Paul J Missel1. 1. Modeling and Simulation, Alcon Research Ltd., Mail Stop TC-47, 6201 South Freeway, Fort Worth, Texas 76134, USA. paul.missel@alconlabs.com
Abstract
PURPOSE: To develop models for rabbit, monkey, and human that enable prediction of the clearance after intravitreal (IVT) injections in one species from experimental results obtained in another species. METHODS: Anatomically accurate geometric models were constructed for rabbit, monkey, and human that enabled computational fluid dynamic simulation of clearance of an IVT injected bolus. Models were constructed with and without the retrozonular space of Petit. Literature data on clearance after IVT injection of substances spanning a range of molecular weight up to 157 kDa were used to validate the rabbit model. RESULTS: The space of Petit had a significant increase on the clearance of slowly diffusing substances cleared by the anterior pathway by reducing the bottleneck for drug efflux. Models that did not include this zone could not accurately predict the clearance of slowly diffusing substances whose clearance was accelerated by intraocular pressure-driven convection. CONCLUSIONS: The ocular anatomy must be carefully reconstructed in the model to enable accurate predictions of clearance. This method offers an alternative means for scaling experimental data from one species to another that may be more appropriate than other simple approaches based entirely upon scaling of compartment volumes and flow rates.
PURPOSE: To develop models for rabbit, monkey, and human that enable prediction of the clearance after intravitreal (IVT) injections in one species from experimental results obtained in another species. METHODS: Anatomically accurate geometric models were constructed for rabbit, monkey, and human that enabled computational fluid dynamic simulation of clearance of an IVT injected bolus. Models were constructed with and without the retrozonular space of Petit. Literature data on clearance after IVT injection of substances spanning a range of molecular weight up to 157 kDa were used to validate the rabbit model. RESULTS: The space of Petit had a significant increase on the clearance of slowly diffusing substances cleared by the anterior pathway by reducing the bottleneck for drug efflux. Models that did not include this zone could not accurately predict the clearance of slowly diffusing substances whose clearance was accelerated by intraocular pressure-driven convection. CONCLUSIONS: The ocular anatomy must be carefully reconstructed in the model to enable accurate predictions of clearance. This method offers an alternative means for scaling experimental data from one species to another that may be more appropriate than other simple approaches based entirely upon scaling of compartment volumes and flow rates.
Authors: David A Atchison; Catherine E Jones; Katrina L Schmid; Nicola Pritchard; James M Pope; Wendy E Strugnell; Robyn A Riley Journal: Invest Ophthalmol Vis Sci Date: 2004-10 Impact factor: 4.799
Authors: Marko Lamminsalo; Ella Taskinen; Timo Karvinen; Astrid Subrizi; Lasse Murtomäki; Arto Urtti; Veli-Pekka Ranta Journal: Pharm Res Date: 2018-05-31 Impact factor: 4.200
Authors: Anita N Penkova; Shuqi Zhang; Mark S Humayun; Scott Fraser; Rex Moats; Satwindar Singh Sadhal Journal: J Porous Media Date: 2020 Impact factor: 1.663
Authors: Kevin D Lance; Daniel A Bernards; Natalie A Ciaccio; Samuel D Good; Thaís S Mendes; Max Kudisch; Elliot Chan; Mynna Ishikiriyama; Robert B Bhisitkul; Tejal A Desai Journal: Drug Deliv Transl Res Date: 2016-12 Impact factor: 4.617
Authors: Karen E Samy; Yiqi Cao; Jean Kim; Nina Rosa Konichi da Silva; Audrey Phone; Michele M Bloomer; Robert B Bhisitkul; Tejal A Desai Journal: J Ocul Pharmacol Ther Date: 2019-01-07 Impact factor: 2.671
Authors: Yu Zhang; Hojjat Bazzazi; Raquel Lima E Silva; Niranjan B Pandey; Jordan J Green; Peter A Campochiaro; Aleksander S Popel Journal: Invest Ophthalmol Vis Sci Date: 2018-10-01 Impact factor: 4.799