|Year : 2020 | Volume
| Issue : 5 | Page : 688-691
Role of intracameral antibiotics in endophthalmitis prophylaxis following-cataract surgery
Jeewan S Titiyal, Manpreet Kaur
Cornea, Cataract and Refractive Surgery Services, Dr. Rajendra Prasad Centre for Ophthalmic Sciences, All India Institute of Medical Sciences, New Delhi, India
|Date of Web Publication||20-Apr-2020|
Jeewan S Titiyal
Cornea, Cataract and Refractive Surgery Services, Dr. Rajendra Prasad Centre for Ophthalmic Sciences, All India Institute of Medical Sciences, New Delhi
Source of Support: None, Conflict of Interest: None
|How to cite this article:|
Titiyal JS, Kaur M. Role of intracameral antibiotics in endophthalmitis prophylaxis following-cataract surgery. Indian J Ophthalmol 2020;68:688-91
|How to cite this URL:|
Titiyal JS, Kaur M. Role of intracameral antibiotics in endophthalmitis prophylaxis following-cataract surgery. Indian J Ophthalmol [serial online] 2020 [cited 2020 Jun 4];68:688-91. Available from: http://www.ijo.in/text.asp?2020/68/5/688/282887
Post-cataract surgery endophthalmitis is a rare complication with an incidence of 0.03–0.2%. The prognosis is usually guarded and results in a loss of visual acuity as well as the anatomical integrity of the eye in severe cases.
Various factors contribute to the development of postoperative endophthalmitis, including use of contaminated surgical instruments or irrigating fluids, complicated cataract surgery, intraocular contamination by indigenous flora, wound leak, postoperative transient hypotony resulting in wound gape and the influx of surface fluid, immunocompromised host status or local lid, and ocular surface anomalies., Good surgical asepsis is the cornerstone to prevent postsurgical infections, and various preoperative, intraoperative, and postoperative measures have been proposed to decrease the incidence of endophthalmitis after cataract surgery. The rationale for use of these perioperative asepsis measures in cataract surgery is based on a reduction of the ocular surface and periocular flora which may potentially result in intraocular contamination. A high bacterial contamination rate of up to 46.25% has been observed in aqueous samples obtained at the end of phacoemulsification, with coagulase-negative Staphylococcus being the most common species isolated. Baillif et al. observed anterior chamber bacterial contamination in only 1.8% cases after using povidone-iodine 10% and 5% to decontaminate the periocular skin and ocular surface respectively, in conjunction with a single dose of oral ofloxacin 400 mg administered 2 h before surgery. Sobaci et al. observed a more than the threefold decrease in bacterial contamination of the aqueous samples obtained after phacoemulsification with the use of antibiotic-containing irrigating solutions. Bacterial growth was observed in aqueous samples of 21.1% cases wherein antibiotic-infused irrigating solutions were not used, compared with 6.8% in cases performed using antibiotic-infused irrigating solutions.
A survey of endophthalmitis prophylaxis measures among 800 surgeons in the United Kingdom revealed the routine use of preoperative topical antibiotics by 5.9% surgeons, use of 10% povidone-iodine for cleaning the periocular skin by 99.4%, instillation of povidone-iodine in the conjunctival sac by 69.8%, intracameral antibiotic usage by 13.6%, subconjunctival antibiotics by 77.3%, and postoperative antibiotics by more than 90% surgeons. In 2007, the European Society of Cataract and Refractive Surgeons (ESCRS) conducted the first randomized controlled trial and observed a five-fold decrease in the incidence of postsurgical endophthalmitis with the use of intracameral cefuroxime. This led to increased adoption of the routine use of intracameral antibiotics as prophylaxis from 30% in 2007 to nearly 50% in 2014., However; there is a lack of conclusive evidence establishing the use of intracameral antibiotics as the definitive standard of care, and asepsis practices generally vary from surgeon to surgeon.
A comprehensive preoperative evaluation is essential to identify patients at high risk for developing postsurgical endophthalmitis, and optimization of systemic status, as well as treatment of localized lid and ocular surface disorders, is imperative before undertaking cataract surgery. Povidone-iodine is routinely used in the immediate preoperative period with a 10% solution to clean the periocular skin and a 5% solution instilled in the conjunctival sac. It results in a significant decrease in the pathogenic bacterial load during and immediately after the surgery; however, it does not alter the growth pattern and antibiotic susceptibility of the native conjunctival flora and thus prevents the emergence of drug resistance.,, A contact time of at least 30 s is recommended to reduce the bacterial colony-forming units on the ocular surface. The use of povidone-iodine may be associated with adverse effects such as edema of epithelial cells, endothelial toxicity, and iridocyclitis. Sterile speculum and surgical drapes to isolate the eyelashes from the surgical field and the use of topical antibiotics in the perioperative period are also routinely practiced. Fluoroquinolones are preferred for topical use and instilled 0–3 days before surgery. The use of topical antibiotics in the preoperative period is not associated with a significant decrease in the rates of postsurgical endophthalmitis. Moreover, prophylactic antibiotic use is linked to the emergence of drug resistance., Trimming of eyelashes in the preoperative period is no longer advocated as it does not lead to a decrease in the incidence of postsurgical endophthalmitis and distorts the cosmetic appearance of the patient.
The main pathogenic mechanism of post-cataract surgery endophthalmitis is related to intraocular contamination by indigenous surface flora during and immediately after surgery, and intraocular instillation of antibiotics during surgery is increasingly being adopted by surgeons as an effective modality to prevent endophthalmitis. Srinivasan et al. observed that the addition of vancomycin to irrigating solutions used intraoperatively was significantly more efficacious in reducing aqueous contamination as compared with preoperative topical antibiotic usage. Haripriya et al. observed a 3.5 times reduction in endophthalmitis rates with the use of intracameral moxifloxacin as prophylaxis after cataract surgery. In addition, they observed a significant benefit in cases with complicated cataract surgery and posterior capsular rupture, wherein the endophthalmitis rates decreased from 0.48% to 0.21% with the use of intracameral moxifloxacin.
Intraoperatively, antibiotics may be instilled in the irrigating solution, injected as a bolus either intracamerally or subconjunctivally toward the end of surgery or instilled topically on the ocular surface after hydrating the corneal incisions. Present-day micro-incision cataract surgery is often performed under topical anesthesia rather than peri-bulbar blocks, and this has led to a shift in surgeon preference from using subconjunctival antibiotic injections to instillation of intracameral antibiotics. The use of antibiotics in irrigating solutions is associated with difficulty in monitoring the intraocular concentrations of antibiotics with a wide variability as well as an increased potential risk of endothelial and macular toxicity, especially with aminoglycosides like gentamicin and amikacin.
Intracameral injection of antibiotics has emerged as the preferred modality of intraoperative antibiotic use during cataract surgery. At present, various antibiotics are routinely used intracamerally, including cefuroxime, vancomycin, and moxifloxacin. These may be administered in the bag behind the intraocular lens toward the end of the surgery, instilled in the anterior chamber or instilled at wound-site. The routinely used intracameral dosage is 1 mg/0.1 mL for cefuroxime and vancomycin, and 0.5 mg/0.1 mL for moxifloxacin.
However, various safety and logistical concerns surround the routine use of intracameral antibiotics. First, there are few commercial formulations of cefuroxime (Aprokam, Thea Pharmaceuticals, Newcastle Under Lyme, UK) and moxifloxacin (Auromox, Aurolab, Madurai, India, and 4-Quin PFS 0.5% single-use prefilled syringes) for intraocular use, which are not widely available and not approved by the United States FDA. A commercial preparation of self-preserved moxifloxacin eyedrops (Vigamox 0.5% ophthalmic solution) has also been reported to be safe and efficacious for intracameral use.,
Second, the use of intracameral antibiotics may in itself be associated with adverse drug reactions. Intracameral cefuroxime use is associated with uveitis, retinal infarction, and macular edema. Endothelial cell loss and toxicity may occur, and toxic anterior segment syndrome, as well as anaphylactic reactions, have been reported after the use of intracameral antibiotics. Hemorrhagic occlusive retinal vasculitis has been reported exclusively after the use of intracameral vancomycin.,
Both cefuroxime and vancomycin are mainly active against Gram-positive organisms and do not provide coverage against Gram-negative organisms. Moxifloxacin has a relatively broader spectrum and covers both Gram-positive and Gram-negative organisms. Intracameral cefuroxime has a time-dependent action and the aqueous concentration is above the minimum inhibitory concentration (MIC) for 4–5 h, which limits its usefulness in the postoperative period. Moxifloxacin has a dose-dependent action and achieves an initial aqueous concentration up to 300 times greater than the MIC when injected intracamerally in a dose of 0.5 mg/0.1 mL.,, It maintains its efficacy for a longer duration as compared with cefuroxime.
Drug resistance, though uncommon, has been observed after the use of intracameral antibiotics. Increased resistance of coagulase-negative Staphylococcus species has been observed to fluoroquinolones, including moxifloxacin, with a decrease in susceptibility from 77% to 43% since 2004. An increased incidence of enterococci endophthalmitis and fungal endophthalmitis has been observed in cases receiving intracameral cefuroxime. Moreover, the prognosis of postsurgical endophthalmitis in cases that received intracameral cefuroxime is dismal. The standard intravitreal drugs may not be effective in these cases with drug-resistant endophthalmitis, and a combination of newer generation antibiotics may often be needed to salvage the eye.
There is only one randomized controlled trial (ESCRS study) that observed the definitive role of intracameral cefuroxime in reducing the incidence of endophthalmitis. There is a lack of level I evidence for the use of intracameral vancomycin and moxifloxacin. The majority of studies are retrospective in nature and generally compare the incidence of endophthalmitis before and after the institution of intracameral antibiotics [Table 1].,,,,,,,
|Table 1: Evidence for intracameral antibiotic use for post.cataract surgery endophthalmitis prophylaxis|
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The present study observed similar endophthalmitis rates between the two groups using intracameral cefuroxime and moxifloxacin. They observed a decrease in the rates of endophthalmitis with the usage of intracameral antibiotics; however, they performed a retrospective comparison between the cohort of cases receiving intracameral antibiotics to cases performed before the routine use of intracameral antibiotics in their centers. The majority of the surgeries were small-incision cataract surgery (SICS).
Topical antibiotics should be instituted within 4–6 h of surgery when the efficacy of intracameral or subconjunctival antibiotics starts decreasing. Fluoroquinolones are the preferred antibiotics for postoperative use, and they are routinely instilled by a majority of surgeons till 1–4 weeks. There is no definitive evidence that their usage prevents postsurgical endophthalmitis. Topical antibiotics should not be tapered to prevent the emergence of drug resistance. There is no role of systemic antibiotics in preventing postsurgical endophthalmitis.
| Conclusion|| |
The reduction in postsurgical endophthalmitis over the decades may be attributed to the increasing emphasis on good surgical asepsis as well as the routine use of povidone-iodine for periocular cleaning, sterile surgical drapes, and speculums. An improvement in sterilization techniques along with the increasing use of disposable surgical instruments, tubings, and cassettes has also reduced the risk of contamination and resulted in a decrease in the incidence of endophthalmitis.
In the present-day scenario, the role of intracameral antibiotics remains controversial, with a paucity of level I evidence to definitively establish its benefit. The large-scale retrospective analysis points toward a significant beneficial trend of using intracameral antibiotics for endophthalmitis prophylaxis, which has led to the adoption of their routine usage as a preferred practice for many surgeons and institutions worldwide. In addition, a systematic review of 18 studies including one randomized controlled trial observed consistent evidence in support of the use of intracameral cefuroxime to decrease the incidence of post-cataract surgery endophthalmitis. Commercial drug preparations for intracameral use may not be universally available and are not approved by the drug regulatory authorities. There is a risk of toxic adverse effects from the use of intracameral antibiotics itself. In addition, there are concerns about antibiotic resistance due to their widespread usage. There is a debate regarding the cost-effectiveness of routine intracameral antibiotic prophylaxis; however, in our view, the risk of developing a potentially sight-threatening disease such as endophthalmitis far outweighs the economic consideration of routine antibiotic usage.
Perioperative prophylactic measures against infection are mandatory in any surgical procedure, and the choice of antibiotic prophylaxis may be governed by a variety of factors including availability of commercial preparations of the drug, approval of the method by drug regulatory bodies, adverse effects, surgeon preference, and the risk-benefit ratio. With increasing preference for topical anesthesia during phacoemulsification, intracameral instillation of antibiotics appears to be a safe and effective method to prevent post-cataract endophthalmitis. In the absence of definitive evidence against the beneficial effect of intracameral antibiotics, they may be routinely administered as prophylaxis post-cataract surgery.
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| Authors|| |
Prof. Jeewan S Titiyal
Prof. Jeewan S Titiyal heads the Cornea, Cataract and Refractive Surgery Services at the Rajendra Prasad Centre for Ophthalmic Sciences, AIIMS, New Delhi. He is the Chairman of the National Eye Bank.
Prof. Titiyal has been conferred with the Padmashri for his outstanding contribution in the field of Medicine (Ophthalmology) by the President of India in 2014. He has also been awarded the AAO Achievement (2009) and Senior Achievement Award (2016), APAO Achievement Award (2015) and APACRS Certified Educator Award (2015). He has been decorated with over 30 orations and keynote addresses. He has been the 'Teacher of Teachers' and has performed over 100 live surgical demonstrations and has delivered over 1000 lectures. He was the first Indian to perform live surgery in ASCRS, USA. He has been regularly conducting instruction courses at AAO, ASCRS, ESCRS, APAO, APACRS and AIOS. He has two patents to his credit for his innovations.
Prof. Titiyal has to his credit more than 250 indexed publications with over 3365 citations. He has co-authored four Text Books in his field of expertise and has written 52 Book Chapters. He has completed over 30 funded International and National Research Projects. IJO is fortunate to have Prof. Titiyal on its Editorial Board and extensively contribute with his analytical peer reviews and cutting-edge articles.