Bart Hens1, Joachim Brouwers1, Maura Corsetti2, Patrick Augustijns3. 1. Drug Delivery & Disposition, KU Leuven, Gasthuisberg O&N2, Herestraat 49, Box 921, 3000 Leuven, Belgium. 2. Translational Research Center for Gastrointestinal Disorders (TARGID), KU Leuven, Belgium. 3. Drug Delivery & Disposition, KU Leuven, Gasthuisberg O&N2, Herestraat 49, Box 921, 3000 Leuven, Belgium. Electronic address: patrick.augustijns@pharm.kuleuven.be.
Abstract
INTRODUCTION: The purpose of this study was (i) to evaluate the gastrointestinal behavior of micro- and nanosized fenofibrate in humans and (ii) to develop a simple yet qualitatively predictive in vitro setup that simulates the observed absorption-determining factors. MATERIALS AND METHODS: Commercially available micro- and nanoparticles of fenofibrate (Lipanthyl® and Lipanthylnano®, respectively) were administered orally to five healthy volunteers in fasting and postprandial conditions. Intraluminal and systemic drug concentrations were determined as reference data for the development of a predictive in vitro setup. To capture the observed solubility/permeability interplay, in vitro dissolution testing was performed in the presence of a permeation bag with sink conditions. RESULTS: In fasting conditions, intake of nanosized fenofibrate generated increased duodenal concentrations compared to microsized fenofibrate, which was reflected in an improved systemic exposure. In postprandial conditions, duodenal concentrations were greatly enhanced for both formulations, however without an accompanying increase in systemic exposure. It appeared that micellar encapsulation of the highly lipohilic fenofibrate limited its potential to permeate from fed state intestinal fluids. To capture these in vivo observations in an in vitro setup, classic dissolution testing was combined with permeation assessment into a permeation bag with sink conditions. In case of fasting conditions, the dissolution/permeation approach allowed for an improved discriminative power between micro- and nanosized fenofibrate by better simulating the dynamic interplay of dissolution and absorption. In case of postprandial conditions, the observed solubility-permeability interplay could be simulated using the dissolution/permeation approach in combination with biorelevant media (FeSSGFFortimel and FeSSIF-V2) to mimic micellar entrapment and reduced permeation potential of fenofibrate. CONCLUSION: For the first time, reduced permeation of a lipophilic drug despite increased intraluminal concentrations, was demonstrated in humans. Dissolution testing using biorelevant media in combination with permeation assessment into a sink permeation bag appeared to be a simple yet pragmatic approach to capture this solubility-permeability interplay in early formulation evaluation.
INTRODUCTION: The purpose of this study was (i) to evaluate the gastrointestinal behavior of micro- and nanosized fenofibrate in humans and (ii) to develop a simple yet qualitatively predictive in vitro setup that simulates the observed absorption-determining factors. MATERIALS AND METHODS: Commercially available micro- and nanoparticles of fenofibrate (Lipanthyl® and Lipanthylnano®, respectively) were administered orally to five healthy volunteers in fasting and postprandial conditions. Intraluminal and systemic drug concentrations were determined as reference data for the development of a predictive in vitro setup. To capture the observed solubility/permeability interplay, in vitro dissolution testing was performed in the presence of a permeation bag with sink conditions. RESULTS: In fasting conditions, intake of nanosized fenofibrate generated increased duodenal concentrations compared to microsized fenofibrate, which was reflected in an improved systemic exposure. In postprandial conditions, duodenal concentrations were greatly enhanced for both formulations, however without an accompanying increase in systemic exposure. It appeared that micellar encapsulation of the highly lipohilic fenofibrate limited its potential to permeate from fed state intestinal fluids. To capture these in vivo observations in an in vitro setup, classic dissolution testing was combined with permeation assessment into a permeation bag with sink conditions. In case of fasting conditions, the dissolution/permeation approach allowed for an improved discriminative power between micro- and nanosized fenofibrate by better simulating the dynamic interplay of dissolution and absorption. In case of postprandial conditions, the observed solubility-permeability interplay could be simulated using the dissolution/permeation approach in combination with biorelevant media (FeSSGFFortimel and FeSSIF-V2) to mimic micellar entrapment and reduced permeation potential of fenofibrate. CONCLUSION: For the first time, reduced permeation of a lipophilic drug despite increased intraluminal concentrations, was demonstrated in humans. Dissolution testing using biorelevant media in combination with permeation assessment into a sink permeation bag appeared to be a simple yet pragmatic approach to capture this solubility-permeability interplay in early formulation evaluation.
Authors: Bart Hens; Patrick D Sinko; Nicholas Job; Meagan Dean; Jozef Al-Gousous; Niloufar Salehi; Robert M Ziff; Yasuhiro Tsume; Marival Bermejo; Paulo Paixão; James G Brasseur; Alex Yu; Arjang Talattof; Gail Benninghoff; Peter Langguth; Hans Lennernäs; William L Hasler; Luca Marciani; Joseph Dickens; Kerby Shedden; Duxin Sun; Gregory E Amidon; Gordon L Amidon Journal: Int J Pharm Date: 2018-06-23 Impact factor: 5.875