Objective:To investigate the therapeutic efficacy and disruptive effects of Meropenem（MEM）-loaded microbubbles（MBs）combined with ultrasound targeted microbubble destruction（UTMD）technology on Escherichia coli and its biofilm.Methods:MEM-MBs were prepared using the thin-film hydration method，and their characterization was assessed using a Zeta potential analyzer，with morphological observations conducted under an optical microscope. An in vitro biofilm model of periprosthetic joint infection（PJI）caused by Escherichia coli was constructed，and the morphology of the biofilm and the distribution of MEM-MBs in the bacterial biofilm were observed under a laser confocal microscope after staining the biofilm with SYTO59 staining and DIL staining for Microbubbles. The biofilm morphology and the distribution of MEM-MBs in bacterial biofilm were observed under laser confocal microscope. The biofilms were randomly divided into 5 groups using a random number table：control，Meropenem（MEM），MEM-MBs，UTMD，and MEM-MBs+UTMD，with 12 samples per group. After applying the respective interventions，scanning electron microscopy（SEM）and laser scanning confocal microscopy（LSCM）were employed to observe the effects on the morphology and structure of Escherichia coli and its biofilm. Crystal violet staining was utilized to determine and compare the biofilm density among groups using a microplate reader. LSCM was also used to observe the biofilm thickness，while both LSCM and spread plate counting were employed to assess bacterial viability differences across groups.Results:①MEM-MBs meeting the experimental requirements were successfully constructed.②A dense Escherichia coli biofilm visible under both the naked eye and LSCM was established，with a thickness of（10.61 ± 0.17）μm and a proportion of dead bacteria within the biofilm of（16.8 ± 0.8）%.③MEM-MBs were observed to penetrate into all layers of the biofilm using LSCM.④The results of crystal violet staining showed a decreasing trend in the biofilm density of the control group，the MEM group，the MEM-MBs group，the UTMD group，and the MEM-MBs+UTMD group. There was no significant difference between the MEM group and the MEM-MBs group（ P＞0.05），while there was a significant difference in biofilm density between the other groups，as revealed by pairwise comparison（all P＜0.05）.⑤UTMD technique and MEM-MBs+UTMD could significantly disrupt the biofilm of Escherichia coli. LSCM results showed that，compared to the control group，the thickness of the biofilm was reduced in all other groups，with only the UTMD group and the MEM-MBs+UTMD group showing an increase in porosity（both P＜0.05）. In comparison with the MEM group and the MEM-MBs group，the UTMD group showed an increase in porosity，while the MEM-MBs+UTMD group had a decrease in biofilm thickness and an increase in porosity（both P＜0.05）. Additionally，compared to the UTMD group，the MEM-MBs+UTMD group had a decrease in biofilm thickness and an increase in porosity（both P＜0.05），based on laser confocal microscopy results.⑥The results of the plate counting and LSCM showed that，compared with the control group，clump counts decreased，and the proportion of dead cells increased in the MEM group，the MEM-MBs group，and the MEM-MBs+UTMD group（all P＜0.05）. Compared with MEM group and MEM-MBs group，the clump counts of UTMD group increased，the proportion of dead cells decreased（all P＜0.05）；the clump counts of MEM-MBs+UTMD group decreased，and the proportion of dead cells increased（all P＜0.05）.Compared with UTMD group（all P＜0.05），the clump counts of MEM-MBs+UTMD group decreased，while the proportion of dead cells increased（all P＜0.05）.⑦The results of scanning electron microscopy revealed that the network structure of Escherichia coli was completely destroyed in the MEM-MBs+UTMD group. Conclusions:UTMD technology combined with MEM-MBs exerts a significant disruptive effect on the morphology and structure of Escherichia coli biofilm and significantly enhances bactericidal efficacy.

Objective:To investigate the therapeutic efficacy and disruptive effects of Meropenem（MEM）-loaded microbubbles（MBs）combined with ultrasound targeted microbubble destruction（UTMD）technology on Escherichia coli and its biofilm.Methods:MEM-MBs were prepared using the thin-film hydration method，and their characterization was assessed using a Zeta potential analyzer，with morphological observations conducted under an optical microscope. An in vitro biofilm model of periprosthetic joint infection（PJI）caused by Escherichia coli was constructed，and the morphology of the biofilm and the distribution of MEM-MBs in the bacterial biofilm were observed under a laser confocal microscope after staining the biofilm with SYTO59 staining and DIL staining for Microbubbles. The biofilm morphology and the distribution of MEM-MBs in bacterial biofilm were observed under laser confocal microscope. The biofilms were randomly divided into 5 groups using a random number table：control，Meropenem（MEM），MEM-MBs，UTMD，and MEM-MBs+UTMD，with 12 samples per group. After applying the respective interventions，scanning electron microscopy（SEM）and laser scanning confocal microscopy（LSCM）were employed to observe the effects on the morphology and structure of Escherichia coli and its biofilm. Crystal violet staining was utilized to determine and compare the biofilm density among groups using a microplate reader. LSCM was also used to observe the biofilm thickness，while both LSCM and spread plate counting were employed to assess bacterial viability differences across groups.Results:①MEM-MBs meeting the experimental requirements were successfully constructed.②A dense Escherichia coli biofilm visible under both the naked eye and LSCM was established，with a thickness of（10.61 ± 0.17）μm and a proportion of dead bacteria within the biofilm of（16.8 ± 0.8）%.③MEM-MBs were observed to penetrate into all layers of the biofilm using LSCM.④The results of crystal violet staining showed a decreasing trend in the biofilm density of the control group，the MEM group，the MEM-MBs group，the UTMD group，and the MEM-MBs+UTMD group. There was no significant difference between the MEM group and the MEM-MBs group（ P＞0.05），while there was a significant difference in biofilm density between the other groups，as revealed by pairwise comparison（all P＜0.05）.⑤UTMD technique and MEM-MBs+UTMD could significantly disrupt the biofilm of Escherichia coli. LSCM results showed that，compared to the control group，the thickness of the biofilm was reduced in all other groups，with only the UTMD group and the MEM-MBs+UTMD group showing an increase in porosity（both P＜0.05）. In comparison with the MEM group and the MEM-MBs group，the UTMD group showed an increase in porosity，while the MEM-MBs+UTMD group had a decrease in biofilm thickness and an increase in porosity（both P＜0.05）. Additionally，compared to the UTMD group，the MEM-MBs+UTMD group had a decrease in biofilm thickness and an increase in porosity（both P＜0.05），based on laser confocal microscopy results.⑥The results of the plate counting and LSCM showed that，compared with the control group，clump counts decreased，and the proportion of dead cells increased in the MEM group，the MEM-MBs group，and the MEM-MBs+UTMD group（all P＜0.05）. Compared with MEM group and MEM-MBs group，the clump counts of UTMD group increased，the proportion of dead cells decreased（all P＜0.05）；the clump counts of MEM-MBs+UTMD group decreased，and the proportion of dead cells increased（all P＜0.05）.Compared with UTMD group（all P＜0.05），the clump counts of MEM-MBs+UTMD group decreased，while the proportion of dead cells increased（all P＜0.05）.⑦The results of scanning electron microscopy revealed that the network structure of Escherichia coli was completely destroyed in the MEM-MBs+UTMD group. Conclusions:UTMD technology combined with MEM-MBs exerts a significant disruptive effect on the morphology and structure of Escherichia coli biofilm and significantly enhances bactericidal efficacy.

Objective To investigate the effect of left bundle branch area pacing(LBBaP)on new-onset atrial fibrillation(NOAF)and atrial high rate episodes(AHREs)in patients with atrioventricular block(AVB).Methods Eighty-four patients with Ⅲ°AVB for pacemaker implantaion were divided into the LBBaP group(n=42)and the RVSP group(n=42)based on the site of the ventricular leads.The two groupswere compared in terms of the pre-and post-operative QRSd,ventricular pacing parameters,complications,incidence of stroke,NOAF and AHREs.Results(1)The incidence of postoperative NOAF and AHREs in the LBBaP group was significantly lower compared with RVSP group(P<0.05).(2)The p-QRSd in the LBBaP group was significantly shorter compared with RVSP group(P<0.05).(3)The two groups showed no significant differences in ventricular pacing parameters,incidence of complications and stroke events(P>0.05).Conclusion LBBaP is superior to right ventricular pacing in reducing the incidence of postoperative AHREs and NOAF in patients after implantation and improving the prognosis of patients.

Purpose: Patients with advanced biliary tract cancer (BTC) have a poor survival. We aim to evaluate the efficacy and safety of nab-paclitaxel plus gemcitabine and cisplatin regimen in Chinese advanced BTC patients. Materials and Methods: Eligible patients with locally advanced or metastatic BTC administrated intravenous 100 mg/m2 nab-paclitaxel, 800 mg/m2 gemcitabine, and 25 mg/m2 cisplatin every 3 weeks. The primary endpoint was progression-free survival (PFS). The secondary endpoints included overall survival (OS) and adverse events, while exploratory endpoint was the association of biomarkers with efficacy. Results: After the median follow-up of 25.0 months, the median PFS and OS of 34 enrolled patients were 7.1 months (95% confidence interval [CI], 5.4 to 13.7) and 16.4 months (95% CI, 10.9 to 23.6), respectively. The most common treatment-related adverse events at ≥ 3 grade were neutropenia (26.5%) and leukopenia (26.5%). Survival analyses demonstrated that carcinoembryonic antigen (CEA) levels could monitor patients’ survival outcomes. A significant increase in the number of infiltrating CD4+ cells (p=0.008) and a decrease in programmed death-1–positive (PD-1+) cells (p=0.032) were observed in the response patients. Conclusion In advanced BTC patients, nab-paclitaxel plus gemcitabine and cisplatin regimen showed therapeutic potential. Potential prognostic factors of CEA levels, number of CD4+ cells and PD-1+ cells may help us maximize the efficacy benefit.

A 19-year-old male patient was admitted to a community hospital in Yangpu District of Shanghai in September 2023 due to diarrhea (4 times per day, watery stool) for 3 consecutive days. The patient had a history of eating out at a barbecue restaurant the night before the onset. The case accorded with diarrhea disease surveillance, and the pathogen was isolated as "non-A-F serogroup Salmonella" by the public health laboratory in the area where the patient′s feces swab was collected. The strain was identified as Salmonella Urbana ST512 by serological typing, antimicrobial resistance phenotype, and whole genome sequencing analysis in the Reference Lab, and then compared with the regional serotype database of Salmonella in China. At last, the patient was cured after taking levofloxacin orally for 3 days.

Robotic-assisted percutaneous coronary intervention (R-PCI) is an innovative way of performing percutaneous coronary intervention (PCI) whereby the operator can manipulate coronary intraluminal guidewires and catheter devices by using remotely controlled technology. Performing tele-R-PCI from a remote location via fifth generation network communication technology has never been reported in China; however, if this were possible, the technique could be used to treat many patients with coronary artery disease who would otherwise not have the opportunity of treatment. The case of a 73-year-old male patient with coronary artery disease who underwent successful tele-R-PCI at 800 km from the operators is presented. Performing long-distance tele-R-PCI in patients with coronary artery disease is feasible with predictably successful outcomes when reliable network connectivity and local cardiac catheterization facilities are present.

Robotic-assisted percutaneous coronary intervention (R-PCI) is an innovative way of performing percutaneous coronary intervention (PCI) whereby the operator can manipulate coronary intraluminal guidewires and catheter devices by using remotely controlled technology. Performing tele-R-PCI from a remote location via fifth generation network communication technology has never been reported in China; however, if this were possible, the technique could be used to treat many patients with coronary artery disease who would otherwise not have the opportunity of treatment. The case of a 73-year-old male patient with coronary artery disease who underwent successful tele-R-PCI at 800 km from the operators is presented. Performing long-distance tele-R-PCI in patients with coronary artery disease is feasible with predictably successful outcomes when reliable network connectivity and local cardiac catheterization facilities are present.

Objective::This study aimed to evaluate the major adverse cardiovascular and cerebrovascular events (MACCEs) and overall safety profile associated with iodixanol in Chinese patients undergoing percutaneous coronary intervention (PCI).Methods::Patients at 30 centers in China registered in the OpenClinic v3.6 database from October 30, 2013, to October 7, 2015, were included in the study. The primary endpoint was in-hospital MACCEs including target lesion revascularization (TLR), stroke, stent thrombosis, cardiac death, and PCI-related myocardial infarction (MI) within 72 h post-PCI. Secondary endpoints were MACCEs from 72 h to 30 d post-PCI and other safety events within 30 d post-PCI.Results::A total of 3,042 patients were enrolled. The incidence of MACCEs within 72 h post-PCI was 2.33% ( n = 71), including cardiac death (0.03%, n = 1) and PCI-related MI (2.30%, n = 70). The incidence of MACCEs from 72 h to 30 d post-PCI was 0.16% ( n = 5), including cardiac death (0.10%, n = 3), PCI-related MI (0.03%, n = 1), and TLR for stent thrombosis (0.03%, n = 1). The incidence of composite angiographic or procedural complications was 2.86% ( n = 87); 233 (7.86%) patients had results suggesting contrast-induced acute kidney injury. Conclusions::These findings indicate that the use of iodixanol in Chinese patients undergoing PCI is associated with a low incidence of MACCEs, confirming its safety in this population.

Objective::This study aimed to evaluate the major adverse cardiovascular and cerebrovascular events (MACCEs) and overall safety profile associated with iodixanol in Chinese patients undergoing percutaneous coronary intervention (PCI).Methods::Patients at 30 centers in China registered in the OpenClinic v3.6 database from October 30, 2013, to October 7, 2015, were included in the study. The primary endpoint was in-hospital MACCEs including target lesion revascularization (TLR), stroke, stent thrombosis, cardiac death, and PCI-related myocardial infarction (MI) within 72 h post-PCI. Secondary endpoints were MACCEs from 72 h to 30 d post-PCI and other safety events within 30 d post-PCI.Results::A total of 3,042 patients were enrolled. The incidence of MACCEs within 72 h post-PCI was 2.33% ( n = 71), including cardiac death (0.03%, n = 1) and PCI-related MI (2.30%, n = 70). The incidence of MACCEs from 72 h to 30 d post-PCI was 0.16% ( n = 5), including cardiac death (0.10%, n = 3), PCI-related MI (0.03%, n = 1), and TLR for stent thrombosis (0.03%, n = 1). The incidence of composite angiographic or procedural complications was 2.86% ( n = 87); 233 (7.86%) patients had results suggesting contrast-induced acute kidney injury. Conclusions::These findings indicate that the use of iodixanol in Chinese patients undergoing PCI is associated with a low incidence of MACCEs, confirming its safety in this population.

Objective:To investigate the effect of vancomycin (Vm)-loaded microbubbles (MBs) combined with ultrasound targeted microbubble destruction (UTMD) technique on the morphological structure, thickness and bacterial viability of methicillin-resistant Staphylococcus aureus (MRSA) biofilms.Methods:Vm-MBs were prepared by thin film hydration. Sterile coverslips in a diameter of 13 mm were placed in 24-well plates to construct in vitro biofilm models using MRSA as the test strain, and the biofilm morphology was observed by naked eye and light microscopy after crystal violet staining. LIVE/DEAD, SYTO59 and DIL were used to stain biofilms and MBs, respectively. After staining, the biofilm morphology and position of the biofilm in relation to MBs were observed using laser confocal scanning microscopy. The biofilms were divided into control group, Vm group, Vm-MBs group, UTMD group and Vm-MBs+UTMD group according to the random number table method, with 9 samples in each group. After biofilms of each group were treated accordingly for 24 hours, the morphological and structural changes of biofilms in each group were observed using laser confocal scanning microscopy and scanning electron microscopy following LIVE/DEAD staining; the difference in biofilm density in each group was measured with the aid of an enzyme marker following crystal violet staining; the difference in biofilm thickness and bacterial viability in each group were observed by laser confocal scanning microscopy. Results:The prepared Vm-MBs met the experimental requirements. The constructed biofilm model observed by naked eye, light microscopy and laser confocal scanning microscopy showed that the biofilm structure was dense with a relatively uniform thickness of (13.8±0.2)nm, a small amount of dead bacteria inside the membrane and the percentage of live bacteria of (94.9±0.3)%. Laser confocal scanning microscopy showed that MBs could penetrate into deeper layers of biofilms. After the respective treatment was given to each group for 24 hours, Laser confocal scanning microscopy and scanning electron microscopy following LIVE/DEAD staining showed that the biofilm morphological structure was most significantly disrupted in Vm-MBs+UTMD group compared to control, Vm, Vm-MBs and UTMD groups. In Vm-MBs+UTMD group, a large number of dead bacteria was observed, with only a few scattered planktonic bacteria and irregular changes in cell membrane morphology. Crystal violet staining showed that the biofilm density was significantly lower in Vm-MBs+UTMD group compared to control group ( P<0.05), while the differences between Vm, Vm-MBs and UTMD groups were not statistically significant (all P>0.05). Laser confocal microscopy showed that the biofilm thickness was thinner in Vm-MBs, UTMD and Vm-MBs+UTMD groups compared to control group (all P<0.05), with no significant difference between Vm group and control group ( P>0.05) and that the biofilm thickness was thinner in Vm-MBs+UTMD group compared to Vm, Vm-MBs and UTMD groups (all P<0.01), with no significant differences between the other groups (all P>0.05). Bacterial activity in Vm, Vm-MBs, UTMD and Vm-MBs+UTMD groups was significantly lower than that in control group (all P<0.01), with lower in Vm-MBs+UTMD group compared to Vm, Vm-MBs and UTMD groups (all P<0.01), but without significant difference between the other groups (all P>0.05). Conclusion:Vm-MBs combined with UTMD technology can effectively destroy the biofilm morphological structure to reduce biofilm thickness. Meanwhile, Vm-MBs combined with UTMD technology can release antibiotics and significantly decrease bacterial viability to improve antibiotic bactericidal efficacy.