Objective:To explore the improvement of the quality standard of Ginkgo Leaf Extract and Dipyridamole Injection and conduct safety tests including abnormal toxicity test,allergic reaction test,hemolysis and coagulation test.Methods:Ginkgo Leaf Extract and Dipyridamole Injection from 3 different manufactures(A,B and C)were tested respectively through abnormal toxicity test and acute toxicity test in mice,active systemic anaphylaxis test in guinea pigs and hemolysis test in vitro.Five mice were used in each batch for abnormal toxicity test according to the abnormal toxicity test method in general notice of the Chinese Pharmacopoeia 2020 Volume Ⅳ(1141),and 50 mice were selected in each batch for acute toxicity test to determine the median lethal dose(LD50)or maximum tol-erable dose(MTD)of Ginkgo Leaf Extract and Dipyridamole Injection,which were used to establish the method of abnormal toxicity experiment.The anaphylaxis of Ginkgo Leaf Extract and Dipyridamole Injection was evaluated by active systemic anaphylaxis test in guinea pigs,which was used to establish the method of allergic test.The hemoly-sis test of Ginkgo Leaf Extract and Dipyridamole Injection was studied by conventional tube method in vitro(macro-scopic observation)and improved hemolysis method in vitro(spectrophotometric method),which were used to establish the method of hemolysis and coagulation test.Results:① In manufacture A,the results of abnormal toxicity test were showed that LD50 was20.8 mL·kg-1and MTD was 16.5 mL·kg-1.No death or abnormal reac-tions were observed in mice tested for abnormal toxicity of 2 manufactures(B and C),and MTD was 50 and 40 mL·kg-1,respectively.②The no-observed-adverse-effect dose of Ginkgo Leaf Extract and Dipyridamole Injec-tion from 3 manufactures to guinea pig intravenous was 0.83 mL·kg-1,and no allergic reaction symptoms were observed when Ginkgo Leaf Extract and Dipyridamole Injection was diluted 4 times to challenge the sensitized guinea pigs(equivalent to human clinical dosage).③Differences were observed in the hemolytic effects of Ginkgo Leaf Extract and Dipyridamole Injection from 3 manufactures,but no obvious hemolytic reaction occurred when it was diluted 1.2 times(equivalent to 5%of the maximum clinical concentration).Conclusion:It is recommended to add abnormal toxicity test,allergic reaction test,hemolysis and coagulation test in the quality standard of Ginkgo Leaf Extract and Dipyridamole Injection as safety test items to control the risk.The proposed method is diluting Ginkgo Leaf Extract and Dipyridamole Injection by 5 times,4 times and 1.2 times to perform abnormal toxicity test,allergic reaction test,hemolysis test and coagulation test respectively.

Objective:To explore the improvement of the quality standard of Ginkgo Leaf Extract and Dipyridamole Injection and conduct safety tests including abnormal toxicity test,allergic reaction test,hemolysis and coagulation test.Methods:Ginkgo Leaf Extract and Dipyridamole Injection from 3 different manufactures(A,B and C)were tested respectively through abnormal toxicity test and acute toxicity test in mice,active systemic anaphylaxis test in guinea pigs and hemolysis test in vitro.Five mice were used in each batch for abnormal toxicity test according to the abnormal toxicity test method in general notice of the Chinese Pharmacopoeia 2020 Volume Ⅳ(1141),and 50 mice were selected in each batch for acute toxicity test to determine the median lethal dose(LD50)or maximum tol-erable dose(MTD)of Ginkgo Leaf Extract and Dipyridamole Injection,which were used to establish the method of abnormal toxicity experiment.The anaphylaxis of Ginkgo Leaf Extract and Dipyridamole Injection was evaluated by active systemic anaphylaxis test in guinea pigs,which was used to establish the method of allergic test.The hemoly-sis test of Ginkgo Leaf Extract and Dipyridamole Injection was studied by conventional tube method in vitro(macro-scopic observation)and improved hemolysis method in vitro(spectrophotometric method),which were used to establish the method of hemolysis and coagulation test.Results:① In manufacture A,the results of abnormal toxicity test were showed that LD50 was20.8 mL·kg-1and MTD was 16.5 mL·kg-1.No death or abnormal reac-tions were observed in mice tested for abnormal toxicity of 2 manufactures(B and C),and MTD was 50 and 40 mL·kg-1,respectively.②The no-observed-adverse-effect dose of Ginkgo Leaf Extract and Dipyridamole Injec-tion from 3 manufactures to guinea pig intravenous was 0.83 mL·kg-1,and no allergic reaction symptoms were observed when Ginkgo Leaf Extract and Dipyridamole Injection was diluted 4 times to challenge the sensitized guinea pigs(equivalent to human clinical dosage).③Differences were observed in the hemolytic effects of Ginkgo Leaf Extract and Dipyridamole Injection from 3 manufactures,but no obvious hemolytic reaction occurred when it was diluted 1.2 times(equivalent to 5%of the maximum clinical concentration).Conclusion:It is recommended to add abnormal toxicity test,allergic reaction test,hemolysis and coagulation test in the quality standard of Ginkgo Leaf Extract and Dipyridamole Injection as safety test items to control the risk.The proposed method is diluting Ginkgo Leaf Extract and Dipyridamole Injection by 5 times,4 times and 1.2 times to perform abnormal toxicity test,allergic reaction test,hemolysis test and coagulation test respectively.

BACKGROUND: Studies have shown that basic fibroblast growth factor has effects on stimulating vessel regeneration and collateral reconstruction. However, administration was performed mostly by peripheral vein, left atrium or percutaneous coronary intervention, and it is difficult to achieve an effective therapeutic concentration in the local myocardium. OBJECTIVE: Based on the property of poly(D, I-lactic-coglycolic acid) (PLGA), to investigate outcomes of inducing neovascularization in the myocardium in combination of basic fibroblast growth factor (bFGF) by ensuring target release of protein growth factor in local tissue. METHODS: PLGA and bFGF were dissolved in dichloromethane. This liquid mixture was rolled into the form of a hollow tube (3.0 mm outer diameter, 2.8 mm inner diameter, 0.1 mm thick, 10 mm length) for further use. The middle third of the left anterior descending coronary artery of mini-swines was ligated, and the local myocardium became dark purple. After the successful establishment by abnormal regional wall motion in the cardiac apex at anterior wall using ultrasound, the mini-swines were assigned to channels and bare scaffolds (BS) group and channels and bFGF-incorporating scaffolds (FS) group. The scaffold was implanted in the myocardium using self-made hollow bit. At 6 weeks, the number of proliferative cells was quantified by immunohistochemical staining. New vessels were quantified utilizing Image-Pro Plus software package in both groups. Quantitative analysis of changes in mass defect percentage was performed by Emory Cardiac Toolbox software combined with single-photon-emission computed tomography. RESULTS AND CONCLUSION: At 6 weeks, number of proliferative cells and the density of new vessels were significantly increased in the FS group compared with BS group(P<0.001). Single-photon-emission computed tomography illustrates that MDP was significantly lower in the FS group compared with the BS group (P < 0.001). Results have suggested that PLGA scaffolds that incorporate bFGF were able to induce angiogenesis and enhance blood-flow perfusion.

Aim To search for colchicine derivatives which have high efficacy and low toxicity. Methods Colchicine was firstly converted into thiocolchicine, and then it was hydrolyzed to get 7-(N-deacetylthiocolchicine). At last, 7-(N-deacetylthiocolchicine) was amidated to get the target compounds. The chemical structure of these new derivatives was confirmed with 1H NMR, IR, MS, and HR-MS. The cytotoxicity of the compounds was tested by MTT assay. Their in vivo antitumor activity was evaluated against mice tumor H22 and U14. Results Twelve thiocolchicine derivatives are new compounds. Conclusion In vitro antitumor activity has showed that some of these thiocolchicines possessed cytotoxic activity superior to colchicine. However, in vivo antitumor activity indicated that these derivatives have poor efficacy in mice.