PURPOSE: To investigate a novel mechanism for oral controlled release of drugs involving a continuous degradation of a phospholipid prodrug along the intestine. An indomethacin-lecithin conjugate with the drug attached to the sn-2 position of the phospholipid through a 5-carbon linker (DP-155) was used as a model molecule. METHODS: The pharmacokinetics of DP-155 and free indomethacin liberated from the prodrug following intravenous, oral or intra-colon administration was investigated in rats, and evaluated in comparison to free indomethacin administration. Degradation by phospholipase A(2) (PLA(2)) enzymes was assessed in-vitro. The impact of the linker length was evaluated in comparison to an indomethacin-phospholipid conjugate with a shorter linker (2-carbons). RESULTS: Following oral or intra-colon DP-155 administration, free indomethacin was liberated along the intestine and absorbed into the systemic circulation, resulting in a controlled release profile of indomethacin in the plasma. The shorter linker caused a 20-fold decrease in the subsequent indomethacin absorption. DP-155 in-vitro degradation by PLA(2) was over 60%, while shorter linkers were profoundly less degradable. CONCLUSIONS: DP-155 caused a continuous input of free indomethacin into the plasma following degradation by PLA(2) in the gut lumen. Since the rate of drug release is not formulation dependent, the prodrug can be compounded even in a liquid dosage form. The phospholipid-drug conjugate is thus a potential novel mechanism for oral controlled release of drugs.
PURPOSE: To investigate a novel mechanism for oral controlled release of drugs involving a continuous degradation of a phospholipid prodrug along the intestine. An indomethacin-lecithin conjugate with the drug attached to the sn-2 position of the phospholipid through a 5-carbon linker (DP-155) was used as a model molecule. METHODS: The pharmacokinetics of DP-155 and free indomethacin liberated from the prodrug following intravenous, oral or intra-colon administration was investigated in rats, and evaluated in comparison to free indomethacin administration. Degradation by phospholipase A(2) (PLA(2)) enzymes was assessed in-vitro. The impact of the linker length was evaluated in comparison to an indomethacin-phospholipid conjugate with a shorter linker (2-carbons). RESULTS: Following oral or intra-colonDP-155 administration, free indomethacin was liberated along the intestine and absorbed into the systemic circulation, resulting in a controlled release profile of indomethacin in the plasma. The shorter linker caused a 20-fold decrease in the subsequent indomethacin absorption. DP-155 in-vitro degradation by PLA(2) was over 60%, while shorter linkers were profoundly less degradable. CONCLUSIONS:DP-155 caused a continuous input of free indomethacin into the plasma following degradation by PLA(2) in the gut lumen. Since the rate of drug release is not formulation dependent, the prodrug can be compounded even in a liquid dosage form. The phospholipid-drug conjugate is thus a potential novel mechanism for oral controlled release of drugs.
Authors: Dipanjan Pan; Nibedita Sanyal; Anne H Schmieder; Angana Senpan; Benjamin Kim; Xiaoxia Yang; Grace Hu; John S Allen; Richard W Gross; Samuel A Wickline; Gregory M Lanza Journal: Nanomedicine (Lond) Date: 2012-06-18 Impact factor: 5.307
Authors: Dipanjan Pan; Benjamin Kim; Grace Hu; Deepti Sood Gupta; Angana Senpan; Xiaoxia Yang; Anne Schmieder; Corban Swain; Samuel A Wickline; Michael H Tomasson; Gregory M Lanza Journal: Nanomedicine (Lond) Date: 2015-01 Impact factor: 5.307
Authors: Dipanjan Pan; Christine T N Pham; Katherine N Weilbaecher; Michael H Tomasson; Samuel A Wickline; Gregory M Lanza Journal: Wiley Interdiscip Rev Nanomed Nanobiotechnol Date: 2015-08-21
Authors: Jaime A Yáñez; Stephen W J Wang; Ian W Knemeyer; Mark A Wirth; Kevin B Alton Journal: Adv Drug Deliv Rev Date: 2011-06-13 Impact factor: 15.470