Careful construction of the incisions is often neglected by beginner surgeons. The keratomes used should be accurately matched with the diameter of the phaco needle and sleeve. A tight wound pinches the sleeve and reduces the flow of fluid into the eye, while the vacuum remains the same. This leads to an unstable AC and severe surge, increasing the chances of PCR. A tight wound is recognized by the difficulty in maneuvering the phaco tip, corneal striae, and, if not recognized early, by wound burn (Fig. 11.3). Once recognized, the tight wound can easily be increased to the right size with a keratome, and the problem is resolved. A large wound leaks (Fig. 11.4), and unless sutured or the bottle height increased, it causes shallowing of the AC, increasing the probability of PCR. When suturing the wound does not help, the wound is closed with sutures, and a fresh one is created at a new location. Side ports that are leaky either due to large size, short length, or tears of the roof should be sutured before continuing with phacoemulsification.

Improperly made or incomplete anterior capsulorhexis can lead to a host of intraoperative and postoperative complications. A small capsulorhexis is easily damaged during phacoemulsification either with the phaco needle or with the second instrument. A runaway capsulorhexis which could not be rescued could have an extension up to the equator at that point. A capsulorhexis that has been completed with a notch pointing to the outside (Fig. 11.5) is weak and can tear at this point. All these scenarios could, during phacoemulsification, lead to the anterior capsule tear extending across the equator into the posterior capsule causing a PCR. A less experienced surgeon would be better off converting to a manual small-incision cataract surgery (MSICS) or a standard extracapsular cataract extraction. A more experienced surgeon would be able to continue with phacoemulsification using a direct chop technique with minimal rotation and lateral stress on the capsule to try and avoid the tear from extending. It is important to prevent collapse of the AC by adjusting the fluidics parameters and by filling the AC with Ophthalmic Viscosurgical Device (OVD) before stopping irrigation.

Hydrodissection is potentially fraught with danger for a beginner surgeon, and at times even the experienced ones. All of us have at some point or the other experienced that sinking feeling seeing the nucleus sink into the vitreous following hydrodissection. A small capsulorhexis adds to the risk of posterior capsule blow out. The ideal capsulorhexis should be around 5–5.5 mm so that it allows the escape of the fluid injected during hydrodissection, at the same time providing 360° coverage of the optic of the IOL by the anterior capsule margin. For a beginning surgeon, it is prudent to create a capsulorhexis which is around 6 mm in diameter. This makes the hydroprocedures safer and the nucleus removal maneuvers easier.

Howard Fine first described cortex-cleaving hydrodissection in 1992 [21]. A 26-gauge blunt cannula is inserted under the edge of the capsulorhexis, and the anterior capsule is tented up to lift it up from the underlying cortex. Fluid is now gently injected till a fluid wave is seen passing between the posterior capsule and the overlying cortex. At the same time, the entire lens bulges forward. At this point, the central part of the lens is depressed backward with the cannula; the trapped fluid is forced out cleaving the cortical-capsular adhesions at the capsular equator and under the anterior capsule. This maneuver can be repeated 6 clock hours away. Instead of performing a decompression, if more fluid is injected at this stage, either the edge of the lens prolapses out of the bag, or, more disastrously, the posterior capsule ruptures backward. I (SD) use an alternate technique (Fig. 11.6, Video 11.7), where I perform hydrodissection in one quadrant alone. On seeing the fluid wave crossing the midpoint of the lens, I move the cannula to the opposite pole of the lens, and gently nudge the nucleus backward and toward the site of injection. This creates more space for the fluid to escape out of the bag, thus making the procedure safer. In posterior polar cataract (PPC) and in cases of suspected preexisting PC dehiscence, hydrodissection should be abandoned altogether in favor of hydrodelineation, (Fig. 11.7 e) which preserves the cushion of the epinucleus.

The PC blow out is seen as a “pupillary snap sign,” [19] (Video 11.1) seen as dilatation of the pupil followed by a sudden and brisk constriction. The dilatation is caused by forward movement of the nucleus against the iris caused by the fluid trapped between the nucleus and the PC. The sudden constriction of the pupil happens at the exact time that the PC ruptures, allowing the nucleus to move backward into the vitreous. If this sign is overlooked, the nucleus is highly likely to drop into the vitreous cavity the moment phacoemulsification is started. If the nucleus is still in the patellar fossa or anterior vitreous, one can use a vectis or posterior-assisted levitation (described elsewhere in the book) to retrieve the nucleus into the anterior chamber. The wound is now extended and the nucleus prolapsed out. If the nucleus is in the midvitreous or beyond, it is best handled by a vitreoretinal specialist.

The commonest cause of PCR during phacoemulsification of the nucleus is due to aspiration of the posterior capsule, often the equatorial part, with the phaco tip while removing the last bit of nucleus (Fig. 11.7 and Video 11.4). The second more common cause is due to the capsulorhexis margin getting accidentally cut by the second instrument or with the phaco tip itself [22]. This goes unnoticed most of the time, resulting in the tear extending beyond the equator into the posterior capsule. The former is prevented by reducing the fluidics parameters and injecting a dispersive OVD into the bag before removing the last nuclear fragment. The latter is prevented by staining the anterior capsule with trypan blue before the capsulorhexis, so that the capsulorhexis margin is clearly visible throughout the phacoemulsification, reducing the chances of inadvertent damage to it. If a capsulorhexis tear is noticed early, the tag is torn to complete it into a capsulorhexis again, preventing extensions during further maneuvers. While performing a vertical chop, one should stay within the capsulorhexis. While performing a horizontal chop which necessitates an excursion of the chopper up to the equator of the lens, it is necessary to scrape the surface of the lens while traversing distal to the capsulorhexis margin so as to not cut it.

Iatrogenic PCRs during irrigation-aspiration (IA) and PC polishing (Fig. 11.8 and Video 11.9) can be caused by poor-quality instruments with sharp edges. Hence, it is prudent to check the IA cannulae under the microscope before using them. The PC can get engaged in the aspiration port if high vacuum is used during PC polishing. This can be avoided by using low-to-moderate vacuum and aspiration flow rate (AFR) and by avoiding random movements while aspirating the cortex. Using silicone-tipped irrigation-aspiration handpieces reduces the incidence of PCR during cortex aspiration and PC polishing [23].

Most PCRs during IOL implantation occur due to a sudden uncontrolled ejection of the IOL from the cartridge (Fig. 11.9 and Video 11.10). The anterior chamber should be kept deep with OVD before IOL implantation. If the plunger of the IOL injector is anything but smooth at any stage of IOL implantation, it should be withdrawn from the eye, the IOL reloaded, and implantation re-attempted. An IOL shooting through the equatorial capsule into the vitreous can have serious consequences. Utmost care is needed while implanting three-piece IOLs. Wait for the optic to open fully after inserting the leading haptic into the bag, before dialing in the trailing haptic. The tip of the leading haptic points backward toward the PC before the optic opens, and if the IOL is implanted in a hurry, the tip may pierce the PC (Videos 11.11 and 11.12).

This last step is not without risks. The cannula detaching from the syringe can enter the eye with considerable force, causing complications such as Descemet’s membrane detachment, PCR, IOL dislocation, and iridodialysis. This is avoided by using a properly fixed cannula on a Luer-locked syringe, and if not available, the hub of the cannula should be grasped firmly between the thumb and forefinger of one hand before injecting saline into the wound margins and the anterior chamber. Even if the cannula was to detach itself, it would still be held between these two fingers and not shoot into the eye.

Even after taking these precautions, surgeons will encounter a PCR sometime, and the next section will deal with its management.