27 s (9). TBUT less than 10 s suggests an abnormal tear film, with values of 5 ...
  4. [4]
    Tear break-up time for tear film evaluation: Are moistening solutions ...
    First introduced by Norn in 1969, TBUT was defined as the time “interval between the last complete blink and the presentation of the first appearance of a dry ...
  5. [5]
    Mechanisms, imaging and structure of tear film breakup - PMC
    According to the 2007 Dry Eye Workshop, “the tear film breakup time is defined as the interval between the last complete blink and the first appearance of a dry ...
  6. [6]
    Examination for Dry Eyes | IntechOpen
    Tear break-up time was first introduced by Norn in 1969 and remains the most frequently used diagnostic test to evaluate tear film stability [31]. It measures ...
  7. [7]
    Noninvasive tear breakup time evaluation with multifunctional ...
    In 1969, the conventional tear breakup time (TBUT) test was introduced. TBUT is defined as the time interval between a blink and the first appearance of gaps or ...
  8. [8]
    TFOS DEWS II Tear Film Report - ScienceDirect.com
    The tear film is composed of many substances including lipids, proteins, mucins and electrolytes. All of these contribute to the integrity of the tear film but ...
  9. [9]
    Biochemistry, Tear Film - StatPearls - NCBI Bookshelf - NIH
    Jun 5, 2023 · The tear film is heterogeneous and is classically divided into three distinct layers – inner mucin, middle aqueous, and outer lipid layer.
  10. [10]
    Biological Functions of Tear Film - PMC
    The tear film consists of an aqueous-mucin layer, containing fluid and soluble factors produced by the lacrimal glands and mucin secreted by the goblet cells, ...
  11. [11]
    TFOS DEWS II Tear Film Report - PMC - PubMed Central
    The three layered model of the tear film proposed by Wolff [1,2] has had an overwhelming allure because it is simple and logical: a mucin layer covering the ...
  12. [12]
    Dynamics and function of the tear film in relation to the blink cycle
    It is thought that tear film instability occurs due to increased evaporation and leads to increased tear film osmolarity, which stresses the ocular surface and ...
  13. [13]
    Impact of Incomplete Blinking Analyzed Using a Deep Learning ...
    Previous reports found that increased incomplete blinking (IB) and reduced blink rate may induce tear film instability and cause evaporative DED.Missing: partial | Show results with:partial
  14. [14]
    Review: The Lacrimal Gland and Its Role in Dry Eye - PMC
    Mar 2, 2016 · The 3-layered tear film inhibits ocular surface invasion by pathogens, provides an air-tissue interface for gas exchange, and supplies ...<|control11|><|separator|>
  15. [15]
    Epidemiology Report - TFOS - Tear Film & Ocular Surface Society
    For example, the prevalence of a tear breakup time (TBUT) of ≤10 s in one or both eyes varied between studies from 15.6 to 85.6%, of a Schirmer test score of ≤5 ...<|control11|><|separator|>
  16. [16]
    Dysfunctional tear syndrome: dry eye disease and associated tear ...
    ... symptoms of ocular discomfort, dryness, burning/stinging, grittiness or a foreign body sensation, photophobia, and blurred/fluctuating vision. Clinical ...
  17. [17]
    Comparison of Diagnostic Tests in Distinct Well-Defined Conditions ...
    TFBUT and OSDI correlated better with other tests. The best combination of diagnostic tests for DED was OSDI, TBUT and Schirmer test (sensitivity 100%, ...
  18. [18]
    Efficacy, Safety, and Acceptability of a Lipid-Based Artificial Tear ...
    Feb 4, 2015 · This 3-month, multicenter, double-masked study was conducted in patients with dry eye symptoms, reduced tear break-up time (TBUT), and ocular ...Missing: predicts | Show results with:predicts
  19. [19]
    The prevalence of meibomian gland dysfunction, tear film and ocular ...
    Current literature even suggests that up to 86% of dry eye patients demonstrate signs of MGD (Lemp et al. 2012). However, it has to be noted that MGD can also ...
  20. [20]
    Influence of Meibomian Gland Dysfunction and Friction ... - PubMed
    Feb 16, 2018 · This study showed associations between MGD, FRD, or both and ocular signs in DED. In the presence of MGD, FRD, or both, TBUT was significantly shortened.
  21. [21]
    Quantitative evaluation of lipid layer thickness and blinking in ...
    May 18, 2021 · Pediatric patients with AC had significant thinner LLT, shorter TBUT, decreased total blinking but increased partial blinking rate, especially in those with ...Missing: shortening | Show results with:shortening
  22. [22]
    Meibomian gland alterations in allergic conjunctivitis: insights from a ...
    Jan 6, 2025 · The non-invasive first tear film break-up time was shorter in the allergy group (8.65 ± 6.31 s) than in the control group (10.48 ± 2.58 s) (P < ...Missing: shortening | Show results with:shortening
  23. [23]
    The effects of six months of contact lens wear on the tear film, ocular ...
    After 6 months of contact lens wear, clinical signs had worsened by less than one-half of a grade, and tear break up time (TBUT) worsened by 3 s.
  24. [24]
    Dry eye after refractive surgery: a meta-analysis - PubMed
    Overall, a significant reduction in postoperative tear production as well as TBUT time was seen with LASIK, and a nonsignificant reduction in postoperative ...Missing: post- | Show results with:post-
  25. [25]
    Post-LASIK dry eye disease: A comprehensive review of ...
    Peripheral nerve damage might take place during LASIK. CN or corneal neuropathic pain would occur due to a set of adversely regenerated nerve endings after ...
  26. [26]
    Olfactory dysfunction in primary Sjogren's syndrome and ... - PubMed
    There is a mild clinical impairment in smell sense in patients with pSS which seems to be correlated with dry eye parameters.Missing: reduced | Show results with:reduced
  27. [27]
    Sjögren's Versus Non-Sjögren's Ocular Features: Similar Symptoms ...
    Jan 2, 2024 · SjD is associated with a higher risk of ocular signs and pathology compared with non-SjD, whereas ocular symptoms remain similar.
  28. [28]
    Tear film and ocular surface dysfunction in diabetes mellitus in an ...
    Tear film abnormality is a significant feature of diabetic ocular surface diseases. These abnormalities are likely on account of poor quality and function ...
  29. [29]
    Age- and gender-related tear function changes in normal population
    Feb 20, 2009 · We detected a statistically highly significant difference among the age groups in respect to the tear film break-up time test (P<0.001), ...
  30. [30]
    Tear film evaporation—Effect of age and gender - ScienceDirect.com
    ... tear production enhanced by hormonal changes. Clinical evidence of an abnormal lipid production system in older patients, in particular women is established.
  31. [31]
    Dry Eye Disease: Consideration for Women's Health - PMC
    These molecular-level differences translate to differences in aqueous tear output, lipid production, mucous secretion, tear film stability, blink rate, and ...
  32. [32]
    Non-invasive Tear Film Assessment in Normal Population - Frontiers
    May 31, 2022 · The current study investigated the age and gender effect on tear film parameters measured in a non-invasive manner using Keratograph 5M.
  33. [33]
    Adaptation of the tear film to work in air-conditioned rooms ... - PubMed
    The breakup time was slightly reduced (decrease, 17.5%; P < 0.01) and also reached a steady state after 2-4 years. The tear-ferning test, however, showed a ...
  34. [34]
    The effect of low humidity on the human tear film - PubMed
    Evaporation rate, tear LLT, ocular comfort, tear stability, and production were adversely affected by low RH.Missing: factors | Show results with:factors
  35. [35]
    The Influence of Work Environment Factors on the OcularSurface in ...
    Feb 25, 2021 · Low relative air humidity in the building and air-conditioned rooms negatively affects the tear film, causing the symptoms of dry eye disease.
  36. [36]
    Computers, Digital Devices, and Eye Strain
    Jun 27, 2024 · 1. Blink! ... Humans normally blink about 15 times in one minute. However, studies show that we only blink about 5 to 7 times in a minute while ...Missing: film | Show results with:film
  37. [37]
    Smartphone Use and Effects on Tear Film, Blinking and Binocular ...
    Oct 7, 2019 · This study examined the effects of 60 min reading on a smartphone on ocular symptoms, binocular vision, tear function, blinking and working distance.Missing: screen | Show results with:screen
  38. [38]
    An evaluation of the ocular drying effects of 2 systemic antihistamines
    005), and a mean decrease of 0.76 seconds (19.6%) in TFBUT (P = .05) vs baseline. Loratadine was shown to induce 93% greater conjunctival staining after 4 days ...
  39. [39]
    Influence of topical and systemic beta-blockers on tear production
    Tear production was significantly decreased (p less than 0,001) after systemic (I.M.) administration of either selective beta 1-blockers (metoprolol, betaxolol) ...
  40. [40]
    Effects of Oral Antihistamines on Tear Volume, Tear Stability, and ...
    Jun 20, 2020 · Neither of the mean changes in TBUT or IOP depended on the treatment given, but there was a significant monocular decrease in tear volume from ...
  41. [41]
    Persistently Worsened Tear Break-up Time and Keratitis ... - PubMed
    Apr 5, 2020 · The tear break-up times (TBUTs) and keratoconjunctival staining results were compared between phakic and pseudophakic eyes. The mean age of the ...
  42. [42]
    Tear Film Break-Up Time and Dry Eye Disease Severity in a Large ...
    Feb 22, 2021 · This study evaluated to what extent tear film break-up time (TFBUT) could discriminate pathological scores for other clinical tests and explore ...
  43. [43]
    The Ocular Protection Index - PubMed
    The relationship between TFBUT and IBI has been quantified by the Ocular Protection Index (OPI), which is calculated by dividing TFBUT by IBI.Missing: TBUT | Show results with:TBUT
  44. [44]
    Measurement of ocular surface protection under natural blink ... - NIH
    Sep 22, 2011 · The ocular protection index (OPI) was developed to capture the nature of the interaction between blinking and TFBUT, and the OPI methodology has ...Missing: TBUT | Show results with:TBUT
  45. [45]
    Diagnosis and remediation of blink inefficiency - ScienceDirect.com
    G.W. Ousler et al. The ocular protection index. Cornea. (2008). L.G. Carney et ... For example, high incomplete blink rates contribute to any form of dry eye ...
  46. [46]
    Breaking Point - The Ophthalmologist
    Feb 2, 2021 · Enter the Ocular Protection Index: the test beyond tear film breakup time. By Aditi Agarwal, Rajesh Sinha 2/2/2021 1 min read. Share.Missing: TBUT | Show results with:TBUT
  47. [47]
    [PDF] TFOS DEWS II Diagnostic Methodology report The Ocular Surface
    The definition of dry eye has been amended by the TFOS DEWS II to “Dry eye is a multifactorial disease of the ocular surface char- acterized by a loss of ...
  48. [48]
    Tear Film Lipid Layer Thickness & Meibomian Gland Loss
    To evaluate the correlation between tear film lipid layer thickness and other objective measurements such as tear film break-up time (TBUT), upper and lower ...
  49. [49]
    [PDF] TFOS DEWS II Report Executive Summary
    Aug 4, 2017 · This article presents an Executive Summary of the conclusions and recommendations of the 10-chapter. TFOS DEWS II report. The entire TFOS ...
  50. [50]
    Corneal Abrasion - StatPearls - NCBI Bookshelf
    Abrasions over the center of the cornea will cause a decrease in visual acuity. Significant reductions in visual acuity require referral to an ophthalmologist.Missing: TBUT | Show results with:TBUT
  51. [51]
    Corneal Abrasion: Background, Anatomy, Pathophysiology
    Sep 17, 2024 · Corneal abrasions usually heal rapidly, without serious sequelae; thereore, they often are considered of little consequence. However, deeper ...
  52. [52]
    Keratoconjunctivitis - StatPearls - NCBI Bookshelf - NIH
    Feb 6, 2025 · Corneal sensation testing is an option in cases of suspected herpetic viral infection, which can cause decreased corneal sensitivity. Tear ...
  53. [53]
    Slit Lamp Examination - EyeWiki
    Jun 2, 2025 · Risks/Benefits. The risks associated with slit lamp examination are minimal. Patients with eye pain or photosensitivity may not tolerate the ...Missing: photophobia | Show results with:photophobia
  54. [54]
    Uveitis - StatPearls - NCBI Bookshelf - NIH
    These special skills include visual acuity testing, IOP measurements, slit lamp biomicroscopy, and fluoroscein staining. Conjunctivitis can present as a painful ...
  55. [55]
    Cataract surgery in patients with ocular surface disease: An update ...
    ST is a practical test to detect patients with moderate to severe aqueous tear deficiency. An abnormal TBUT is similarly suggestive of an inadequate tear film ...Missing: contraindication | Show results with:contraindication
  56. [56]
    Dry eye post-cataract surgery: a systematic review and meta-analysis
    Jan 13, 2025 · This systematic review establishes a link between cataract surgery and a reduction in TBUT score extending up to 3-month follow-up period, but ...Missing: contraindication | Show results with:contraindication
  57. [57]
    Investigation of fluorescein stain–based tear film breakup time test ...
    Nov 26, 2021 · Observer 1 consistently recorded shorter TFBUT measurements than observer 2, with a mean difference of approximately 3 seconds throughout all 4 ...
  58. [58]
    Reliability and efficacy of maximum fluorescein tear break-up time in ...
    Jun 1, 2021 · This study aims to investigate the reliability and efficacy of maximum fluorescein tear break-up time (FTBUTmax) in diagnosing dry eye disease (DED).
  59. [59]
    Evaluating Observer Variability in Tear Breakup Time for Improved ...
    TBUT measures between different examiners show good correlation validating its use. COR scores improved with level of training suggesting that teaching ...
  60. [60]
    Comparing automated and manual assessments of tear break-up ...
    Jan 30, 2024 · The non-invasive break-up time (NIBUT) is determined as the interval of time that elapses between the end of a complete blink and the appearance ...
  61. [61]
    The Influence of Work Environment Factors on the Ocular Surface in ...
    Environmental factors such as reduced relative air humidity, increased air temperature, and decreased illumination have a negative impact on the ocular surface.
  62. [62]
    Climatic and Environmental Correlates of Dry Eye Disease Severity
    TBUT was significantly correlated with several weather and pollution variables. Shorter (worse) TBUT correlated with lower average daily temperature (ρ = 0.08).
  63. [63]
    Impact of environmental adaptation on tear film assessments
    In 1987, Wyon and Wyon reported that tear stability in healthy eyes significantly decreased after 30 min exposure to high air velocity (1.0 m/s), but moderate ...
  64. [64]
    Evaluation of incomplete blinking as a measurement of dry eye ...
    May 29, 2019 · Incomplete blinking is associated with decreased TBUT, increased OSDI, and increased MGd possibly through its contribution to meibomian gland obstruction.Missing: errors | Show results with:errors
  65. [65]
    Subjective and Objective Evaluation of the Effect of Blink... - LWW
    The purpose of this study was to determine to what extent the type of blink affects the tear-film breakup time and its assessment using two types of ...
  66. [66]
    Short Tear Film Breakup Time–Type Dry Eye | IOVS | ARVO Journals
    Short TBUT-type dry eye is characterized by TBUT of less than 5 seconds and dry eye symptoms such as ocular fatigue or dryness.