Primary cataract surgery to address traumatic cataract and/or lens subluxation/dislocation has certain advantages over secondary surgery, including:

However, surgery may be deferred until certain surgeon-related or center-related factors are addressed (e.g., availability of a more experienced surgeon able to undertake technically challenging techniques, trained support personnel, or special instrumentation that may not be available to the surgeon in emergent surgeries that are performed outside normal working hours such as vitrectomy, capsular tension rings, or special IOLs). Surgery is also better deferred if the cataract is presumed to be visually insignificant, particularly in the absence of coexisting ocular injuries requiring surgery. However, traumatic cataracts can be stationary or progressive (particularly in the presence of an intralenticular foreign body due to siderosis) [42, 43], and regular follow-up is required to rule out progression of traumatic cataracts initially considered visually insignificant.

Primary closure of globe lacerations (corneal, limbal, scleral, or corneoscleral), when present, is the first step in the management of traumatic cataract, since a formed globe is necessary for safe cataract removal. Constructing a separate incision for the removal of cataract (clear corneal, limbal, scleral, or pars plana) is preferred to utilizing the existing traumatic corneal wound to avoid inflicting damage to the endothelium or inducing Descemet’s detachment [44]. Liberal use of ophthalmic viscoelastic devices (OVDs) or the use of an anterior chamber maintainer should be employed to keep the globe formed at all times and to avoid potentially devastating complications such as suprachoroidal hemorrhage (SCH). The anterior chamber should be washed to remove hyphema to improve the view, and any floating lens particles should be removed. Anterior chamber vitrectomy should also be performed when vitreous strands are visible anterior to the crystalline lens plane. The pupil should be dilated using iris retractors or pupil-dilating (e.g., Malyugin) rings if the pupil is not readily and sufficiently dilated, and capsular staining should be considered to improve the view for capsulorhexis.

Important factors to consider when determining the method of cataract removal are:

In cases in which zonular support is deemed to be sufficient for safe removal of the cataract through an anterior (limbal) approach, cataract can be removed using manual extracapsular cataract extraction (ECCE), phacoemulsification, or vitrectomy. Capsulorhexis can be challenging in the traumatic cataract. Minimal downward pressure on the lens and compression of the lens should be carried out using a pair of capsulorhexis (e.g., Utrata) forceps or a cystotome needle in order to avoid further weakening of the zonules. The capsulorhexis should start away from the presumed area of zonular weakness. Partial capsulorhexis may be done, followed by, when necessary, insertion of capsule retractors to support the area of zonular loss, before capsulorhexis is safely completed. Capsular tension rings or ring segments can be used either after performing capsulorhexis or prior to nuclear disassembly in phacoemulsification. Capsular microscissors (which insert through a paracentesis) may be used if the anterior capsule is torn and the direction of tear does not allow safe redirection of the capsular flap to achieve a continuous, curvilinear capsulorhexis to avoid extension of the anterior capsule tear. Capsular staining using trypan blue dye under an air bubble should be used in traumatic cataracts where adequate visibility of the capsule cannot be achieved, due to the lack of a contrasting red reflex due to either a hard cataract, vitreous hemorrhage, or milky white traumatic cataract.

Phacoemulsification (with low vacuum and aspiration settings to avoid anterior chamber size fluctuation and prevent further zonular damage) [45] is the preferred technique when the posterior capsule is intact and adequate zonular support is present due to its less traumatic nature and faster visual recovery. Manual ECCE or slow-motion phacoemulsification can be carefully attempted if the status of the posterior capsule cannot be precisely determine in the presence of good zonular support or in the presence of a small posterior capsule rent with no vitreous prolapse. If the chamber is deep enough, supracapsular cataract extraction is also a good approach to remove the lens since this approach, with the partial prolapse of the cataract in the iris plane for phacoemulsification, reduces zonular stress with the lens being fractured outside the capsular bag.

The surgeon needs to be ready to switch to vitrectomy if vitreous prolapse is detected. Posterior-assisted levitation (PAL) using a 1-mm spatula inserted through a pars plana sclerotomy created by a microvitreoretinal (MVR) blade 3.5-mm posterior to the limbus to lift the posterior capsule-lens complex upward and resume phacoemulsification of remaining nuclear fragments may be attempted by experienced surgeons when a rent in the posterior capsule is inadvertently brought about or becomes evident or when further zonular damage is inflicted during nuclear fragmentation [46]. This technique can also be planned preoperatively in subluxated lenses thought to not be adequately fixable using capsular tension rings. Viscoelastic agents should be liberally used to return into the vitreous cavity any vitreous strands attached to the posterior capsule or prolapsing into the bag or anterior chamber if this technique is used. However, the technique is technically challenging and carries a risk of significant complications such as nuclear drop and retinal detachment. Intracapsular cataract extraction (ICCE), while can be employed in cases of significantly severed zonular support, requires the creation of a large incision and carries a high risk of suprachoroidal hemorrhage (SCH) [44].

In the presence of vitreous prolapse or a large rent in the posterior capsule, or if there is an indication of a posterior segment surgery at the time of cataract extraction, pars plana lensectomy/vitrectomy (PPLV), with the possible aid of phacofragmentation in hard nuclei, is the procedure of choice [44]. Lens removal using the vitrector has the advantage of utilizing a small incision and minimizing the risk of suprachoroidal hemorrhage (SCH). The pars plana approach, while requires special expertise and equipment, is preferred to corneal or limbal approaches when vitrectomy is planned, since it maintains corneal clarity and achieves a more complete vitrectomy behind the iris plane [44].

Age of the traumatic cataract patient is also an important determinant of the surgical technique to be employed. In young children, performing primary posterior capsulotomy and anterior vitrectomy is indicated due to the high rate of posterior capsule opacification [47, 48]. Anterior and posterior lens capsules are very elastic in young children, and standard continuous curvilinear capsulorhexis (CCC) is technically challenging. Vitrectorhexis is gaining popularity as an equally effective alternative to anterior and posterior CCC in children, with the added benefit of being faster, more predictable, and reproducible and requiring only a short learning curve [49–51]. The authors prefer using the vitrectomy system for cutting the lens matter through a limbal incision with the aid of an anterior chamber maintainer over the older irrigation/aspiration techniques for soft pediatric cataracts. A separate pars plana port is subsequently created for posterior vitrectorhexis and limited anterior vitrectomy, although suturing the sclerotomy site may be required, even with the use of 23-gauge and 25-gauge vitrectomy systems [49].

The age also determines the vitrectomy settings to be used when cutting the nuclear matter utilizing the vitrectomy system is planned. In children and young adults, using only aspiration without cutting usually suffices, with more cutting required with older patients and harder cataracts.

Preservation of anterior and/or posterior capsular support to allow in-the-bag or in-sulcus implantation of IOLs is an important goal of surgery in most traumatic cataract. However, achieving adequate capsular support is not always feasible, especially when the degree of zonular loss is significant or when pars plana lensectomy/vitrectomy is employed, and in some complex cases, it may be better to leave a patient aphakic and take a staged approach for refractive purposes.

When enough anterior and posterior capsular support permissive of in-the-bag IOL implantation is present, it is best to proceed with in-the-bag implantation, since the IOL-capsular bag complex is more resilient and resistant to subsequent trauma [52]. Three-piece foldable IOLs are preferred over single-piece IOLs since three-piece lenses provide more tensile strength, can provide enough support in mild degrees of zonular loss when implanted in the bag, and may afford better resistance to capsular phimosis [53–55]. Moreover, the optic of a three-piece lens can be captured in the bag with placement of the haptics in the sulcus to provide additional tensile support.

Sulcus implantation of a three-piece foldable IOL is indicated when the capsular support available is not enough to permit in-the-bag implantation of the IOL or anterior optic capture. Viscoelastic agents should be injected in the ciliary sulcus between the iris and the remaining capsular support in order to insure proper placement of the IOL optic and haptics in the sulcus. Central polishing or removal of the capsular support tissue is recommended in such cases [56].

If no enough capsular support permissive of IOL implantation in the bag or in sulcus or when such positioning may result in a significant IOL tilt with or without the use of capsular tension rings, the use of an angle-supported anterior chamber IOL, sulcus-sutured or glued posterior chamber IOL, or iris-fixated IOL is indicated following anterior vitrectomy. The visual outcome achieved using these techniques is generally comparable [57].

Angle-supported anterior chamber IOLs are implanted in close proximity to the posterior corneal surface. Therefore, they have the potential for inducing corneal decompensation and precipitating pseudophakic bullous keratopathy (PBK), especially when the older model is used [58, 59]. It is important that the haptics are well seated in the angle to minimize PAS and effects on the cornea. These types of IOLs in younger patients or in patients in whom the axial length and/or anterior chamber depth (ACD) is relatively small may have greater long-term complications.

Various techniques for fixating IOLs to the ciliary sulcus have been described. Sutured scleral fixation of IOLs with specialized haptics harboring suture eyelets can be achieved using double-armed permanent 8-0 or 9-0 polypropylene sutures and long straight or curved hollow needles (Fig. 2.12a–h) [57]. Most techniques utilize scleral flaps, tunnels, or grooves to provide access to the ciliary sulcus, bury the knots, and guard against suture erosion/exposure. However, difficult centration, IOL tilt, and rotational and anteroposterior instability are potential pitfalls of sulcus-sutured IOLs and may warrant secondary surgical intervention. A peripheral iridectomy using the vitrectomy system is recommended to prevent pupillary block glaucoma. This is achieved by introducing the vitrector into the anterior chamber at the 12 or 9 o’clock position with the port facing down, cutting rate initially set to zero, and an aspiration pressure of 300 mmHg. Once occlusion is achieved, the cutting speed is carefully increased until a full, patent iridectomy is made. In cases of traumatic coexisting aniridia, a black diaphragm tinted IOL (Fig. 2.13) may be sutured to the sulcus [60].

Sutureless sulcus fixation of IOLs can be achieved with the utility of scleral flaps, limbus parallel tunnels, or both [57]. Sulcus-glued IOLs (Fig. 2.14) are becoming exceedingly popular and are thought to have better stability and fewer postoperative complications than do sulcus-sutured IOLs [61–65]. The technique of the procedure involves insertion of an infusion cannula or an anterior chamber maintainer, creation of two limbal-based, partial-thickness scleral flaps 180° apart, and performing two sclerotomies underneath the flaps 1.5-mm from the limbus [66]. This is followed by limited pars plana or limbal anterior vitrectomy to remove all vitreous strands in the anterior chamber, anterior vitreous cavity, and sclerotomy sites. Two scleral tunnels are then created in the edge of the scleral bed underlying the flaps adjacent and parallel to the limbus and following the curvature of the IOL haptics. These tunnels are created in such a way to allow tucking of the IOL haptics once externalized. The IOL is then introduced through a limbal-based incision and the two haptics externalized through the sclerotomies and tucked into the limbal scleral tunnels. Proper IOL centration is ensured by adjusting the tucked length of each haptic. Fibrin glue is then applied over the haptics underneath the scleral flaps which are subsequently repositioned. The infusion cannula or the anterior chamber maintainer is then removed, and the overlying conjunctiva is closed using the same glue. A glued aniridia IOL may also be used in cases of coexisting aniridia [67].

Iris-claw lenses (e.g., Artisan/Verisyse “rigid” and Artiflex “foldable” lenses, Ophtec BV, Groningen, the Netherlands) are popular phakic IOLs used in refractive surgery in patients with high degrees of ametropia (Fig. 2.15) [68–70]. They have, however, been widely used for the correction of aphakia in the absence of sufficient capsular support in adults and children [71–73]. The technique of implantation of iris-claw lenses entails creation of an appropriately sized clear corneal incision centered at the 12 o’clock position and two side ports aligned with the enclavation sites, injection of a miotic agent, filling the anterior chamber with a cohesive viscoelastic, and introduction of the lens into the anterior chamber through the main wound. The lens is then rotated 90° so that the iris claws are horizontally placed in line with the side ports. Iris enclavation of the lens claws is then achieved through the two side port incisions, where a knuckle of iris tissue is captured by the claws on either side of the lens. A peripheral iridectomy is then made at the 12 o’clock position using the vitrectomy system as explained above. Although iris-claw lenses are considered effective in achieving the desired refractive outcome, the relatively high rate of endothelial cell loss remains a major concern [71, 74]. The retro-enclavation of these lenses to the posterior surface of the iris in aphakic eyes has thus become an attractive alternative to anterior iris enclavation, achieving a comparable refractive outcome and inducing less endothelial cell loss [75–77]. Other complications that could result from iris-claw lens implantation include trauma to the iris vessels with subsequent intraocular bleeding, interference with pupillary dilation, dyscoria, and peripheral anterior synechiae formation [57, 78, 79].