Justification of Drug Product Dissolution Rate and Drug Substance Particle Size Specifications Based on Absorption PBPK Modeling for Lesinurad Immediate Release Tablets.

In silico absorption modeling has been performed, to assess the impact of in vitro dissolution on in vivo performance for ZURAMPIC (lesinurad) tablets. The dissolution profiles of lesinurad tablets generated using the quality control method were used as an input to a GastroPlus model to estimate in vivo dissolution in the various parts of the GI tract and predict human exposure. A model was set up, which accounts for differences of dosage form transit, dissolution, local pH in the GI tract, and fluid volumes available for dissolution. The predictive ability of the model was demonstrated by confirming that it can reproduce the Cmax observed for independent clinical trial. The model also indicated that drug product batches that pass the proposed dissolution specification of Q = 80% in 30 min are anticipated to be bioequivalent to the clinical reference batch. To further explore the dissolution space, additional simulations were performed using a theoretical dissolution profile below the proposed specification. The GastroPlus modeling indicates that such a batch will also be bioequivalent to standard clinical batches despite having a dissolution profile, which would fail the proposed dissolution specification of Q = 80% in 30 min. This demonstrates that the proposed dissolution specification sits comfortably within a region of dissolution performance where bioequivalence is anticipated and is not near an edge of failure for dissolution, providing additional confidence to the proposed specifications. Finally, simulations were performed using a virtual drug substance batch with a particle size distribution at the limit of the proposed specification for particle size. Based on these simulations, such a batch is also anticipated to be bioequivalent to clinical reference, demonstrating that the proposed specification limits for particle size distribution would give products bioequivalent to the pivotal clinical batches.

[1]  J. Dressman,et al.  Dissolution Media Simulating Conditions in the Proximal Human Gastrointestinal Tract: An Update , 2008, Pharmaceutical Research.

[2]  Kiyohiko Sugano,et al.  Oral Absorption of Poorly Water-Soluble Drugs: Computer Simulation of Fraction Absorbed in Humans from a Miniscale Dissolution Test , 2006, Pharmaceutical Research.

[3]  J. Tack,et al.  Review article: the role of gastric motility in the control of food intake , 2011, Alimentary pharmacology & therapeutics.

[4]  N. Hosten,et al.  Intestinal fluid volumes and transit of dosage forms as assessed by magnetic resonance imaging , 2005, Alimentary pharmacology & therapeutics.

[5]  P. Tothill,et al.  The dependence of paracetamol absorption on the rate of gastric emptying , 1973, British journal of pharmacology.

[6]  M. Katschinski Nutritional implications of cephalic phase gastrointestinal responses , 2000, Appetite.

[7]  M. Grimm,et al.  Intragastric pH and pressure profiles after intake of the high-caloric, high-fat meal as used for food effect studies. , 2015, Journal of controlled release : official journal of the Controlled Release Society.

[8]  Masoud Jamei,et al.  Prediction of intestinal first-pass drug metabolism. , 2007, Current drug metabolism.

[9]  Raimar Löbenberg,et al.  Computer simulations using GastroPlus to justify a biowaiver for etoricoxib solid oral drug products. , 2009, European journal of pharmaceutics and biopharmaceutics : official journal of Arbeitsgemeinschaft fur Pharmazeutische Verfahrenstechnik e.V.

[10]  Malfertheiner,et al.  Citric acid or orange juice for the 13C‐urea breath test: the impact of pH and gastric emptying , 1999, Alimentary pharmacology & therapeutics.

[11]  Kiyohiko Sugano,et al.  Theoretical dissolution model of poly-disperse drug particles in biorelevant media. , 2008, Journal of pharmaceutical sciences.

[12]  Dion R. Brocks,et al.  Multiple Peaking Phenomena in Pharmacokinetic Disposition , 2010, Clinical pharmacokinetics.

[13]  Malcolm Rowland,et al.  PhRMA CPCDC initiative on predictive models of human pharmacokinetics, part 3: comparative assessement of prediction methods of human clearance. , 2011, Journal of pharmaceutical sciences.

[14]  G. Amidon,et al.  Variable gastric emptying and discontinuities in drug absorption profiles: Dependence of rates and extent of cimetidine absorption on motility phase and pH , 1994, Biopharmaceutics & drug disposition.

[15]  A. Lindahl,et al.  Use of physiologically relevant biopharmaceutics tools within the pharmaceutical industry and in regulatory sciences: Where are we now and what are the gaps? , 2016, European journal of pharmaceutical sciences : official journal of the European Federation for Pharmaceutical Sciences.

[16]  Martin Bergstrand,et al.  PBPK models for the prediction of in vivo performance of oral dosage forms. , 2014, European journal of pharmaceutical sciences : official journal of the European Federation for Pharmaceutical Sciences.

[17]  Steven C. Sutton,et al.  Role of Physiological Intestinal Water in Oral Absorption , 2009, The AAPS Journal.