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Clinical characteristics of Fuchs' uveitis syndrome.


Fuchs' uveitis syndrome (FUS) accounts for 1-6% of all uveitis cases. (1,2) This syndrome is diagnosed based on clinical findings, without any laboratory testing. The clinical features of FUS have been described extensively in many studies. (3,4,5) However, there are data in the literature indicating that the clinical findings of FUS vary between different populations. (3,6,7,8) Despite the clinical signs being well known, the incorrect and/or delayed diagnosis of FUS is still a frequent occurrence.

The aim of this study was to evaluate the findings at time of presentation, the clinical and demographic characteristics, medical and surgical approaches used and complications during follow-up in Turkish patients diagnosed with FUS presenting to a reference hospital.

Materials and Methods

Of the 1,084 patients who presented to the Uvea unit of the Ulucanlar Eye Hospital, the medical records of the 161 patients (14.8%) diagnosed with FUS were analyzed retrospectively. FUS diagnosis was based on clinical findings as previously described in the literature. (5,9,10,11) Accordingly, cases exhibiting typically unilateral, chronic, low-grade anterior chamber reaction with varying degrees of vitreous opacity, widespread small- or medium-sized keratic precipitates (KP) in the corneal epithelium, diffuse iris atrophy and/or heterochromia but without acute exacerbations, posterior synechiae or cystoid macular edema were clinically diagnosed with FUS. All patients' diagnosis and follow-up visits were conducted in the uvea unit by the same physician (P.C.O.).

A detailed history was obtained from each patient followed by a thorough ophthalmologic examination. Each follow-up visit included best corrected visual acuity (BCVA) assessment, slit-lamp examination of the anterior segment in both eyes, intraocular pressure (IOP) measurement by Goldmann applanation tonometry, and dilated fundus examination using a 90 diopter (D) lens. Patients with IOP [greater than or equal to] 21 mmHg underwent angle assessment using gonioscopy. Glaucoma was defined as IOP [greater than or equal to] 21 mmHg with optic disc cupping and/or glaucomatous visual field loss, or as the presence of glaucomatous visual field loss despite IOP <21 mmHg.

In order to aid differential diagnosis, erythrocyte sedimentation rate, whole blood count, tuberculin skin test, chest radiograph, angiotensin converting enzyme test, syphilis serology, and cranial magnetic resonance imaging (MRI) were performed as necessary. Fundus fluorescein angiography (FFA) was done in cases with retinal vasculitis findings. Visual field evaluation and ultrasonography were also conducted in selected patients when necessary.

Patients who had sight-limiting KP and cells and were scheduled for surgery were treated with topical corticosteroid for one week prior to the procedure. Patients with severe vitreous haze that significantly limited their vision were treated with posterior sub-Tenon's triamcinolone injection prior to planning the surgical approach.

Analysis included patients' age at diagnosis, gender, clinical findings at disease onset, follow-up duration, systemic diseases, BCVA at initial and final visits, complications, and medical and surgical treatments.

Data were analyzed with Statistical Package for the Social Sciences version 22.0 (SPSS Inc., Chicago, IL, USA). Mean values and percentages were obtained for analysis.


The present study included 171 eyes of 161 patients diagnosed with FUS. Ninety-four (58.4%) of the patients were female, 67 (41.6%) were male. Mean age at diagnosis was 35.2 [+ or -] 11.0 years (range, 11-65 years). Five patients (3.1%) were under the age of 16. Mean follow-up time was 23.5 [+ or -] 32.8 months (range, 2-216 months). Four (2.4%) of the patients had rheumatoid arthritis, 1 (0.6%) had type 1 diabetes mellitus, 1 (0.6%) had epilepsy, and 1 (0.6%) had thyroid disease. The right eye was involved in 84 patients (52.1%) and the left eye was involved in 67 patients (41.6%), while 10 patients (6.2%) had bilateral involvement.

Blurred vision or decreased visual acuity was the most common complaint at presentation (63 patients, 39.1%). Sixty-eight patients (42.2%) had no symptoms, and the condition was noticed incidentally during routine examinations in the outpatient clinic. Symptoms at presentation are summarized in Table 1.

BCVA at the initial visit was [greater than or equal to] 0.6 in 98 eyes (57.3%), between 0.2 and 0.5 in 38 eyes (22.2%), and [less than or equal to] 0.1 in 35 eyes (20.4%). At the final visit, BCVA distribution was [greater than or equal to] 0.6 in 137 eyes (80.1%), between 0.2 and 0.5 in 15 (8.7%), and [less than or equal to] 0.1 in 19 (11.1%). Of the patients with a final BCVA [less than or equal to] 0.1, 1 eye (0.6%) was aphakic, while glaucomatous optic atrophy was observed in 4 eyes (2.4%), cataract in 8 (4.9%), cataract plus vitreous condensation in 4 (2.4%), and vitreous condensation alone in 2 eyes (1.2%).

KP was observed in 168 eyes (98.2%) at initial presentation, while 3 eyes (1.8%) did not exhibit KP During follow-up, KP occasionally disappeared and reappeared or fluctuated in severity. In the majority of cases (143 eyes, 85.1%) KP were small to medium-sized, round, thin, white precipitates diffusely scattered over the entire posterior corneal surface (Figure 1). At initial visit the anterior chamber reaction was usually mild to moderate (reaction [less than or equal to] [1+] in 67 eyes [39.2%]). Although the severity of vitreous cells and opacity could not be evaluated in some of the involved eyes due to cataract, inflammatory cell reaction between (1 +) and (3 +) in the vitreous was observed in 120 eyes (70.2%). Forty-seven eyes (27.4%) exhibited heterochromia with varying degrees of iris depigmentation. The iris was atrophic at the pupillary margin in 80 eyes (46.7%), while flattening of iris crypts was observed in 41 eyes (23.9%) (Figure 2). Small multifocal Koeppe nodules localized to the pupillary margin were present in 32 eyes (18.7%); both Koeppe and Busacca nodules were present in 4 eyes (2.4%) (Figure 3). Posterior synechia was observed in 1 patient (0.7%) who had an IOL implant.

At diagnosis, 89 eyes (52%) had cataract. Of these, 2 (2.2%) were nuclear, 5 (5.6%) were mature, and 82 (92.1%) were posterior subcapsular cataract (Figure 4). Twenty-six eyes (15.2%) were pseudophakic. Findings at presentation are summarized in Table 2.

At final visit, 60 eyes (35.0%) were pseudophakic and 1 (0.6%) was aphakic. IOP was within normal limits in 134 patients (83.2%), whereas medical treatment for glaucoma was administered in 31 eyes (18.1%) of 27 patients (16.8%).

The most common complication during follow-up was cataract (89 eyes, 52.0%), followed by glaucoma (31 eyes, 18.1%), vitreous condensation (27 eyes, 15.7%) and secondary cataract (24 eyes, 14.0%). Complications observed are presented in Table 3.

Topical steroid therapy was administered in 26 eyes (15.2%) and periocular steroid injection was administered in 6 eyes (3.5%) due to severe inflammation in the vitreous. Thirty-one eyes (18.1%) received topical antiglaucomatous medication.

The visual acuity of 35 eyes (20.4%) worsened during the follow-up period; these eyes were treated with phacoemulsification (phaco) and intraocular lens (IOL) implantation. Trabeculectomy was performed on 8 eyes (4.7%) with uncontrolled IOP despite maximum medical treatment. Posterior capsule opacification developed in 34 eyes (19.8%) and was treated with YAG laser capsulotomy. Pars plana vitrectomy was performed in a total of 3 eyes (1.8%), 2 (1.2%) due to severe vitreous condensation and 1 (0.6%) due to vitreous hemorrhage. All surgical procedures performed are summarized in Table 4.


FUS, which was first described in 1906 by Fuchs, (4) cannot be diagnosed by any laboratory test; its diagnosis is based solely on clinical findings. Despite these clinical findings being well defined in many studies, an accurate diagnosis is often delayed. (9,12) Misdiagnosis results in unnecessary tests and ineffective treatment. (5,7,9,10,11,12,13) The condition is usually unilateral, with only 5-10% of cases showing bilateral involvement. (10,14) One of the classic findings is KP, which have been described as diffuse, small, nonpigmented stellate precipitates that are usually nongranulomatous and tend not to aggregate. The vast majority of our patients (93.7%) exhibited unilateral involvement with small to medium white KP diffusely scattered over the corneal endothelium as well as mild anterior uveitis. Tugal-Tutkun et al. (10) described most of the KPs in their study (74.6%) as medium-sized. Descriptions of the clinical features of FUS have focused on findings related to anterior uveitis, while inflammatory findings in the posterior segment were assigned less importance. (7,9,13,15,16) However, this plays a major role in the misdiagnosis of FUS. Failure to realize that heterochromia, described as a primary clinical sign of FUS, does not occur in all cases or that inflammatory reaction in the vitreous is a sign of FUS has been reported as the main causes of misdiagnosis. (12,17) Consistent with these reports, in the current study heterochromia was present in 27.4% of cases at presentation, while inflammatory reaction in the vitreous was observed in 71.3% of cases. Bouchenaki and Herbort (17) reported that among 105 FUS patients, 77.1% with posterior segment manifestation had been referred with incorrect diagnoses (intermediate uveitis, 56.8%; posterior uveitis, 8.1%; panuveitis, 12.2%) and that their diagnosis were delayed by 3 years on average. Various studies have reported this diagnostic delay ranging from 3 to 6.7 years. (9,12) The clinical and demographic characteristics of studies in the literature are summarized in Table 5.

The most common complaint at presentation among the patients in the current study was decreased visual acuity or blurred vision (39.1%). Similarly, Yang et al. (3) reported that decline in visual acuity or blurred vision were the most common symptoms (in 82.6%) of the patients in their study. A large proportion of our patients had no additional symptoms (42.2%) and FUS was detected incidentally during routine outpatient follow-up visits. This is attributable to the disease course characterized by chronic, low-grade inflammation.

FUS usually manifests unilaterally, though the reported rate of bilateral involvement varies in the literature (0-21%). (3,6,7,10) In the current study, both eyes were involved in 6.2% of our cases. Norrsell and Sjodell (12) found that patients with bilateral involvement had more progressive disease, developed glaucoma more frequently, and required surgical approaches such as pars plana vitrectomy and cataract surgery more often. Of the bilateral FUS cases in our study, 2 developed glaucoma and another 2 formed epiretinal membrane associated with posterior segment involvement.

Iris changes are a typical finding of FUS. Hypochromia in the affected eye resulting from diffuse pigment loss is the key feature of FUS. (4,7,18,19) Heterochromia, characterized by color differences between the two eyes, is more apparent in light colored eyes than in dark eyes; therefore, the reported frequency of heterochromia varies widely between populations (12.7-82%). (3,5,6,7,10,12,13,18) In this study, we found heterochromia at a rate of 27.4%. This finding has long been considered a principal sign of FUS and even lead to it being called 'Fuchs' heterochromic iridocyclitis'. However, due to its varying rate of presentation it is important to remember, especially during diagnosis, that heterochromia is not observed in all cases.

Other findings of FUS include iris edema, iris nodules, abnormal iris blood vessels, and more rarely peripheral anterior adhesions and filiform hemorrhage of the anterior chamber angle during paracentesis. (20) Tugal-Tutkun et al. (10) analyzed a large case series and emphasized that medium-sized round KP and iris nodules were more common findings than heterochromia in the Turkish population. They observed iris nodules in 32% of the cases in their study, compared to 21% in our study population. This low rate may be due to these nodules, which are small and few in number in the majority of cases, not being recorded.

Many studies have emphasized cataract development as the most common complication observed in FUS patients. (3,7,10,16,19) Tugal-Tutkun et al. (10) found a 56% risk of cataract formation in patients not receiving steroid treatment over their 8-year follow-up period. Yang et al. (3) also emphasized cataract as the most common (70.7%) complication in their study Similarly, cataract development was the most common complication observed in our study, at 52%. The variation reported in different studies may be related to disease duration and the chronic nature of the disease. Cataract develops due to changes in lens permeability resulting from recurrent uveitis attacks. (21) Unnecessary steroid therapy also increases the risk of cataract formation.

Today, successful visual outcomes can be achieved with modern cataract surgical techniques and IOL implantation. The most common surgical approach utilized during follow-up in our study was phaco-IOL implantation (20.4%). Following cataract surgery, 85.2% of the patients had a final BCVA of 0.6 or better.

Glaucoma is another of the main complications seen in FUS. Its reported frequency varies widely in the literature (11-59%). (3,7,9,16,18) Glaucoma was detected in 18.1% of our cases. IOP could not be controlled with medical treatment in 25.8% of those patients, necessitating trabeculectomy. IOP was controlled postoperatively with or without medication in all patients who underwent surgery.

There are reports in the literature of posterior segment findings in FUS patients such as chorioretinal scars associated with ocular toxoplasmosis infection, epiretinal fibrosis, and peripheral vascular changes. (7,9,18) Posterior segment findings observed in the current study included chorioretinal scar (2.3%), peripheral vascular sheathing (2.3%) and intravitreal hemorrhage (0.6%).


In this study we investigated clinical findings in FUS patients. Most of our patients exhibited diffuse, small to medium, white, round or large, stellate KP, low-grade anterior chamber reaction, and vitreous cells and/or vitreous opacity and/or vitreous degeneration with no marked involvement of the posterior pole. We found that vitreous involvement and KP pattern were more prominent diagnostic features than heterochromia. The most common complications during follow-up were cataract, posterior capsule opacification after cataract surgery, glaucoma and vitreous condensation. Based on our data, we believe that a diagnosis of FUS should be considered in cases that are generally unilateral with no marked iris depigmentation but with diffuse small white KP and low-grade anterior chamber reaction, where the fundus is visible and there are no other inflammatory findings except vitreous cells, opacity and/or changes in the vitreous collagen fibers.


Ethics Committee Approval: It was taken from Yildirim Beyazit University Yenimahalle Research and Training Hospital, Informed Consent: It was taken. Peer-review: Externally peer-reviewed.

Authorship Contributions

Surgical and Medical Practices: Pinar Cakar Ozdal, Concept: Pinar Nalcacioglu, Pinar Cakar Ozdal, Design: Pinar Nalcacioglu, Data Collection or Processing: Pinar Nalcacioglu, Mert Simsek, Analysis or Interpretation: Pinar Nalcacioglu, Literature Search: Pinar Nalcacioglu, Mert Simsek, Writing: Pinar Nalcacioglu. Conflict of Interest: No conflict of interest was declared by the authors.

Financial Disclosure: The authors declared that this study received no financial support.

DOI: 10.4274/tjo.99897


(1.) Kazokoglu H, Onal S, Tugal-Tutkun I, Mirza E, Akova Y Ozyazgan Y Soylu M, Batioglu F, Apaydin C Demographic and clinical features of uveitis in tertiary centers in Turkey. Ophthalmic Epidemiol. 2008;15:285-293.

(2.) Rathinam SR, Namperumalsamy P Global variation and pattern changes in epidemiology of uveitis. Indian J Ophthalmol. 2007;55:173-183.

(3.) Yang P, Fang W Jin H, Li B, Chen X, Kiljstra A. Clinical features of Chinese patients with Fuchs' syndrome. Ophthalmology. 2006;113:473-480.

(4.) Fuchs E. Ueber Komplikationen der heterochromie. Ophthalmologica. 1906;15:191-212.

(5.) Mohamed Q, Zamir E. Update on Fuchs' uveitis syndrome. Curr Opin Ophthalmol. 2005;16:356-363.

(6.) Arellanes-Garcia L, del Carmen Preciado-Delgadillo M, Recillas-Gispert C. Fuchs' heterochromic iridocyclitis: clinical manifestations in dark-eyed Mexican patients. Ocul Immunol Inflamm. 2002;10:125-131.

(7.) Tabbut BR, Tessler HH, Williams D. Fuchs' heterochromic iridocyclitis in blacks. Arch Ophthalmol. 1988;106:1688-1690.

(8.) Rothova A, La Hey E, Baarsma GS, Breebaart AC. Iris nodules in Fuchs' heterochromic uveitis. Am J Ophthalmol. 1994;118:338-342.

(9.) Fearnley IR, Rosenthal AR. Fuchs' heterochromic iridocyclitis revisited. Acta Ophthalmol Scand. 1995;73:166-170.

(10.) Tugal-Tutkun I, Guney-Tefekli E, Kamaci-Duman F, Corum I. A cross-sectional and longitudinal study of Fuchs uveitis syndrome in Turkish patients. Am J Ophthalmol. 2009;148:510-515.

(11.) Ozdal PC, Yazici A, Elgin U, Ozturk F. Fuchs uveit sendromunda santral kornea kalinligi. Turk J Ophthalmol. 2013;43:225-228.

(12.) Norrsell K, Sjodell L. Fuchs' heterochromic uveitis: a longitudinal clinical study. Acta Ophthalmol. 2008;86:58-64.

(13.) Jones NP. Fuchs' heterochromic uveitis: an update. Surv Ophthalmol. 1993;37:253-272.

(14.) Cunningham ET Jr, Baglivo E. Fuchs heterochromic iridocyclitis-syndrome, disease, or both? Am J Ophthalmol. 2009;148:479-481.

(15.) Velilla S, Dios E, Herreras JM, Calonge M. Fuchs' heterochromic iridocyclitis: a review of 26 cases. Ocul Immunol Inflamm. 2001;9:169-175.

(16.) Liesegang TJ. Clinical features and prognosis in Fuchs' uveitis syndrome. Arch Ophthalmol. 1982;100:1622-1626.

(17.) Bouchenaki N, Herbort CP. Fuchs' uveitis: failure to associate vitritis and disc hyperfluorescence with the disease is the major factor for misdiagnosis and diagnostic delay. Middle East Afr J Ophthalmol. 2009;16:239-244.

(18.) La Hey E, Baarsma GS, De Vries J, Kijlstra A. Clinical analysis of Fuchs heterochromic cyclitis. Doc Ophthalmol. 1991;78:225-235.

(19.) Jones NP. Fuchs' Heterochromic Uveitis: a reappraisal of the clinical spectrum. Eye (Lond). 1991;5:649-661.

(20.) La Hey E, de Jong PT, Kijlstra A. Fuchs' heterochromic cyclitis: review of the literature on the pathogenetic mechanisms. Br J Ophthalmol. 1994;78:307312.

(21.) Gupta R, Murray PI. Chronic non-infectious uveitis in the elderly: epidemiology, pathophysiology and management. Drugs Aging. 2006;23:535-558.

Pinar Nalcacioglu *, Pinar Cakar Ozdal **, Mert Simsek **

* Yildirim Beyazit University Faculty of Medicine, Department of Ophthalmology, Ankara, Turkey

** Ulucanlar Eye Training and Research Hospital, Ankara, Turkey

Address for Correspondence: Pinar Nalcacioglu MD, Yildirim Beyazit University Faculty of Medicine, Department of Ophthalmology, Ankara, Turkey Phone: +90 530 402 30 88 E-mail: Received: 05.04.2015 Accepted: 22.06.2015 This article is also published in Turkish under doi:10.4274/tjo.99897 pages 2016;46:52-57

This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestric distribution, and reproduction in any medium, provided the original work is properly cited.

Table 1. Patients' symptoms at presentation

Symptom *                                    n (%)

No symptoms                                  68 (42.2%)
Decreased visual acuity or blurred vision    63 (39.1%)
Floaters                                     19 (11.8%)
Irritation                                   14 (8.6%)

* Some patients had more than one symptom

Table 2. Ocular findings in 171 eyes of 161 patients at
time of presentation

Finding                               n (%)

Keratic precipitates                  168 (98.2%)

Iris atrophy
  Heterochromia                       47 (27.4%)
  Loss of iris crypts                 41 (23.9%)
  Atrophy at the pupillary margin     80 (46.7%)

Iris nodules
  Koeppe nodules                      32 (18.7%)
  Koeppe ve Busacca nodules           4 (2.3%)

Anterior chamber reaction
  [less than or equal to]+1           67 (39.2%)
  +1<x[less than or equal to]+2       15 (8.7%)

Vitreous reaction
  [less than or equal to]+1           63 (36.8%)
  +1<x[less than or equal to]+2       52 (30.4%)
  +2<x[less than or equal to]+3       5 (2.9%)
  +4 (severe vitritis)                2 (1.2%)

Lens opacity
  Posterior subcapsular opacity       82 (47.9%)
  Mature cataract                     5 (2.9%)
  Nuclear opacity                     2 (1.2%)

Table 3. Complications observed in patients with
Fuchs' uveitis syndrome

Complication *                   n (%)

Cataract                         89 (52%)
Glaucoma                         31 (18.1%)
Vitreous condensation            27 (15.7%)
Secondary cataract               24 (14.0%)
Iris pigmentation on the IOL     19 (11.1%)
Glaucomatous optic disc          12 (7.0%)
Epiretinal membrane              4 (2.3%)
Peripheral vascular sheathing    4 (2.3%)
Chorioretinal scar               4 (2.3%)
Intravitreal hemorrhage          1 (0.6%)
Corneal endothelial plaque       1 (0.6%)

* In some eyes there were multiple complications; n:
Number of eyes affected, IOL: Intraocular lens

Table 4. Surgical procedures performed in patients with
Fuchs' uveitis syndrome

Surgery *                 n (%)

Phaco-IOL                 35 (20.4%)
YAG laser capsulotomy     34 (19.8%)
Trabeculectomy            8 (4.6%)
Pars plana vitrectomy     3 (1.7%)

* Some eyes underwent more than one surgical procedure; n: Number
of eyes, phaco-IOL: Phacoemulsification and intraocular lens

Table 5. Demographic and clinical characteristics of patients with
Fuchs' uveitis syndrome as reported in the literature

Characteristic               Yang et        Arellanes-
                             al. (3)        Garcia et
                                            al. (6)

Patient number (n)           104            68
Mean age (years, min-max)    39.5 (16-78)   31 (5-80)
Gender (Male:Female)         1:1.1          1:0.8
Bilateral involvement        13.5%          10.3%
Keratic precipitates         99.2%          90%
Aqueous cells *              68.7%          86%
Vitreous cells               73.8%          46.7%
Heterochromia                12.7%          25.3%
Iris atrophy                 100%           53.3%
Iris nodules                 28%            47.8%
Cataract and IOL             70.7%          69.3%
Elevated IOP and Glaucoma    23.1%          34.6%
Chorioretinal lesion         0%             1.3%

Characteristic               Norrsell and   Tugal-Tutkun
                             Sjodell (12)   et al. (10)

Patient number (n)           54             172
Mean age (years, min-max)    37 (19-57)     29.5 (10-75)
Gender (Male:Female)         1:1.6          1:1.3
Bilateral involvement        5.5%           5.2%
Keratic precipitates         100%           96.7%
Aqueous cells *              --             74%
Vitreous cells               92.6%          71.8%
Heterochromia                75.9%          39.7%
Iris atrophy                 100%           88.4%
Iris nodules                 --             32%
Cataract and IOL             92.6%          69.1%
Elevated IOP and Glaucoma    11.1%          12.7%
Chorioretinal lesion         11.1%          7.7%

Characteristic               La Hey         Liesegang
                             et al. (18)    (16)

Patient number (n)           51             54
Mean age (years, min-max)    40 (17-71)     44.5
Gender (Male:Female)         1:0.7          1:1.3
Bilateral involvement        4%             0%
Keratic precipitates         88%            96%
Aqueous cells *              60%            74%
Vitreous cells               84%            53.7%
Heterochromia                82%            77.8%
Iris atrophy                 100%           98%
Iris nodules                 10%            1.9%
Cataract and IOL             82%            90.7%
Elevated IOP and Glaucoma    22%            59%
Chorioretinal lesion         8%             3.7%

Characteristic               The current

Patient number (n)           161
Mean age (years, min-max)    35.2 (11-65)
Gender (Male:Female)         0.7:1
Bilateral involvement        6.2%
Keratic precipitates         98.2%
Aqueous cells *              47.9%
Vitreous cells               71.3%
Heterochromia                27.4%
Iris atrophy                 46.7%
Iris nodules                 14.0%
Cataract and IOL             66.6%
Elevated IOP and Glaucoma    18.1%
Chorioretinal lesion         2.3%

* In some studies, evaluation of aqueous cells was done by laser
flare photometry. --: Was not included in analysis, IOL: Intraocular
lens, IOP: Intraocular pressure
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Title Annotation:Original Article
Author:Nalcacioglu, Pinar; Ozdal, Pinar Cakar; Simsek, Mert
Publication:Turkish Journal of Ophthalmology
Article Type:Report
Date:Mar 1, 2016
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