Monte Carlo Simulation of diffusion-limited drug release from finite fractal matrices

VILLALOBOS, R.; VIDALES, A M; CORDERO, S.; QUINTANAR, D.; DOMINGUEZ, A.

JOURNAL OF SOL-GEL SCIENCE AND TECHNOLOGY

Springer

Año: 2006 vol. 37 p. 195 - 199

0928-0707

How fast can drug molecules escape from a controlled matrix-type release system? This important question is of both scientific and practical importance, as increasing emphasis is placed on design considerations that can be addressed only if the physical chemistry of drug release is better understood. In this work, this problem is studied via Monte Carlo computer simulations. The drug release is simulated as a diffusion-controlled process. Six types of Menger sponges (all having the same fractal dimension, df = 2.727, but with different values of random walk dimension, dw ?¸ [2.028, 2.998]) are employed as models of drug delivery devices with the aim of studying the consequences of matrix structural properties (characterized by df and dw) on drug release performance. The results obtained show that, in all cases, drug release fromMenger sponges follows an anomalous behavior. Finally, the influence of the matrix structural properties on the drug release profile is quantified. release performance. The results obtained show that, in all cases, drug release fromMenger sponges follows an anomalous behavior. Finally, the influence of the matrix structural properties on the drug release profile is quantified. with the aim of studying the consequences of matrix structural properties (characterized by df and dw) on drug release performance. The results obtained show that, in all cases, drug release fromMenger sponges follows an anomalous behavior. Finally, the influence of the matrix structural properties on the drug release profile is quantified. release performance. The results obtained show that, in all cases, drug release fromMenger sponges follows an anomalous behavior. Finally, the influence of the matrix structural properties on the drug release profile is quantified. but with different values of random walk dimension, dw ?¸ [2.028, 2.998]) are employed as models of drug delivery devices with the aim of studying the consequences of matrix structural properties (characterized by df and dw) on drug release performance. The results obtained show that, in all cases, drug release fromMenger sponges follows an anomalous behavior. Finally, the influence of the matrix structural properties on the drug release profile is quantified. release performance. The results obtained show that, in all cases, drug release fromMenger sponges follows an anomalous behavior. Finally, the influence of the matrix structural properties on the drug release profile is quantified. with the aim of studying the consequences of matrix structural properties (characterized by df and dw) on drug release performance. The results obtained show that, in all cases, drug release fromMenger sponges follows an anomalous behavior. Finally, the influence of the matrix structural properties on the drug release profile is quantified. release performance. The results obtained show that, in all cases, drug release fromMenger sponges follows an anomalous behavior. Finally, the influence of the matrix structural properties on the drug release profile is quantified. df = 2.727, but with different values of random walk dimension, dw ?¸ [2.028, 2.998]) are employed as models of drug delivery devices with the aim of studying the consequences of matrix structural properties (characterized by df and dw) on drug release performance. The results obtained show that, in all cases, drug release fromMenger sponges follows an anomalous behavior. Finally, the influence of the matrix structural properties on the drug release profile is quantified. release performance. The results obtained show that, in all cases, drug release fromMenger sponges follows an anomalous behavior. Finally, the influence of the matrix structural properties on the drug release profile is quantified. with the aim of studying the consequences of matrix structural properties (characterized by df and dw) on drug release performance. The results obtained show that, in all cases, drug release fromMenger sponges follows an anomalous behavior. Finally, the influence of the matrix structural properties on the drug release profile is quantified. release performance. The results obtained show that, in all cases, drug release fromMenger sponges follows an anomalous behavior. Finally, the influence of the matrix structural properties on the drug release profile is quantified. dw ?¸ [2.028, 2.998]) are employed as models of drug delivery devices with the aim of studying the consequences of matrix structural properties (characterized by df and dw) on drug release performance. The results obtained show that, in all cases, drug release fromMenger sponges follows an anomalous behavior. Finally, the influence of the matrix structural properties on the drug release profile is quantified. release performance. The results obtained show that, in all cases, drug release fromMenger sponges follows an anomalous behavior. Finally, the influence of the matrix structural properties on the drug release profile is quantified. df and dw) on drug release performance. The results obtained show that, in all cases, drug release fromMenger sponges follows an anomalous behavior. Finally, the influence of the matrix structural properties on the drug release profile is quantified.