Objective To evaluate the efficacy of Puerariae lobatae radix （PLR） and Anemarrhenae Rhizoma （AR） in preventing and treating Alzheimer’s disease （AD） and explore its potential mechanism of action by LC-MS serum metabolomics strategy. Methods The AD rat model was established by administering aluminum chloride （AlCl₃） and D-galactose （D-gal） for 20 weeks. The traditional Chinese medicine intervention group was given the PLR, AR, and PLR-AR extracts for 8 weeks by gavage. The model effect and efficacy were evaluated by Morris water maze test and biochemical indicators including SOD, NO, and MDA; Metabolomics research based on the UHPLC-Q/TOF-MS method was conducted, and relevant metabolic pathways were analyzed through the MetaboAnalyst online website. Results The learning and memory abilities of AD model rats were significantly decreased compared with the control group, and the levels of oxidative stress and lipid peroxides were significantly increased （P<0.05）, while the SOD content was decreased considerably （P<0.01）. The learning and memory abilities of AD model rats were improved, oxidative stress and lipid peroxidation levels were reversed, and serum SOD content was increased significantly after the intervention of PLR-AR, with better effects than single drugs. Through metabolomics, 70 differential metabolites were identified between the AD model group and the control group, mainly involving 10 pathways, including phenylalanine, tyrosine, and tryptophan biosynthesis, phenylalanine metabolism, and unsaturated fatty acid biosynthesis, et.al. The intervention of PLR-AR could adjust 47 metabolites, with 20 metabolites showing significant differences （P<0.05）. The significantly adjusted metabolites involve 6 pathways, including phenylalanine, tyrosine, and tryptophan biosynthesis, et al. Conclusion The combination of PLR and AR could significantly improve the learning and memory abilities of AD rat models. The mechanism may be related to the improvement of oxidative stress and lipid peroxidation levels, the increase of serum SOD content, and the regulation of phenylalanine, tyrosine, and tryptophan biosynthesis pathways.

Objective To construct a glioma microfluidic chip model to simulate tumor microenvironment for evaluating the medicinal efficacy of anti-glioma traditional Chinese medicines. Methods Glioblastoma cells U251 were seeded into microfluidic chips with different culture modes, and the cell viability and tumour microenvironment within the constructed model were characterized. Fluorescence staining was used to evaluate the effects of the positive drugs temozolomide （TMZ） and docetaxel （DOC） on the cell activity and apoptosis within the model, which was applied to evaluate the medicinal efficacy of the extracts of the herb Scutellaria barbata on gliomas. Results The cells in the constructed U251 microfluidic chip model displayed high viability and were able to mimic the hypoxic microenvironment of tumor to a certain extent. The viability of the U251 cells in the microfluidic chips decreased with the increasing of the concentration of the positive drug, and the viability of the 3D cultured U251 cells was higher than that in the 2D condition （P<0.05）. The intracellular mitochondrial membrane potential decreased with the increasing of the concentration of the positive drug. And the 2 mg/ml Scutellaria barbata extract killed U251 cells to a certain extent and reduced the mitochondrial membrane potential of the cells in the model. Conclusion This study successfully constructed a microfluidic chip model of glioma that could effectively simulate the tumor microenvironment and rapidly evaluate the anti-tumor medicinal efficacy, which provided a new strategy for the medicinal efficacy evaluation and active components screening of anti-glioma traditional Chinese medicines.

The intestine is the main site of oral drug absorption, and the epithelial cells of the intestine contain villi and microvilli, which promote secretion, cell adhesion, and absorption by increasing surface area and other factors. Traditional two-dimensional/three-dimensional (2D/3D) cell culture models and animal models have played an important role in studying drug absorption, but their application is limited due to the lack of sufficient predictability of human pharmacokinetics or ethical issues, etc. Therefore, mimicking the core structure and key functions of the human intestine based on in vitro live cells has been the focus of research on constructing a microfluidic chip-based intestinal model. The model is a microfluidic chip bionic system that simulates the complex microstructure, microenvironment, and physiological functions of the human intestine using microfabrication technology. Compared with 2D cell culture and animal experiments, the intestinal microarray model can effectively simulate the human in vivo environment and is more specific in drug screening. The research progress and applications in disease modeling, drug absorption and transport of intestinal microarray models and intestine-related multi-organ coupled microarray models at home and abroad were reviewed in this paper. The current challenges of intestinal chip simulating intestinal homeostasis and diseases were summarized，in order to provide reference for the further establishment of a more reliable in vitro intestinal chip model.

Chiral drugs are closely related to the safety and effectiveness of drug use.Most dihydropyridine drugs have chiral carbon atoms,which are used as racemes and produce stereoselective disposal characteristics after entering the body,and may affect the safety and effectiveness of drugs.Therefore,based on the chiral resolution and pharmacokinetic characteristics of this class of drugs,the selection rules of chiral HPLC and CE methods and in vivo analysis applications of this class of drugs in recent years were reviewed.The stereoselective pharmacokinetics of this class of drugs were listed and compared.It was found that some of these drugs had obvious differences in stereoselective pharmacokinetics,and the pharmacokinetics and toxicity in vivo were also different.

Cell metabolomics is an important branch of metabolomics, which could dynamically monitor cell response and metabolic changes after drugs acting on cells, and look for potential biomarkers. Cell metabolomics has been widely used in illustration of disease mechanism, evaluation of drug efficacy and development of new drug through elucidating the pathophysiological mechanism of the disease and the effect of drug treatment intervention. The researches process of cellular metabolomics and its application in central nervous system diseases were reviewed in order to provide theoretical basis for in-depth study of the pathogenesis and prevention and treatment of central nervous system diseases.

Objective To construct a cardiovascular chip model for evaluating the damage of vascular glycocalyx induced by four marine toxins: okadaic acid (OA), conotoxin (CTX), tetrodotoxin (TTX) and gymnodimine (GYM), and explore the protective effect of triptolide on toxin-induced injury. Methods Human umbilical vein endothelial cells（HUVEC) were inoculated into a three-channel microfluidic chip. CCK-8 method and immunofluorescence staining were used to analyze the damage of cell viability and glycocalyx tissue induced by low, middle and high concentrations of marine toxin, as well as the protective effect of triptolide on toxin-induced injury. Results The cells in the cardiovascular chip grew well and had structurally intact glycocalyx. Compared with the control group, the activity of HUVEC cells were inhibited in group of the medium and high concentration of OA and high concentration of GYM (P<0.05). The activity of cells had not been inhibited by CTX and TTX significantly , but all the four toxins caused serious damage to the glycocalyx tissue (P<0.01). After pre-protection with triptolide, the toxicity of the four toxins to HUVEC cells and the damage rate of glycocalyx decreased significantly. Conclusion The four marine biotoxins could damage the activity and glycocalyx of HUVEC cells in a dose-dependent manner, while triptolide has a protective effect on HUVEC cells injured by toxin.

P-glycoprotein (P-gp) highly expressed in cancer cells can lead to multidrug resistance (MDR) and the combination of anti-cancer drugs with P-gp inhibitor has been a promising strategy to reverse MDR in cancer treatment. In this study, we established a label-free and detergent-free system combining surface plasmon resonance (SPR) biosensor with styrene maleic acid (SMA) polymer membrane proteins (MPs) stabilization technology to screen potential P-gp inhibitors. First, P-gp was extracted from MCF-7/ADR cells using SMA polymer to form SMA liposomes (SMALPs). Following that, SMALPs were immobilized on an SPR biosensor chip to establish a P-gp inhibitor screening system, and the affinity between P-gp and small molecule ligand was determined. The methodological investigation proved that the screening system had good specificity and stability. Nine P-gp ligands were screened out from 50 natural products, and their affinity constants with P-gp were also determined. The in vitro cell verification experiments demonstrated that tetrandrine, fangchinoline, praeruptorin B, neobaicalein, and icariin could significantly increase the sensitivity of MCF-7/ADR cells to Adriamycin (Adr). Moreover, tetrandrine, praeruptorin B, and neobaicalein could reverse MDR in MCF-7/ADR cells by inhibiting the function of P-gp. This is the first time that SMALPs-based stabilization strategy was applied to SPR analysis system. SMA polymer can retain P-gp in the environment of natural lipid bilayer and thus maintain the correct conformation and physiological functions of P-gp. The developed system can quickly and accurately screen small molecule ligands of complex MPs and obtain affinity between complex MPs and small molecule ligands without protein purification.

Objective To establish a method for the simultaneous determination of new mangiferin, mangiferin, artemisinin BⅡ, icariin and artemisinin A in Anemarrhenae Rhizoma by high performance liquid chromatography-evaporation light scattering detector (HPLC-ELSD). Methods The column was Agilent Poroshell 120 EC-C₁₈. The mobile phase used acetonitrile-0.2% acetic acid water system with gradient elution. Column temperature was 30 ℃. Flow rate was 0.7 ml/min. Evaporative light scattering detector used nitrogen as atomizing gas. The atomizing gas temperature was 40 ℃ and the drift tube temperature was 90 ℃. The nitrogen volume flow rate was 2.00 L/min and the sample volume was 20 μl. Results The five components were able to achieve baseline separation. Neomangiferin, Mangiferin, Anemaponin BⅡ, Baohuoside I , Anemarrhena saponin AⅢwere determined as 24.1-386 μg/ml (r=0.999 3), 23.2-371 μg/ml (r=0.998 6), 54.2-867.2 μg/ml(r=0.995 6), 5.3-84.8 μg/ml (r=0.996 8), 10-160 μg/ml (r=0.998 9) respectively, which showed a good linear relationship within the concentration range. The average recovery rate of the five components was between 101.8% and 105.0%, and the repeatability RSD was less than 2.4%. The content of the above five components in Zhimu medicinal materials were 1.62%, 0.82%, 7.36%, 0.07%, 0.34%, respectively. Conclusion The method is simple, accurate, and highly sensitive, which could be used as the quantitative determination of multiple index components of Anemarrhenae Rhizoma.

Astragali Radix(AR)is a clinically used herbal medicine with multiple immunomodulatory activities that can strengthen the activity and cytotoxicity of natural killer(NK)cells.However,owing to the complexity of its composition,the specific active ingredients in AR that act on NK cells are not clear yet.Cell membrane chromatography(CMC)is mainly used to screen the active ingredients in a complex system of herbal medicines.In this study,a new comprehensive two-dimensional(2D)NK-92MI CMC/C18 column/time-of-flight mass spectrometry(TOFMS)system was established to screen for potential NK cell acti-vators.To obtain a higher column efficiency,3-mercaptopropyltrimethoxysilane-modified silica was synthesized to prepare the NK-92MI CMC column.In total,nine components in AR were screened from this system,which could be washed out from the NK-92MI/CMC column after 10 min,and they showed good affinity for NK-92MI/CMC column.Two representative active compounds of AR,isoastragaloside Ⅰ and astragaloside Ⅳ,promoted the killing effect of NK cells on K562 cells in a dose-dependent manner.It can thus suggest that isoastragaloside Ⅰ and astragaloside Ⅳ are the main immunomodulatory compo-nents of AR.This comprehensive 2D NK-92MI CMC analytical system is a practical method for screening immune cell activators from other herbal medicines with immunomodulatory effects.

Therapeutic drug monitoring(TDM)has played an important role in clinical medicine for precise dosing.Currently,chromatographic technology and immunoassay detection are widely used in TDM and have met most of the needs of clinical drug therapy.However,some problems still exist in practical appli-cations,such as complicated operation and the influence of endogenous substances.Surface plasmon resonance(SPR)has been applied to detect the concentrations of small molecules,including pesticide residues in crops and antibiotics in milk,which indicates its potential for in vivo drug detection.In this study,a new SPR-based biosensor for detecting chloramphenicol(CAP)in blood samples was developed and validated using methodological verification,including precision,accuracy,matrix effect,and extraction recovery rate,and compared with the classic ultra-performance liquid chromatography-ultraviolet(UPLC-UV)method.The detection range of SPR was 0.1-50 ng/mL and the limit of detec-tion was 0.099±0.023 ng/mL,which was lower than that of UPLC-UV.The intra-day and inter-day ac-curacies of SPR were 98％-114％and 110％-122％,which met the analysis requirement.The results show that the SPR biosensor is identical to UPLC-UV in the detection of CAP in rat blood samples;moreover,the SPR biosensor has better sensitivity.Therefore,the present study shows that SPR technology can be used for the detection of small molecules in the blood samples and has the potential to become a method for therapeutic drug monitoring.