AIM To review retrospectively 74 consecutive cases of combined phacoemulsification and transpupillary drainage of silicone oil.
METHODS Candidate patients for intraocular silicone oil removal and cataract extraction underwent combined phacoemulsification and transpupillary drainage of silicone oil through a planned posterior capsulorrhexis and without the use of a pars plana infusion line.
RESULTS The retina remained attached in 59 (79.7%) patients postoperatively. In this success group, the postoperative visual acuity improved in 42 (71.2%) patients. There was no association between age, duration of silicone oil tamponade, preoperative diagnosis, macular status or number and nature of previous surgery, and the incidence of redetachment following silicone oil removal.
CONCLUSION Combined phacoemulsification and transpupillary drainage of silicone oil is a safe and reliable technique that offers the main advantage of diminished surgical trauma.
- transpupillary drainage
- silicone oil
- intraocular lens
Statistics from Altmetric.com
If you wish to reuse any or all of this article please use the link below which will take you to the Copyright Clearance Center’s RightsLink service. You will be able to get a quick price and instant permission to reuse the content in many different ways.
Silicone oil serves as intraocular tamponade after pars plana vitrectomy and is widely used for the treatment of complex retinal detachments. Because the incidence and severity of its complications such as cataract and glaucoma increase with its intraocular duration1-3 it is recommended that silicone oil is removed as soon as its tamponade effect is no longer needed.4-6 Cataracts can develop in nearly all eyes in which the silicone oil remains in situ for a few months7-10 and up to 60% of lenses that appear relatively clear at the time of silicone oil removal will also develop a clinically significant cataract after 2 years.1011
Removal of oil can be combined with either extracapsular cataract extraction1213 or phacoemulsification. Various techniques of combined phacoemulsification and oil removal have been described14-17 and a less invasive method obviating the use of a pars plana infusion line and based on hydrodynamic expression of the oil through a planned posterior capsulorrhexis has recently been recommended and adopted.1819 This simplified method described in small series offers the advantages of quicker and less invasive surgery with faster visual rehabilitation. Theoretical disadvantages lie in the violation of the posterior capsule integrity. This study was conducted to assess the outcome of 74 consecutive patients undergoing this particular technique of combined clear corneal phacoemulsification, transpupillary silicone oil drainage, and intraocular lens implantation.
Materials and methods
Candidate patients for intraocular silicone oil removal and cataract extraction underwent combined phacoemulsification and transpupillary silicone oil drainage through a single superior corneal incision and without a pars plana infusion line. The surgery was performed under general anaesthetic in 65 (88%) cases. At the end of a standard clear corneal phacoemulsification a central posterior capsulorrhexis with a diameter of approximately 3 mm was performed with forceps. A 20 gauge Rycroft canula was then introduced through the corneal incision and balanced salt solution (BSS) irrigated into the vitreous cavity. The stream of fluid directed through the posterior capsulorrhexis floats the silicone oil out through the pupil and the corneal incision and simultaneously replaces it with balanced salt solution. The infusion flow was continued until all oil was removed. The corneal section was then enlarged and a single piece poly(methylmethacrylate) (PMMA) intraocular lens (IOL) implanted in the capsular bag or in the ciliary sulcus in front of the anterior capsule as appropriate. The corneal wound was then closed with a 10.0 nylon suture and a subconjunctival injection of steroid and antibiotic was given at the end of each case. Care was taken throughout the procedure to avoid prolonged hypotony. All the patients were reviewed and examined on the first postoperative day and at regular intervals thereafter. Descriptive methods were used in statistical analysis except when assessing the association between categorical study factors and redetachment where Fisher's exact test was used.
Seventy four patients (51 men, 23 women) with a mean age of 52.9 years (range 12–82 years) underwent combined phacoemulsification and silicone oil removal. The commonest indications for vitrectomy and silicone oil (1000 centistoke) injection were rhegmatogenous retinal detachment (RRD) with proliferative vitreoretinopathy (PVR) (n = 45) and giant retinal tear (GRT) (n = 22). Other indications are summarised in Table 1. The macula was detached in 61 eyes (82.4%). Twenty eight eyes (37.8%) had silicone oil injection as a primary procedure and 46 eyes (62.1%) had a history of at least one other retinal detachment operation before the placement of silicone oil. Additional surgical manoeuvres at the time of silicone oil injection included epiretinal membrane (ERM) peel where appropriate, encirclement with a 276 hard silicone tyre (n = 14) and relaxing retinectomy (n = 31). The median duration of silicone oil tamponade after pars plana vitrectomy was 5.0 months (range 3–19 months). The retina was clinically attached in all cases with no evidence of residual traction before silicone oil removal and 65 (87.8%) eyes received preoperative prophylactic 360 degrees peripheral argon laser retinopexy (Table 1). The median length of patient follow up was 10 months (range 2–42 months).
The retina remained attached in 59 (79.7%) eyes following combined phacoemulsification and silicone oil removal. In this success group, the postoperative visual acuity (VA) improved in 42 (71.2%) eyes, remained the same in nine (15.2%) eyes and deteriorated in seven (11.8%) eyes. Visual acuity could not be assessed in one of these patients with learning difficulties. The best corrected postoperative VA of the 48 eyes with previous macula-off retinal detachment was 6/12 or better in seven eyes (14.6%), between 6/60 and 6/18 in 24 eyes (50%), and worse than 6/60 in the remaining 16 eyes (33.3%). The best corrected postoperative VA of the 11 eyes with previous macula-on retinal detachment was 6/12 or better in four cases (36.4%) and between 6/18 and 6/60 in seven cases (63.6%).
Fifteen eyes (20.2%) sustained a recurrent retinal detachment after silicone oil removal (Table 2). Ten (66.7%) occurred within the first 3 weeks and five (33.3%) redetached after 1 month. Of the 15 failures, one eye was reattached with a cryo/buckle procedure and 11 required oil exchange with epiretinal membrane (ERM) peel and argon laser retinopexy as indicated. Three eyes were deemed inoperable due to massive ERM reproliferation and were treated symptomatically. The best corrected postoperative VA in this group of 15 eyes with redetachment was less than 6/60 in all patients except for one case with a VA of 6/12 (Table2).
Peroperative anterior capsulorhexis tear occurred in two eyes and necessitated conversion to extracapsular cataract extraction.
Postoperative subluxation of the lens within the capsular bag was observed in one eye and led to successful replacement of the 5 mm lens with a larger one.
Of the four eyes that developed persistent postoperative hypotony (intraocular pressure <5 mm Hg) only one eye had a preoperative pressure of less than 10 mm Hg (8 mm Hg). Three eyes redetached subsequently and one eye remained hypotonous but attached. Four other eyes developed raised postoperative intraocular pressure requiring medical treatment.
Excluding the group of eyes with recurrent retinal detachment, the postoperative visual acuity was limited by macular ERM proliferation in 13 eyes and non-specific macular scarring in 10 others. Cystoid macular oedema (CMO) occurred in two eyes and a macular hole in one eye. Posterior capsular thickening and contraction necessitated neodymium-yttrium-aluminium-garnet (YAG) laser capsulotomy in three cases. No cases of vitreous haemorrhage, choroidal haemorrhage, hyphaema, or postoperative keratopathy were seen in our patients. One eye only had a small residual symptomatic oil bubble postoperatively.
Our technique of silicone oil removal combined with phacoemulsification is similar to that described by Jonaset al18 except that we performed clear corneal incisions on all eyes. This combined approach is less invasive, averts conjunctival and scleral incisions, and avoids the complication of iris prolapse and loss of iris pigment epithelium as reported by some authors during silicone oil extrusion through a more posterior limbal wound.18 There is no interference with the pars plana and peripheral retina thus reducing the risk of peripheral iatrogenic retinal breaks, subretinal infusion, and vitreous or choroidal haemorrhage.18 In addition, it offers the advantages of shorter duration of surgery and quicker visual rehabilitation and reduces the need to perform a potentially difficult postoperative neodymium-YAG capsulotomy on a densely thickened posterior capsule.79121620 Drainage of silicone oil is usually complete reducing the risk of oil bubbles adhering to the posterior IOL surface and the only five patients who received a foldable silicone intraocular lens early in our series did not show any sign of complications. It is nevertheless recommended to avoid silicone IOL implants as silicone oil bubbles can irreversibly adhere to these artificial lenses.152122
The main disadvantage of this technique lies in the violation of the posterior capsule integrity. This offers the increased theoretical risk of capsular bag instability, postoperative retinal detachment,2324 and cystoid macular oedema.25 In case of the posterior capsulotomy becoming too large or irregular with inadequate capsular support, the IOL can be implanted in the ciliary sulcus in front of the anterior lens capsule. Conversely, the absence of vitreous traction in these eyes decreases the risk of postoperative retinal detachment and cystoid macular oedema. These are more likely to arise as a consequence of the complicated nature of the initial retinal detachment rather than be attributable to the method of oil removal.26 On the other hand, theoretical concerns exist regarding the damage caused to corneal endothelium by silicone oil flowing across the anterior chamber and out of the eye but no cases of postoperative clinically significant keratopathy were encountered in this series. In addition, by virtue of using one corneal incision only, this technique has the inconvenience of precluding additional necessary intraoperative posterior segment manoeuvres such as epiretinal membrane peeling.
Redetachment rate after silicone oil removal has been reported to vary between 6% and 33%.56111427-31 Our redetachment rate (20%) is similar to that reported above and in other smaller series using a similar technique of combined phacoemulsification and silicone oil removal.151819The incidence of new iatrogenic retinal breaks may be reduced by avoiding pars plana sclerotomies and the risk of redetachment may also be lessened by performing preoperative prophylactic 360 degree peripheral laser retinopexy.3233 However, in the absence of similar preoperative characteristics and similar criteria for oil removal, valid comparison of redetachment rates between studies is difficult.
Age did not seem to influence the outcome of surgery in our series, as the mean age of patients who redetached after silicone oil removal (54.0 years, range 19–82) was similar to that of patients who remained attached (52.6 years, range 12–81). There was also no association between the length of oil retention and the incidence of retinal redetachment as the median duration of silicone oil tamponade was equal in both groups (5.0 months). This failure to demonstrate a reduction in the redetachment rate after longer silicone oil tamponade is also confirmed by some studies4527283034 but not others.2935
Although the proportion of eyes with a giant retinal tear is higher in the redetachment group (47%) compared with the success group (25%), these data provide no evidence of a difference in preoperative diagnosis between the two groups as assessed by the Fisher's exact test (p = 0.19). This test also demonstrates no significant difference in the macular status of the detachment (on or off) before silicone oil injection between the two groups (p = 1.0). Although the proportion of patients without preoperative 360 degree peripheral laser retinopexy is higher in the redetachment group (20%) than in the success group (10%), the Fisher's exact test demonstrates no significant difference in the number of patients with preoperative retinopexy between the two groups (p = 0.37). Moreover, we did not detect any association between previous encirclement (p = 1.0) or retinectomy (p = 0.77) and surgical outcome after silicone oil removal. Contrary to a previous report,29 a higher number of previous vitreoretinal procedures was not associated with a higher redetachment rate in our study (p = 0.86) and this result is confirmed elsewhere.30The fact that we have found little evidence of any association between the factors under study and redetachment may well be a reflection of the low power of this study.
The silicone oil study confirmed that removal of silicone oil in anatomically successfully operated eyes significantly increases the likelihood of improved visual acuity in eyes after surgery for severe PVR.4 The postoperative visual acuity improved in 42 (71.2%) of 59 successfully operated eyes in our series, remained the same in nine (15.2%) eyes and deteriorated in seven (11.8%) eyes. This incidence of postoperative visual acuity deterioration is similar to that reported by other authors1130 and has been attributed to maculopathy (hypotony, ERM, CMO and non-specific scarring) in all these cases. Postoperative visual acuity may be improved by epiretinal membrane peel at the time of surgery.4 On the other hand, 14 (93.3%) redetached eyes in this series failed to achieve a vision of 6/60. This poor visual prognosis after redetachment is confirmed by other studies.2930
Combined phacoemulsification and transpupillary silicone oil drainage through a planned posterior capsulorrhexis and without a pars plana infusion line is a simpler and less invasive technique that offers the advantages of diminished surgical trauma and reduced incidence of postoperative capsular thickening. We believe that this technique should be reserved for patients with a stable retina and closed retinal breaks not in need of additional surgical manoeuvres at the time of oil removal.