Your search keyword '"Arjang Talattof"' showing total 3 results

1. Linking the Gastrointestinal Behavior of Ibuprofen with the Systemic Exposure between and within Humans—Part 2: Fed State

Author

Duxin Sun, Bo Wen, Bart Hens, Jianghong Fan, Gregory E. Amidon, Joseph Dickens, Allen Lee, Gail Benninghoff, Marival Bermejo, Gordon L. Amidon, Jeffrey Wysocki, Paulo Paixão, Raimar Löbenberg, William L. Hasler, Arjang Talattof, Niloufar Salehi, Jason Baker, Alex Yu, Robert Lionberger, Yasuhiro Tsume, Ann Frances, Mark J. Koenigsknecht, and Kerby Shedden

Subjects

Male, BIOAVAILABILITY, Administration, Oral, Datasets as Topic, Pharmaceutical Science, Ibuprofen, 02 engineering and technology, Research & Experimental Medicine, buffer capacity, Pharmacology, 030226 pharmacology & pharmacy, Food-Drug Interactions, CALORIC CONTENT, 0302 clinical medicine, Oral administration, oral absorption, Drug Discovery, ABSORPTION, VITRO, Pharmacology & Pharmacy, IN-VIVO DISSOLUTION, ibuprofen, Biological Variation, Individual, Stomach, immediate release, Hydrogen-Ion Concentration, Middle Aged, Postprandial Period, 021001 nanoscience & nanotechnology, Healthy Volunteers, Postprandial, Medicine, Research & Experimental, Area Under Curve, Molecular Medicine, Female, MEAL, 0210 nano-technology, Life Sciences & Biomedicine, Tablets, medicine.drug, Adult, in vivo dissolution, Cmax, Biological Availability, Bioequivalence, Models, Biological, DOSAGE FORMS, Article, in vivo study, Young Adult, 03 medical and health sciences, Pharmacokinetics, In vivo, MOTILITY, medicine, Humans, Computer Simulation, Gastric Absorption, bioequivalence, Science & Technology, business.industry, manometry, fed state, Bioavailability, Drug Liberation, Biological Variation, Population, Gastric Emptying, Solubility, LIQUIDS, local drug concentration in the GI tract, business, TRACT

Abstract

Exploring the intraluminal behavior of an oral drug product in the human gastrointestinal (GI) tract remains challenging. Many in vivo techniques are available to investigate the impact of GI physiology on oral drug behavior in fasting state conditions. However, little is known about the intraluminal behavior of a drug in postprandial conditions. In a previous report, we described the mean solution and total concentrations of ibuprofen after oral administration of an immediate-release (IR) tablet in fed state conditions. In parallel, blood samples were taken to assess systemic concentrations. The purpose of this work was to statistically evaluate the impact of GI physiology (e.g., pH, contractile events) within and between individuals (intra and intersubject variability) for a total of 17 healthy subjects. In addition, a pharmacokinetic (PK) analysis was performed by noncompartmental analysis, and PK parameters were correlated with underlying physiological factors (pH, time to phase III contractions postdose) and study parameters (e.g., ingested amount of calories, coadministered water). Moreover, individual plasma profiles were deconvoluted to assess the fraction absorbed as a function of time, demonstrating the link between intraluminal and systemic behavior of the drug. The results demonstrated that the in vivo dissolution of ibuprofen depends on the present gastric pH and motility events at the time of administration. Both intraluminal factors were responsible for explaining 63% of plasma Cmax variability among all individuals. For the first time, an in-depth analysis was performed on a large data set derived from an aspiration/motility study, quantifying the impact of physiology on systemic behavior of an orally administered drug product in fed state conditions. The data obtained from this study will help us to develop an in vitro biorelevant dissolution approach and optimize in silico tools in order to predict the in vivo performance of orally administered drug products, especially in fed state conditions. ispartof: MOLECULAR PHARMACEUTICS vol:15 issue:12 pages:5468-5478 ispartof: location:United States status: published

Published

2018

2. Pulse Packet Stochastic Model for Gastric Emptying in the Fasted State: A Physiological Approach

Author

Gordon L. Amidon and Arjang Talattof

Subjects

Stochastic modelling, Variable time, Gastric motility, Pharmaceutical Science, 02 engineering and technology, 030226 pharmacology & pharmacy, Models, Biological, 03 medical and health sciences, 0302 clinical medicine, Drug Discovery, Humans, Migrating motor complex, Mathematics, Stochastic Processes, Gastric emptying, Pulse (signal processing), digestive, oral, and skin physiology, Stomach, Mechanics, Fasting, 021001 nanoscience & nanotechnology, Magnetic Resonance Imaging, Healthy Volunteers, Intensity (physics), Fasted state, Gastric Emptying, Molecular Medicine, 0210 nano-technology

Abstract

Fasted-state gastrointestinal (GI) fluid transit is typically represented as a first-order, deterministic process (averaged and viewed as a continuous approximation). It is, however, most likely a discrete process involving fluid packets interrupted by variable time periods of little to no fluid emptying. In this report we present a physiologically based pulsed-packet gastric fluid emptying model and evaluate it with respect to recent gastrointestinal fluid volume emptying results, published gastric emptying of various dosage forms, and gastric fluid emptying as a function of GI motility. We develop the mathematical model for gastric emptying of discrete volumes emptied during intermittent pulse times of variable lengths, defined as a function of gastric motility utilizing a Poisson point process with motility-dependent intensity. We compare the simulations with observed gastric emptying results. The discrete pulse packet gastric volumetric emptying model is a more physiologically realistic mathematical model for gastric emptying, and it accounts well for the average observed emptying rates and, importantly, encompasses the variability of of observed volume and dosage form emptying rates.

Published

2018

3. Low Buffer Capacity and Alternating Motility along the Human Gastrointestinal Tract: Implications for in Vivo Dissolution and Absorption of Ionizable Drugs

Author

Gordon L. Amidon, Bart Hens, William L. Hasler, Bo Wen, Gail Benninghoff, Robert Lionberger, Raimar Loebenberg, Greg E. Amidon, Jason Baker, Kerby Shedden, Jeffrey Wysocki, Mark J. Koenigsknecht, Duxin Sun, Niloufar Salehi, Yasuhiro Tsume, Jianghong Fan, Allen Lee, Marival Bermejo, Joseph Dickens, Paulo Paixão, Arjang Talattof, Alex Yu, and Ann Frances

Subjects

Absorption (pharmacology), Adult, Time Factors, Manometry, Pharmaceutical Science, Administration, Oral, Ibuprofen, 02 engineering and technology, Bioequivalence, Pharmacology, Buffers, 030226 pharmacology & pharmacy, Jejunum, 03 medical and health sciences, Young Adult, 0302 clinical medicine, Oral administration, Drug Discovery, medicine, Ingestion, Humans, Intestinal Mucosa, Chemistry, Hydrogen-Ion Concentration, Middle Aged, 021001 nanoscience & nanotechnology, Healthy Volunteers, Bioavailability, Absorption, Physiological, Body Fluids, Gastrointestinal Tract, Drug Liberation, medicine.anatomical_structure, Intestinal Absorption, Solubility, Therapeutic Equivalency, Duodenum, Molecular Medicine, 0210 nano-technology, Gastrointestinal Motility, medicine.drug, Tablets

Abstract

In this study, we determined the pH and buffer capacity of human gastrointestinal (GI) fluids (aspirated from the stomach, duodenum, proximal jejunum, and mid/distal jejunum) as a function of time, from 37 healthy subjects after oral administration of an 800 mg immediate-release tablet of ibuprofen (reference listed drug; RLD) under typical prescribed bioequivalence (BE) study protocol conditions in both fasted and fed states (simulated by ingestion of a liquid meal). Simultaneously, motility was continuously monitored using water-perfused manometry. The time to appearance of phase III contractions (i.e., housekeeper wave) was monitored following administration of the ibuprofen tablet. Our results clearly demonstrated the dynamic change in pH as a function of time and, most significantly, the extremely low buffer capacity along the GI tract. The buffer capacity on average was 2.26 μmol/mL/ΔpH in fasted state (range: 0.26 and 6.32 μmol/mL/ΔpH) and 2.66 μmol/mL/ΔpH in fed state (range: 0.78 and 5.98 μmol/mL/ΔpH) throughout the entire upper GI tract (stomach, duodenum, and proximal and mid/distal jejunum). The implication of this very low buffer capacity of the human GI tract is profound for the oral delivery of both acidic and basic active pharmaceutical ingredients (APIs). An in vivo predictive dissolution method would require not only a bicarbonate buffer but also, more significantly, a low buffer capacity of dissolution media to reflect in vivo dissolution conditions.

Published

2017