α-Cyanoacrylate Rapid Medical Adhesive (Medical EC Glue) Localization of Pulmonary Nodules Guided by Computed Tomography before Thoracoscopic Surgery.

OBJECTIVE: The study aims to conduct lung cancer screening by low-dose CT to identify the nature of the pulmonary nodule. The purpose of this study was to evaluate the role of preoperative medical EC glue localization of pulmonary nodules of uncertain nature by minimally invasive surgical resection. METHODS: From December 2017 to December 2019, 18 patients (12 women, 6 men; median age: 54 years)with pulmonary nodules were located using medical EC glue under the guidance of preoperative CT and then resected under video thoracoscopy at Air Force Medical Center of PLA. The clinical characteristics were retrospectively collected to evaluate the effectiveness, safety and feasibility of the operation. RESULTS: The mean value of the maximum diameter of pulmonary nodules on CT images before the operation was 10.8 mm. The average depth was 10.3 mm (1.0-39.5 mm). Among 18 nodules, 8 were pure ground glass nodules, 3 were solid nodules, and 7 were partial solid nodules. The diagnosis rate of medical glue localization under the guidance of CT after the operation was 100%. Postoperative pathological diagnosis showed that there were 10 cases of primary lung adenocarcinoma, 1 case of invasive lung adenocarcinoma, 3 cases of adenocarcinoma in situ, 1 case of metastatic adenocarcinoma, and 3 cases of benign nodules. No obvious serious complications were found after localization. CONCLUSION: This study suggests that CT-guided percutaneous medical EC glue localization is a reliable, safe, feasible and practical method for undiagnosed pulmonary nodules and can significantly improve the rate of resection of small pulmonary nodules. Furthermore, it was considered to be more reasonable to remove pulmonary nodules and maximize the preservation of lung function.

Study of epirubicin sustained-release chemoablation in tumor suppression and tumor microenvironment remodeling.

Introduction: Although intratumoral chemoablation can obtain an impressive therapeutic effect, there is still incomplete ablation and tumor recurrence in some patients. This could be due to the short retention time of the drug in the tumor, the limited distribution of intratumoral drugs, and, beyond that, the immunotolerance caused by the tumor microenvironment (TME). There is still an urgent need to find an optimal drug sustained-release carrier and figure out the impact of regional injection to TME. Methods: In this study, we supposed to use polyethylene glycol (PEG) hydrogel as a drug carrier to improve the retention time of the drug to extend the exposure of tumor cells and investigate the feasibility of combination local Epirubicin injection with anti-PD-L1. Results: The results revealed obvious tumor suppression based on the tumor volume and the inhibition time of tumor growth in the A549 lung cancer mouse model after local injection. Furthermore, the enhanced antitumor effects of the combination of systematic anti- programmed death ligand 1 (PD-L1) therapy with local chemoablation (EPI-GEL/PD-L1) for abscopal tumor reduction in the 4T1 breast model were also observed. Flow cytometry analysis of the tumor and blood samples showed significant variations in the proportions of PD-L1+ and CD3+CD8+PD-1+ cells before and after anti-PD-L1 therapy. On day 4 after local injection of the EPI gel, the expression of PD-L1 in abscopal tumors was upregulated, while the expression of PD-L1 in bilateral tumors in mice was significantly reduced after anti-PD-L1 treatment. The proportion of CD3+CD8+PD-1+ cells in the tumor and circulating blood in the EPI-GEL/PD-L1 group was decreased compared with that in the EPI-GEL (single injection of epirubicin) group. Discussion: The combination of local injection of the chemoablation agent with anti-PD-L1 monoclonal antibody (mAb) therapy may strengthen the antitumor activity, and the use of PEG hydrogel as the drug carrier can extend the retention time of the chemoablation agent around the tumor, maintaining a long-term tumor-killing activity.

Hydrogen storage behavior of nanocrystalline and amorphous Mg-Ni-Cu-La alloys.

Alloying and structural modification are two effective ways to enhance the hydrogen storage kinetics and decrease the thermal stability of Mg and Mg-based alloys. In order to enhance the characteristics of Mg2Ni-type alloys, Cu and La were added to an Mg2Ni-type alloy, and the sample alloys (Mg24Ni10Cu2)100-x La x (x = 0, 5, 10, 15, 20) were prepared by melt spinning. The influences of La content and spinning rate on the gaseous and electrochemical hydrogen storage properties of the sample alloys were explored in detail. The structural identification carried out by XRD and TEM indicates that the main phase of the alloys is Mg2Ni and the addition of La results in the formation of the secondary phases LaMg3 and La2Mg17. The as-spun alloys have amorphous and nanocrystalline structures, and the addition of La promotes glass formation. The electrochemical properties examined by an automatic galvanostatic system show that the samples possess a good activation capability and achieve their maximal discharge capacities within three cycles. The discharge potential characteristics were vastly ameliorated by melt spinning and La addition. The discharge capacities of the samples achieve their maximal values as the La content changes, and the discharge capacities always increase with increasing spinning rate. The addition of La leads to a decline in hydrogen absorption capacity, but it can effectively enhance the rate of hydrogen absorption. The addition of La and melt spinning significantly increase the hydrogen desorption rate due to the reduced activation energy.