The aim of this study was to investigate the improvement effect of Wenpi Pills(WPP) on non-alcoholic fatty liver disease(NAFLD). The experiment was divided into two parts, using C57BL/6 mouse models induced by a high-fat diet(HFD) and a methionine and choline deficiency diet(MCD). The HFD-induced experiment lasted for 16 weeks, while the MCD-induced experiment lasted for 6 weeks. Mice in both parts were divided into four groups: control group, model group, low-dose WPP group(3.875 g·kg~(-1), WPP＿L), and high-dose WPP group(15.5 g·kg~(-1), WPP＿H). After sample collection from the HFD-induced mice, lipid content in the serum and liver, liver function indexes in the serum, and hepatic pathology were examined. Real-time fluorescent quantitative reverse transcription PCR(qRT-PCR) was used to detect the expression of lipid-related genes. After sample collection from the MCD-induced mice, serum liver function indexes and inflammatory factors were measured, and hepatic pathology and lipid changes were analyzed by hematoxylin-eosin(HE) staining and widely targeted lipidomic profiling, respectively. The results from the HFD-induced experiment showed that, compared with the HFD group, WPP administration significantly reduced the levels of aspartate aminotransferase(AST), alanine aminotransferase(ALT), triglyceride(TG), and total cholesterol(TC) in the serum, with the WPP＿H group showing the most significant improvement. HE staining results indicated that, compared with the HFD group, WPP treatment improved the morphology of white adipocytes, reducing their size, and alleviated hepatic steatosis and lipid droplet accumulation. The qRT-PCR results suggested that WPP might increase the mRNA expression of liver cholesterol-converting genes, such as liver X receptor α(LXRα) and cytochrome P450 family 27 subfamily A member 1(CYP27A1), as well as lipid consumption genes like peroxisome proliferator-activated receptor α(PPARα) and adenosine mono-phosphate-activated protein kinase(AMPK). Meanwhile, WPP decreased the mRNA expression of lipid synthesis genes, including fatty acid synthetase(FAS), stearoyl-CoA desaturase 1(SCD1), and sterol regulatory element-binding protein 1c(SREBP-1c), thereby reducing liver lipid accumulation. The results from the MCD-induced experiment showed that, compared with the MCD group, WPP administration reduced the levels of ALT, AST, and inflammatory factors in the serum, thereby alleviating liver injury and the inflammatory response. HE staining of liver tissue indicated that WPP effectively improved hepatic steatosis. Non-targeted lipidomics analysis showed that WPP improved lipid metabolism disorders in the liver, mainly by affecting the metabolism of TG and cholesterol esters. In conclusion, WPP can improve hepatic lipid accumulation in NAFLD mice induced by both HFD and MCD. This beneficial effect is primarily achieved by alleviating liver injury and inflammation, as well as regulating lipid metabolism.
Animals ; Non-alcoholic Fatty Liver Disease/genetics* ; Lipid Metabolism/drug effects* ; Mice ; Mice, Inbred C57BL ; Drugs, Chinese Herbal/administration & dosage* ; Male ; Diet, High-Fat/adverse effects* ; Liver/drug effects* ; Humans ; Disease Models, Animal ; Methionine

Objective To observe the clinical efficacy of multi-target repetitive transcranial magnetic stimulation on freezing of gait in Parkinson's disease. Methods A total of 45 Parkinson's disease patients with freezing of gait in our hospital from January 2023 to January 2024 were selected and randomly divided into primary motor cortex(M1) treatment group (M1 group),dorsolateral prefrontal cortex (DLPFC) group (D group),and M1+DLPFC group (MD group),with 15 cases in each group. The stimulation site of patients in M1 group was bilateral M1 region lower limb innervation region,the stimulation site of patients in D group was bilateral DLPFC,and the left M1 region and DLPFC region of patients in MD group were stimulated on alternate days. The efficacy of Parkinson's disease patients with freezing of gait and the changes of mood scores were compared among the groups. Results One patient in D group and one in MD group were lost to follow-up,and 43 patients were eventually included. The freezing of gait questionnaire (FOGQ) scores,timed up and go test (TUGT) total time,modified standing-start 180° turn test (SS-180) time,unified Parkinson's disease rating scale part Ⅲ(UPDRS Ⅲ) scores,Hamilton depression scale (HAMD) scores and Hamilton anxiety scale (HAMA) scores of patients after treatment were improved compared with those before treatment in all three groups (P<0.05),and the improvement effect of MD group was significantly better than those of M1 group and D group (P<0.05). Conclusion High-frequency repetitive transcranial magnetic stimulation targeting bilateral M1 region and DLPFC region can improve freezing of gait,walking ability,and motor function,and alleviate symptoms of depression and anxiety of Parkinson's disease patients.

Objective:To investigate the impacts of the radiosensitivity of cell lines on a microdosimetric kinetic model (MKM) used in carbon-ion radiotherapy.Methods:The saturation-corrected specific energy ( ) of monoenergetic carbon ions was calculated using the Kiefer-Chatterjee (K-C) track structure model. Correction curve f(LET) was derived from experimental data on relative biological effectiveness (RBE) (RBE DSB-LET) defined based on the double-strand DNA break of the Chinese hamster ovary (CHO) and Fibroblast cell lines irradiated using carbon ions with varying linear energy transfer (LET) values. Then, based on the MKM, the D10-LET curves, as well as α and β databases, of the CHO and Fibroblast cell lines with varying radiosensitivity were determined. Results:Compared to the clinically applied MKM, the predicted D10 after correction while accounting for cell line radiosensitivity agreed better with experimental D10 values of the CHO and Fibroblast cell lines. Specifically, compared to experimental values in the literature, the D10 values calculated in the study and determined using the MKM showed mean squared errors (MSEs) of 0.04 and 0.71, for the CHO cell line and 0.35 and 0.55, respectively, for the Fibroblast cell line. For monoenergetic carbon ions with varying LET values, the calculated α and β values generally increased with cellular radiosensitivity. Conclusions:Incorporating cellular radiosensitivity into the MKM framework serves as a more specific method for RBE assessment while also providing a reference for advancing MKM applications and achieving the fine-scale calculations of RBE in carbon-ion radiotherapy.

Objective To explore the damage results and structural response laws of medical cabins in ships under explosion attack.Methods Firstly,the cabin structure was equivalently regarded as a T-shaped plate frame based on the explosion load theory,then four finite element models for the medical cabins were established with the dimensions(length ×width×height)of 2.8 m×2.6 m×2.3 m,3.2 m×3.2 m×2.4 m,4.2 m×3.2 m×2.5 m and 5.4 m×4.0 m×2.6 m.Secondly,an explosion damage model was constructed using ABAQUS simulation software,and explosion damage simulation was carried out with the explosion locating at the cabin center and the outside of the bulkhead and the explosion energy of 10 kg and 100 kg trinitrotoluene(TNT)equivalent.Finally,the 10 kg and 100 kg TNT explosion damage results were ananlyzed at the cabin center and the outside of the bulkhead.Results At the cabin center,10 kg TNT explosion resulted in local deformation and limited affected area of the large-sized cabin,while 100 kg TNT explosion lead to extensive affected ranges in the functional areas and severe deformation and damage in the small-sized cabin.At the outside of the bulkhead,10 kg TNT explosion gave rise to breaches in some areas of the small-sized cabin and local deformation of the large-sized cabin,while 100 kg TNT explosion caused large breaches in all the cabins.Conclusion The explosion load induces serious deformation and damage and complicated breaches in the cabin with small size and weak structural strength.The cabin with large size and thick bulkhead and stiffener behaves well in explosion resistance,while high equivalent explosions may bring about serious damage to its local structure.[Chinese Medical Equipment Journal,2025,46(1):27-32]

Objective:To investigate the impacts of the radiosensitivity of cell lines on a microdosimetric kinetic model (MKM) used in carbon-ion radiotherapy.Methods:The saturation-corrected specific energy ( ) of monoenergetic carbon ions was calculated using the Kiefer-Chatterjee (K-C) track structure model. Correction curve f(LET) was derived from experimental data on relative biological effectiveness (RBE) (RBE DSB-LET) defined based on the double-strand DNA break of the Chinese hamster ovary (CHO) and Fibroblast cell lines irradiated using carbon ions with varying linear energy transfer (LET) values. Then, based on the MKM, the D10-LET curves, as well as α and β databases, of the CHO and Fibroblast cell lines with varying radiosensitivity were determined. Results:Compared to the clinically applied MKM, the predicted D10 after correction while accounting for cell line radiosensitivity agreed better with experimental D10 values of the CHO and Fibroblast cell lines. Specifically, compared to experimental values in the literature, the D10 values calculated in the study and determined using the MKM showed mean squared errors (MSEs) of 0.04 and 0.71, for the CHO cell line and 0.35 and 0.55, respectively, for the Fibroblast cell line. For monoenergetic carbon ions with varying LET values, the calculated α and β values generally increased with cellular radiosensitivity. Conclusions:Incorporating cellular radiosensitivity into the MKM framework serves as a more specific method for RBE assessment while also providing a reference for advancing MKM applications and achieving the fine-scale calculations of RBE in carbon-ion radiotherapy.

Objective To explore the damage results and structural response laws of medical cabins in ships under explosion attack.Methods Firstly,the cabin structure was equivalently regarded as a T-shaped plate frame based on the explosion load theory,then four finite element models for the medical cabins were established with the dimensions(length ×width×height)of 2.8 m×2.6 m×2.3 m,3.2 m×3.2 m×2.4 m,4.2 m×3.2 m×2.5 m and 5.4 m×4.0 m×2.6 m.Secondly,an explosion damage model was constructed using ABAQUS simulation software,and explosion damage simulation was carried out with the explosion locating at the cabin center and the outside of the bulkhead and the explosion energy of 10 kg and 100 kg trinitrotoluene(TNT)equivalent.Finally,the 10 kg and 100 kg TNT explosion damage results were ananlyzed at the cabin center and the outside of the bulkhead.Results At the cabin center,10 kg TNT explosion resulted in local deformation and limited affected area of the large-sized cabin,while 100 kg TNT explosion lead to extensive affected ranges in the functional areas and severe deformation and damage in the small-sized cabin.At the outside of the bulkhead,10 kg TNT explosion gave rise to breaches in some areas of the small-sized cabin and local deformation of the large-sized cabin,while 100 kg TNT explosion caused large breaches in all the cabins.Conclusion The explosion load induces serious deformation and damage and complicated breaches in the cabin with small size and weak structural strength.The cabin with large size and thick bulkhead and stiffener behaves well in explosion resistance,while high equivalent explosions may bring about serious damage to its local structure.[Chinese Medical Equipment Journal,2025,46(1):27-32]

Objective To observe the clinical efficacy of multi-target repetitive transcranial magnetic stimulation on freezing of gait in Parkinson's disease. Methods A total of 45 Parkinson's disease patients with freezing of gait in our hospital from January 2023 to January 2024 were selected and randomly divided into primary motor cortex(M1) treatment group (M1 group),dorsolateral prefrontal cortex (DLPFC) group (D group),and M1+DLPFC group (MD group),with 15 cases in each group. The stimulation site of patients in M1 group was bilateral M1 region lower limb innervation region,the stimulation site of patients in D group was bilateral DLPFC,and the left M1 region and DLPFC region of patients in MD group were stimulated on alternate days. The efficacy of Parkinson's disease patients with freezing of gait and the changes of mood scores were compared among the groups. Results One patient in D group and one in MD group were lost to follow-up,and 43 patients were eventually included. The freezing of gait questionnaire (FOGQ) scores,timed up and go test (TUGT) total time,modified standing-start 180° turn test (SS-180) time,unified Parkinson's disease rating scale part Ⅲ(UPDRS Ⅲ) scores,Hamilton depression scale (HAMD) scores and Hamilton anxiety scale (HAMA) scores of patients after treatment were improved compared with those before treatment in all three groups (P<0.05),and the improvement effect of MD group was significantly better than those of M1 group and D group (P<0.05). Conclusion High-frequency repetitive transcranial magnetic stimulation targeting bilateral M1 region and DLPFC region can improve freezing of gait,walking ability,and motor function,and alleviate symptoms of depression and anxiety of Parkinson's disease patients.

As artificial intelligence technology rapidly advances, its deployment within the medical sector presents substantial ethical challenges. Consequently, it becomes crucial to create a standardized, transparent, and secure framework for processing medical data. This includes setting the ethical boundaries for medical artificial intelligence and safeguarding both patient rights and data integrity. This consensus governs every facet of medical data handling through artificial intelligence, encompassing data gathering, processing, storage, transmission, utilization, and sharing. Its purpose is to ensure the management of medical data adheres to ethical standards and legal requirements, while safeguarding patient privacy and data security. Concurrently, the principles of compliance with the law, patient privacy respect, patient interest protection, and safety and reliability are underscored. Key issues such as informed consent, data usage, intellectual property protection, conflict of interest, and benefit sharing are examined in depth. The enactment of this expert consensus is intended to foster the profound integration and sustainable advancement of artificial intelligence within the medical domain, while simultaneously ensuring that artificial intelligence adheres strictly to the relevant ethical norms and legal frameworks during the processing of medical data.
Artificial Intelligence/legislation & jurisprudence* ; Humans ; Consensus ; Computer Security/standards* ; Confidentiality/ethics* ; Informed Consent/ethics*

Objective To evaluate the blast damage of the medical cabin in the coast guard ship based on the neural network prediction model.Methods Firstly,a cabin finite element model was established with the typical medical cabin in some coast guard ship as the subject;secondly,ABAQUS simulation software was used to construct a blast damage simulation model and perform blast damage numerical simulation;thirdly,three neural network prediction models respectively based on Levenberg-Marquardt,Bayesian regularization and conjugate gradient algorithms were formed with the sample data from the simulation results and MATLAB software;finally,visualization over the prediction results of the neural network prediction models was carried out in terms of three blast conditions at the interior,bulkhead and near field of the cabin,and the blast damage to the cabin was analyzed with reference to the simulation results.Results Near the observation points the damage prediction results by the models were similar to those by the simulation.The blasts at the interior and bulkhead both resulted in obvious damages to the cabin framework,with serious effects and large damage areas;near-field blasts did not cause direct damage to the inter-nal framework of the cabin.Conclusion The neural network prediction model forecasts the blast damage to the medical carin in the coast guard ship,and references are provided for the structural design of the cabins in the coast guard ship.[Chinese Medical Equipment Journal,2024,45(12):14-18]

Objective To evaluate the blast damage of the medical cabin in the coast guard ship based on the neural network prediction model.Methods Firstly,a cabin finite element model was established with the typical medical cabin in some coast guard ship as the subject;secondly,ABAQUS simulation software was used to construct a blast damage simulation model and perform blast damage numerical simulation;thirdly,three neural network prediction models respectively based on Levenberg-Marquardt,Bayesian regularization and conjugate gradient algorithms were formed with the sample data from the simulation results and MATLAB software;finally,visualization over the prediction results of the neural network prediction models was carried out in terms of three blast conditions at the interior,bulkhead and near field of the cabin,and the blast damage to the cabin was analyzed with reference to the simulation results.Results Near the observation points the damage prediction results by the models were similar to those by the simulation.The blasts at the interior and bulkhead both resulted in obvious damages to the cabin framework,with serious effects and large damage areas;near-field blasts did not cause direct damage to the inter-nal framework of the cabin.Conclusion The neural network prediction model forecasts the blast damage to the medical carin in the coast guard ship,and references are provided for the structural design of the cabins in the coast guard ship.[Chinese Medical Equipment Journal,2024,45(12):14-18]