Article Date: 7/1/2012

CooperVision Launches Multifocal Daily Disposable

Update on Central Serous Chorioretinopathy

Among other findings, reduce-fluence and low-dose PDT look promising.

Michael Colucciello, MD

Central serous chorioretinopathy (also referred to as central serous retinopathy, but more appropriately termed a chorioretinopathy) is a condition characterized by a serous macular detachment due to a focal disruption in the outer blood-retinal barrier.

In the time since my reviews appeared in Retinal Physician in September 2008 and March 2010, continued study of CSC has occurred to guide us in epidemiology /prevention, diagnosis, and management of this disorder. In this update, I will summarize recent findings regarding CSC.

The exudation in CSC is due to hyperpermeability at the retinal pigment epithelium, rather than neovascularization. The hyperpermeable RPE sites are associated with a disruption in the choroidal circulation and choroidal vascular congestion. The cause of the increased choroidal permeability is unknown, but choroidal venous stasis, choroidal ischemia, and inflammation have been proposed to play a role.

CSC can lead to visual impairment: The resultant neurosensory macular detachment yields symptoms of micropsia, metamorphopsia, and reduced visual acuity. Although the majority of cases are self-limited, resolving spontaneously after a number of weeks, some cases will be chronic, lasting six months or longer.

Despite the idiopathic nature of the disease's pathogenesis, it is known that CSC is associated with states of hypercortisolism, such as Cushing's syndrome, pregnancy, and systemic glucocorticoid therapy, as well as following stressful life events.

Michael Colucciello, MD, is a clinical associate in the Department of Ophthalmology at the University of Pennsylvania School of Medicine in Philadelphia and a retina specialist practicing with South Jersey Eye Physicians in Moorestown, NJ. He reports no financial interests in products mentioned in this article. Dr. Colucciello can be reached via e-mail at

One-year recurrence rates after a primary event may be as high as 50%; these recurrences may be associated with diminished visual acuity, color vision, and stereopsis. Chronic CSC may be associated with irreversible vision loss due to the effects of recurrence and chronic subretinal fluid.1

CSR has a predilection for occurrence in young men (often in those with a “Type A” personality under perceived stress); it presents most frequently as a unilateral disorder. The natural history of CSC includes a several-week period of visual disturbance in the affected eye, followed by spontaneous resolution in the majority of patients.

Figure 1. Central serous chorioretinopathy: clinical images with fluorescein angiographic overlay. From upper left, clockwise: clinical image showing exudative foveal detachment and extrafoveal serous pigment epithelial detachments in the temporal macula, and angiographic images at one, two, and five minutes showing point source RPE leak.

However, the affected patient frequently has high visual demands, and recurrences may be noted in 30% to 50% of patients. Recurrent episodes, especially if they are chronic, can be accompanied by histopathological changes that are associated with irreversible visual loss.


In a recent community population-based retrospective cohort and case-control study evaluating the incidence of CSC, the mean annual age-adjusted incidences per 100,000 were 9.9 (95% CI, 7.4-12.4) for men and 1.7 (95% CI, 0.7-2.7) for women.2

A recent retrospective review of untreated CSC patients followed for three or more years showed that during follow-up, 52% of patients experienced ≥1 episode of CSC recurrence. Also, patients with a history of psychiatric illness (adjustment disorder and depression) were associated with an increased risk of CSC recurrence (hazard ratio = 3.5).3


The occurrence of CSC is potentiated in those predisposed by the administration of steroids. Corticosteroids upregulate transcription and expression of adrenergic receptor genes and may increase the affects of adrenergic stimulation on certain target tissues. Therefore, corticosteroids may cause changes in blood pressure and fluid homeostasis.

Certainly, counseling the CSC patient regarding avoidance of steroids (oral, intravenously, inhaled, intra-articular, and topical) is important. Recently, loss of visual acuity was reported in a patient, associated with CSC following a steroid injection into the shoulder bursa.4

Sympathomimetic Agents

Sympathomimetic agents (such as pseudoephedrine, oxymetazoline, or 3,4-methylenedioxymethamphetamine) may also initiate a CSC episode in a predisposed patient.5

Raf/MEK/ERK Inhibitors

The Raf/MEK/ERK pathway in a cell involves a chain of proteins, beginning at a cell surface receptor, that is involved in cell signaling. This signal chain is stimulated by growth factors, ending in DNA-coded cell division. A mutated protein in the chain can result in “constant-on” signaling, resulting in uncontrolled cell division and cancer.

Raf/MEK/ERK inhibitors include drugs such as sorafenib (used to treat cancers such as hepatocellular cancer and renal cell cancer) and vemurafenib (used to treat melanoma and non-Hodgkin's lymphoma). Acute CSC has been reported to occur with the use of MEK/ERK inhibitors, resolving shortly after discontinuance in each case.

Patients currently under treatment with MEK/ERK inhibitors should be informed about the possibility of developing CSR and its self-limited nature.6

Figure 2. Central serous chorioretinopathy: clinical image with fluorescein angiographic overlay. Clinical image showing exudative foveal detachment and extrafoveal serous pigment epithelial detachments in the temporal macula, with overlying angiographic images at one minute showing point source RPE leak.

PDE-5 Inhibitors

The occurrence of a positive challenge and dechallenge and second challenge seems to implicate PDE-5 inhibitors (used for the treatment of erectile dysfunction) in certain cases of CSC.7

Helicobacter pylori

Focal occlusion of the choroidal microcirculation associated with interaction between Helicobacter pylori and the vascular endothelium could explain the mechanism of choroidal ischemia and the development of CSC in H. pylori-infected patients.8

Also, H. pylori urease activates platelets; this activation in the choroid could initiate the choroidal vascular congestion and choroidal ischemia that may lead to CSC.9

Obstructive Sleep Apnea

Overactivation of the hypothalamic-pituitary-adrenal axis and sympathetic nervous system, seen with the disrupted and poor quality sleep characteristic of obstructive sleep apnea, may contribute to the development of CSC.10

DIAGNOSIS/EVALUATION OF TREATMENT Spectral-domain Optical Coherence Tomography

Spectral-domain high-resolution (6 µm axial) optical coherence tomography is very helpful in evaluating the patient with CSC. In addition to demonstrating shallow neuro-sensory retinal detachments in CSC, SD-OCT has shown that patients with CSC have increased choroidal thickness.

Figure 3. Central serous chorioretinopathy: clinical image with OCT macular cube and HD line overlays. Clinical image showing exudative foveal detachment and extrafoveal serous pigment epithelial detachments in the temporal macula.

Choroidal thickness has been shown to be related to leakage from the RPE, choroidal vascular hyperpermeability, and punctate hyperfluorescent lesions. These findings provide evidence that CSC may be caused by focally increased hydrostatic pressure in the choroid.11


Enhanced depth imaging (EDI) OCT uses “swept-source” OCT imaging to increase imaging depth resolution; it is useful in studying the choroid. Swept-source OCT uses a wavelength swept laser as the light source. Swept-source OCT in practice can achieve much less loss in sensitivity with increasing imaging depth, as compared with conventional SD-OCT — less than half of what is observed in SD-OCT implementations.

Also, current swept-source OCTs use a longer wavelength, which penetrates deeper within tissue, as compared with the conventional wavelengths used in standard SD-OCT devices.12

Enhanced depth imaging SD-OCT demonstrated a very thick choroid in patients with CSC, consistent with choroidal vascular congestion. This finding provides additional evidence that CSC may be caused by increased hydrostatic pressure in the choroid.13

Macular Microperimetry

Macular microperimetry detects decreased macular sensitivity in CSC and may be helpful in determining CSC treatment response to photodynamic therapy. The value of testing macular function by central microperimetry in chronic CSC has been shown.14

One study indicated that visual acuity alone may significantly underestimate the improvement in macular function that accompanies successful treatment of CSC with PDT. Macular microperimetry was shown to evaluate accurately the retinal sensitivity in patients with CSC treated with PDT: Patients were noted to experience improvement in central retinal sensitivity after treatment with PDT. Further improvement in macular microperimetric sensitivity occurred during follow-up between three and six months after treatment.

These data highlight the value of functional mapping for patients with symptomatic CSC and indicate that visual acuity alone may underestimate the functional benefit of treating this group of patients.15

Fundus Autofluorescence Imaging

Recently, fundus autofluorescence (FAF) imaging has been used to study fundus diseases. In normal FAF images, the optic disc and retinal vessels appear dark because of their lack of autofluorescent fluorophores. In eyes with CSC, FAF images tend to show patchy increased autofluorescence in the macular area.

In CSC, the punctate increased FAF originates from subretinal and intraretinal precipitates. These precipitates may be macrophages with phagocytized outer segments. The source of the hyperautofluoresence is the outer photoreceptor segments, which contain a precursor of lipofus-cin. Spaide and Klancnik16 believe that the origin of FAF in CSC is due to either the accumulated photoreceptor outer segments that are not phagocytized by the RPE or macrophages with phagocytized outer segments.

The measured length of the outer segment in the detached retina was noted to be increased in CSC. The patchy increased FAF in CSC may originate from the elongated photoreceptor outer segments in the detached retina. The autofluorescent fluorophores in the elongated photoreceptor outer segments may be present in precipitates or could have settled into the inferior exudative retinal detachment seen in CSC.17

Indocyanine Green Angiography

Indocyanine green angiography has demonstrated staining of the inner choroidal vessels, in the mid-stages (approximately 10 minutes after dye injection) of a study, as areas of ICG hyperfluorescence from the posterior pole to the peripheral fundus.18

Multifocal Electroretinography

Multifocal electroretinography (mfERG) may be useful in objectively evaluating the functional changes in central serous chorioretinopathy. Visual acuity and OCT central foveal thickness improvement have been shown to correlate with macular mfERG responses after PDT treatment of CSC.19


The optimal management of CSC remains controversial. In the acute phase of the disease, particularly when the neurosensory detachment is associated with a single point leak, spontaneous resolution occurs within three months in many cases. Therefore, in the acute phase, close observation with the expectation of spontaneous resolution remains the accepted standard.

Recurrent/Chronic CSC

In recurrent or persistent cases, treatment varies depending upon the location and nature of the leak. If the lesion is focal and extrafoveal, focal photocoagulation remains popular, but in cases in which the leak is foveal or the leakage pattern is diffuse, PDT has been shown to be beneficial.


Photodynamic therapy may allow for faster resolution of the neurosensory retinal detachment than laser.20 ICG-guided treatment with PDT was first demonstrated to be efficacious by Yannuzzi et al. This ICG angiographically guided treatment works best in patients who exhibit the most intense hyperfluorescence on ICG angiography.21,22 In eyes without hyperfluorescence, another treatment could be explored to absorb the subretinal fluid.23

Half-fluence PDT

Photodynamic therapy may be given in the “standard” fluence and dose (the parameters used in treating wet AMD: 83 seconds of 689-nm light wavelength spot at an exposure of 600 mW/cm2, five minutes after a 10-minute infusion of verteporfin dose 6 mg/m2, yielding 50 J/cm2 fluence), in low fluence (“half” that used in the treatment of standard wet AMD: 3 mg/m2 for 42 seconds) or in “half” dose (verteporfin 3 mg/m2 vs standard wet AMD treatment) for the treatment of CSC.

An important consideration is the potential for collateral damage that PDT might cause due to its effect on the choroid and the RPE. PDT may cause further RPE damage in areas with disrupted RPE in eyes with chronic CSC.

Atrophic RPE changes have been noted in areas with previously normal RPE after application of PDT for chronic CSC performed in the same manner as that used to treat wet AMD.24

A shorter irradiation time using the standard dose of verteporfin may be safer for eyes with CSC. Evidence has accumulated that lower PDT fluence and dosage may be beneficial in CSC. A multicenter, retrospective study indicated that half-fluence PDT was as effective as conventional PDT, while minimizing PDT's adverse effects on choriocapillaris perfusion and retinal thickness.25

A recent prospective, longitudinal study evaluated microperimetry data on chronic CSC patients treated with standard-fluence vs low-fluence PDT. The results indicated a significant improvement in macular sensitivity after PDT in eyes with chronic CSC, with greater efficacy in low-fluence-treated eyes.26

A retrospective review of 19 patients over 12 months showed that ICG angiography-guided half-fluence PDT with verteporfin is effective in treating acute symptomatic CSC, resulting in visual improvement and complete resolution of exudative macular detachment.27

Half-dose PDT

Chan and associates modified the PDT protocol by using a half-dose of verteporfin to treat CSC, and no RPE atrophy developed in that study.28

In one interventional case series, half-dose verteporfin PDT in cases of CSC induced significant increases in central 10º, 20º, and paracentral 10º to 20º sensitivity, as well as PDT laser spot area retinal sensitivity, over six months.29

With the implication that half-dose PDT decreases choroiodal hyperpermeability, a recent retrospective series demonstrated that subfoveal choroidal thickness significantly decreased after half-dose PDT treatment of central serous chorioretinopathy.30

Multifocal electroretinography demonstrated improved retinal function at the central macula in CSC patients after treatment with half-dose verteporfin PDT.19 While treatment of chronic and recurrent CSC appears to be most efficiently performed with PDT, other options to be considered may be on the horizon.


Small case series have shown potential benefit of treating CSC with bevacizumab.31,32 However, another case series showed no beneficial effect of bevacizumab on CSC.33


Finasteride (an inhibitor of dihydrotestosterone synthesis), 5 mg daily, was shown to elicit a positive response in a small series of patients with chronic CSC, with recurrent exudation noted after discontinuance.34

Acetylsalicylic Acid

Aspirin has been shown in one study to be beneficial in allowing resolution of CSC.35 The treatment effect may be associated with aspirin's anti-inflammatory and antiplatelet effects, its ability to reduce serum levels of tissue plasminogen activator-1, and its action on inhibiting the hyperfunction of the HPA axis — all potentially beneficial in counteracting choroidal vascular congestion and ischemia and inflammation in CSC.

A dosage of 75 to 100 mg may provide the best activity in this regard because at higher doses, aspirin could have a paradoxical effect of vasoconstriction, predisposing to local and systemic hemorrhagic events.


As glucocorticoids are implicated in the development of CSC, glucocorticoid inhibition with rifampin has been suggested as a potential treatment modality. Rifampin increases the metabolism of endogenous steroids through its induction of the enzyme cytochrome P450,3A4.36

Before starting rifampin, a baseline measurement of liver enzymes (SGPT, SGOT), bilirubin, serum creatinine, complete blood count, and platelet count are recommended. Rifampin 300 mg twice daily has been used in a small series to treat chronic CSC with success.37


Mifepristone (formerly RU-486) is an antagonist of glucocorticoids and progesterone receptors; it has a weak antiandrogen action. Also, mifepristone inhibits cortisol-induced peripheral vasoconstriction. A treatment response was seen in a group of 16 patients with chronic CSC treated with 200 mg daily mifepristone for 12 weeks; longer-term treatment is most likely necessary in such patients.38


Ketoconazole exerts its potential effects in the treatment of CSC by inhibiting some steps in steroid synthesis, resulting in decreased levels of cortisol, androgen, and aldosterone and in elevated progesterone.39 These effects seem to be present at the minimum dosage of 400 mg/day.

An additional action of ketoconazole is its direct antiglucocorticoid effect as an antagonist at the receptor level. One study indicated a treatment response at eight weeks when a dose of 600 mg daily was given for four weeks.40 Current study on this medication for treatment of CSC is, however, limited by the short follow-up and the number of patients recruited.

Obstructive Sleep Apnea Treatment

Hypothalamic-pituitary-adrenal axis and sympathetic nervous system overactivation, seen with disrupted and poor quality sleep, may contribute to the development of CSC. A case report emphasized the possible importance of identifying and treating obstructive sleep apnea to allow for the resolution of CSC in some individuals.41

H. pylori Treatment

A small case series used metronidazole and amoxicillin 500 mg three times daily for two weeks and omeprazole once daily for six weeks as an H. pylori eradication regimen in CSC patients. Compared to a control group that was not given this treatment, the treated patients experienced enhanced absorption of subretinal fluid.42


From 1866, when Graefe first described recurrent central retinitis,43 to 1967, when Gass provided the classic description of the pathogenesis and clinical features of the condition that he called idiopathic central serous choroidopathy,44 to the present, much study and effort continues to be directed toward the understanding and treatment for patients with CSC.

Ongoing efforts include study regarding methods of evaluation, understanding of pathogenesis, and strategies for the treatment and prevention of this disease, which can cause significant short-term and long-term vision loss in affected individuals. RP


1. Wang M, Munch IC, Hasler PW, et al. Central serous chorioretinopathy. Acta Ophthalmol. 2008;86:126-145.
2. Kitzmann AS, Pulido JS, Diehl NN, et al. The incidence of central serous chorioretinopathy in Olmsted County, Minnesota, 1980-2002. Ophthalmology. 2008;115:169-173.
3. Fok AC, Chan PP, Lam DS, et al. Risk factors for recurrence of serous macular detachment in untreated patients with central serous chorioretinopathy. Ophthalmic Res. 2011;46:160-163
4. Kassam AA, White W, Ling RH, et al. Loss of visual acuity due to central serous retinopathy after steroid injection into the shoulder bursa. J Shoulder Elbow Surg. 2011;20:e5-e6.
5. Michael JC, Pak J, Pulido J, et al. Central serous chorioretinopathy associated with administration of sympathomimetic agents. Am J Ophthalmol. 2003;136:182-185.
6. Velez-Montoya R, Olson J, Petrash M, et al. Acute onset central serous retinopathy in association with Mek inhibitor use for metastatic cancer. Invest Ophth Vis Sci. 2011;52:2153.
7. Aliferis K, Petropoulos IK, Farpour B, et al. Should central serous chorioretinopathy be added to the list of ocular side effects of phosphodiesterase 5 inhibitors? Ophthalmologica. 2012;227:85-89.
8. Rahbani-Nobar MB, Javadzadeh A, Ghojazadeh L, et al. The effect of Helicobacter pylori treatment on remission of idiopathic central serous chorioretinopathy. Mol Vis. 2011;17:99-103.
9. Wassermann GE, Olivera-Severo D, Uberti AF, et al. Helicobacter pylori urease activates blood platelets through a lipoxygenase-mediated pathway. J Cell Mol Med. 2010;14:2025-2034.
10. Kim, JT, Eichling, PS, Wang, M. Central serous chorioretinopathy associated with narcolepsy. Retin Cases Brief Rep. 2011;5:302-305.
11. Jirarattanasopa P, Ooto S, Tsujikawa, A, et al. Assessment of macular choroidal thickness by optical coherence tomography and angiographic changes in central serous chorioretinopathy. Ophthalmology. 2012 Apr 20. [Epub ahead of print]
12. Spaide RF, Koizumi H, Pozzoni MC. Enhanced depth imaging spectral-domain optical coherence tomography. Am J Ophthalmol. 2008;146:496-500.
13. Imamura Y, Fujiwara T, Margolis R, et al. Enhanced depth imaging optical coherence tomography of the choroid in central serous chorioretinopathy. Retina. 2009;29:1469-1473.
14. Ozdemir H, Senturk F, Karacorlu M, et al. Macular sensitivity in eyes with central serous chorioretinopathy. Eur J Ophthalmol. 2008;18:799-804.
15. Ehrlich R, Mawer NP, Mody, CH, et al. Visual function following photodynamic therapy for central serous chorioretinopathy: a comparison of automated macular microperimetry versus best-corrected visual acuity. Clin Exp Ophthalmol. 2012:40:e32-e39.
16. Spaide RF, Klancnik JM. Fundus autofluorescence and central serous chorioretinopathy. Ophthalmology. 2005;112:825-833.
17. Matsumoto H, Kishi S, Sato T, et al. Fundus autofluorescence of elongated photoreceptor outer segments in central serous chorioretinopathy. Am J Ophthalmol. 2011;151:617-623.
18. Spaide RF, Hall L, Haas A, Campeas L, et al. Indocyanine green videoangiography of older patients with central serous chorioretinopathy. Retina. 1996;16: 203-213.
19. Wu ZH, Lai RY, Yip YW, et al. Improvement in multifocal electroretinography after half-dose verteporfin photodynamic therapy for central serous chorioretinopathy: a randomized placebo-controlled trial. Retina. 2011;31: 1378-1386.
20. Lim JW , Kang SW, Kim YT et al. Comparative study of patients with central serous chorioretinopathy undergoing focal laser photocoagulation or photodynamic therapy. Br J Ophthalmol. 2011;95:514-517.
21. Yannuzzi LA, Slakter JS, Gross NE, et al. Indocyanine green angiography-guided photodynamic therapy for treatment of chronic central serous chorioretinopathy: a pilot study. Retina. 2003;23:288-298.
22. Inoue R, Sawa M, Tsujikawa M, et al. Association between the efficacy of photodynamic therapy and indocyanine green angiography findings for central serous chorioretinopathy. Am J Ophthalmol. 2010;149:441-446.
23. Inoue R, Sawa M, Tsujikawa M, Gomi F. Association between the efficacy of photodynamic therapy and indocyanine green angiography findings for central serous chorioretinopathy. Am J Ophthalmol. 2010;149:441-446.
24. Cardillo Piccolino F, Eandi CM, Ventre L, Rigault de la Longrais RC, Grignolo FM. Photodynamic therapy for chronic central serous chorioretinopathy. Retina. 2003;23:752-763
25. Shin JY, Woo SJ, Yu HG et al. Comparison of efficacy and safety between half-fluence and full-fluence photodynamic therapy for chronic central serous chorioretinopathy. Retina. 2011;31:119-126.
26. Reibaldi M, Boscia F, Avitabile T, et al. Functional retinal changes measured by microperimetry in standard-fluence vs low-fluence photodynamic therapy in chronic central serous chorioretinopathy. Am J Ophthalmol. 2011;151: 953-960.
27. Smretschnig E, Ansari-Shahrezaei S, Moussa, S, et al. Half-fluence photodynamic therapy in acute central serous chorioretinopathy. Retina. 2012;10:1-6.
28. Chan WM, Lam DS, Lai TY, et al. Choroidal vascular remodelling in central serous chorioretinopathy after indocyanine green guided photodynamic therapy with verteporfin: a novel treatment at the primary disease level. Br J Ophthalmol. 2003;87:1453-1458.
29. Senturk F, Karacorlu M, Ozdemir H, et al. Microperimetric changes after photodynamic therapy for central serous chorioretinopathy. Am J Ophthalmol. 2011;151:303-309.
30. Maruko I, Iida T, Sugano Y, et al. Subfoveal choroidal thickness after treatment of central serous chorioretinopathy. Ophthalmology. 2010;117:1792-1799.
31. Lee ST, Adelman RA. The treatment of recurrent central serous chorioretinopathy with intravitreal bevacizumab. J Ocul Pharmacol Ther. 2011;27:611-614.
32. Inouea M, Kadonosonoa K, Watanabea Y, et al. Results of one-year follow-up examinations after intravitreal bevacizumab administration for chronic central serous chorioretinopathy. Ophthalmologica. 2011;225:37-40.
33. Lim JW, Ryu SJ, Shin MC. The effect of intravitreal bevacizumab in patients with acute central serous chorioretinopathy. Kor J Ophthalmol. 2010;24: 155-158.
34. Forooghian F, Meleth AD, Cukras C, et al. Finasteride for chronic central serous chorioretinopathy. Retina. 2011;31:766-771.
35. Caccavale A, Romanazzi F, Imparato M, et al. Low-dose aspirin as treatment for central serous chorioretinopathy. Clin Ophthalmol. 2010;4:899-903.
36. Jampol LM, Weinreb R, Yannuzzi L. Involvement of corticosteroids and catecholamines in the pathogenesis of central serous chorioretinopathy: a rationale for new treatment strategies. Ophthalmology. 2002;109:1765-1766
37. Steinle NC, Gupta N, Yuan A, et al. Oral rifampin utilisation for the treatment of chronic multifocal central serous retinopathy. Br J Ophthalmol. 2012;96: 10-13.
38. Nielsen JS, Jampol LM.. Oral mifepristone for chronic central serous chorioretinopathy. Retina. 2011;31:1928-1936.
39. Caccavale A, Romanazzi F, Imparato M, et al. Central serous chorioretinopathy: a pathogenetic model. Clin Ophthalmol. 2011;5:239-243.
40. Meyerle CB, Freund KB, Bhatnagar P, et al. Ketoconazole in the treatment of chronic idiopathic central serous chorioretinopathy. Retina. 2007;27:943-946.
41. Kim, JT, Eichling, PS, Wang, M. Central serous chorioretinopathy associated with narcolepsy. Retin Cases Brief Rep. 2011;5:302-305.
42. Bagher M, Rahbani-Nobar R, Alireza Javadzadeh A, et al. The effect of Helicobacter pylori treatment on remission of idiopathic central serous chorioretinopathy. Mol Vis. 2011;17:99-103.
43. von Graefe A. Central recurrent retinitis. Graefes Arch Clin Exp Ophthalmol. 1866;12:211-215.
44. Gass JDM. Pathogenesis of disciform detachment of the neuro-epithelium. II. Idiopathic central serous choroidopathy. Am J Ophthalmol. 1967;63:587-615.

Retinal Physician, Volume: 9 , Issue: July 2012, page(s): 42 - 76