RESUMEN
Purpose: Desvenlafaxine succinate (DSV) is a water soluble anti-depressant drug, which is rapidly absorbed after oral administration exaggerating its side effects. The current work aimed to prepare controllable release DSV matrix to reduce DSV side effects related to its initial burst. Methods: Fifteen DSV matrix formulations were prepared using different polymers, polymer/drug ratios and matrix excipients and characterized using Differential Scanning Calorimetry (DSC), infrared (IR) spectroscopy, water uptake and in vitro DSV release. The release kinetics were calculated to determine the drug release mechanism. Ex-vivo DSV absorption via rat intestinal mucosal cells and the calculation of the apparent permeability coefficient (Papp) were performed using everted sac technique. Results: Maltodextrin was the best matrix excipient (F7 and F10) showing acceptable decrease in the initial burst compared to the innovator. The addition of negatively charged polymers sodium carboxy methyl cellulose (SCMC) or sodium alginate resulted in an interaction that was proved by DSC and IR findings. This interaction slowed DSV release. F10 showed an excellent absorption of more than 80% of DSV after 4 h and the highest similarity factor with the innovator (84.7). Conclusion: A controllable release pattern of DSV was achieved using Methocel, Maltodextrin and SCMC. The obtained results could be used as a platform to control the release of cationic water soluble drugs that suffer from side effects associated with their initial burst after oral administration.
RESUMEN
BACKGROUND: With its reported side effects Desvenlafaxine succinate (DSV) is a good candidate to prepare prolonged release system. Such prolonged release could decrease the rapid DSV absorption after oral administration and reduce its exaggerated side effects. METHODS: A prolonged release Desvenlafaxine succinate (DSV) multilayered system was prepared by ionotropic gelation using sodium alginate (SA) and calcium chloride as a cross-linker. DSV was incorporated simultaneously during the gelation stage and the formed beads were evaluated for shape and particle size. Thirteen formulation variables including pH, DSV: polymer ratio, cross-linker concentration and curing time were optimized for optimal drug entrapment. The optimized formula was evaluated ex vivo using the everted sac technique to predict DSV absorption through intestinal mucosal cells, follow the permeation and calculate its apparent permeability coefficient. RESULTS: The optimum formulation variables were: pH (8-9), DSV: SA ratio (2:1), cross-linker concentration (5%w/v) and 30 min curing time. Multilayered beads coating using chitosan and SA was compared with uncoated beads or the innovator for DSV release. Coating of the beads greatly retarded DSV release with a release profile similar to that of the innovator. An optimized formula (T13) coated with 0.04% w/v of each of chitosan and SA was selected. The developed system gave rise to a prolonged release pattern with high similarity factor with the innovator. CONCLUSION: The results of the current work can be applied to prepare controlled release systems of similar drugs that have intense side effects associated with their initial burst after oral administration.