BACKGROUND: Studies have indicated that intracameral administration of moxifloxacin (MFLX), a fourth-generation fluoroquinolone, is safe and effective. However, administration methods vary between studies, and no definite protocol exists. A prospective study clarifying the incidence of endophthalmitis and complication rates associated with each administration method would require an extremely large sample size because endophthalmitis has a low incidence rate. Therefore, we investigated appropriate intracameral MFLX administration methods by assessing intraocular concentrations following simple injection and flushing, and by measuring drug kinetics (half-life). METHODS: Experiment 1: (human eyes). Irrigation (flushing) with 33.33 μg/ml MFLX (150-fold dilution) and simple injection with 0.1 ml of 500 μg/ml MFLX (10-fold dilution) were assessed after cataract surgery. Experiment 2: (rabbits: kinetics study). Flushing with 30-fold or 150-fold dilutions of MFLX was assessed. Aqueous humor samples (0.1 ml) obtained immediately after irrigation and 1, 3, and 5 h after irrigation were analyzed using high-performance liquid chromatography. RESULTS: Experiment 1: MFLX (500 μg/ml) administered using simple injection in humans underwent a 3.3-fold dilution (152.33 μg/ml). Total anterior chamber displacement after flushing with 33.33 μg/ml MFLX resulted in a concentration of 29.54 μg/ml (90% displacement). Experiment 2: Concentrations at baseline were 52% at 1 and 15% at 3 h respectively, suggesting that the half-life of intracameral MFLX was >1 h. CONCLUSIONS: Considering that the half-life of MFLX was >1 h, a final concentration of 150 μg/ml results in a 2 h concentration of 38 μg/ml, which was beyond the minimum inhibitory concentration required to inhibit the growth of 90% of bacteria (MIC90) for most resistant pathogens. We postulate that a final concentration of 150 μg/ml is considerably effective and safe. However, more resistant bacteria will evolve in the future, and the standard MIC90 may change accordingly. Therefore, even if a suitable concentration is determined, it may not necessarily remain constant. This effective concentration should be continually revised on the basis of safety and effectiveness assessments.
BACKGROUND: Studies have indicated that intracameral administration of moxifloxacin (MFLX), a fourth-generation fluoroquinolone, is safe and effective. However, administration methods vary between studies, and no definite protocol exists. A prospective study clarifying the incidence of endophthalmitis and complication rates associated with each administration method would require an extremely large sample size because endophthalmitis has a low incidence rate. Therefore, we investigated appropriate intracameral MFLX administration methods by assessing intraocular concentrations following simple injection and flushing, and by measuring drug kinetics (half-life). METHODS: Experiment 1: (human eyes). Irrigation (flushing) with 33.33 μg/ml MFLX (150-fold dilution) and simple injection with 0.1 ml of 500 μg/ml MFLX (10-fold dilution) were assessed after cataract surgery. Experiment 2: (rabbits: kinetics study). Flushing with 30-fold or 150-fold dilutions of MFLX was assessed. Aqueous humor samples (0.1 ml) obtained immediately after irrigation and 1, 3, and 5 h after irrigation were analyzed using high-performance liquid chromatography. RESULTS: Experiment 1: MFLX (500 μg/ml) administered using simple injection in humans underwent a 3.3-fold dilution (152.33 μg/ml). Total anterior chamber displacement after flushing with 33.33 μg/ml MFLX resulted in a concentration of 29.54 μg/ml (90% displacement). Experiment 2: Concentrations at baseline were 52% at 1 and 15% at 3 h respectively, suggesting that the half-life of intracameral MFLX was >1 h. CONCLUSIONS: Considering that the half-life of MFLX was >1 h, a final concentration of 150 μg/ml results in a 2 h concentration of 38 μg/ml, which was beyond the minimum inhibitory concentration required to inhibit the growth of 90% of bacteria (MIC90) for most resistant pathogens. We postulate that a final concentration of 150 μg/ml is considerably effective and safe. However, more resistant bacteria will evolve in the future, and the standard MIC90 may change accordingly. Therefore, even if a suitable concentration is determined, it may not necessarily remain constant. This effective concentration should be continually revised on the basis of safety and effectiveness assessments.
Authors: K Metzler; G M Hansen; Peter Hedlin; Elizabeth Harding; Karl Drlica; J M Blondeau Journal: Int J Antimicrob Agents Date: 2004-08 Impact factor: 5.283
Authors: Randy C Bowen; Andrew Xingyu Zhou; Sailaja Bondalapati; Thomas W Lawyer; Karisa B Snow; Patrick R Evans; Tyler Bardsley; Mary McFarland; Matthew Kliethermes; Dallas Shi; Christina A Mamalis; Tom Greene; Christopher J Rudnisky; Balamurali Krishna Ambati Journal: Br J Ophthalmol Date: 2018-01-11 Impact factor: 4.638
Authors: Lisa J Herrinton; Neal H Shorstein; John F Paschal; Liyan Liu; Richard Contreras; Kevin L Winthrop; William J Chang; Ronald B Melles; Donald S Fong Journal: Ophthalmology Date: 2015-10-14 Impact factor: 12.079