Objective:To analyze the influencing factors of low liver regeneration in patients with hilar cholangiocarcinoma (HCCA) after portal vein embolization (PVE).Method:Clinical data of 62 patients with HCCA undergoing PVE at Henan Provincial People's Hospital (People's Hospital of Zhengzhou University) from January 2019 to March 2024 were retrospectively analyzed, including 33 males and 29 females, aged (59.1±10.3) years. Patients were divided into two groups based on the median regeneration rate of remnant liver volume (28.6%) three weeks after PVE: low regeneration ( n=31, <28.6%) and high regeneration group ( n=31, ≥28.6%). The proportion of lymph node metastasis, history of alcohol consumption, liver fibrosis, biliary tract infection, alkaline phosphatase (ALP), and tumor necrosis factor-α (TNF-α) were compared between two groups. Multivariate logistic regression analysis was used to indentify the influencing factors of low liver regeneration in patients with HCCA after PVE surgery. Results:The proportion of lymph node metastasis, history of alcohol consumption, liver fibrosis, biliary tract infection, ALP, and level of TNF-α were higher in the low regeneration group than those in the high regeneration group (all P<0.05). Multivariate logistic regression analysis showed that patients with regional lymph node metastasis ( OR=2.561, 95% CI: 1.265-5.185), history of alcohol consumption ( OR=2.616, 95% CI: 1.321-5.181), liver fibrosis ( OR=2.351, 95% CI: 1.265-4.369), biliary tract infection ( OR=2.461, 95% CI: 1.226-4.940), elevated level of ALP ( OR=2.687, 95% CI: 1.351-5.344), and elevated level of TNF-α ( OR=2.781, 95% CI: 1.452-5.326) had an increased risk of low liver regeneration after PVE (all P<0.05). Conclusion:Regional lymph node metastasis, history of alcohol consumption, liver fibrosis, biliary tract infection, and elevated ALP and TNF-α are risk factors for low liver regeneration in patients with HCCA after PVE surgery, which should be noted in clinical practice.

OBJECTIVE：To study the inhibitor y effects of cajanonic acid A on 5 kinds of cytochrome P 450（CYP）enzyme，in human liver microsomes in vitro . METHODS ：By Cocktail probe substrate method ，50.0，15.0，5.0，1.5，0.5，0.15，0.05 μmol/L cajanonic acid A were added into liver microsomes ， and incubated with mixed probe substrates [including phenacetin ， dextromethorphan，omeprazole，testosterone and toluenesulfonbutylurea （probe substrates of CYP 1A2，CYP2D6，CYP2C19， CYP3A4，CYP2C9，respectively）]. On the basis of setting up blank group and positive control group [ α-naphthalene brass ， quinidine，（+）-N-3-benzyl vanillin ，ketoconazole and sulfabendazole （specific inhibitors of CYP 1A2，CYP2D6，CYP2C19， CYP3A4，CYP2C9，respectively）]，using puerarin as internal standard ，UPLC-MS/MS method was adopted to determine the contents of corresponding metabolites （acetaminophen， dextrophane， 5-hydroxy omeprazole ， 6 β-hydroxytestosterone， hydroxytolbutamide）. The determination was performed on ACQUITY UPLC ® BEH C 18 column，with mobile phase consisted of 0.01％ formic acid aqueous solution- 0.01％ acetonitrile formic acid （gradient elution ）at the flow rate of 0.4 mL/min. The column temperature was 40 ℃，and the sample size was 2 μL. An electrospray ionization source was used to conduct positive and negative ion scanning in the multiple reaction monitoring mode. The data acquisition range was m/z 100-1 200，the collision gas was argon ， the atomized gas was nitrogen ，the gas flow rate of the cone hole was 50 L/h，the desorption gas flow rate was 800 L/h，the capillary voltage under positive and negative mode was 2.0， 1.5 kV，and the ion source temperature was 120 ℃，110 ℃， respectively. The desolvent temperature were 400 ℃ and 450 ℃ ， respectively. Non linear regression analysis was performed by using Graphpad Prism 5.0 software and IC 50 wascalculated. RESULTS ：The linear ranges of above metabolifes were 0.26-8.35，0.36-34.56，0.10-3.09, 3.67-117.37，0.15-4.88 μmol/L（R2＞0.99）. The limits of quantitation were 0.26，0.36， 0.10，3.67，0.15 μmol/L，respectively. The IC 50 values of specific inhibitors in positive control group to CYP 1A2，CYP2D6， CYP2C19，CYP3A4 and CYP 2C9 in human liver microsomes were all within the acceptable range reported in the literature. The IC50 values of cajanonic acid A to CYP 1A2，CYP2D6 and CYP 3A4 in human liver microsomes were all more than 50 μmol/L，and the IC 50 values of CYP 2C9 and CYP 2C19 were 4.94 and 18.00 μmol/L，respectively. CONCLUSIONS ：Cajanonic acid A has no inhibitory effect on CYP 1A2，CYP2D6 and CYP 3A4，but has a certain inhibitory effect on CYP 2C9 and CYP 2C19.

OBJECTIVE：To establish the method for determining protein binding rate of dipeptidyl peptidase- 4 inhibitor LGT- 6 in different species of plasma ，and to compare their difference. METHODS ：By equilibrium dialysis ，LGT-6（3，30，300，3 000 nmol/L）was equilibrated in rat ，monkey and human plasma （i. e. internal dialysis solution ）for 48 h，using phosphate buffer as the external dialysis solution. The concentration of LGT- 6 in internal and external dialysis solution was determined by UPLC-MS/MS using tolbutamide as internal standard ，and the plasma protein binding rate was calculated. The determination was performed on ACQUITY UPLC HSS T 3 column with water （containing 0.01％ formic acid ）-acetonitrile（containing 0.01％ formic acid ）as mobile phase at the flow rate of 0.6 mL/min. The column temperature was 40 ℃，and the sample size was 2 μL. The ion source was electrospray ion source ，and the multiple ion monitoring mode was used to carry out positive ionization scanning. The ion pairs for quantitative analysis were m/z 487.0→434.3（LGT-6），m/z 271.1→172.0（internal standard ），respectively. RESULTS ：At the concentrations of 3，30，300，and 3 000 nmol/L，the protein binding rates of LGT- 6 in rat plasma were （96.25±0.97）％，（84.16± 1.24）％，（78.25±0.61）％，（66.63±0.95）％；the protein protein binding rates in monkey plasma were （98.54±0.58）％，（87.27± 1.01）％，（79.35±0.86）％，（66.69±0.54）％；the protein binding rates in human plasma were （99.40±1.03）％，（84.48± 1.15）％，（77.62±0.77）％，（66.93±0.48）％. At the same concentration ，the protein binding rates of LGT- 6 in rat ，monkey and human plasma had no significant difference （P＞0.05）. In the same species of plasma ，there were significant differences in the plasma protein binding rates of different concentration of LGT-6 among those groups （P＜0.05），and it decreased with 才〔2016〕4015） the increase of drug concentration. CONCLUSIONS ： The method for the determination of plasma protein binding rate of LGT-6 is successfully established. The data revealed that the protein binding rate of LGT- 6 is concentration-dependent ， there was no obvious spec ies difference on protein binding rates of LGT- 6 in rat ，monkey and human plasma under the same concentration.

OBJECTIVE：To establish the metho d for the concentration det ermination of foretinib derivative LWK- 126 in liver microsomes，and to study its metabolism stability in liver microsomes of rats ，Beagle dogs and human. METHODS ：In the in vitro incubation system of liver microsomes ，LWK-126 was dissolved in liver microsomal incubation systems of rats ，Beagle dog and human initiated by reduced nicotinamide adenine dinucleotide phosphate solution. After incubation in water at 37 ℃ for 0，5，10，20， 30 and 60 min，the reaction was terminated with acetonitrile containing internal standard （1 μg/mL tolbutamide）. UPLC-MS/MS method was applied to determine the concentration of LWK- 126 in the incubation systems. The determination was performed on Waters BEH C 18 column with mobile phase consisted of water （containing 0.1％ formic acid ）-acetonitrile（containing 0.1％ formic acid）by gradient elution at the flow rate of 0.4 mL/min. The column temperature was 30 ℃，and the sample size was 2 μL. The mass spectral analysis was performed in a positive electrospray ionization mode ，and the full MS experiment was run with the selective reaction monitoring mode with a scanning range of m/z 50→1 200. Taking the concentration of LWK- 126 at 0 min as reference，the remaining percentage and the enzyme kinetic parameters were calculated. RESULTS ：The linear range of LWK- 126 was 0.05-15 μg/mL（R 2＝0.999 2）；the lower limit of quantification was 0.05 μg/mL，and the lowest detection limit was 0.01 μg/mL. The precision，accuracy，extraction recovery and matrix effect all met the analysis requirements of biological samples. The remaining percentage of LWK- 126 in liver microsomes of human ，rats and Beagle dogs for 60 min were （33.17±4.52）％，（3.14± 6.73）％，（1.38±5.85）％；t1/2 of them were 33.15，11.76，5.62 min；the clearance rates were 38.45，118.81，245.76 μL（/ min·mg）， respectively. CONCLUSIONS ：The method for the content ； determination of LWK- 126 in liver microsomes is established successfully. The order of metabolic stability of LWK- 126 in 〔2016〕4015） liver microsomes of different species is human ＞rats＞Beagle dogs.

OBJECTIVE：To i nvestigate the metabolism stabilities of novel hypoglycemic compound LSM- 13 in rat liver microsomes，and to analyze the possible metabolites. METHODS ：LSM-13 was dissolved in rat liver microsome incubation system initiated by reduced nicotinamide adenine dinucleotide phosphate ，and was incubated in water at 37 ℃. The reaction was terminated with acetonitrile at 0，5，10，15，30，45 and 60 min，respectively. Using indomethacin as internal standard ，the concentration of LSM-13 in incubation system was determined by HPLC. The residual percentage and enzyme kinetic parameters of LSM- 13 were calculated at different incubation time points with the concentration of LSM- 13 incubated for 0 min as reference. UPLC-Q-TOF/MS was used to analyze and speculate the metabolites of LSM- 13 in rat liver microsomes. RESULTS ：After 60 min incubation ，the remaining percentage of LSM- 13 was（56.07±0.95）％，the half-life was 42.78 min，and the intrinsic clearance was 0.032 4 mL/（min·mg）. Compared with total ion flow diagram of rat liver microsome blank samples ，three chromatographic peaks were added in the samples incubated for 60 min；the corresponding molecular ion peaks were m/z 505.133 8，417.102 4，293.111 7 [M+H]+；the possible metabolites may be dehydrogenation ，O-debentylation and hydrolysis products of LSM- 13. CONCLUSIONS ： The compound LSM- 13 has moderate stability in rat liver microsomes ，and may undergo dehydrogenation ，O-debentylation and hydrolysis.

To investigate the computed tomography (CT) characteristics and differential diagnosis of high altitude pulmonary edema (HAPE) and COVID-19, CT findings of 52 cases of HAPE confirmed in Medical Station of Sanshili Barracks, PLA 950 Hospital from May 1, 2020 to May 30, 2020 were collected retrospectively. The size, number, location, distribution, density and morphology of the pulmonary lesions of these CT data were analyzed and compared with some already existed COVID-19 CT images which come from two files, "Radiological diagnosis of COVID-19: expert recommendation from the Chinese Society of Radiology (First edition)" and "A rapid advice guideline for the diagnosis and treatment of 2019 novel corona-virus (2019-nCoV) infected pneumonia (standard version)". The simple or multiple ground-glass opacity (GGO) lesions are located both in the HAPE and COVID-19 at the early stage, but only the thickening of interlobular septa, called "crazy paving pattern" belongs to COVID-19. At the next period, some increased cloudy shadows are located in HAPE, while lesions of COVID-19 are more likely to develop parallel to the direction of the pleura, and some of the lesions show the bronchial inflation. At the most serious stage, both the shadows in HAPE and COVID-19 become white, but the lesions of HAPE in the right lung are more serious than that of left lung. In summary, some cloudy shadows are the feature of HAPE CT image, and "crazy paving pattern" and "pleural parallel sign" belong to the COVID-19 CT, which can be used for differential diagnosis.
Altitude ; COVID-19/diagnostic imaging* ; China ; Diagnosis, Differential ; Humans ; Lung/diagnostic imaging* ; Pulmonary Edema/diagnostic imaging* ; Retrospective Studies ; Tomography, X-Ray Computed

Objective: To compare the clinical effects between laparoscopic cholecystectomy and choledochotomy versus traditional open cholecystectomy plus choledochotomy. Methods: One hundred and sixty-eight elderly patients with gallbladder and choledocholithiasis were divided into a laparoscopy group(n=75, receiving laparoscopic cholecystectomy and choledochotomy)and an open abdominal group(n=93, undergoing traditional open cholecystectomy and common bile duct exploration). The surgical incision length, operation time, intraoperative blood loss, anal exhaust time, hospital stay and postoperative complications were compared between the two groups. Results: The surgical incision length, operation time, intraoperative blood loss, anal exhaust time, hospital stay were lower in the laparoscopic group than in the open abdominal group(P<0.05). The incidence of postoperative complications was lower in the laparoscopic group than in the open group(P<0.05). Conclusions Laparoscopic cholecystectomy and choledochotomy can obviously improve the clinical efficacy and reduce complications in elderly patients with gallbladder and choledocholithiasis, and it is worthy of clinical application.

OBJECTIVE： To compare plasma protein binding rate of cajanonic acid A with different species of plasma. METHODS：Using UPLC-MS/MS as the detection means. Plasma protein binding rate of low， medium and high concentrations of cajanonic acid A （2.5， 5， 20 μg/mL） with rats， rabbits and human plasma were determined by ultrafiltration method. The chromatographic conditions included that Waters BEH C18 as chromatographic column， WatersVanGuard BEH C18 as guard column， mobile phase consisted of ultrapure water solution containing 0.01％ formic acid （solvent A） and acetonitrile solution of 0.01％ formic acid （solvent B） gradient elution， at the flow rate of 0.15 mL/min， column temperature of 30 ℃， sample size of 2 μL. Mass spectrum condition included that ESI， negative ion mode acquisition， capillary voltage of 1.5 kV， cone voltage of 30 V， ion source temperature of 100 ℃， desolvent gas temperature of 400 ℃， cone gas flow of 50 L/h， desolvent gas flow of 800 L/h， scanning range of m/z 50→1 200. RESULTS： At the concentration of 2.5， 5 and 20 μg/mL， the plasma protein binding rates of cajanonic acid A were （75.63±0.90）％， （98.30±0.03）％ and （99.42±0.01）％ in the rats plasma； （79.61±1.08）％， （98.48±0.10）％ and （99.42±0.03）％ in rabbits plasma （n＝3）； （76.74±1.22）％， （97.99±0.11）％ and （99.37±0.01）％ in human plasma （n＝3）. At the concentration of 2.5 μg/mL， plasma protein binding rates of cajanonic acid A in plasma of rats and human were significantly lower than that in plasma of rabbits （P＜0.05）. CONCLUSIONS： The plasma protein binding rate of 5，20 μg/mL cajanonic acid A with rats， rabbits and human plasma are higher than that of 2.5 μg/mL cajanonic acid A. There is significant difference in plasma protein binding rate of 2.5 μg/mL cajanonic acid A with different species of plasma，and there is no significant difference in plasma protein binding rate of 5， 20 μg/mL cajanonic acid A with different species of plasma.

OBJECTIVE： To establish a determination method for the concentration of cajanonic acid A （CAA） in liver microsome incubation system， and to compare the metabolism characteristics of it in different species of liver microsomes. METHODS： CAA was dissolved in liver microsome incubation system of rat， Beagle dog and human initiated by reduced nicotinamide adenine dinucleotide phosphate （NADPH）， and was incubated in water at 37 ℃. The reaction was terminated with acetonitrile at 0， 5， 10， 15， 30， 45 and 60 min， respectively. Using genistein as internal standard， the concentration of CAA in  different incubation systems was determined by UPLC-MS/MS. The determination was performed on Waters BEH C18 column with mobile phase consisted of water （containing 0.1％ formic acid）-acetonitrile （containing 0.1％ formic acid） （45 ∶ 55， V/V） at the flow rate of 0.25 mL/min. The column temperature was 30 ℃， and the sample size was 2 μL. The electrospray ionization source was used to the select reaction monitoring mode for negative ion scanning. The ion pairs for quantitative analysis were m/z 353.14→309.11 （CAA）， m/z 269.86→224.11 （internal standard） respectively. The residual percentage and enzymatic kinetic parameters of CAA in different incubation systems were calculated according to the mass concentration of CAA at 0 min. RESULTS： The linear range of CAA was 0.05-20 μg/mL； the limit of quanti- tation was 0.05 μg/mL， and the lowest detection limit was 0.01 μg/mL. RSDs of intra-day and inter-day were lower than 10％； relative errors ranged －4.83％-8.94％； extraction method and matrix effect did not affect the determination of the substance to be measured. At 60 min of incubation， residual percentages of CAA in rat， Beagle dog and human liver microsomes were（62.79±9.99）％，（64.07±11.59）％，（96.66±5.71）％， respectively. The half-life period （72.19， 68.61 min） of CAA in rat and Beagle dog liver microsomes were significantly shorter than human liver microsome （364.74 min）. The clearance rates [0.019 2， 0.020 2 mL/（min·mg）] were significantly higher than human liver microsome [0.003 8 mL/（min·mg）] （P＜0.05）. CONCLUSIONS： Established UPLC-MS/MS method is simple， rapid， specific and sensitive， and can be used for the determination of CAA concentration in liver microsome incubation system and the study of metabolism stability in vitro. The stability of CAA metabolism in rat and Beagle dog liver microsomes are poorer than human liver microsome.

Objective To evaluate the effects of selective brain hypothermia on the expression of miR-484 during cerebral ischemia-reperfusion ( I/R) in rats. Methods A total of 120 clean-grade healthy male Sprague-Dawley rats, aged 8-10 weeks, weighing 250-300 g, were divided into 4 groups ( n=30 each) using a random number table method: sham operation group ( group S) , cerebral I/R group ( group I/R) , hypothermia group ( group H) and normothermia group ( group N) . Blood vessels were only separa-ted and ligated without blockade in group S. In the other three groups, cerebral I/R was induced by inser-ting a nylon thread with rounded tip into the right internal carotid artery, and the middle cerebral artery was occluded for 2 h followed by reperfusion. In group H, 4℃ normal saline was infused for 15 min at a rate of 80 ml·kg-1 ·h-1 through the internal carotid artery immediately after removing the nylon thread. In group N, 37 ℃ normal saline was infused in the same way. Neurological deficit scores were evaluated at 6, 24 and 48 h after reperfusion. Animals were then sacrificed, the cerebral cortex of the ischemic penumbra was removed for determination of nerve cell apoptosis ( by TUNEL method) , expression of mitochondrial fission protein 1 ( Fis1) ( by Western blot) and expression of miR-484 ( quantitative real-time polymerase chain re-action) . The apoptotic rate was calculated. Results Compared with group S, the neurological deficit score and apoptotic rate of nerve cells were significantly increased, and the expression of Fis1 was up-regulated at each time point in the other three groups, the expression of miR-484 was significantly down-regulated in I/R and N groups, and the expression of miR-484 was significantly up-regulated in group H ( P＜0. 05 or 0. 01) . Compared with group I/R and group N, the neurological deficit score and apoptotic rate of nerve cells were significantly decreased, and the expression of Fis1 was down-regulated, and the expression of miR-484 was up-regulated at each time point in group H ( P＜0. 05 or 0. 01) . Conclusion The mechanism by which se-lective cerebral hypothermia attenuates cerebral I/R injury is associated with up-regulating miR-484 expres-sion and thus down-regulating Fis1 expression in rats.