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( Qizhe Quan ),( Dong Wuk Kim ),( Nirmal Marasini ),( Dae Hwan Kim ),( Jin Ki Kim ),( Jong Oh Kim ),( Chul Soon Yong ),( Han Gon Choi ) 영남대학교 약품개발연구소 2013 영남대학교 약품개발연구소 연구업적집 Vol.23 No.0
To formulate a self-nanoemulsifying drug delivery system (SNEDDS) for the oral administration of docetaxel as an alternative to commercial docetaxel-loaded injectable products, it was prepared by spray-drying an aqueous solution containing liquid SNEDDS and colloidal silica. Its physicochemicalproperties and oral bioavailability were investigated compared to a clear docetaxel solution administered intravenously or orally to rats. In the docetaxel-loaded solid SNEDDS prepared with colloidal silica, the liquid SNEDDS composed of Capryol 90, Cremophore EL and Transcutol HP (45/35/20, volume ratio) was absorbed inside the pores of carriers, and docetaxel was present in a changed amorphous state. The solid SNEDDS with 3.3% (w/v) docetaxel produced nanoemulsions, and showed about 12.5% absolute bioavailability in rats. Thus, this solid SNEDDS may be a potential candidate for oral pharmaceutical product with improved oral bioavailability of docetaxel.
Quan, Qizhe,Kim, Dong-Wuk,Marasini, Nirmal,Kim, Dae Hwan,Kim, Jin Ki,Kim, Jong Oh,Yong, Chul Soon,Choi, Han-Gon Informa UK Ltd. 2013 Journal of microencapsulation Vol.30 No.4
<P>To formulate a self-nanoemulsifying drug delivery system (SNEDDS) for the oral administration of docetaxel as an alternative to commercial docetaxel-loaded injectable products, it was prepared by spray-drying an aqueous solution containing liquid SNEDDS and colloidal silica. Its physicochemical properties and oral bioavailability were investigated compared to a clear docetaxel solution administered intravenously or orally to rats. In the docetaxel-loaded solid SNEDDS prepared with colloidal silica, the liquid SNEDDS composed of Capryol 90, Cremophore EL and Transcutol HP (45/35/20, volume ratio) was absorbed inside the pores of carriers, and docetaxel was present in a changed amorphous state. The solid SNEDDS with 3.3% (w/v) docetaxel produced nanoemulsions, and showed about 12.5% absolute bioavailability in rats. Thus, this solid SNEDDS may be a potential candidate for oral pharmaceutical product with improved oral bioavailability of docetaxel.</P>
Lipid Emulsion as a Drug Delivery System for Breviscapine: Formulation Development and Optimization
Lijun Wei,Qizhe Quan,Gao Li,Yi-Dong Yan,Roshan Pradhan,김종오 대한약학회 2012 Archives of Pharmacal Research Vol.35 No.6
In this study, we developed an optimized formulation of a breviscapine lipid emulsion (BLE) and evaluated the physicochemical properties and in vivo pharmacokinetics of BLE in rats. For the preparation of the lipid emulsion, soybean oil and oleic acid were used as the oil phase, lecithin and poloxamer 188 as surfactants and glycerol as co-surfactant. An optimized formulation consisting of soybean oil (10.0%), oleic acid (0.9%), lecithin (1.5%), poloxamer 188 (0.4%), and glycerol (2.25%) was selected. The results showed that the average particle size, polydispersity index, and zeta potential of the optimized formulation were 183.5 ± 5.5 nm, 0.098 ± 0.046, and −35.0 ± 2.5 mV, respectively. The BLE was stable for at least three month at room temperature. After a single intravenous dose of 4 mg/kg to rats, the AUC of scutellarin from the lipid emulsion was about 1.5-fold higher than that of the commercial product (breviscapine injection). In conclusion, the optimized formulation of BLE showed positive results over the commercial product in terms of the physicochemical properties and pharmacokinetics of BLE in rats.
Lipid Emulsion as a Drug Delivery System for Breviscapine: Formulation Development and Optimization
Wei, Lijun,Li, Gao,Yan, Yi-Dong,Pradhan, Roshan,Kim, Jong Oh,Quan, Qizhe 대한약학회 2012 Archives of Pharmacal Research Vol.35 No.6
In this study, we developed an optimized formulation of a breviscapine lipid emulsion (BLE) and evaluated the physicochemical properties and in vivo pharmacokinetics of BLE in rats. For the preparation of the lipid emulsion, soybean oil and oleic acid were used as the oil phase, lecithin and poloxamer 188 as surfactants and glycerol as co-surfactant. An optimized formulation consisting of soybean oil (10.0%), oleic acid (0.9%), lecithin (1.5%), poloxamer 188 (0.4%), and glycerol (2.25%) was selected. The results showed that the average particle size, polydispersity index, and zeta potential of the optimized formulation were $183.5{\pm}5.5$ nm, $0.098{\pm}0.046$, and $-35.0{\pm}2.5$ mV, respectively. The BLE was stable for at least three month at room temperature. After a single intravenous dose of 4 mg/kg to rats, the AUC of scutellarin from the lipid emulsion was about 1.5-fold higher than that of the commercial product (breviscapine injection). In conclusion, the optimized formulation of BLE showed positive results over the commercial product in terms of the physicochemical properties and pharmacokinetics of BLE in rats.
( Lijun Wei ),( Nirmal Marasini ),( Gao Li ),( Chul Soon Yong ),( Jong Oh Kim ),( Qizhe Quan ) 영남대학교 약품개발연구소 2013 영남대학교 약품개발연구소 연구업적집 Vol.23 No.0
Ligustrazine is a traditional Chinese medicine used to treat various cardiovascular and neurovascular complications. However, this compound exhibits rapid first-pass metabolism, a short biological half-life, low stability and potential vascular irritation that restrict its use for long-term therapy. The use of a lipid emulsion as a carrier for intravenous administration of ligustrazine might provide sustained and prolonged release, thereby reducing the frequency of administration and improving patient compliance. The main purpose of our study was to develop a highly stable and sterile optimal formulation of a ligustrazine lipid emulsion (LLE) and to evaluate its pharmacokinetic behavior and tissue distribution in rats. The final optimal formulation consisted of soybean oil (12.0%), oleic acid (0.6%), lecithin (1.0%), poloxamer 188 (0.6%) and glycerol (2.25%). The average particle size, polydispersity index (PDI), zeta-potential and pH of the final product were 215.0±2.5 nm, 0.076±0.033, -40.4±5.3 mV and 7.25±0.05, respectively. The LLE was stable for at least three months at room temperature. In vitro drug release studies of the LLE suggested a sustained release profile, which was further confirmed by in vivo pharmacokinetic studies in rats. The area under the drug concentration-time curve from 0 h to 10 h (AUC(0-10h)) for LLE was increased by 1.6-fold compared with that of the commercially available ligustrazine injection (LI), suggesting enhanced bioavailability from the lipid-based emulsion. Furthermore, a tissue distribution study showed significant improvement in the distribution pattern of ligustrazine with a higher AUC(0-180 min) observed in all tissues for LLE than for LI. In conclusion, LLE, with excellent stability, improved pharmacokinetics and tissue distribution, demonstrates great potential for the delivery of ligustrazine for clinical applications.ⓒ2012 Elsevier B.V.All rights reserved.