1.Study on the Bacterial Endotoxin Test for Lomefloxacin Hydrochloride and Glucose Injection
Cuiyan HAN ; Weiyu ZHAI ; Guoping CHENG
China Pharmacy 1991;0(05):-
OBJECTIVE:To study the bacterial endotoxin test for lomefloxacin hydrochloride and glucose injection.METHODS:According to the assigned method and guiding principle for bacterial endotoxin test in CHINESE PHARMACOPOEIA 2000,the interference test was performed.RESULTS:Lomefloxacin and glucose injection could interfere with limulus test,however,the interference could be eliminated after adjusting the pH of injection to 6.8~7.0.The proper concentration of limulus test agent of bacterial endotoxin test was 0.25EU/ml.CONCLUSION:Bacterial endotoxin test can be used for quality control of lomefloxacin and glucose injection.
2.Preparation of Urapidil Osmotic Pump Tablets
Cuiyan HAN ; Nan XU ; Changjiang SHENG
China Pharmacy 2005;0(22):-
OBJECTIVE:To prepare urapidil osmotic pump tablet(OPT) characterized by 24 h constant drug release in vitro.METHODS:OPT of urapidil was prepared using NaCl and low or high moleculan weight PEO(Mr 4?106、2?105) as core,CA and PEG-400 as the coating material.Similarity factor was used to evaluate formulation of osmotic pump tablets.The drug release mechanism was investigated as well.RESULTS:The optimal core formulation consisted of urapidil 60 mg,NaCl 190 mg,PEO(Mr 4?106) 90 mg,PEO(Mr 2?105) 90 mg.The drug was released from OPT at controlled rate 24 h.CONCLUSION:The preparation of osmotic pump tablets was simple and characterized by zero-order release.
3.Determination of the Content of Lomefloxacin in Hollow Type Suppository by RP-HPLC
Weiyu ZHAI ; Cuiyan HAN ; Guoping CHENG
China Pharmacy 2001;0(10):-
OBJECTIVE:To establish the method for determining the content of Lomefloxacin in hollow type suppository of Lomefloxacin hydrochloride.METHODS:RP-HPLC was used with Eclipse XDB-C 18 column(4.6mm?250mm)and the mobile phase consisting of citric acid(0.05mol/L)-acetonitrile(82∶18)the pH of which was adjusted to4.0with triethy?lamine.The flow rate was1.0ml/min and the detection wavelength was287nm.RESULTS:The average recovery of Lome?floxacin was99.8%and RSD was0.6%.CONCLUSION:The method is rapid and accurate and can be used for determination of the content of Lomefloxacin in hollow type suppository.
4.Preparation and Determination of Entrapment Efficiency of Puerarin Polymeric Micelles
Xiaoxing MA ; Cuiyan HAN ; Chang LIU ; Dan ZHU ; Xiaoyu SUI ; Cheng YUAN ; Haitao HUANG
China Pharmacy 2016;27(22):3122-3124
OBJECTIVE:To prepare Puerarin polymeric micelles and establish a method to determine its entrapment efficiency. METHODS:Puerarin polymeric micelles were prepared by film dispersion method. The polymeric micelles and free drug were sepa-rated by centrifugal-millipore filter filtration method. The entrapment efficiency of puerarin polymeric micelles was determined by HPLC. Diamonsil C18(2)column was used with 1% citric acid solution-methanol(65∶35)at the flow rate of 1 ml/min. The detec-tion wavelength was set at 250 nm,and column temperature was room temperature. RESULTS:The prepared polymeric micelles were spherical and spherical-like in shape with a mean particle size of 54.12 nm,polydispersity index of 0.122,Zeta potential of -13.60 mV;the linear range of puerarin was 2-10μg/ml(R2=0.999 4)with average recovery rate of 99.2%(RSD=0.9%,n=3). The re-covery rate of free drug was 95.3%(RSD=1.7%,n=3). The mean entrapment efficiency and drug-loading amount of puerarin were(35.5±2.12)% and(0.3±0.07)%,respectively(n=3). CONCLUSIONS:Film dispersion method is suitable for the prepara-tion of Puerarin polymeric micelles. Established method is convenient,accurate and reliable for the content and entrapment efficien-cy determination of Puerarin polymeric micelles.
5.Nano-Se-chondroitin sulfate inhibits T-2 toxin-induced apoptosis of cultured chondrocytes from patients with Kashin-Beck disease.
Jing HAN ; Xiong GUO ; Cuiyan WU ; Chunyan LI ; Shulan HE ; Chen DUAN ; Yujie NING
Journal of Southern Medical University 2013;33(2):225-229
OBJECTIVETo observe the effect of nano-Se-chondroitin sulfate on the growth and apoptosis of chondrocytes from patients with Kashin-Beck disease (KBD) exposed to T-2 toxin in vitro.
METHODSSamples of the articular cartilage were obtained from 6 patients with grade II/III KBD diagnosed in line with the National Clinical Diagnostic Criteria of KBD (WS/T 207-2010) for chondrocyte separation and culture in vitro. The separated chondrocytes were treated with synthesized nano-Se-chondroitin sulfate particles and T-2 toxin, alone or in combination, and the cell growth and apoptosis were observed using MTT assay, HE staining and flow cytometry.
RESULTSThe synthesized nano-Se-chondroitin sulfate, with a selenium entrapment ratio of 10.1%, spontaneously formed nanoparticles in distilled water with sizes ranging from 30 to 200 nm. Fourier-transform infrared spectroscopy suggested a possible covalent bond that bound Nano-Se and chondroitin sulfate. Within the concentration range of 50-200 ng/ml, nano-Se-chondroitin sulfate significantly inhibited T-2 toxin-induced apoptosis of the cultured chondrocytes and reduced the early apoptosis rate to (8.64∓1.57)% (P<0.05).
CONCLUSIONNano-Se-chondroitin sulfate can inhibit T-2 toxin-induced apoptosis of cultured chondrocytes from KBD patients in vitro, and serves as a promising candidate therapeutic agent for KBD.
Apoptosis ; drug effects ; Cells, Cultured ; Chondrocytes ; drug effects ; pathology ; Chondroitin Sulfates ; administration & dosage ; pharmacology ; Humans ; Kashin-Beck Disease ; pathology ; Middle Aged ; Nanostructures ; T-2 Toxin ; toxicity
6.Formula Optimization of Captopril Timing Osmotic Pump Tablets
Wuqi YE ; Ding ZUO ; Zihao ZHANG ; Tianmin CHEN ; Minfen JIAO ; Cuiyan HAN
China Pharmacy 2018;29(10):1328-1332
OBJECTIVE:To optimize the formula of Captopril timing osmotic pump tablets. METHODS:Using accumulative release rate (Q) as index, single factor test was used to investigate the effects of blocking layer coating weight gain, semipermeable membrane coating weight gain,the type of polyepoxide (PEO),the amount of PEO (3 × 105) and HPMC in drug bearing layer,the amount of PEO (7 × 106) and NaCl in booster layer on drug release of Captopril timing osmotic pump tablets. Based on single factor investigation,using comprehensive score of release behavior(L)as index,the amount of PEO(3×105)and HPMC in drug bearing layer,the amount of PEO(7×106)and NaCl in booster layer as factors,L9(43)orthogonal test was used to optimize the formula of tablet core validation test was conducted. RESULTS:The optimal formula of tablet core included PEO(3× 105)71 mg and HPMC 15 mg in drug bearing layer,PEO(7×106)61 mg and NaCl 18 mg in booster layer,coating weight gain 7% and semipermeable membrane coating weight gain 10% in blocking layer. The osmotic pump tablet prepared by optimized formula released after 4 h;in vitro drug release regression equation was Q=5.118t-21.441(R2=0.9956),which was in line with zero-order release characteristics. CONCLUSIONS:The optimal formula is stable,feasible and controllable in quality,and can provide reference for further development of Captopril timing osmotic pump tablets.
7.Preparation of Salinomycin Nanostructured Lipid Carriers and Formulation Optimization
Cuiyan HAN ; Shanshan JIN ; Xiaoli WANG ; Baiyu JIAN ; Xiaoyu SUI ; Lixin CAO
China Pharmacy 2018;29(3):317-321
OBJECTIVE: To prepare Salinomycin nanostructured lipid carriers (Sal-NLCs) and optimize its formulation. METHODS: Sal-NLCs was prepared by emulsion evaporation-low temperature solidification method. Using particle size, Zeta potential, encapsulation efficiency and drug loading as evaluation indexes, central composite design-response surface methodology was used to optimize the amount of Sal, the ratio of solid lipid glyceryl bisstearate to liquid lipid glyceryl octanoate in oil phase, ratio of surface active agent polyoxyethylene 35 castor oil (EL) to polyethylene glycol-15-hydroxy stearate (HS 15), the amount of polyoxyethylene (40) stearate (P40). The morphology, particle size, polydispersity index (PDI), Zeta potential, encapsulation efficiency, drug loading and in vitro release mechanism of Sal-NLCs were investigated. RESULTS: The optimal prescription was as follows as Sal 0. 86 mg, glyceryl bisstearate 40.70 mg, glyceryl octanoate 11.30 mg, EL 44.05 mg, HS15 7.95 mg, P40 3.8 mg. Prepared Sal-NLCs was round-like and dispersed evenly. The particle size, PDI, Zeta potential, encapsulation efficiency and drug loading of prepared Sal-NLCs were(81.81 ± 2.60) nm, 0.183 ± 0.042, (-24.9 ± 3.4) mV,(94.35 ± 1.50)% and (1.47 ±0.04)% (n=5), respectively.24 h accumulative release rate was (99.81 ± 3.90)% (n=3).Drug release behavior was in line with Higuchi model, and relative error of particle size, Zeta-potential, encapsulation efficiency and drug loading to predicted value of model were all lower than 4%. CONCLUSIONS: Sal-NLCs with sustained-release effect is prepared successfully according to optimized formulation, and its quality meets the expected standard.
8.Preparation of Small Peptide AEYLR Modified Paclitaxel Nanostructured Lipid Carriers and Evaluation of Its Anti-tumor Effects
Cuiyan HAN ; Jianwen ZHOU ; Chang LIU ; Xiaoxing MA ; Cheng YUAN ; Yan DONG ; Shanshan JIN
China Pharmacy 2019;30(6):770-775
OBJECTIVE: To prepare Paclitaxel(PTX)nanostructured lipid carriers (NLC) modified by small peptide alanine-glutamic acid-tyrosine-leucine-arginine (AEYLR), and to evaluate its anti-tumor effect in vitro and in vivo. METHODS: NLC, PTX-NLC (P-NLC) and AEYLR modified P-NLC (A-P-NLC) were prepared by emulsion evaporation-low temperature solidification curing method. Its appearance, particle size, multi-dispersion index(PDI) and Zeta potential were characterized,encapsulation rate,drug loading and in vitro drug release were detected respectively. Using NCI-H1299 and S180 cells as objects, CCK-8 method was adopted to investigate inhibitory effects of free PTX, P-NLC and A-P-NLC (0.44-44.00 μg/mL, by PTX) to those cells. The half inhibition concentration (IC50) was calculated. Using S180 tumor-bearing mice as model animal, anti-tumor effects of free PTX, P-NLC and A-P-NLC (5 mg/kg, by PTX) were evaluated. RESULTS: P-NLC and A-P-NLC were round-like and dispersed evenly. The particle size, PDI and Zeta potential of A-P-NLC were (43.92±0.76) nm, 0.203±0.034 and (-19.77±1.16) mV, which were all increased to certain extent, compared with P-NLC. The encapsulation efficiency and drug loading of A-P-NLC were (95.71±0.68)% and(1.97±0.25)%, which were both decreased to certain extent, compared with P-NLC. The cumulative release rate of A-P-NLC was(35.17±2.08)% within 48 h, showing significant sustained-release effect compared with free PTX; the release of A-P-NLC was slower than P-NLC. Compared with free PTX and P-NLC, inhibitory rates of same concentration of A-P-NLC to NCI-H1299 cells and S180 cells were almost increased significantly, while IC50 values were all decreased significantly. There was no death in S180 tumor-bearing mice treated with A-P-NLC and the general condition was good; the volume of tumors was significantly reduced, the mass of tumors was significantly reduced, and the inhibition rate of tumors was significantly increased (P<0.05 or P<0.01). CONCLUSIONS: A-P-NLC has significantly sustained-release effects; its inhibitory rate to NCI-H1299 cells and S180 cells in vitro, and its inhibitory effects on S180 solid tumor in mice are all better than free PTX and P-NLC, while the toxicity is decreased to certain extent.