Abstract

Drug absorption and bioavailability is largely treated on an empirical basis with after-the-fact analysis of studies in animals and/or humans. This is undoubtedly due to the complexity of processes involved in drug absorption and metabolism from the gastrointestinal tract. The proposed research project has as its long-term objective the development of a comprehensive physiologically based transport model of the gastrointestinal tract which, when combined with appropriate results of animal and human experiments on the basic underlying physiological processes, will be predictive of drug absorption in humans. When fully developed, the approach will be mechanistic and enable the prediction of mean plasma levels as well as expected intra- and intersubject variation based on the measured variation of the underlying physiological parameters, such as gastric emptying rate, intestinal transit rate, intestinal pH and permeability, in both the fasted and fed-states.
the specific aims of the proposed project are: (1) develop a general macroscopic model for estimating the extent of drug absorption from the gastrointestinal tract that includes permeability, stability, enzymatic activity, solubility and dissolution rate, measure the required parameters in animal models and/or humans and compare the estimated extent and variation of absorption with the observed results for ddI, foscarnet, cimetidine, and furosemide or nadolol; (2) extend the transport model for drug dissolution into surfactant solutions to emulsions and apply this model to estimating the extend of drug absorption for water insoluble drugs in humans; (3) develop a binding, transport and physiological model for the efficacy of cholestyramine and colestipol resins, determine the appropriate in vitro measurements to correlate with in vivo efficacy and apply this pharmacodynamic model to improving the efficacy of these drug products; (4) extend the gastrointestinal hepatic physiological flow model for the systemic bioavailability variability of the beta-blocker propranolol and the NSAID ibuprofen from dogs to humans; and (5) develop a physiological micro- mixing model of the gastrointestinal tract, including transit, dissolution and drug permeation through the intestinal membrane. The model will account for intestinal permeability changes down the gastrointestinal tract as well as flow rate and luminal environment changes, i.e., pH, buffer surfactant and lipid content and enzyme concentrations. The model will also include the gastrointestinal variations associated with gastric emptying and intestinal transit in the fasted and fed-state and the phase related variations in transit and luminal content. When fully developed this mechanistic approach will allow the estimation of drug absorption and drug absorption variability in humans based on a minimum amount of basic information on the drug and dosage form. Furthermore, when fully developed, a mechanistic approach will have the further advantage of being able to predict drug absorption and plasma levels in diseased states that alter the gastrointestinal physiological variables. This will aid in more optimal treatment of sick patients, such as those with AIDS.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
Food and Drug Administration (FDA)
Type
Research Project (R01)
Project #
5R01FD001462-05
Application #
3267698
Study Section
Pharmacology A Study Section (PHRA)
Project Start
1989-07-01
Project End
1994-09-29
Budget Start
1993-09-30
Budget End
1994-09-29
Support Year
5
Fiscal Year
1993
Total Cost
Indirect Cost

  Institution

Name
University of Michigan Ann Arbor
Department
Type
Schools of Medicine
DUNS #
791277940
City
Ann Arbor
State
MI
Country
United States
Zip Code
48109

  Publications

Takamatsu, Narushi; Welage, Lynda S; Hayashi, Yayoi et al. (2002) Variability in cimetidine absorption and plasma double peaks following oral administration in the fasted state in humans: correlation with antral gastric motility. Eur J Pharm Biopharm 53:37-47
Crison, J R; Weiner, N D; Amidon, G L (1997) Dissolution media for in vitro testing of water-insoluble drugs: effect of surfactant purity and electrolyte on in vitro dissolution of carbamazepine in aqueous solutions of sodium lauryl sulfate. J Pharm Sci 86:384-8
Takamatsu, N; Welage, L S; Idkaidek, N M et al. (1997) Human intestinal permeability of piroxicam, propranolol, phenylalanine, and PEG 400 determined by jejunal perfusion. Pharm Res 14:1127-32
Crison, J R; Shah, V P; Skelly, J P et al. (1996) Drug dissolution into micellar solutions: development of a convective diffusion model and comparison to the film equilibrium model with application to surfactant-facilitated dissolution of carbamazepine. J Pharm Sci 85:1005-11
Polli, J E; Amidon, G L (1995) In vitro characterization of sodium glycocholate binding to cholestyramine resin. J Pharm Sci 84:55-61
Amidon, G L; Lennernas, H; Shah, V P et al. (1995) A theoretical basis for a biopharmaceutic drug classification: the correlation of in vitro drug product dissolution and in vivo bioavailability. Pharm Res 12:413-20
Polli, J E; Amidon, G L (1995) Mathematical model and dimensional analysis of glycocholate binding to cholestyramine resin: implications for in vivo resin performance. J Pharm Sci 84:1446-54
Luner, P E; Amidon, G L (1993) Description and simulation of a multiple mixing tank model to predict the effect of bile sequestrants on bile salt excretion. J Pharm Sci 82:311-8
Luner, P E; Amidon, G L (1992) Equilibrium and kinetic factors influencing bile sequestrant efficacy. Pharm Res 9:670-6
Guo, J H; Robertson, R E; Amidon, G L (1991) Influence of physical aging on mechanical properties of polymer free films: the prediction of long-term aging effects on the water permeability and dissolution rate of polymer film-coated tablets. Pharm Res 8:1500-4

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