PURPOSE: To compare the permeability characteristics of HT29-18-C1 colonic epithelial cell line with Caco-2, an established model of intestinal drug transport. METHODS: Cell lines were grown as epithelial monolayers. Permeability was measured over a range of transepithelial electrical resistance (Rt) using a group of drug compounds. RESULTS: HT29-18-C1 develop Rt slowly when grown in culture, allowing permeability to be measured over a wide range (80-600 Omega x cm2). In contrast, Caco-2 monolayers rapidly develop Rt of approximately equal 300 Omega x cm2 and require Ca2+ -chelation to generate Rt equivalent to human intestine (60-120 Omega x cm2). Permeability of atenolol, ranitidine, cimetidine, hydrochlorothiazide and mannitol across HT29-18-C1 decreased 4-5 fold as Rt developed from 100-300 Omega x cm2 indicating they permeate via the paracellular route. In contrast, ondansetron showed no difference in permeability with changing Rt consistent with transcellular permeation. Permeability profiles across low Rt HT29-18C1 and pulse EGTA-treated Caco-2 monolayers were the same for all 5 paracellular drugs suggesting that transient Ca2+ removal does not alter selectivity of the tight junctions. Permeabilities of cimetidine, hydrochlorothiazide and atenolol across 100 Omega x cm2 HT29-18-C1 monolayers reflect more closely those reported for the human ileum in vivo than did mature Caco-2 monolayers. CONCLUSIONS: HT29-18-C1 monolayers can be used to study drug permeability at Rt values similar to human intestine without the need for Ca2+ chelation. As such, they offer a useful alternative to Caco-2 for modelling intestinal drug absorption.
PURPOSE: To compare the permeability characteristics of HT29-18-C1 colonic epithelial cell line with Caco-2, an established model of intestinal drug transport. METHODS: Cell lines were grown as epithelial monolayers. Permeability was measured over a range of transepithelial electrical resistance (Rt) using a group of drug compounds. RESULTS: HT29-18-C1 develop Rt slowly when grown in culture, allowing permeability to be measured over a wide range (80-600 Omega x cm2). In contrast, Caco-2 monolayers rapidly develop Rt of approximately equal 300 Omega x cm2 and require Ca2+ -chelation to generate Rt equivalent to human intestine (60-120 Omega x cm2). Permeability of atenolol, ranitidine, cimetidine, hydrochlorothiazide and mannitol across HT29-18-C1 decreased 4-5 fold as Rt developed from 100-300 Omega x cm2 indicating they permeate via the paracellular route. In contrast, ondansetron showed no difference in permeability with changing Rt consistent with transcellular permeation. Permeability profiles across low Rt HT29-18C1 and pulse EGTA-treated Caco-2 monolayers were the same for all 5 paracellular drugs suggesting that transient Ca2+ removal does not alter selectivity of the tight junctions. Permeabilities of cimetidine, hydrochlorothiazide and atenolol across 100 Omega x cm2 HT29-18-C1 monolayers reflect more closely those reported for the human ileum in vivo than did mature Caco-2 monolayers. CONCLUSIONS: HT29-18-C1 monolayers can be used to study drug permeability at Rt values similar to human intestine without the need for Ca2+ chelation. As such, they offer a useful alternative to Caco-2 for modelling intestinal drug absorption.
Authors: Staffan Tavelin; Jan Taipalensuu; Lauri Söderberg; Rick Morrison; Saeho Chong; Per Artursson Journal: Pharm Res Date: 2003-03 Impact factor: 4.200
Authors: Floriane Lignet; Eva Sherbetjian; Nicole Kratochwil; Russell Jones; Claudia Suenderhauf; Michael B Otteneder; Thomas Singer; Neil Parrott Journal: Pharm Res Date: 2016-07-28 Impact factor: 4.200