Background

Vitrectomy is the most common surgical technique performed to treat rhegmatogenous retinal detachment, and the most common vitreous substitutes used are air, expandable gases, and silicone oil (SO). Heavy silicone oil (HSO) is an alternative hydrophobic agent and heavier than water that provides a good tamponade effect in the inferior retina. The potential indications for the use of HSO are retinal detachments with large inferior breaks, complicated cases with redetachments and/or inferior proliferative vitreoretinopathy, cases requiring inferior retinotomies, glaucomatous eyes with previously implanted drainage valves located superiorly, and patients incapable of proper head positioning, such as patients with spinal osteoarthritis, or cognitive impairment such as autism or dementia [1]. However, HSO removal can be tricky for inexperienced surgeons because it concentrates in the posterior pole during its removal and requires special attention to mitigate intraoperative complications.

HSO removal technique

The HSO removal requires a four-port bimanual technique performed under direct visualization. An infusion line is placed followed by positioning of Chandelier illumination. One hand maintains the active aspiration (vacuum, 600 mmHg) and the second hand controls passive drainage using two 18-gauge needles from temporal and nasal sclerotomies. The needle is kept inside the bubble during the entire removal procedure to avoid leaving a residual SO bubble in the posterior pole. The use of the second needle helps mobilize the final HSO bubble into the needle and prevent its release back to the posterior pole. Video Supplemental Digital Content 1 and 2 demonstrates the HSO removal technique in complex retinal detachment surgeries.

Another point to highlight is the importance of placing the sclerotomy removal site as temporal as possible to ease temporal eye tilting and dislocation of the SO bubble outside the macula. Suturing the sclerotomy is mandatory to prevent postoperative leakage.

Use of 20-gauge peripheral intravenous catheters instead of 18-gauge needles is possible. However, we prefer to use the needles because the catheter frequently clogs due to the Oxane HD® (Bausch & Lomb, Toulouse, France) viscosity and usually needs to be replaced. The use of this bimanual technique facilitates the removal of smaller residual SO bubbles that stick to the outside of the cannula and may be scraped off when the cannula is removed from the trocars [2, 3].

The surgery to remove the HSO must be performed carefully to avoid intraoperative complications. For example, high-pressure active aspiration in the posterior pole may damage the retinal and optic disc tissues, possibly resulting in retinal holes [4,5,6]. Moreover, intraoperative hypotony occurs if an active aspiration cannula is placed in the balanced saline solution rather than into the SO bubble or due to clogging of the infusion line [4]. Eyes with media opacity such as corneal scarring or lens blurring require extra care [7].

Another noteworthy consideration is the tubeless siphon effect of a non-Newtonian fluid. It happens when the SO converts to a tunnel shape during active aspiration and the HSO is aspirated from the posterior pole, avoiding the proximity of the needle to the retina [3, 8].

Other techniques have been described for Densiron® HSO (Fluoron, Gmbh, Neu-Ulm, Germany) removal but they are not appropriate for Oxane HD in our opinion. One is injecting perfluorocarbon liquid (PFCL) posteriorly to the HSO and leaving a 20-gauge sclerotomy open for HSO drainage [4]. This technique has not been accepted widely because previous studies have suggested that the SO that forms becomes sticky when these two compounds are mixed [3]. Although most cases of sticky SO occur when PFCL remnants are in persistent contact with SO or HSO, one case of sticky SO formation was described intraoperatively. It that case, the surgeon exchanged PFCL for SO (fluid-fluid exchange) and removed the SO during the same surgery to retreat residual subretinal fluid [9, 10].

Another procedure is the use of the blue connector from the Constellation Viscous fluid Control Pak® (Alcon, Ft. Worth, TX) connected to a 23-gauge trocar. It reduces Densiron® HSO removal time by combining suction with a short cannula. After the removal, a flute cannula is used to remove residual bubbles in the posterior pole [3]. In our experience, the higher viscosity of Oxane HD (3.300) compared to that of Densiron (1.400) makes this technique difficult because the cannulas usually clog and need to be replaced. This would result in residual posterior bubbles that need to be aspirated in the posterior pole with increased risk to the retina [11].

Active aspiration using a 7.5-mm 20-gauge needle is another technique. According to Poiseuille’s law (flow = ∆Pπr4/8Ln), the use of a shorter needle compensates for a smaller diameter and maintains sufficient flow to aspirate HSO Densiron [8]. In our experience, Oxane HD is more viscous and the flow is compromised. In addition, if the tip of the needle looses contact with the HSO, the bubble falls to the posterior pole and cannot be reached using the short cannula. This must be considered, especially in myopic eyes with longer axial lengths. The 18-gauge needle has a greater diameter to override the limitation of the greater length (40 mm) and still achieves sufficient flow to fully aspirate the HSO. In both scenarios, sclerotomies must be sutured to prevent leakage and postoperative hypotony.

The main concern associated with HSO use for most retina surgeons is the difficulty it presents when it is removed. However, appropriate modification of surgical techniques during removal of Oxane HD SO is advised to limit intraoperative complications. These issues notwithstanding, heavy SO remains a useful vitreous substitute in selected high-risk retinal detachment surgery cases.