Secondary Logo

Journal Logo

Original Study


Zhao, Xiujuan MD, PhD*; Huang, Li MD, PhD*; Lyu, Cancan MD, PhD*; Liu, Bingqian MD, PhD*; Ma, Wei MD, PhD*; Deng, Xiaoyan MD*; Jiang, Huaiyan MD; Wang, Yan MD; Yu, Xiling MD, PhD*; Ding, Xiaoyan MD, PhD*; Luo, Yan MD, PhD*; Ma, Jin MD, PhD*; Stewart, Jay M. MD, PhD§; Liang, Xiaoling MD, PhD*; Jin, Chenjin MD, PhD*; Lu, Lin MD, PhD*

Author Information
doi: 10.1097/IAE.0000000000002348
  • Open

Rhegmatogenous retinal detachment (RRD) occurs when the fluid from the vitreous cavity passes through a break and separates the outer segments of the photoreceptors from the retinal pigment epithelium (RPE)1 with an estimated prevalence of 1/10,000 individuals.2 The general treatments for an RRD are pars plana vitrectomy (PPV) and scleral buckling (SB).3,4 The PPV technique directly relieves the vitreous traction by using internal drainage of the subretinal fluid (SRF), gas–fluid exchange, and laser photocoagulation or cryotherapy of the reattached retina combined with or without gas or silicone oil tamponade.4 The SB technique is known to relieve the vitreous traction indirectly by using a segmental scleral silicone implant in the area corresponding to the retinal break and the encircling silicone band, combined with drainage of the SRF and transscleral cryotherapy.3

Although SB can be applied to a large variety of retinal detachments (RDs), it does have some predictable complications, such as axial elongation with secondary myopization, anterior-segment ischemia with the compression of the long posterior arteries, choroidal detachment and lens displacement with anterior chamber shallowing, and motility disturbances.5–9 To reduce the incidence of such complications, we modified the conventional SB procedure and designed a releasable SB (RSB) technique.10 Instead of the silicone sleeves, we used 6-0 absorbable sutures to tie up both the ends of the encircling band. In our previous study, we compared a releasable encircling band with a conventional encircling scleral band for treating primary RRD and found that the surgery-associated axial elongation and myopization and flattening of the anterior chamber were dramatically reduced, with no change in the surgical anatomical success with the releasable encircling band.10

There is still no consensus on the optimal approach for the management of uncomplicated RRD cases. A previous comparison of the SB and PPV procedures for treating primary RRD showed that there were no significant differences in the single-operation success rates and visual acuities.11 In addition, Heimann et al7 compared the SB and PPV techniques in phakic RRD cases and showed that better postoperative best-corrected visual acuity (BCVA) was achieved in the SB group, with the same anatomical outcome. Sun et al12 conducted a meta-analysis determining that SB was superior in terms of the final visual acuity and the occurrence of postoperative cataracts in uncomplicated phakic RRD cases, and that PPV was more likely to achieve a favorable final reattachment in pseudophakic RRD cases.

The aim of this study was to determine whether the RSB procedure for phakic patients with RRD is an effective approach, and whether it reduces the risk of developing cataracts and reduces the disadvantages associated with a conventional SB.


Trial Design

This study was conducted as a randomized controlled clinical trial in which two interventions (RSB and PPV) were compared in patients with primary RRD. The eligible patients were randomized in a 1:1 ratio to receive either the RSB or PPV. This study adhered to the tenets of the Declaration of Helsinki and was approved by the Ethics Committee of the Zhongshan Ophthalmic Center (2017KYPJ058), registered at the International Standard Randomized Controlled Trial registry (ISRCTN95808249). Written informed consent was obtained from all of the participants before surgery.


The study participants were recruited at the Zhongshan Ophthalmic Center from January 2015 until May 2016. The inclusion criteria were as follows: primary RRD without any complicating factors,13 aged 18 years and older, and Grade A or B proliferative vitreoretinopathy. Those patients with any kind of previous ocular surgery, trauma, RD resulting from a macular hole, RD with choroidal detachment as detected by ultrasound biomicroscopy,14 severe cataracts, and previous posterior uveitis were excluded from this study. The patients meeting the inclusion criteria were randomized into RSB and PPV groups according to the random number table method. Six scheduled follow-up visits were assigned for 1 day, 1 week, 1 month, 3 months, 6 months, and 12 months after surgery.


The surgeries were performed by one experienced surgeon (L.L.). In the RSB group, the episcleral encircling band (2.5 × 120 mm) was fixed by 5-0 nonabsorbable sutures in the equatorial region of each quadrant. The ends of the encircling band were joined and preliminarily fixed by a silicone sleeve to adjust the strain of the encircling band. Then, we tied up both ends using 6-0 absorbable sutures and removed the silicone sleeve. The retinal breaks were coagulated by retinal transscleral cryopexy. At the surgeon's discretion, an additional segmental silicone buckle, if needed, was placed under the encircling band at the location of the retinal breaks. These additional segmental buckles were orientated parallel to the encircling band and were fixed on the sclera with additional sutures, independent of the encircling band. The other optional surgical steps included the transscleral exodrainage of the SRF and anterior chamber paracentesis. In the PPV group, the patients underwent a standard 23-gauge (23-G) vitrectomy, and the vitreous was removed to relieve all the traction surrounding the retinal break. The SRF drainage was achieved through a preexisting break, with or without perfluoro-N-octane assistance. An endolaser was used to surround all the retinal breaks, and all the surgeries used a 10% C3F8 intraocular tamponade agent. The 23-G sclerotomy was sutured only if it leaked at the end of the surgery.

Clinical Data

The baseline data collected included the age, sex, lens status, extension of RD, macula-off/-on, BCVA, intraocular pressure (IOP), and symptom duration. Macula-off was defined as the complete detachment of the macula. The carefully recorded postoperative data included the BCVA, IOP, choroidal thickness (CT), axial length (AL), anterior chamber fibrin, anterior chamber inflammation,15 cataract progression, choroidal/subretinal hemorrhage, and any other associated complications. Primary success was defined as the retina remaining reattached for 12 months after one operation. The final anatomical success was defined as the retina remaining reattached for 12 months after one or more operations. Small incidences of localized SRF without an increase during the follow-up visits were not considered to be surgical failures. All the recurrent cases underwent PPVs for the second surgery.

The IOP and BCVA were recorded at the following postoperative intervals: 1 day, 1 week, 1 month, 3 months, 6 months, and 12 months. The BCVA was determined using the Early Treatment Diabetic Retinopathy Study chart converted to the logarithm of the minimum angle of resolution (logMAR)16 for statistical analysis. Grading of inflammation was based on the Standardization of Uveitis Nomenclature criteria.15 The postoperative cataract formation or progression was determined at 1 year by one doctor (C.L.), if it was considered to be visually significant. The CT was measured using enhanced depth imaging through spectral domain optical coherence tomography at the fovea (Spectralis; Heidelberg Engineering, Heidelberg, Germany). The CT was measured as the distance from the outer edge of the hyperreflective RPE to the chorioscleral interface (Figure 1). The CT was recorded according to the average parameters measured by two doctors (X.Z. and L.H.), and the AL was measured by using the IOL Master (Carl Zeiss Meditec AG, Jena, Germany).

Fig. 1.
Fig. 1.:
Optical coherence tomography images of patients who underwent RSB (AD) and PPV (EH) for primary RRD. The preoperative (A and E), 1-month postoperative (B and F), 3-month postoperative (C and G), and 6-month postoperative (D and H) optical coherence tomography images are shown respectively.


The statistical analysis was performed using SPSS 12 software (SPSS Inc, Chicago, IL). The continuous data were presented as the mean values ± SDs. The chi-square test, Fisher's exact test, and independent-samples t-test were used as appropriate, with a P value <0.05 considered to be statistically significant.


Participant Characteristics

Figure 2 displays the consort flow diagram. A total of 110 patients were included in this study and were randomly assigned into a PPV group (55 patients: 25 men and 30 women) and an RSB group (55 patients: 32 men and 23 women) (P = 0.182). The demographic and clinical characteristics of the patients are shown in Table 1. The statistical comparison between the PPV and RSB groups showed that there was no significant difference in the baseline data.

Fig. 2.
Fig. 2.:
Participant disposition.
Table 1.
Table 1.:
Demographic and Preoperative Examination Findings for PPV Group Versus RSB Group

Anatomical Outcomes

Initial surgery anatomical success was achieved in 41 of 43 patients (95.35%) in the PPV group and in 38 of 41 (92.68%) patients in the RSB group (P = 0.606). Two eyes (4.65%) in the PPV group developed retinal redetachment because of the development of new retinal breaks. Three eyes (7.32%) in the RSB group developed retinal redetachment because of a new retinal break (1 eye), missed retinal breaks at the initial surgery (1 eye), and macular hole formation (1 eye). For the 5 eyes with retinal redetachment, PPV combined with a silicone oil tamponade was performed in 2 eyes, PPV combined with C3F8 gas injection was performed in 1 eye, and PPV combined with silicone oil tamponade and SB was performed in 2 eyes. Final anatomical success was achieved in 100.00% of both groups.

Best-Corrected Visual Acuity

There was no difference of the baseline BCVA between the groups. The mean preoperative BCVA was 1.41 logMAR (20/510) and 1.26 logMAR (20/360) in the PPV and RSB groups, respectively (P = 0.141, Table 2). Overall, the mean BCVA improved in both groups, with a final BCVA of 0.68 logMAR (20/95) in the PPV group and 0.63 logMAR (20/87) in the RSB group (P = 0.731).

Table 2.
Table 2.:
Comparison of BCVA and IOP Between PPV and RSB Group

Intraocular Pressure

There was no difference in the baseline IOP between the groups. The mean preoperative IOPs were 12.54 mmHg and 11.26 mmHg in the PPV and RSB groups, respectively (P = 0.766, Table 2). Although the IOP increased to 16.96 mmHg in the PPV group and 19.38 mmHg in the RSB group on the first postoperative day, there was no significant difference (P = 0.051). Overall, the mean IOP decreased in both groups, with a final IOP of 13.15 mmHg in the PPV group and 13.35 mmHg in the RSB group (P = 0.824).

Choroidal Thickness

The subfoveal CT was measured by enhanced depth imaging optical coherence tomography (Table 3). In the PPV group, there was no difference between the 1-, 3-, 6-, and 12-month postoperative follow-ups (P = 0.926). However, the subfoveal CT at 3 months (260.43 ± 50.30 µm) was significantly higher than that at 1 month (249.03 ± 47.28 µm), 6 months (234.78 ± 46.69 µm), and 12 months (236.68 ± 46.70 µm) after surgery in the RSB group (P = 0.043). At the 1-month postsurgical follow-up, there was no statistically significant difference between the PPV (226.44 ± 46.38 µm) and RSB (249.03 ± 47.28 µm) groups (P = 0.068). However, the subfoveal CT was significantly higher in the RSB group (260.43 ± 50.30 µm) when compared with the PPV group (225.88 ± 47.33 µm) at the 3-month postsurgical follow-up (P = 0.009). There was no difference between the groups at the 6-month (P = 0.843) or 12-month (P = 0.635) follow-up.

Table 3.
Table 3.:
Comparison of CT and AL Between PPV Group and RSB Group

Axial Length

No significant differences were seen within the PPV group (P = 0.967) or RSB group (P = 0.589) at the different postsurgical periods. Although the AL was significantly higher in the RSB group (25.44 ± 2.20 mm) when compared with the PPV group (24.40 ± 1.68 mm) 1 month after surgery (P = 0.038), there were no statistically significant differences between the groups at 3 months (P = 0.087), 6 months (P = 0.481), and 12 months (P = 0.767).


All the complications recorded during the procedures and follow-ups are shown in Table 4. Elevated IOP requiring pharmacotherapy (IOP over 25 mmHg) was observed in 5 of the 55 (9.09%) patients in the PPV group and in 3 of the 55 (5.45%) patients in the RSB group (P = 0.463). Anterior chamber inflammation was observed in three patients (5.45%) in the PPV group, but none in the RSB group (P = 0.243). In addition, anterior chamber fibrin was observed in one patient in the PPV group and none in the RSB group (P = 1.000). None of the eyes had globe perforations during the RSB procedures, and no eye in either group had complications, such as endophthalmitis, choroidal hemorrhage, or subretinal hemorrhage. A primary anatomical failure was obtained in 2 of 43 patients (4.65%) in the PPV group and in 3 of 41 patients (7.32%) in the RSB group (P = 0.606). There was cataract development and progression in 26 of 43 patients (60.47%) in the PPV group and in 4 of 41 patients (9.76%) in the RSB group (P = 0.000) at 12 months, which included 9 eyes that underwent cataract surgery in the PPV group. Residual SRF was observed in 0 of 43 patients in the PPV group and 2 of 41 patients in the RSB group (P = 0.235). Epiretinal membranes were observed on optical coherence tomography in three eyes in the PPV group and one eye in the RSB group (P = 0.616).

Table 4.
Table 4.:
Analysis of Postoperative Complications for PPV Versus RSB


Our study indicated that both the RSB and PPV can achieve similar final BCVAs and single surgery anatomical successes in patients with primary RRD; however, the incidence and progression of cataracts in the RSB group was significantly lower than that in the PPV group. At the 12-month postsurgical follow-up, there was no difference in the IOP, CT, AL, or complications between the RSB and PPV groups.

In a conventional SB, the sutured encircling band is a permanent procedure.17 The undesirable postoperative side effects, such as a shallow anterior chamber, increased AL, and myopia, are caused by the encircling band tension. The RSB is a modified procedure based on the conventional SB in which we used 6-0 absorbable sutures to tie up both ends of the encircling band, instead of silicone sleeves and nonabsorbable sutures. After the sutures were absorbed around 3 months postoperatively (Figure 3), the biometric parameters stabilized. In a previous study, the comparison of the RSB and conventional SB concluded that they had the same effects on the reattachment rates, but the RSB reduced the surgery-associated axial elongation and persistent high IOP caused by the conventional SB.10

Fig. 3.
Fig. 3.:
Peripheral indentation at 1 month after surgery (A). The indentation disappeared at 3 months after surgery (B).

Schwartz and Flynn18 summarized the comparison of SB with PPV. Scleral buckling relieved the vitreous traction indirectly with equal effectiveness for superior and inferior breaks, whereas PPV relieved the vitreous traction directly, with higher effectiveness in the superior breaks. The advantages of SB included no prone positioning required after surgery and a lower equipment cost, while the advantage of PPV was less pain after surgery. The potential complications for SB were refractive changes, motility disturbances, vitreous or retinal incarceration, suprachoroidal or subretinal hemorrhage, and migration of the buckling elements. The potential complications for PPV were induced cataracts, elevated IOP, new breaks, retinal trauma, and optic nerve trauma.

The RSB is a modified SB procedure, and in this study, we compared the RSB and PPV in patients with primary RRD. The cataract progression was much greater in the PPV group than in the RSB group (P < 0.001). Our results showed postoperative cataract progression in 60.47% of the patients in the PPV group and 9.76% in the RSB group (P < 0.001). Up until the 1-year follow-up, most of the patients with cataracts had nuclear opacities. Among them, 9 eyes underwent cataract surgery in the PPV group and none did in the RSB group. The cataract progression in this study was comparable with the outcomes from other series after PPV surgery (from 58% to 85%).7,19,20

Our study also indicated that the RSB had no effect on the AL at the 3-month postsurgical follow-up. A number of studies have implied that the SB used to treat RRD induces axial elongation, causing secondary myopization.8,21 In this study, the AL in the RSB group was significantly longer than that in the PPV group (P = 0.038) at 1 month postoperatively. However, from 3 months to 12 months postoperatively, there was no statistically significant difference between groups, presumably due to the absorbable suture dissolving and releasing the band tension and the height of the buckle diminishing. In our study, we found a statistically significant increase in the subfoveal CT in the RSB group at 3 months, but no significant difference at 1 month, 6 months, and 12 months, which could be explained by venous engorgement caused by the encircling band.22

This study does have several limitations. First, the CT measurements were performed manually using a built-in caliper. Second, the sample size in our study was small, and it was difficult to draw definitive conclusions due to the low statistical power. Third, there was a lack of AL and CT before surgery due to RD involving the macula.

In summary, we compared the RSB and PPV in primary RRD patients. When compared with PPV, the rates of single surgery anatomical success and the final BCVA were similar, but the incidence of cataract progression was much lower in the RSB group. Based on these results, we believe that the RSB technique should be preferred and recommended.


The authors thank all the patients for their participation in this study.


1. Machemer R. The importance of fluid absorption, traction, intraocular currents, and chorioretinal scars in the therapy of rhegmatogenous retinal detachments. XLI Edward Jackson memorial lecture. Am J Ophthalmol 1984;98:681–693.
2. Michaelson IC, Stein R. A national study on the prevention of retinal detachment. Isr J Med Sci 1972;8:1421–1423.
3. Ho CL, Chen KJ, See LC. Selection of scleral buckling for primary retinal detachment. Ophthalmologica 2002;216:33–39.
4. SPR Study group. View 2: the case for primary vitrectomy. Br J Ophthamol 2003;87:784–787.
5. Goezinne F, La Heij EC, Berendschot TT, et al. Anterior chamber depth is significantly decreased after scleral buckling surgery. Ophthalmology 2010;117:79–85.
6. Barile GR, Chang S, Horowitz JD, et al. Neovascular complications associated with rubeosis iridis and peripheral retinal detachment after retinal detachment surgery. Am J Ophthalmol 1998;126:379–389.
7. Heimann H, Bartz-Schmidt KU, Bornfeld N, et al. Scleral buckling versus primary vitrectomy in rhegmatogenous retinal detachment: a prospective randomized multicenter clinical study. Ophthalmology 2007;114:2142–2154.
8. Wong CW, Ang M, Tsai A, et al. A prospective study of biometric stability after scleral buckling surgery. Am J Ophthalmol 2016;165:47–53.
9. Wu TE, Rosenbaum AL, Demer JL. Severe strabismus after scleral buckling: multiple mechanisms revealed by high-resolution magnetic resonance imaging. Ophthalmology 2005;112:327–336.
10. Yu XL, Liang XL, Ding XY, et al. Releasable encircling band for primary rhegmatogenous retinal detachment. Ophthalmology 2014;121:2504–2505.
11. McLeod D. Is it time to call time on the scleral buckle? Br J Ophthalmol 2004;88:1357–1359.
12. Sun Q, Sun T, Xu Y, et al. Primary vitrectomy versus scleral buckling for the treatment of rhegmatogenous retinal detachment: a meta-analysis of randomized controlled clinical trials. Curr Eye Res 2012;37:492–499.
13. D'Amico DJ. Clinical practice. Primary retinal detachment. N Engl J Med 2008;359:2346–2354.
14. Li Z, Li Y, Huang X, et al. Quantitative analysis of rhegmatogenous retinal detachment associated with choroidal detachment in Chinese using UBM. Retina 2012;32:2020–2025.
15. Jabs DA, Nussenblatt RB, Rosenbaum JT, et al. Standardization of uveitis nomenclature for reporting clinical data. Results of the First International Workshop. Am J Ophthalmol 2005;140:509–516.
16. Holladay JT. Visual acuity measurements. J Cataract Refract Surg 2004;30:287–290.
17. Schepens CL. Management of retinal detachment. Ophthalmic Surg 1994;25:427–431.
18. Schwartz SG, Flynn HW. Primary retinal detachment: scleral buckle or pars plana vitrectomy? Curr Opin Ophthalmol 2006;17:245–250.
19. Kinori M, Moisseiev E, Shoshany N, et al. Comparison of pars plana vitrectomy with and without scleral buckle for the repair of primary rhegmatogenous retinal detachment. Am J Ophthalmol 2011;152:291–297.
20. Heimann H, Zou X, Jandeck C, et al. Primary vitrectomy for rhegmatogenous retinal detachment: an analysis of 512 cases. Graefes Arch Clin Exp Ophthalmol 2006;244:69–78.
21. Cetin E, Ozbek Z, Saatci AO, Durak I. The effect of scleral buckling surgery on corneal astigmatism, corneal thickness, and anterior chamber depth. J Refract Surg 2006;22:494–499.
22. Odrobina D, Laudańska-Olszewska I, Gozdek P, et al. Influence of scleral buckling surgery with encircling band on subfoveal choroidal thickness in long-term observations. Biomed Res Int 2013;2013:586894.

releasable scleral buckling; vitrectomy; rhegmatogenous retinal detachment

Copyright © 2018 The Author(s). Published by Wolters Kluwer Health, Inc. on behalf of the Opthalmic Communications Society, Inc.