Objective To establish a method for the content determination of c hlorogenic acid in Yinren Granules. Methods The content of chlorogenic acid wa s detected by HPLC. HPLC was performed with Shim- Pack CLC- ODS column(150? 6.0 mm, 5 ? m) at room temperature, 3 % methyl alcohol- methanol( 79 ∶ 2 1) as mobile phase, the detection wavelength at 327 nm, the flow rate being 1. 2 mL/min and sample loop volume being 10 ? L. Results Chlorogenic acid has a good linearity within 0.102～ 1.02? g (r=0.999)and the average recovery was 98. 17 % with RSD being 1.31 % . Conclusion This method is simple, accurate and can be used for the quality control of Yinren Granules.

Objective: To investigate the biocompatibility of copper-gadolinium nanomaterials and their antibacterial efficacy againstEscherichia coli(E.coli). Methods: Copper-gadolinium nanomaterials were prepared using a hydrothermal method, and the samples were characterized and analyzed using instruments such as transmission electron microscopy. The biocompatibility of copper-gadolinium nanomaterials was evaluated through CCK-8 experiments with mouse fibroblast cells(L929). Copper-gadolinium nanomaterials were co-cultured withE.coli, and their antibacterial performance was observed and assessed. Results: Transmission electron microscopy and Fourier transform infrared spectroscopy analysis confirmed the synthesis of the copper-gadolinium nanomaterials. The CCK-8 experiment results showed that the material had reliable biocompatibility within a concentration range of 0-2 μg/ml. The antibacterial experiments verified the excellent anti-E.coliactivity of copper-gadolinium, with the antibacterial effect positively correlating with concentration and co-cultivation time. When copper-gadolinium nanomaterials at a concentration of 2 μg/ml were co-cultured withE.colifor 4 hours, the antibacterial rate reached 99.99%. Conclusion The 2 μg/ml copper-gadolinium nanomaterials exhibit reliable biocompatibility and excellent anti-E.colicapabilities.