TY - JOUR
T1 - Novel farnesylthiosalicylate (FTS)-eluting composite structures
AU - Kraitzer, Amir
AU - Kloog, Yoel
AU - Zilberman, Meital
N1 - Funding Information:
The authors are grateful to the Israel Science Foundation (ISF, grant number 1312/07) and to the Slezak Foundation, Tel-Aviv University, for supporting this research.
PY - 2009/6/28
Y1 - 2009/6/28
N2 - Farnesylthiosalicylate (FTS) is a new specific nontoxic drug with a mild hydrophobic nature, which acts as a Ras antagonist and can therefore be used for stent applications as well as for local cancer treatment. FTS-loaded bioresorbable core/shell fiber structures were developed and studied in order to investigate the FTS release mechanism. These structures were composed of a polyglyconate core and a porous poly(d,l-lactic-glycolic acid) shell loaded with FTS, prepared using freeze drying of inverted emulsions. The effects of the emulsion's composition (formulation) and process kinetics on the FTS release from the coatings were studied with reference to the shell morphology and degradation profile. The FTS release profiles exhibited a burst effect accompanied by a release rate which decreased with time and lasted for 15-40 days. The process was found to affect the drug release profile via two routes: (1) Direct, through water uptake and swelling of the structure, leading to a FTS burst release. Degradation of the host polymer affects the FTS release rate at a later stage. (2) Indirect effect of the microstructure on the release profile, which occurs via an emulsion stability mechanism. The copolymer composition is the most important parameter affecting the release behavior in our system. Other parameters, including polymer content, O:A phase ratio and homogenization rate exhibited only minor effects on the FTS release profile. The controlled release of the new drug FTS is reported here for the first time.
AB - Farnesylthiosalicylate (FTS) is a new specific nontoxic drug with a mild hydrophobic nature, which acts as a Ras antagonist and can therefore be used for stent applications as well as for local cancer treatment. FTS-loaded bioresorbable core/shell fiber structures were developed and studied in order to investigate the FTS release mechanism. These structures were composed of a polyglyconate core and a porous poly(d,l-lactic-glycolic acid) shell loaded with FTS, prepared using freeze drying of inverted emulsions. The effects of the emulsion's composition (formulation) and process kinetics on the FTS release from the coatings were studied with reference to the shell morphology and degradation profile. The FTS release profiles exhibited a burst effect accompanied by a release rate which decreased with time and lasted for 15-40 days. The process was found to affect the drug release profile via two routes: (1) Direct, through water uptake and swelling of the structure, leading to a FTS burst release. Degradation of the host polymer affects the FTS release rate at a later stage. (2) Indirect effect of the microstructure on the release profile, which occurs via an emulsion stability mechanism. The copolymer composition is the most important parameter affecting the release behavior in our system. Other parameters, including polymer content, O:A phase ratio and homogenization rate exhibited only minor effects on the FTS release profile. The controlled release of the new drug FTS is reported here for the first time.
KW - Degradation
KW - Drug-eluting fibers
KW - Drug-eluting stents
KW - Farnesylthiosalicylate (FTS)
KW - Stent coatings
UR - http://www.scopus.com/inward/record.url?scp=67349258532&partnerID=8YFLogxK
U2 - 10.1016/j.ejps.2009.03.004
DO - 10.1016/j.ejps.2009.03.004
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C2 - 19491026
AN - SCOPUS:67349258532
SN - 0928-0987
VL - 37
SP - 351
EP - 362
JO - European Journal of Pharmaceutical Sciences
JF - European Journal of Pharmaceutical Sciences
IS - 3-4
ER -