Abstract
Background/aims: Uveitis is a major cause of visual morbidity in the working age group. The authors investigated the duration, degree, and causes of visual loss in uveitis patients with the aim of better defining the visual morbidity and identifying potential risk factors.
Methods: A retrospective, non-interventional, observational survey of 315 consecutive patients attending a tertiary referral uveitis service.
Results: The mean duration of follow up was 36.7 months. Reduced vision (⩽6/18) was found in 220/315 (69.95%) of the patients with a subset of 120 patients having vision ⩽6/60. Unilateral visual loss occurred in 109 (49.54%), while 111 (50.45%) had bilateral loss. The mean duration of visual loss was 21 months. Of the 148 patients with pan-uveitis, 125 (84.45%) had reduced vision, with 66 (53%) having vision ⩽6/60. Main causes of visual loss were cystoid macular oedema (CMO) (59/220, 26.8%), cataract (39/220, 17.7%), and combination of CMO and cataract (44/220, 20%). The following were predictive of a poorer visual prognosis: pan-uveitis (p = 0.0005), bilateral inflammation (p = 0.0005), increasing duration of reduced vision (p = 0.0005), an Indian or Pakistani ethnic background (p = 0.004), and increasing patient age (p = 0.02).
Conclusion: Prolonged visual loss occurred in two thirds of uveitis patients, with 70 (22%) patients meeting the criteria for legal blindness at some point in their follow up. Older patients with bilateral inflammation and an increasing duration of reduced vision are at the greatest risk of severe visual loss (⩽6/60). CMO and cataract were responsible for visual loss in 64.5% of patients.
Keywords: uveitis, vision loss
Uveitis is a term used to describe a group of intraocular inflammatory diseases that can occur at any age but predominantly affects patients in the working age group.1 The average annual incidence of uveitis has been reported as approximately 14–17 per 100 000, rising to a peak in the 20–50 age group, when it then declines.2–6 The total population prevalence of uveitis varies geographically; 38 per 100 000 in France,4 68–76.6 per 100 000 in Finland,7 around 200 per 100 000 in the United States,2 and is estimated to be 730 per 100 000 in India.8 It can cause devastating visual loss and is the fifth commonest cause of visual loss in the developed world, accounting for about 10–15% of the cases of total blindness (World Health Authority definition) and up to 20% of legal blindness.2,9–11 The WHO defines blindness as the best corrected vision in the better eye of less than 3/60 or a visual field ⩽10°, whereas severe visual impairment is defined as the best corrected visual acuity in the better eye of 3/60 or more, but less than 6/60 or a visual field ⩽20°. Legal blindness can be defined in certain countries as the level of blindness that makes a person eligible for social support and financial benefits.
The main causes of vision loss in the 20–60 years age group include diabetes (20%), tapetoretinal degeneration (20%), congenital anomalies (20%), uveitis (10%), and trauma (5%).1 Of these, only blindness caused by diabetes and uveitis is potentially treatable. Most of the published data on blindness focus on the older age group with very few data available for this age group. Recent epidemiological studies looking at serious eye diseases and blindness do not even mention uveitis.13–18
With a majority of the patients in the working age group, the potential social and economic costs are tremendous. For a disease with such far reaching consequences, relatively few data exist about visual morbidity caused by uveitis. A comprehensive review of the literature that included Embase, Medline, OHE HEED, and the Cochrane library (database of systematic reviews DARE, CCTR, NHS EDD) up to July 2003 found no studies of the economic cost of blindness from uveitis.
The aims of this retrospective, observational, non-interventional study are to investigate the degree, duration, and causes of visual loss in uveitis patients. The duration of uveitis associated visual loss has not previously been investigated. We feel this is a key factor in providing a better insight into the socioeconomic implication of this disease, by not only identifying those patients with permanent visual loss but also any subgroup of patients with a severe but temporary visual disability.
PATIENTS AND METHODS
The medical records of 315 consecutive patients attending a tertiary referral uveitis service at the Birmingham and Midland Eye Centre over a two year period (January 1998 to December 2000) were reviewed. All patients had undergone a detailed clinical history and ocular examination including visual acuity, pupillary reactions, slit lamp examination, intraocular pressure (IOP) measurement, posterior pole biomicroscopy, and indirect ophthalmoscopy. Where appropriate, patients were investigated for any underlying disease association. The data recorded included age, sex, race, duration of follow up, and laterality of inflammation and causes of visual loss. Patients were identified as having permanent ocular damage if they had irreversible changes, such as macular scarring or atrophy, lamellar macular hole formation, optic atrophy, and so on. The anatomical site of inflammation was used to classify the uveitis according to the recommendations of the International Uveitis Study Group.9 Snellen visual acuity was recorded at each visit. For the purpose of this study, visual loss was defined as best corrected vision of 6/18 or worse. Patients with visual morbidity were subdivided into two groups: those with moderate visual loss defined as 6/18 to 6/36, and those with severe visual reduction defined as ⩽6/60. In addition to the degree of reduced vision, the duration of visual loss was also calculated. As the level of vision in uveitis may fluctuate with varying severity or sequelae of inflammation, the total duration of visual loss was calculated by adding the duration of individual episodes. The causes of visual impairment were also recorded.
Statistical analysis was carried out using MINITAB statistical software, version 13.1 (Minitab Inc, University Park, PA, USA). The impact of patient sex, race, type of uveitis, age, and age of onset on visual loss, was analysed using binary logistic regression while the association between duration, laterality of inflammation, and severity of visual loss were analysed using a two sample t test and Mann-Whitney test.
RESULTS
A total of 315 consecutive uveitis patients with a mean age of 48 years (range 7–86 years) and a mean duration of follow up of 36.71 months (standard deviation 53.73, range 2–360 months) were included in the study. Patient demographics are presented in table 1 and the type of uveitis in table 2. Within this cohort of 315 patients, 220 (69.95%) had visual loss of ⩽6/18 in at least one eye. Of this subset of 220 patients with unilateral or bilateral reduced vision, 100 (45.45%) had moderate visual loss (6/18–6/36), and 120 (54.54%) had severe visual loss of ⩽6/60. Some degree of permanent visual damage was found in 54/220 (24.5%) patients; 11 patients had unilateral and 46 had bilateral damage. Only 36 of the 315 (11.4%) patients met the WHO blindness criteria.
Table 1.
Patients (n = 315) | |
Age (years) | |
Mean | 48 |
Range | 7–86 |
Follow up (years) | |
Mean | 3 |
Range (years) | (0.3–30) |
Sex | |
Male | 121 (38.4%) |
Female | 194 (61.6%) |
Race | |
Caucasian | 190 (60.3%) |
Indian/Pakistani | 88 (27.9%) |
Afro-Caribbean | 35 (11.1%) |
Mixed race | 1 (0.6%) |
Table 2.
Diagnosis | Total population (n = 315) | Patients with visual loss (n = 220, 69.84%) | Severity* (%) | |
Moderate | Severe | |||
Pan-uveitis | 148 | 125 (84.45%) | 59 (47) | 66 (53) |
Anterior uveitis | 81 | 45 (55.55%) | ||
Acute | 40 | 19 (47.5%) | 9 (47.36) | 10 (52.63) |
Chronic | 41 | 26 (63.41%) | 10 (38.46) | 16 (61.53) |
Intermediate uveitis | 33 | 17 (51.51%) | 12 (70) | 5 (30) |
Fuchs’ heterochromic uveitis | 29 | 18 (62%) | 7 (39) | 11 (61) |
Posterior uveitis | 11 | 7 (63.6%) | 3 (43) | 4 (57) |
Sclero-uveitis | 13 | 8 (61.5%) | 3 (38) | 5 (62) |
*Moderate, 6/18–6/36; severe, ⩽6/60.
Of the 315 patients chronic unilateral intraocular inflammation was present in 107 (34%) patients and resulted in reduced vision (moderate and severe) in 68 of those (63%). Moderate loss was in 19/68 (28%), and 49/68 (72%) had severe reduction in vision. Bilateral inflammation was present in 208/315 (66%) patients with 152/208 (73%) having moderate or severe visual loss; 41/152 (27%) lost vision in one eye and 111/152 (73%) in both eyes. Of the 111 patients with bilateral visual loss, 70 (63%) experienced severe visual loss, thus meeting the criteria for legal blindness in many parts of the world.
The mean duration of visual loss was 20.35 months for patients with moderate visual loss and 22.8 months in patients with severe loss of vision. In patients with unilateral visual loss the mean duration was 20 months whereas it was 42.61 months in patients with bilateral visual morbidity.
Visual loss was more common in patients with pan-uveitis (125/148, 84.45%), followed by anterior uveitis (AU) (45/81, 55.5%). Of the patients with AU, 40 had acute AU and 41 had chronic AU. Visual reduction was more common and severe in the chronic AU subgroup (table 2).
Of the patients under the age of 40 years (n = 111, 35.5%), 40% had pan-uveitis and 24.8% had bilateral visual loss. In the 40–60 years age group (n = 120, 38%), 48.3% had pan-uveitis and 29.8% had bilateral loss of vision. For patients over 60 years of age (n = 87, 26.5%) pan-uveitis was found in 46% of the cases but prevalence of bilateral visual morbidity increased to 49%.
In the 220 patients with visual loss the main causes were cystoid macular oedema (CMO) (n = 59, 26.8%), cataract (n = 39, 17.7%), and a combination of CMO and cataract (n = 44, 20%). A variety of other causes including glaucoma, band keratopathy, vitreous debris, severe vitritis, retinal detachment, optic neuropathy, epiretinal membrane formation, and submacular fibrosis resulted in visual loss in an additional 78 (35.5%) of the patients (table 3).
Table 3.
Causes of visual loss | Number (%) |
Cystoid macular oedema (CMO) | 59 (26.8) |
Lens opacity (LO) | 39 (17.7) |
CMO+LO | 44 (20) |
Vitreous debris | 24 (10.9) |
Macular pathology (scarring, atrophy, hole) | 17 (7.7) |
Optic neuropathy (non-glaucomatous) | 11 (5) |
Glaucoma | 11 (5) |
Retinal detachment | 8 (3.6) |
Multiple factors (other than CMO, LO) | 7 (3.1) |
The following were found to be strong predictors of visual loss (table 4): pan-uveitis (p = 0.0005, OR = 4.14, 95% CI 2.37 to 7.24), an Asian (Indian or Pakistani) race (p = 0.004, OR = 2.65, 95% CI 1.37 to 5.11), and increasing patient age (p = 0.02, OR = 1.02, 95% CI 1.0 to 1.04). Age of onset of uveitis and patient sex were not found to have a statistically significant impact on vision. Patients with an increasing duration of reduced vision (p = 0.0005, t value = −4.62, 95% CI = −0.5099 to −0.174), and bilateral inflammation were at a much higher risk of visual loss (p = 0.0005, t value = −4.62, 95% CI −0.556 to −0.224).
Table 4.
Factor | p Value | Odds ratio/t value* | 95% confidence interval |
Pan-uveitis | 0.0005 | 4.14 | 2.37 to 7.24 |
Bilateral inflammation | 0.0005 | *−4.62 | −0.5561 to −0.2236 |
Duration of visual loss | 0.0005 | *−4.01 | −0.5099 to −0.1736 |
Indian/Pakistani | 0.004 | 2.65 | 1.37 to 5.11 |
Patient age | 0.019 | 1.02 | 1.00 to 1.04 |
DISCUSSION
In our cohort of 315 patients, 220 (69.9%) experienced visual loss ⩽6/18 with 50.45% having bilateral reduced vision. This is higher than previously reported,1,12,13 and may be due to our definition of visual loss as an acuity of ⩽6/18, as we felt that visual reduction to this level was more likely to interfere with daily life. This is supported by a recent study by Evans et al14 that also defines visual impairment as a vision ⩽6/18. Most other studies used the WHO definition of vision loss.1,12,15,16 Also, being a tertiary referral centre, more patients are likely to suffer from severe, often bilateral uveitis. A similar pattern is seen in most studies from specialist centres with pan-uveitis being the most common diagnosis.17,18 Results from population or community based studies are likely to have a different referral pattern with anterior uveitis as the most common type of uveitis.19,20 A recent study by Taylor and Keeffe21 suggests that economic blindness actually occurs when vision drops below 6/12, as vision below this level affects a person’s ability to drive and function in the workplace. This is supported by a study by West et al that found vision less than 20/30 (6/9, logMAR 0.2) affected visually intensive tasks such as reading.22
Studies by Rothova et al and Bodaghi et al have investigated the incidence and aetiology of blindness in similar cohorts of patients but do not provide information on the duration of visual morbidity, or document temporary visual loss that is likely to reduce the quality of life and impair the economic productivity of these patients.12,18 Our data suggest that loss of vision in uveitis occurs predominantly as a temporary, sometimes severe visual deterioration lasting weeks, months, or even years primarily from CMO, cataract, or a combination of the two. In most forms of uveitis, visual morbidity usually does not occur from a single episode of uveitis; rather recurrent episodes of inflammation cause cumulative damage. However some patients with severe disease can develop refractory CMO at an early stage whereas patients with Behçet’s disease can develop devastating visual loss within days despite intensive immunosuppression.
In our study we used the IUSG classification to record the type of uveitis and found pan-uveitis to have a poorer visual outcome. The aetiology of the underlying inflammation, if known, must also be taken in to account as not all types of uveitis have the same impact on vision. Conditions such as Behçet’s disease and birdshot retinochoroidopathy are likely to have a much worse prognosis compared with Fuchs’ heterochromic uveitis syndrome, where visual prognosis is much better, though cataract formation occurs in most patients and causes reduced vision until cataract surgery is performed.
Considering that the mean duration of follow up was 36.7 months, 70% of the patients had some degree of visual loss for two thirds of that time. Difficulties in achieving control of intraocular inflammation result in delays in performing cataract surgery, while CMO is also unlikely to resolve in the presence of active disease. These patients are likely to suffer tremendous visual and socioeconomic hardship and may not qualify for visual disability registration. This dilemma is highlighted as only 36 out of 220 patients with visual morbidity in our cohort were eligible for blind registration, even though 70 patients (22% of the total cohort) met the criteria for legal blindness at some point during their follow up. An additional 18 patients had some degree of permanent visual damage (7 bilateral and 11 unilateral) but did not fulfil the requirements of blind registration. The adverse impact of unilateral as well as bilateral visual reduction on quality of life is also well established.23–26 Two studies based on the Blue Mountains Eye Study cohort found that although bilateral visual morbidity results in reduced functional status and wellbeing that is comparable to a major medical condition, moderate to severe unilateral visual loss also has a measurable impact on quality of life.27,28 A study by the Royal National Institute for the Blind suggested that 34% of individuals lose jobs within two years of visual impairment.29 In the 1993 annual report of Research to Prevent Blindness, an estimated 2.3 million Americans suffered visual impairment because of uveitis.30 In the Netherlands in a hospital based study (1975–77), uveitis caused 6% of all blindness and ranked fifth after diabetic retinopathy, age related macular degeneration, retinal dystrophies, and glaucoma.9 As these studies do not include all uveitis cases and do not report separately on the complications of uveitis, such as cataract and glaucoma, this percentage is probably higher.1 The estimated cost of blindness to the United States economy from uveitis is equal to the cost of blindness from diabetes where the incidence of diabetes is twice as high as uveitis.9 Additional morbidity from associated systemic diseases is present in 25–50% of the patients.9,31,32
We recently investigated the correlation between tests of visual function and perceived visual ability recorded with a vision quality of life questionnaire (VQOL) for patients with uveitis.23 We studied 132 patients with various types of uveitis and found that binocular high contrast visual acuity was able to predict VQOL (p<0.01), and VQOL was worst in younger patients with poor binocular visual acuity (p<0.001). VQOL also declined with reduced uniocular performance of high contrast visual acuity of the better (p = 0.0012) and worse eye (p = 0.015), in agreement with the findings of the Blue Mountain Eye Studies.27,28 Although VQOL instruments have been validated in English, this is not the case for many other languages.33 We live in a multiracial and multicultural society, but we are unable to use some these tools on many of our patients from other parts of the world as no validated translations exist.
Patients with bilateral intraocular inflammation had a poorer visual prognosis compared with the other groups in our cohort (p = 0.0005): the mean duration of visual loss was found to be twice as long (42.6 months) as patients with unilateral inflammation (20 months), with almost three out of four having reduced vision. Our experience would suggest that these patients tend to have more severe inflammation that is difficult to control. Pan-uveitis was the most common diagnosis followed by anterior uveitis, intermediate uveitis, and Fuchs’ heterochromic uveitis (table 2). Bodagi et al, in their study of 927 patients with severe uveitis, also found pan-uveitis as the most common diagnosis followed by anterior uveitis. They concluded that the results of their study could not be applied to the general population because of the tertiary nature of the patient population; this conclusion also applies to our cohort.18 Rothova et al also found pan-uveitis to have a worse visual prognosis, which was in agreement with our findings.12
Age of onset of uveitis was not found to be predictive of severity of visual loss in our cohort; this may be related to the fact that none of the patients had JIA, a known cause of visual morbidity in children.34 An increasing patient age, however, was found to have an adverse impact on vision (p = 0.019). This is probably related to an increasing prevalence of pan uveitis and bilateral disease with increasing age, though Darrell et al did not find age to be a risk factor.2 None of our patients had age related macular degeneration, but the possibility of age related cataract contributing to visual reduction cannot be ruled out in this subgroup.
A strong association was found between duration of visual loss and its severity (p = 0.0005), with an increasing duration of visual morbidity being strongly associated with poorer visual acuity. When control of inflammation is difficult, CMO persists and permanent macular changes including lamellar hole formation may occur, and any delay in cataract surgery may result in progressive deterioration of vision.
Cataract and CMO either alone or in combination were responsible for visual loss in 64.5% of the patients in our cohort, in agreement with Bodaghi et al.18 Rothova et al, investigating causes of visual loss in 582 patients with intraocular inflammation, found CMO to be the most common cause of decreased vision (26%) followed by cataract (19%).12 Although cataract surgery carries an excellent prognosis in most types of uveitis,35 it is acknowledged that the eye should be inflammation free for at least three months before surgery (Fuchs’ heterochromic uveitis being the most obvious exception), thus the patient may suffer prolonged visual morbidity until the eye is quiet enough for surgery to be undertaken.
Racial predisposition for diseases like Behçet’s disease, Vogt Koyanagi Harada disease, and sarcoidosis are well known36–38 but an association between ethnic background and visual loss in uveitis has not been described before. Our results suggest that an Indian/Pakistani ethnic background was predictive of a poorer visual prognosis (p = 0.004). The clinical significance of this association needs further investigation. Perhaps this subgroup is more prone to develop complications associated with uveitis and requires more aggressive control of inflammation, but other factors such as poor compliance due to language difficulties and cultural differences are also possible. Our cohort also had a higher preponderance or female patients (61.6%). This is unusual as most studies do not report a higher susceptibility in either sex. Merrill et al also found a higher percentage of women in their study (62%).17 As their study is based on patients from a tertiary referral service, it raises the possibility that women may be more susceptible to more severe uveitis compared with men but this needs further investigation.
Recent years have seen significant improvement in the management strategies for uveitis, but despite this visual loss occurs in up to 35–40% of the patients.12,13 A review of the literature suggests that very few data exist on the incidence and prevalence of visual loss and blindness from uveitis. This is surprising considering the likely socioeconomic impact of the disease. Most studies investigating the causes of blindness look at an older age group and do not classify uveitis as a separate entity. Epidemiological studies investigating blindness in the working age group are badly needed to define the true impact of uveitis on visual morbidity.33
Abbreviations
AU, anterior uveitis
CMO, cystoid macular oedema, IOP, intraocular pressure
LO, lens opacity
VQOL, vision quality of life
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