Microsoft Word - Mazharul Hassan 30 Original Article Complication and Visual Outcome after Peadiatric Cataract Surgery with or Without Intra Ocular Lens Implantation Mazhar-ul-Hasan, Umair A. Qidwai, Aziz-ur-Rehman, Nasir Bhatti, Rashid H. Alvi Pak J Ophthalmol 2011, Vol. 27 No. 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .. . .. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . See end of article for authors affiliations …..……………………….. Correspondence to: Mazhar-ul-Hasan Isra Postgraduate Institute of Ophthalmology Al Ibrahim Eye Hospital Gaddap town, Malir Karachi Received for publication November’ 2010 …..……………………….. Purpose: To compare the rate of complications and visual outcome after peadiatric cataract extraction with or without intraocular lens implantation. Material and Methods: A total of 202 consecutive children (281 eyes) aged 10 years and younger with unilateral or bilateral congenital cataract, treated and followed up at our institution between March 1st, 2008 and July 30th, 2009, were included in this prospective study. The study was performed at Al-Ibrahim eye hospital, Karachi. Results: Most frequent early complication seen in patients after cataract surgery was striate keratopathy, which was observed in 90 (32%) eyes, while the most common late complication was posterior capsular opacification in 95 (34%), which required either Yag laser capsulotomy or surgical capsulotomy. Among the early complications striate keratopathy was most commonly noted in patients of age older than 1 year having cataract surgery without IOL. Around 50 % patients of psuedophakic groups have visual acuity better than 6/60 while only 26 % of aphakic group patients achieved vision of better than 6/60 with spectacle correction (p<0.05). Conclusion: Correction of aphakia after peadiatric cataract surgery with primary IOL implantation results in improved visual acuity compared to spectacle correction but a higher rate of complications requiring reoperation. ataract in childhood is a most important cause of visual impairment and blindness. Lack of vision in early years of life can adversely affect overall development of child with far reaching effects on personal, educational, occupational and social aspects1. Consequently early detection and treatment is crucial for maximizing visual development and preventing amblyopia2. Treatment of congenital/developmental cataract poses a challenge to the ophthalmologists, patients and parents in terms of visual development and rehabilitation3. Advances and development of new microsurgical techniques and amblyopia management have improved the safety and effectiveness of peadiatric cataract treatment4,5. On the other hand, management of congenital cataract remains a challenge and postoperative complications are still common6,7. In last few years, many retrospective studies have reported varying prevalence’s of several postoperative complications after pediatric lensectomy. However, most of these studies have estimated the risk of secondary cataract formation or aphakic glaucoma separately, and there are only few reports that include other complications8,9). MATERIAL AND METHODS A total of 202 consecutive children (281 eyes) aged 10 years and younger with unilateral or bilateral congenital cataract treated and followed up at our institution between March 1st, 2008 and July 30th, 2009, were included in this prospective study. The study was performed at Al-Ibrahim eye hospital and Indus hospital Karachi. Informed consent was taken from the C 31 guardians of the patients included in the study, as all patients included in this study were less than 10 years of age. Exclusion criteria were ocular trauma, infection, congenital glaucoma, anterior segment dysgenesis, Lowe syndrome, maternal rubella syndrome, trisomy 13, optic nerve or other fundus abnormalities, and prematurity. After detailed history and relevant investigations, ophthalmic checkup including visual acuity, slit lamp examination, fundus examination, retinoscopy, keratometery, B-scan ultrasonography and intra ocular lens power calculation wherever possible were done. Intra ocular lens power was calculated by using SRK II formula. Eyes of patients younger than 1 year were randomly allocated to either group A (patients in this group underwent lens material aspiration with anterior vitrectomy and intra-ocular lens implantation) and group B (patients in this group underwent lens material aspiration with anterior vitrectomy and without intra-ocular lens implantation). Similarly, patients between the age of 1 year to 10 years were randomly allocated to either group C (patients in this group underwent lens material aspiration with anterior vitrectomy and intra-ocular lens implantation) and group D (patients in this group underwent lens material aspiration with anterior vitrectomy and without intra-ocular lens implantation). Dilatation of pupil was done by using cyclopentolate 1% and phenylepherine 10% at 90, 60, 30 and 15 minutes preoperatively. In all cases irrigation and aspiration was done with wide anterior capsulotomy. Primary posterior capsulotomy was done in all cases. In children with bilateral lens opacities requiring surgery, eye with poorer vision was operated first and surgery for second eye was done three months later. All cases remained on topical steroids and mydriatic for six weeks. Patients were followed on 1st post operative day and 1st post operative week for early postoperative complications. Patients were followed after 3 months, 6 months and 1 year. On follow up after 1 year, patients visual acuity, if possible, were noted so is the strabismus if present. Visual acuity was assessed using the Teller Acuity Cards Test or the Lea Test depending on the age and with one eye occluded. All refraction readings were obtained after instillation of combination of cyclopentolate 1%, tropicamide 1%, and phenylephrine 2.5%. Data was analyzed using SPSS version 17. Frequencies of gender, age, and complications were noted. Statistical analysis of the prevalence of several postoperative complications was performed by the Fisher exact test. All tests were two- tailed, and acceptable significance was recorded when P values were less than 0.05. RESULTS 281 eyes of 202 patients were included in the study. All the patients were in the age between 2 months to 10 years with mean age of 4.67 years. Out of 202 patients included in the study, 124 (61%) were females while 78 (39%) were males. Group A included 43 eyes while group B included 48 eyes. Similarly group C and D included 102 and 88 eyes respectively. Most frequent early complication seen in patients after cataract surgery was striate keratopathy, which was observed in 90 (32%) eyes, while the most common late complication was posterior capsular opacification in 95 (34%), which lead to either Yag laser capsulotomy or surgical capsulotomy. Frequencies of different complications are shown in figure 1 and 2, among the early complications striate keratopathy was most commonly noted in patients of age older than 1 year having cataract surgery without IOL. Similarly among the late complications posterior capsular opacification was noted more in cases of lens material aspiration with IOL implantation in patients younger than 1 year. Distribution of different complications in all the groups is shown in table 1. We noted that visual acuity after 1 year of follow up was much better in the pseudophakic groups than aphakic groups when they were corrected with spectacles. Around 50 % patients of psuedophakic groups have visual acuity better than 6/60 while only 26 % of aphakic group patients achieved vision of better than 6/60 with spectacle correction (p<0.05) table 2. Similarly, esotropia or exotropia of more than 8 prism diopters was noted more in the aphakic groups (46%) than in psuedophakic groups (14%) (p<0.05) (Table 3). DISCUSSION In this study, we have tried to investigate the incidence of early and late postoperative complications after cataract surgery with or without IOL implantation in children younger than 1 year and between 1 to 10 years. In this study the most frequent early postoperative complication was striate keratopathy, which was treated successfully in almost all the patients with topical steroids. On the other hand common late complications were aphakic glaucoma in aphakic eyes while posterior capsular opacification in psuedophakic eyes. In other studies the reported prevalence of aphakic glaucoma in 32 Table 1: Distribution of complications among all the study groups Group A (LMA+IOL+av) <1 year n (%) Group B (LMA+av) <1 year n (%) Group C (LMA+IOL+av) 1-10 years n (%) Group D (LMA+av) 1-10 years n (%) No of eyes 43 48 102 88 Early complications Fibrinous reaction 5 (12) 11(23) 13 (13) 13 (15) Hyphema 0 1 (2) 0 0 Striate keratopathy 10 (28) 22 (46) 22 (21.5) 36 (41) Late complications Retinal detachement 0 2 (4) 1 (0.98) 4 (4.5) Aphakic/pseudophakic glaucoma 0 2 (4) 1 (0.98) 1 (1.12) Posterior capsular opacification 35 (81) 18 (37) 34 (33) 8 (9) LMA=Lens matter aspiration AV=Anterior vitrectomy IOL=Intra ocular lens Table 2: Visual acuity among psueudophakic and aphakic groups Psuedophakic group (145 eyes) n (%) Aphakic group (136 eyes) n (%) 6/60 or better 73(50) 35(26) Less than 6/60 20(14) 41(30) Non recordable 52(36) 60(44) Psuedophakic Group (145) = Group A (43) + Group C (102) Aphakic Group (136) = Group B (48) + Group D (88) children after cataract surgery varies between 6% and 59%8,9. This variability has been linked to differences in the patient population, the type of cataract, the age at surgical correction, the definition of glaucoma, and the length of follow-up. The main reason of aphakic glaucoma is still poorly understood. It has been suggested that immaturity of the developing infant’s angle leads to increased susceptibility to surgical trauma. Besides, the combination of difficult surgery, retained lens matter, and poor pupil dilatation may contribute to an increased postoperative inflammation leading to early-onset acute glaucoma. It seems reasonable that with improvement of surgical techniques, including extensive removal of lens matter and anterior vitrectomy, this subtype of aphakic glaucoma may become less common. It is well recognized that the peadiatric cornea reaches adult thickness at between two and four years of age10. There is increasing data that central corneal thickness (CCT) has a clinically major effect on IOP measurements in patients with pediatric glaucoma. Nonetheless, the question of exactly how much to adjust the measured value remains controversial. Therefore, our study cannot rule out the possibility that the IOP was overestimated in some eyes. Table 3: Strabismus in psuedophakic and aphakic groups Psueduphakic Group (145 eyes) n (%) Aphakic group (136 eyes) n (%) esotropia/exotro pia of more than 8 prism diopter 21 (14) 62 (46) Psueduphakic Group (145) = Group A (43) + Group C (102) Aphakic Group (136) = Group B (48) + Group D (88) 33 0 10 20 30 40 50 60 Cataract Surgery with IOL Cataract Surgery without IOL Keratitis Hyphema Fibrinous Reaction Fig. 1: Early complications of peadiatric cataract surgery N = 281 0 20 40 60 80 Cataract Surgery with IOP Cataract Surgery without IOL Retinal detachment Apkakic / psdudo phakic glaucoma Posterior capsular opacification Fig. 2: Late complications of peadiatric cataract surgery In our study vitreous hemorrhage and retinal detachment were very rarely noted. One study by Chen and associates reported a very low prevalence of 0.5%11. In our study, vitreous hemorrhages cleared significantly in each case within three weeks, we recommend conservative management in children for the first postoperative weeks. In our study, all children underwent posterior capsulorhexis and anterior vitrectomy. We observed secondary cataract formation in 90 eyes (34 %). One study by Hosal and Biglan, have shown an association of posterior capsulorhexis and anterior vitrectomy with a decreased risk of PCO in children12. Nonetheless, there is still no consensus about the management of the posterior capsule during cataract removal in children10. According to our results, we would recommend performing primary posterior capsulorhexis with anterior vitrectomy in young children without primary IOL implantation. Besides, we determined young age at the time of surgery to be a strong risk factor for the development of PCO. This is also consistent with a study by Hosal and Biglan, who concluded the younger the child at cataract surgery, the greater the risk of secondary membrane formation12. Although several authors,12 suggest that the presence of an IOL increases the risk of secondary membrane formation, there is increasing evidence that a well-placed IOL for example optic capture, can reduce the incidence of secondary cataract in children13,14. But, this is still a matter of controversy, and there are little data on children younger than 1 year of age. The surgical treatment of peadiatric Cataract is constantly changing. It may be hypothesized that improved surgical techniques has contributed to a lower incidence of postoperative complications. Further research will be required to investigate the ideal timing in peadiatric cataract surgery. CONCLUSION Correction of aphakia after peadiatric cataract surgery with primary IOL implantation results in improved visual acuity compared to spectacle correction and less occurrence of strabismus, but a higher rate of complications requiring reoperation. Further studies with a larger pediatric patient group are necessary to confirm the optimal treatment of aphakia after peadiatric cataract extraction. Author’s affiliation Dr. Mazhar-ui-Hasan Isra Postgraduate Institute of Ophthalmology Al- Ibrahim Eye Hospital Karachi DR. Umair A. Qidwai Isra Postgraduate Institute of Ophthalmology Al- Ibrahim Eye Hospital Karachi DR. Aziz-ur-Rehman Isra Postgraduate Institute of Ophthalmology Al- Ibrahim Eye Hospital Karachi 34 DR. Nasir Bhatti Isra Postgraduate Institute of Ophthalmology Al- Ibrahim Eye Hospital Karachi DR. Rashid H. Alvi Isra Postgraduate Institute of Ophthalmology Al- Ibrahim Eye Hospital Karachi REFERENCE 1. Wilson ME, Pandey SK, Thakur J. Paediatric cataract blindness in the developing world: Surgical technique and intraocular lenses in new millennium. Br J Opthalmol. 2003; 87: 14-9. 2. Lambort SP. Management of monocular congenital cataract. Eye. 1999; 13: 474-79. 3. Angra, Mohan SK. Management of Rubella cataract. Ind J Ophthalmol 1982; 302: 13-16. 4. Lundvall A, Kugelberg U. Outcome after treatment of congenital bilateral cataract. Acta Ophthalmol Scand. 2002; 80: 593–7. 5. Robb RM, Petersen RA. Outcome of treatment for bilateral congenital cataracts. Ophthalmic Surg. 1992; 23: 650-6. 6. Keech RV, Tongue AC, Scott WE. Complications after surgery for congenital and infantile cataracts. Am J Ophthalmol. 1989; 108: 136-41. 7. Lundvall A, Zetterström C. Complications after early surgery for congenital cataracts. Acta Ophthalmol Scand. 1999; 77: 677– 80. 8. Chen TC, Bhatia LS, Halpern EF, et al. Risk factors for the development of aphakic glaucoma after congenital cataract surgery. Trans Am Ophthalmol Soc. 2006; 104: 241–51. 9. Rabiah PK. Frequency and predictors of glaucoma after pediatric cataract surgery. Am J Ophthalmol. 2004; 137: 30-7. 10. Ehlers N, Sorensen T, Bramsen T, et al. Central corneal thickness in newborns and children. Acta Ophthalmol. (Copenh) 1976; 54: 285–90. 11. Chen TC, Bhatia LS, Walton DS. Complications of pediatric lensectomy in 193 eyes. Ophthalmic Surg Lasers Imaging. 2005; 36: 6–13. 12. Hosal BM, Biglan AW. Risk factors for secondary membrane formation after removal of pediatric cataract. J Cataract Refract Surg. 2002; 28: 302–9. 13. Koch DD, Kohnen T. Retrospective comparison of techniques to prevent secondary cataract formation after posterior chamber intraocular lens implantation in infants and children. J Cataract Refract Surg. 1997; 23: 657–63. 14. Kohnen T, Lüchtenberg M. Surgical treatment of congenital cataracts. Ophthalmologe. 2007; 104: 566–71.