Congenital and infantile cataract is an opacification of the crystalline lens of the eye, estimated to cause 5% to 20% of blindness in children worldwide. Early diagnosis and surgical removal of these cataracts are critical to improving the visual prognosis of the child and preventing amblyopia, which can lead to irreversible vision loss. Unlike adults, pediatric cataract surgery has a far greater risk for complications due to the enhanced inflammatory response in children.¹ 

One treatment option for congenital cataract is to remove the cataract and treat the refractive error with glasses or contact lenses. These remain costly and are a considerable burden to caregivers. For a unilateral cataract, the difference in prescription of the eyes can be cosmetically relevant and uncomfortable because of the difference in lens weight. The contact lens must appropriately match the refractive error of the child, leading to multiple appointments and adjustments. In addition, approximately 18% of patients with aphakia experience a contact lens-related adverse event, including corneal abrasion, ulcer, or keratitis.² Anytime the child is without the appropriate refractive correction, he or she is at risk for amblyopia. Another option is to insert an intraocular lens (IOL), offering continuous refractive correction, but due to the exaggerated immune response, postoperative scarring still can occlude the visual axis, thereby still limiting the child's vision.³ 

These treatment plans were compared previously in a randomized clinical trial, the Infant Aphakia Treatment Study (IATS).⁴ This study reported that subjects treated with an IOL needed more surgeries in the first postoperative year secondary to complications, many of which were related to scarring and membrane formation.⁵ Although this may encourage physicians to perform lensectomy without IOL implantation, the significant burdens and challenges of contact lenses still result in complicated outcomes for these children. Given these current limitations, our goal is to develop treatments to reduce the postoperative adverse events and additional surgeries associated with use of an IOL for pediatric cataracts, potentially improving visual outcomes and significantly reducing the burden of the caretaker. The IATS reported that pupillary membranes and corectopia accounted for 17 and 11 of the 62 postoperative complications, respectively.⁵ These complications are believed to result from scarring and fibrin membrane formation. 

To further investigate these complications, we used a juvenile rabbit animal model of lensectomy with IOL insertion. This model has been used to study many new surgical techniques and tools, including phacoemulsification systems, IOL insertion systems, irrigating solutions, and other novel technologies.⁶ Compared to humans, rabbits have similarities in anterior chamber size and lens diameters that allow them to be an excellent animal model for evaluating the biocompatibility of IOLs in preclinical trials.^7,8 Similar to human infants, younger rabbits have a more robust response to lensectomy than adults, making juvenile rabbits ideal models for studying the effect of IOL implantation for congenital cataracts. Using this model, we investigated the use of pharmacologic agents triamcinolone and enoxaparin, a low molecular weight heparin, for management of postoperative inflammation and scarring following lensectomy with IOL implantation. 

Triamcinolone is a corticosteroid that is five times more potent than the natural compound cortisol, making it an extremely potent anti-inflammatory agent,⁹ and it is approved by the United States Food and Drug Administration for the management of chronic ocular inflammatory conditions, such as uveitis.¹⁰ Additionally, triamcinolone has been reported previously to prevent postoperative complications after pediatric lensectomy,¹¹ making it an appropriate choice to investigate in this rabbit animal model. 

Heparin is an anticoagulant that forms a complex with antithrombin III (AT III). The heparin–AT III complex prevents conversion of prothrombin to thrombin and, hence, decreases the formation of fibrin clots. The heparin–AT III complex also exhibits anti-inflammatory properties.¹² Enoxaparin is a low molecular weight heparin with a longer half-life in the blood than heparin. It functions as an anticoagulant that is administered via subcutaneous injection. Given these therapeutic properties, we investigated the effect of intraocular injection of triamcinolone, enoxaparin, and a combination of these agents into the anterior chamber of the eye of a juvenile rabbit model. 

All experiments were approved and in compliance with the Institutional Animal Care and Use Committee at the University of Illinois at Chicago (UIC) and the Medical College of Wisconsin (MCW). A total of 36 New Zealand White Rabbits between 6 and 7 weeks old from Harlan (Indianapolis, IN) or Covance (Denver, PA), weighing between 600 and 900 g were used in this study. Seven of these rabbits were used for testing surgically naïve eyes. A total of 29 rabbits were anesthetized for bilateral clear-cornea lensectomy surgery with IOL insertion with intravenous ketamine and xylazine 50 to 60/5 mg/kg. The surgical technique, as described below, was standardized for every procedure, and the same surgeon performed all procedures for each experiment. The eye was prepped with 5% betadine solution (Alcon, Fort Worth, TX) into the eye and the surrounding area was prepped with 10% betadine and draped. A clear corneal incision was made just anterior to the limbus using a 20-gauge MVR blade. The anterior chamber was reformed with viscoelastic (Keralon V++; Keragenix, Rapid City, SD). A cystitome needle was used to puncture the anterior capsule followed by micro-Utrata forceps to make a continuous curvilinear capsulorrhexis. The lens then was removed by irrigation and aspiration with balanced salt solution (BSS; Sterile Irrigating Solution; Alcon Laboratories, Inc., Fort Worth, TX) via a Simcoe double lumen irrigation/aspiration cannula. No additional medications were added to the solution. The anterior chamber and capsular bag then were filled with viscoelastic and the wound was expanded with a 2.4 mm keratome blade. A 10-0 nylon mattress suture was preplaced into the corneal wound. A +30 diopter acrylic foldable IOL (Alcon, Fort Worth, TX), was inserted into the capsular bag. The viscoelastic then was removed with Simcoe irrigation and aspiration. The preplaced suture was tied to close the wound and the knot was buried. Once the wound was deemed watertight, either enoxaparin 8 mg (seven rabbits), preservative-free triamcinolone 0.5 mg (six rabbits), 8 mg enoxaparin plus 0.5 mg triamcinolone (combination therapy; seven rabbits), or BSS (untreated, 9 rabbits) was injected into the anterior chamber. The rabbit then was awakened from anesthesia. The rabbits received topical erythromycin twice daily for 4 days and analgesia with subcutaneous buprenorphine (0.01–0.05 mg/kg) perioperatively twice a day for 3 days as needed. Rabbits then were separated into two sets of postoperative testing, either clinical examinations (12 rabbits) or aqueous humor sampling with pathology (17 rabbits) as described below. These two groups allowed for clinical testing without sampling of the aqueous humor disrupting testing of the postoperative clinical course. An additional seven rabbits did not have any surgery and were examined clinically as described below. 

Postoperatively, 19 rabbits were examined under sedation with ketamine and dexmeditomidine 1 to 5/0.5 mg/kg subcutaneously on days 3 through 7 and 14. Twelve rabbits underwent bilateral lensectomy as described above and seven had unoperated eyes examined for baseline testing. Although docile, rabbits were sedated to prevent stress and discomfort during these exams. The examinations consisted of spectral domain optical coherence tomography (OCT) inferior to the optic nerve (Spectralis; Heidelburg Engineering, Heidelberg, Germany), intraocular pressure (IOP), and slit-lamp biomicroscopy examinations with photography. The IOP in each eye was measured using an Icare rebound tonometer (icare USA, Raleigh, NC). Slit-lamp biomicroscopy was used to evaluate each eye in the following categories: iris synechiae, pupil dilation in millimeters, hemorrhage in the anterior chamber, amount of fibrin in the anterior chamber, cell grade, flare grade, and amount of posterior capsule opacity that was present. Cell and flare grades were measured using the SUN classification system criteria.¹³ The size of the fibrin clot in the anterior chamber was measured as a percentage of the 6 mm optic that was covered. 

OCT was used as an objective measure to quantify the clarity of the visual axis following surgery.¹⁴ We approximated visual axis clarity based on signal strength determined by the Spectralis OCT. At each postoperative day, operated eyes underwent OCT (19 b-scan volume), and the average signal strength was calculated from the 19 scans. These average signal strengths then were grouped and compared between control and treatment groups. 

Surgical complications, such as posterior capsule tears or dislocated IOLs, could increase postoperative inflammation and fibrin or decrease the OCT signal strength. While there were complications in each treatment group, coincidentally, we experienced no surgical complications in the untreated group. Following clinical examination on postoperative day 14, rabbits then were euthanized with intravenous Fatal Plus (Vortec Pharmaceuticals, Dearborn, MI) until there was an absence of respiration, cardiac function, corneal reflex, muscle tone, and mucus membrane color to confirm death. 

A total of 17 rabbits undergoing bilateral clear cornea lensectomy with IOL implantation were used for ELISA assays of the aqueous humor. ELISA assays were used to quantify the amount of fibrinogen and fibrin analytes present in aqueous humor preoperatively (Pre) and on postoperative day 3 (POD 3). POD 3 was chosen because it was determined to be the peak of the postoperative response from preliminary studies.¹⁵ On POD 3, a brief clinical exam with a slit-lamp was performed to ensure the findings were consistent with clinical exam data. Following sterile preparation, approximately 100 to 200 μL of aqueous humor was aspirated from the anterior chamber via paracentesis using a sterile 30-gauge needle on a 1 cc syringe. Aqueous fibrinogen and fibrin levels were quantified using a double-antibody solid-phase sandwich ELISA for rabbit fibrinogen or fibrin (TSZ ELISA; Biotang, Waltham, MA). Briefly, 96-well flat bottom polystyrene plates were coated with an antifibrinogen or antifibrin antibody; 100 μL of aqueous humor sample then was loaded onto the plate to bind with the coated antibody. Following the addition of a biotinylated-fibrinogen or fibrin antibody, the HRP-Streptavidin enzyme conjugate was added into the wells. After washing, tetramethylbenzidine substrate was added. Following incubation, the reaction was terminated using an acidic stop solution and the absorbance value was read by a microplate reader. Because the volume of aqueous humor collected was not sufficient to allow for testing of fibrinogen and fibrin levels, all conditions did not have equal sample sizes. The number of aqueous humor samples included in the ELISA fibrinogen analysis preoperatively (Pre) were n = 8 eyes, and at POD 3 they were n = 6, n = 7, n = 5, and n = 8 for untreated, and enoxaparin-, triamcinolone, and combination therapy–treated eyes, respectively. The number of aqueous humor samples included in the fibrin analysis were as follows: Pre: n = 10 eyes, and POD 3 n = 5, n = 7, n = 5, and n = 8 for enoxaparin-, triamcinolone-, and combination therapy-treated eyes, respectively. 

Following aqueous humor sample collection on POD 3, rabbits then were euthanized with intravenous Fatal Plus (Vortec Pharmaceuticals, Dearborn, MI) until death was confirmed by absence of respiration, cardiac function, corneal reflex, muscle tone, and mucus membrane color. 

The eyes of rabbits euthanized on POD 3 then were removed and fixed in 10% neutral buffered formalin for 7 days. After fixation, tissues were dehydrated through graded ethanol, cleared with xylene, paraffin infiltrated, and embedded into tissue blocks. Tissue blocks were cut coronally between the pars plana and equator of the eye to isolate the anterior segment at a thickness of 4 μm and mounted on poly-L-lysine–coated slides. Sections were stained immunohistochemically for detection of fibrin using a 1:1000 dilution of mouse monoclonal antifibrin antibody 59D8¹⁶ purified from ascites (gift from Dr. Sood, Pathology & Laboratory Medicine, Medical College of Wisconsin; Hybridoma Core, Blood Center of Wisconsin, Milwaukee, WI). With standard labeled streptavidin-biotin (LSAB) detection, the tissue sections were deparaffinized, rehydrated, and antigen retrieved with citrate buffer. After application of peroxidase, avidin/biotin, and endogenous protein blocks, the primary antibody was incubated for 60 minutes at ambient temperature. A biotinylated anti-mouse secondary antibody (715-066-151; Jackson ImmunoResearch, West Grove, PA) was applied before streptavidin-horseradish peroxidase (HRP) and visualized with detection of antibody binding (DAB). High-resolution images were obtained with a Hamamatsu Nanozoomer 2.0-HT high-resolution digital slide scanner (Hamamatsu Corporation, Bridgewater, NJ). 

Continuous data were compared using a generalized linear mixed model with interactions (R version 3.1.2, R Foundation for Statistical Computing, Vienna, Austria). Categorical data, including assessments of cell, flare, and anterior chamber fibrin, were compared using Fisher's exact tests. P = 0.05 was set to determine statistical significance, and a Bonferroni correction was applied for three comparisons. ELISA data were analyzed using GraphPad Prism (GraphPad, La Jolla, CA) with one-way analysis of variance (ANOVA) followed by Tukey's test. 

In the juvenile rabbit, after lensectomy with IOL implantation, untreated eyes had a large amount of opacification in the anterior chamber that decreased over time (Fig. 1, 2). Treated eyes with injections of enoxaparin or a combination of enoxaparin and triamcinolone increased clarity of the visual axis (Fig. 1). This corresponded to a significant increase in OCT signal strength (Fig. 2, P < 0.005). The average OCT signal strength in surgically naïve eyes was 30.15 ± 1.02 (n = 6). Examining the average amount of fibrin in the anterior chamber over time in all eyes in each group over time, enoxaparin and the combination of enoxaparin and triamcinolone significantly reduced the amount of fibrin observed in the anterior chamber compared to untreated eyes (Fig. 2, P < 0.005). Triamcinolone 0.5 mg did not significantly decrease anterior chamber fibrin (P = 0.3853). 

Anterior chamber fibrin results correlated with the posterior synechiae, where the iris is adherent to either the anterior capsule or the lens itself. Posterior synechiae were present in the untreated and triamcinolone groups that were not present in the eyes treated with enoxaparin or combination therapy (Fig. 1). Consistent with less synechiae, eyes treated with enoxaparin or combination therapy dilated more, with the entire optic and parts of the haptic being visible compared to either the untreated or triamcinolone-treated eyes (Fig. 1). Mean ± standard deviation (SD) pupil dilation size on POD 3 was 5.95 ± 0.373 mm for untreated eyes and 7.65 ± 0.273 mm for eyes treated with combination therapy (P = 0.00426). 

Next, we examined the anterior chamber for the two measures of anterior chamber inflammation, cell and flare, in addition to IOP (Fig. 3). Combination therapy significantly reduced the amount of flare on POD 3. Eyes treated with combination therapy had a higher IOP compared to untreated eyes, which was closer to eyes that did not have any surgical intervention. 

ELISAs revealed significant differences in fibrinogen levels when comparing untreated eyes with Pre samples and eyes treated with combination therapy (Fig. 4A). Interestingly, despite a clinical appearance of a large membranous component we suspected to be fibrin, the amount of fibrin detected by ELISA was not statistically different between eyes preoperatively and untreated eyes on POD 3. In fact, the only significant differences observed in fibrin levels were identified between eyes treated with combination therapy compared to enoxaparin-treated eyes and eyes before surgical intervention (Pre) (Fig. 4B). No apparent complications or iris trauma occurred during these sample collections. Despite the clear visual axis shown in clinical images (Fig. 1D), the combination treatment group had the highest levels of fibrin. 

Antibody testing using a fibrin-specific antibody was not observed in an unoperated eye (Fig. 5A). Sections of fibrin could be observed in the untreated (Fig. 5B) and triamcinolone-treated eyes (Fig. 5C) and appeared reduced in enoxaparin-treated (Fig. 5D), and combination-treated (Fig. 5E) eyes. 

The surgical and postoperative management of pediatric cataracts remain a challenge in ophthalmology. Treatment decisions made by pediatric ophthalmologists have lifelong implications regarding the visual potential of the child. By reducing the incidence of adverse events with implantation with an IOL, it is possible that children may have improved visual acuities and a lower influence of socioeconomic disparities on the visual outcomes of children who need cataract surgery. To investigate potential pharmacotherapies that could be used to address this problem, we performed a similar operation in a rabbit animal model. In this model, the inflammatory response and fibrin formation is more severe than that typically observed in a child. By addressing exaggerated cases of inflammation and fibrin formation with our rabbit model, our study showed the pharmacotherapies we evaluated may yield promising outcomes in children as well. 

Our results showed a significant reduction in the formation of postoperative fibrin with enoxaparin alone and combined with a low dose of triamcinolone (Fig. 1). At the low dose, triamcinolone alone did not significantly improve fibrin in the anterior chamber (Figs. 1C, 5C), grading scores of cell or flare, or OCT signal strength (Figs. 2, 3). Although all groups did show some improvement in OCT signal strength, they did not reach the signal strength of surgically naïve eyes at day 14, although enoxaparin and combination therapy were closest to naïve eyes. These data correlated with other studies where a lower dose of only 1.2 mg triamcinolone had no effect on postoperative outcomes in patients undergoing congenital cataract surgery.¹ The triamcinolone dose of 0.5 mg is relatively low, with other studies using up to 4 mg with observed postoperative benefits.^17,18 We intentionally chose a lower dose of the corticosteroid, triamcinolone, to determine if there was a synergistic effect when used combined with the low molecular weight heparin, enoxaparin, because of their different mechanisms of action. There also is the potential added benefit of decreasing the risk of steroid response glaucoma with a lower dose of triamcinolone. Given the benefits that we observed in using a combined dose, we would suspect a higher dose of triamcinolone may provide even better clinical outcomes. Enoxaparin alone also did not demonstrate the same anti-inflammatory properties when compared to combination therapy, as the cell and flare grades after treatment with enoxaparin remained high in several eyes (Figs. 3B, 3C). Combining enoxaparin and triamcinolone appears to provide a synergistic therapeutic benefit by decreasing fibrin (Figs. 1D, 5D) and inflammation. 

The use of enoxaparin has been reported previously for cataract surgical management, with mixed results observed in postoperative inflammation.^19–22 We chose enoxaparin over heparin in this study due to the longer half-life of enoxaparin to increase the duration of action. Prior studies investigated enoxaparin or heparin in the irrigating solution used during human congenital cataract surgery. However, the solution was present at a relatively dilute dose during surgery in the irrigating solution. The dose of enoxaparin in this study is 500-fold more concentrated than that used in the irrigation fluid for the randomized study of children (0.08 mg/mL in previous studies versus 40 mg/mL in this study). 

Previous studies have investigated coating IOLs in heparin to decrease intraocular inflammation in children²³ and adults,^24,25 but the studies have yielded inconsistent outcomes. Furthermore, all of these trials previously performed in humans were done with consistent treatment of topical steroids. Our study involved a single therapeutic dose with no additional treatment of topical steroids, easing the requirements of postoperative management. 

We used ELISA assays to compare the clinical efficacy of the therapies tested with the concentrations of aqueous fibrinogen and fibrin. The concentration of fibrinogen was higher in the untreated group at POD 3 compared to treated groups and preoperatively. Treatment with a combination of enoxaparin and triamcinolone significantly reduced the amount of fibrinogen present in the aqueous compared to untreated rabbits. Surprisingly, the combination therapy, which resulted in the highest fibrin concentration in the anterior chamber (Fig. 4B), did not correlate with the slit-lamp images of the anterior chamber fibrin clot (Fig. 1D). We also anticipated the levels of fibrin to be higher in the untreated rabbits compared to eyes preoperatively, yet this difference was not statistically significant. It is possible that this difference is due to fibrin becoming insoluble in the eyes to become fibrin clots; therefore, reducing the soluble fibrin detected in the aqueous with ELISA. Histology staining (Fig. 5) confirmed that the anterior chamber clot was composed of fibrin. It is possible that the combination therapy makes this fibrin more soluble, so it is present in the aqueous via paracentesis on POD 3. It is possible that paracentesis of the aqueous humor of untreated eyes, which could not withdraw portions of the insoluble clot, would miss the fibrin mass; thus resulting in a low fibrin concentration reading despite visually significant fibrin appearing on clinical examination. 

Although informative, our study had several limitations. Given the inclusion of rabbits with complications in the treated groups, it is possible that the effect would be even more apparent in the absence of surgical complications. An additional limitation is the rather limited number of eyes (n = 6) used in clinical evaluations. Lastly, we did not evaluate the postoperative course beyond 2 weeks, so the effect of therapies on posterior capsule opacity formation cannot be determined from this study. Larger and long-term studies are needed to help confirm these observations. 

The injection of both drugs used in this study carries inherent risks. Enoxaparin, a potent anticoagulant, increases bleeding risk. Bleeding was not observed at an increased frequency in any treatment group. It is possible that by injecting the enoxaparin after the wound was closed and the anterior chamber was stable, the risk of bleeding was minimized. Triamcinolone, a corticosterioid, can result in steroid-response elevations in IOP, which also was not observed in our treatment groups. Steroids also can reduce the immune response from triamcinolone and can make the eye more prone to infection, which was not seen in this study.²⁶ 

Our study demonstrated the therapeutic efficacy of a combination of enoxaparin and triamcinolone in this juvenile rabbit model after lensectomy with IOL insertion. More studies must be done to determine its potential use in humans. Additional studies must examine the effect of different drug doses, such as higher amount of triamcinolone alone, and combined with a lower dose of enoxaparin, on postoperative fibrin and inflammation. Furthermore, determining the duration of half-life and clearance in the anterior chamber will help us further titrate the most effective intraocular dose of combination therapy in the context of lensectomy. Understanding the effect of enoxaparin and/or triamcinolone on the inflammatory cascade of the eye may give us clues about the mechanism of action and synergy as well as other potential therapeutic targets. Nevertheless, establishing this procedure in a juvenile rabbit model is a critical first step as we work towards reducing fibrin formation and inflammation associated with pediatric lensectomy with IOL implantation. 

The authors thank Deborah Conklyn, Herbert Whitely, D.V.M, PhD, and Christine Skumatz for technical assistance and helpful discussion; the lab of Rasmi Sood, PhD, for the 59D8 fibrin antibody; Qiuhui Yang for helping to facilitate access to the antibody; and the Children's Research Institute Histology core for all of their assistance, specifically Tatunya Bufford and Christine Duris. 

Supported in part by the National Eye Institute of the National Institutes of Health (Bethesda, MD) under awards K08EY024645 (ISK), P30EY001931, and P30EY001792, and by an unrestricted departmental grant from Research to Prevent Blindness and Children's Research Institute grants. The sponsor or funding organization had no role in the design or conduct of this research. 

Disclosure: J.D. Bogaard, None; J.B. Young, None; A. Movahedan, None; I.S. Kassem, None