OBJECTIVE To explore the potential mechanisms of forkhead box protein A1(FOXA1)in benzo[a]pyrene(BaP)-induced carcinogenesis by investigating the effect of FOXA1 by knockout on microRNA(miRNA)expression profiles in BaP malignant transformed cells THBEc1 and establishing regulatory networks between FOXA1,miRNA and their target genes.METHODS FOXA1 knockout THBEc1 cells THBEc1-ΔFOXA1-c34 and control cells THBEc1-ctrl were used as study models.Western blotting was employed to determine FOXA1 protein expression levels.Next-generation sequencing(NGS)tech-nology was used to identify differentially expressed miRNAs between THBEc1-ΔFOXA1-c34 and THBEc1-ctrl cells,with subsequent validation by RT-qPCR.Five databases(ENCORI,miRDB,mirDIP,miRWalk and TargetScan 8.0)were used in conjunction with NGS results of mRNA between THBEc1-ΔFOXA1-c34 and THBEc1-ctrl to predict different expressed genes(DEGs)regulated by the identified differentially expressed miRNAs.GO and KEGG enrichment analyses were conducted on the DEGs using the DAVID database.Interaction network analysis of the proteins encoded by the DEGs was performed using STRING 12.0 and Cytoscape 3.10.2 software.RESULTS No FOXA1 expression was detected in THBEc1-ΔFOXA1-c34 cells.A differential analysis of miRNA expressions revealed 33 miRNAs with a fold change of＞2 or＜0.5 and a false discovery rate of＜0.05 between THBEc1-ΔFOXA1-c34 and THBEc1-ctrl cells,13 of which were down-regulated and 20 were up-regulated in THBEc1-ΔFOXA1-c34 cells.A regulatory network was formed by 11 down-regulated miRNAs and 32 up-regulated mRNAs,while a second network included 16 up-regulated miRNAs and 56 down-regulated mRNAs.The 27 differentially expressed miRNAs participated in various biological processes through the regulation of 88 DEGs,primarily associated with cell growth,proliferation,migration,apoptosis,angiogenesis,epithe-lial-mesenchymal transition,and signal transduction(TGF-β,Hippo,NF-kappa B and MAPK pathways).CONCLUSION The miRNA expression profile in BaP-malignant transformed THBEc1 cells is altered following FOXA1 knockout that may disrupt TGF-β and MAPK signaling pathways by changing miRNA expression levels,thereby inhibiting cell proliferation and migration.

OBJECTIVE To establish an in vitro simulated one compartment extravascular adminis-tration model with lanthanum nitrate as the test substance,and explore the differences between this model and the classic in vitro administration model in lanthanum nitrate induced HepG2 cell death.METHODS An in vitro administration device was designed based on compartment model theories which consisted of four functional chambers:the liquid storage chamber,mixing chamber,toxicant exposure chamber,and waste liquid receiving chamber.The four chambers were connected by peristaltic pump hoses.The peristaltic pumps were employed to ensure unidirectional and constant speed trans-mission of liquid between these chambers.According to the preset toxicokinetic parameters such as T1/2a and T1/2,an in vitro simulated one compartment extravascular administration model of lanthanum nitrate was constructed using the device.The content of lanthanum nitrate in the toxicant exposure chamber at different time points was measured using inductively coupled plasma mass spectrometry.The concentration-time curves of lanthanum nitrate were analyzed using PKsolver and GraphPad Prism 8.0 software.The constructed in vitro simulated one compartment extravascular administration model was evaluated by comparing the measured and theoretical values of toxicokinetic parameters.HepG2 cells were treated with lanthanum nitrate in the in vitro simulated one compartment extravascular administration model and classic in vitro administration model,respectively,and cell death was measured using the Hoechst 33342/propidium iodide staining method.RESULTS Within the Cmax range of 3.91-1 000.00 μmol·L-1,the measured concentration-time curves of lanthanum nitrate in the toxicant expo-sure chamber almost conformed with the corresponding calculated theoretical curves(the correlation coefficients were all>0.998 0).The measured values of toxicokinetic parameters,including Ke,T1/2,Ka,T1/2a,Tmax,Cmax,CL and AUC0-∞,were close to the corresponding theoretical values.The fitting coeffi-cients(R2)of the concentration-time curves for each experimental group were all>0.990 0,which was consistent with one compartment model for extravascular administration.In the simulated one compart-ment extravascular administration model,no significant death of HepG2 cells was observed in any lanthanum nitrate dose group.In the classic in vitro administration model,the cell death rate of the 0.500 mmol·L-1 lanthanum nitrate group was higher than that of the solvent control group,but no significant cell death was observed in the 0.119 mmol·L-1 group or 0.243 mmol·L-1 group.When Cmax or Cadministration was 0.500 mmol·L-1,classic in vitro administration induced a higher cell death rate than simulated one compart-ment extravascular administration.However,there was no statistically significant difference in lanthanum nitrate induced HepG2 cell death between the two administration models when the AUC was equal.CONCLUSION The device designed in this study can be used to in vitro simulate one compartment extravascular administration,making in vitro toxicity testing more similar to in vivo scenarios,and providing data for optimizing administration methods of in vitro toxicity testing.There are differences in lanthanum nitrate induced HepG2 cell death between simulated one compartment extravascular administration and classic in vitro administration,indicating that different in vitro exposure modes can affect toxicity.

Objective To understand the current situation of the management of patients'self-provided infusion drugs in secondary and above general hospitals in China,and to provide a theoretical and practical basis for improving the management system.Methods The annual pharmacy professional quality control work survey conducted by the National Pharmaceutical Management Professional Quality Control Center was used to obtain information on the management of patients'self-provided infusion drugs in secondary and above general hospitals in 31 provinces(autonomous regions and municipalities directly under the central government)and the Xinjiang Production and Construction Corps of Chinese mainland from 2020 to 2022,and was summarized and calculated using data-processing software.Results The total number of secondary and above general hospitals included in the analysis from 2020 to 2022 is 4 786,5 063 and 6 041,respectively.In 2022,compared with 2020,the percentage of hospitals allowing patients to use self-provided infused drugs decreased from 55.08％to 48.54％,the percentage of hospitals that have established a system for managing patients' self-provided drugs increased from 81.54％to 98.09％,and the percentage of hospitalized patients' use of self-provided drugs that are all documented in their medical orders increased from 79.76％to 90.72％.The types of drugs that hospitals allow patients to use for self-provided infusion are mainly antitumor drugs,the places where self-provided infusion drugs are dispensed are mainly clinical departments(wards),and the main source of self-provided infusion drugs is self-pickup by patients.Conclusion Hospitals should establish a management system for patients'self-provided drugs,strengthen the information management of self-provided infusion drugs,and ensure drug supply and medication safety for patients.

OBJECTIVE To explore the potential mechanisms of forkhead box protein A1(FOXA1)in benzo[a]pyrene(BaP)-induced carcinogenesis by investigating the effect of FOXA1 by knockout on microRNA(miRNA)expression profiles in BaP malignant transformed cells THBEc1 and establishing regulatory networks between FOXA1,miRNA and their target genes.METHODS FOXA1 knockout THBEc1 cells THBEc1-ΔFOXA1-c34 and control cells THBEc1-ctrl were used as study models.Western blotting was employed to determine FOXA1 protein expression levels.Next-generation sequencing(NGS)tech-nology was used to identify differentially expressed miRNAs between THBEc1-ΔFOXA1-c34 and THBEc1-ctrl cells,with subsequent validation by RT-qPCR.Five databases(ENCORI,miRDB,mirDIP,miRWalk and TargetScan 8.0)were used in conjunction with NGS results of mRNA between THBEc1-ΔFOXA1-c34 and THBEc1-ctrl to predict different expressed genes(DEGs)regulated by the identified differentially expressed miRNAs.GO and KEGG enrichment analyses were conducted on the DEGs using the DAVID database.Interaction network analysis of the proteins encoded by the DEGs was performed using STRING 12.0 and Cytoscape 3.10.2 software.RESULTS No FOXA1 expression was detected in THBEc1-ΔFOXA1-c34 cells.A differential analysis of miRNA expressions revealed 33 miRNAs with a fold change of＞2 or＜0.5 and a false discovery rate of＜0.05 between THBEc1-ΔFOXA1-c34 and THBEc1-ctrl cells,13 of which were down-regulated and 20 were up-regulated in THBEc1-ΔFOXA1-c34 cells.A regulatory network was formed by 11 down-regulated miRNAs and 32 up-regulated mRNAs,while a second network included 16 up-regulated miRNAs and 56 down-regulated mRNAs.The 27 differentially expressed miRNAs participated in various biological processes through the regulation of 88 DEGs,primarily associated with cell growth,proliferation,migration,apoptosis,angiogenesis,epithe-lial-mesenchymal transition,and signal transduction(TGF-β,Hippo,NF-kappa B and MAPK pathways).CONCLUSION The miRNA expression profile in BaP-malignant transformed THBEc1 cells is altered following FOXA1 knockout that may disrupt TGF-β and MAPK signaling pathways by changing miRNA expression levels,thereby inhibiting cell proliferation and migration.

Objective To understand the current situation of the management of patients'self-provided infusion drugs in secondary and above general hospitals in China,and to provide a theoretical and practical basis for improving the management system.Methods The annual pharmacy professional quality control work survey conducted by the National Pharmaceutical Management Professional Quality Control Center was used to obtain information on the management of patients'self-provided infusion drugs in secondary and above general hospitals in 31 provinces(autonomous regions and municipalities directly under the central government)and the Xinjiang Production and Construction Corps of Chinese mainland from 2020 to 2022,and was summarized and calculated using data-processing software.Results The total number of secondary and above general hospitals included in the analysis from 2020 to 2022 is 4 786,5 063 and 6 041,respectively.In 2022,compared with 2020,the percentage of hospitals allowing patients to use self-provided infused drugs decreased from 55.08％to 48.54％,the percentage of hospitals that have established a system for managing patients' self-provided drugs increased from 81.54％to 98.09％,and the percentage of hospitalized patients' use of self-provided drugs that are all documented in their medical orders increased from 79.76％to 90.72％.The types of drugs that hospitals allow patients to use for self-provided infusion are mainly antitumor drugs,the places where self-provided infusion drugs are dispensed are mainly clinical departments(wards),and the main source of self-provided infusion drugs is self-pickup by patients.Conclusion Hospitals should establish a management system for patients'self-provided drugs,strengthen the information management of self-provided infusion drugs,and ensure drug supply and medication safety for patients.

OBJECTIVE To establish an in vitro simulated one compartment extravascular adminis-tration model with lanthanum nitrate as the test substance,and explore the differences between this model and the classic in vitro administration model in lanthanum nitrate induced HepG2 cell death.METHODS An in vitro administration device was designed based on compartment model theories which consisted of four functional chambers:the liquid storage chamber,mixing chamber,toxicant exposure chamber,and waste liquid receiving chamber.The four chambers were connected by peristaltic pump hoses.The peristaltic pumps were employed to ensure unidirectional and constant speed trans-mission of liquid between these chambers.According to the preset toxicokinetic parameters such as T1/2a and T1/2,an in vitro simulated one compartment extravascular administration model of lanthanum nitrate was constructed using the device.The content of lanthanum nitrate in the toxicant exposure chamber at different time points was measured using inductively coupled plasma mass spectrometry.The concentration-time curves of lanthanum nitrate were analyzed using PKsolver and GraphPad Prism 8.0 software.The constructed in vitro simulated one compartment extravascular administration model was evaluated by comparing the measured and theoretical values of toxicokinetic parameters.HepG2 cells were treated with lanthanum nitrate in the in vitro simulated one compartment extravascular administration model and classic in vitro administration model,respectively,and cell death was measured using the Hoechst 33342/propidium iodide staining method.RESULTS Within the Cmax range of 3.91-1 000.00 μmol·L-1,the measured concentration-time curves of lanthanum nitrate in the toxicant expo-sure chamber almost conformed with the corresponding calculated theoretical curves(the correlation coefficients were all>0.998 0).The measured values of toxicokinetic parameters,including Ke,T1/2,Ka,T1/2a,Tmax,Cmax,CL and AUC0-∞,were close to the corresponding theoretical values.The fitting coeffi-cients(R2)of the concentration-time curves for each experimental group were all>0.990 0,which was consistent with one compartment model for extravascular administration.In the simulated one compart-ment extravascular administration model,no significant death of HepG2 cells was observed in any lanthanum nitrate dose group.In the classic in vitro administration model,the cell death rate of the 0.500 mmol·L-1 lanthanum nitrate group was higher than that of the solvent control group,but no significant cell death was observed in the 0.119 mmol·L-1 group or 0.243 mmol·L-1 group.When Cmax or Cadministration was 0.500 mmol·L-1,classic in vitro administration induced a higher cell death rate than simulated one compart-ment extravascular administration.However,there was no statistically significant difference in lanthanum nitrate induced HepG2 cell death between the two administration models when the AUC was equal.CONCLUSION The device designed in this study can be used to in vitro simulate one compartment extravascular administration,making in vitro toxicity testing more similar to in vivo scenarios,and providing data for optimizing administration methods of in vitro toxicity testing.There are differences in lanthanum nitrate induced HepG2 cell death between simulated one compartment extravascular administration and classic in vitro administration,indicating that different in vitro exposure modes can affect toxicity.

Objective:To report five families of familial periodic paralysis.Methods:The clinical and genetic data of 5 families with familial periodic paralysis caused by SCN4A gene mutation who visited the First Affiliated Hospital of Henan University of Science and Technology from 2017 to 2022 were analyzed retrospectively.Results:The probands carried heterozygous missense mutations of SCN4A gene c. 3395G>A p. Arg1132Gln (Case 1), c. 2015G>A p. Arg672His (Case 2 and case 3), c. 2006G>A p. Arg669His (Case 4), c. 2111C>T p. Thr704Met (Case 5), respectively. Among them, four probands were diagnosed as hypokalemic periodic paralysis, one patient considered normal blood potassium periodic paralysis, and the treatment of acute attack was mainly potassium supplement. The main treatment for acute attacks was potassium supplementation, which was administered through intravenous infusion of potassium chloride combined with oral potassium chloride sustained-release tablets in the hospital. Simultaneously blood potassium levels and electrocardiogram monitoring were closely monitored. The main approach outside the hospital was to adopt a reasonable lifestyle and avoid triggering factors.Conclusions:The clinical manifestations caused by SCN4A gene mutation are diverse, and special attention should be paid in diagnosis, treatment and genetic counseling. Gene sequencing is an important molecular genetic diagnostic method.

Objective:To report five families of familial periodic paralysis.Methods:The clinical and genetic data of 5 families with familial periodic paralysis caused by SCN4A gene mutation who visited the First Affiliated Hospital of Henan University of Science and Technology from 2017 to 2022 were analyzed retrospectively.Results:The probands carried heterozygous missense mutations of SCN4A gene c. 3395G>A p. Arg1132Gln (Case 1), c. 2015G>A p. Arg672His (Case 2 and case 3), c. 2006G>A p. Arg669His (Case 4), c. 2111C>T p. Thr704Met (Case 5), respectively. Among them, four probands were diagnosed as hypokalemic periodic paralysis, one patient considered normal blood potassium periodic paralysis, and the treatment of acute attack was mainly potassium supplement. The main treatment for acute attacks was potassium supplementation, which was administered through intravenous infusion of potassium chloride combined with oral potassium chloride sustained-release tablets in the hospital. Simultaneously blood potassium levels and electrocardiogram monitoring were closely monitored. The main approach outside the hospital was to adopt a reasonable lifestyle and avoid triggering factors.Conclusions:The clinical manifestations caused by SCN4A gene mutation are diverse, and special attention should be paid in diagnosis, treatment and genetic counseling. Gene sequencing is an important molecular genetic diagnostic method.

OBJECTIVES: Patients with classical type 1 diabetes mellitus (T1DM) require lifelong dependence on exogenous insulin therapy due to pancreatic beta-cell destruction and absolute insulin deficiency. T1DM accounts for about 90% of children with diabetes in China, with a rapid increase in incidence and a younger-age trend. Epidemiological studies have shown that the overall glycated haemoglobin (HbA1c) and compliance rate are low in Chinese children with T1DM. Optimal glucose control is the key for diabetes treatment, and maintaining blood glucose within the target range can prevent or delay chronic vascular complications in patients with T1DM. Therefore, this study aims to investigate the glycemic control of children with T1DM from Hunan and Henan Province with flash glucose monitoring system (FGMS), and to explore factors associated with glycemic variability. METHODS: A total of 215 children with T1DM under 14 years old were enrolled continuously in 16 hospitals from August 2017 to August 2020. All subjects wore a FGMS device to collect glucose data. Correlation of HbA1c, duration of diabetes, or glucose scan rates with glycemic variability was analyzed. Glucose variability was compared according to the duration of diabetes, HbA1c, glucose scan rates and insulin schema. RESULTS: HbA1c and duration of diabetes were positively correlated with mean blood glucose, standard deviation of glucose, mean amplitude of glucose excursions (MAGE), and coefficient of variation (CV) of glucose (all P<0.01). The glucose scan rates during FGMS wearing was significantly positively correlated with time in range (TIR) (P=0.001) and negatively correlated with MAGE and mean duration of hypoglycemia (all P<0.01). Children with duration ≤1 year had lower time below range (TBR) and MAGE when compared with those with duration >1 year (all P<0.05). TIR and TBR in patients with HbA1c ≤7.5% were higher (TIR: 65% vs 45%, TBR: 5% vs 4%, P<0.05), MAGE was lower (7.0 mmol/L vs 9.4 mmol/L, P<0.001) than those in HbA1c >7.5% group. Compared to the multiple daily insulin injections group, TIR was higher (60% vs 52%, P=0.006), MAGE was lower (P=0.006) in the continuous subcutaneous insulin infusion group. HbA1c was lower in the high scan rates (≥14 times/d) group (7.4% vs 8.0%, P=0.046), TIR was significantly higher (58% vs 47%, P<0.001), and MAGE was lower (P<0.001) than those in the low scan rate (<14 times/d) group. CONCLUSIONS The overall glycemic control of T1DM patients under 14 years old in Hunan and Henan Province is under a high risk of hypoglycemia and great glycemic variability. Shorter duration of diabetes, targeted HbA1c, higher glucose scan rates, and CSII are associated with less glycemic variability.
Adolescent ; Blood Glucose ; Blood Glucose Self-Monitoring ; Child ; Diabetes Mellitus, Type 1/drug therapy* ; Glucose ; Glycated Hemoglobin A/analysis* ; Humans ; Hypoglycemia/prevention & control* ; Hypoglycemic Agents/therapeutic use* ; Insulin/therapeutic use*

The impairment of islets β cell by autoimmune response is an important cause of type 1 diabetes mellitus (T1DM). Some monogenic autoimmune syndromes could induce T1DM in difference chance, which are important disease models to deeply understand autoimmunity and T1DM. This article reviews the diagnosis, treatment and genetic detection of eight known single gene autoimmune syndromes associated with T1DM, arming to expand the diagnosis and treatment of T1DM.