Identification of dynamic signatures associated with smoking‐related squamous cell lung cancer and chronic obstructive pulmonary disease

Chronic obstructive pulmonary disease (COPD) is a risk factor for the development of lung cancer. The aim of this study was to identify early diagnosis biomarkers for lung squamous cell carcinoma (SQCC) in COPD patients and to determine the potential pathogenetic mechanisms. The GSE12472 data set was downloaded from the Gene Expression Omnibus database. Differentially co‐expressed links (DLs) and differentially expressed genes (DEGs) in both COPD and normal tissues, or in both SQCC + COPD and COPD samples were used to construct a dynamic network associated with high‐risk genes for the SQCC pathogenetic process. Enrichment analysis was performed based on Gene Ontology annotations and Kyoto Encyclopedia of Genes and Genomes pathway analysis. We used the gene expression data and the clinical information to identify the co‐expression modules based on weighted gene co‐expression network analysis (WGCNA). In total, 205 dynamic DEGs, 5034 DLs and one pathway including CDKN1A, TP53, RB1 and MYC were found to have correlations with the pathogenetic progress. The pathogenetic mechanisms shared by both SQCC and COPD are closely related to oxidative stress, the immune response and infection. WGCNA identified 11 co‐expression modules, where magenta and black were correlated with the “time to distant metastasis.” And the “surgery due to” was closely related to the brown and blue modules. In conclusion, a pathway that includes TP53, CDKN1A, RB1 and MYC may play a vital role in driving COPD towards SQCC. Inflammatory processes and the immune response participate in COPD‐related carcinogenesis.     

Boosting Polysulfide Redox Kinetics by Graphene‐Supported Ni Nanoparticles with Carbon Coating

Lithium–sulfur batteries have attracted extensive attention because of their high energy density. However, their application is still impeded by the inherent sluggish kinetics and solubility of intermediate products (i.e., polysulfides) of the sulfur cathode. Herein, graphene‐supported Ni nanoparticles with a carbon coating are fabricated by directly carbonizing a metal–organic framework/graphene oxide composite, which is then dispersed on a commercial glass fiber membrane to form a separator with electrocatalytic activity. In situ analysis and electrochemical investigation demonstrate that this modified separator can effectively suppress the shuttle effect and regulate the catalytic conversion of intercepted polysulfides, which is also confirmed by density functional theory calculations. It is found that Ni–C sites can chemically interact with polysulfides and stabilize the radical S₃^?? through Ni? S bonds to enable fast dynamic equilibrium with S₆^2?, while Ni nanoparticles reduce the oxidation barrier of Li₂S and accelerate ion/electron transport. As a result, the corresponding lithium–sulfur battery shows a high cycle stability (88% capacity retention over 100 cycles) even with a high sulfur mass loading of 8 mg cm^?2 and lean electrolyte (6.25 µ L mg^?1). Surprisingly, benefitting from the improved kinetics, the battery can work well at ?50 °C, which is rarely achieved by conventional Li–S batteries.     

Suppressing Voltage Fading of Li‐Rich Oxide Cathode via Building a Well‐Protected and Partially‐Protonated Surface by Polyacrylic Acid Binder for Cycle‐Stable Li‐Ion Batteries

Li‐rich manganese based oxides (LRMOs) are considered an attractive high‐capacity cathode for advanced Li‐ion batteries; however, their poor cyclability and gradual voltage fading have hindered their practical applications. Herein, an efficient and facile strategy is proposed to stabilize the lattice structure of LRMOs by surface modification of polyacrylic acid (PAA). The PAA‐coated LRMO electrode exhibits only 104 mV of the voltage fading after 100 cycles and 88% capacity retention over 500 cycles. The structural stability is attributed to the carboxyl groups in PAA chains reacting with oxygen species on the surface of LRMO to form a uniform and tightly coated film, which significantly suppresses the dissolution of transition metal elements from the cathode materials into the electrolyte. Importantly, a H⁺/Li⁺ exchange reaction takes place between the LRMO and PAA, generating a proton‐doped surface layer. Density functional theory calculations and experimental evidence demonstrates that the H⁺ ions in the surface lattice efficiently inhibit the migration of transition metal ions, leading to a stabilized lattice structure. This surface modification approach may provide a new route to building a stable Li‐rich oxide cathode with high capacity retention and low voltage fading for practical Li‐ion battery applications.     

Half‐Heusler Thermoelectric Module with High Conversion Efficiency and High Power Density

Half‐Heusler (HH) compounds have shown great potential in waste heat recovery. Among them, p‐type NbFeSb and n‐type ZrNiSn based alloys have exhibited the best thermoelectric (TE) performance. However, TE devices based on NbFeSb‐based HH compounds are rarely studied. In this work, bulk volumes of p‐type (Nb_0.8Ta_0.2)_0.8Ti_0.2FeSb and n‐type Hf_0.5Zr_0.5NiSn_0.98Sb_0.02 compounds are successfully prepared with good phase purity, compositional homogeneity, and matchable TE performance. The peak zTs are higher than 1.0 at 973 K for Hf_0.5Zr_0.5NiSn_0.98Sb_0.02 and at 1200 K for (Nb_0.8Ta_0.2)_0.8Ti_0.2FeSb. Based on an optimal design by a full‐parameters 3D finite element model, a single stage TE module with 8 n‐p HH couples is assembled. A high conversion efficiency of 8.3% and high power density of 2.11 W cm^?2 are obtained when hot and cold side temperatures are 997 and 342 K, respectively. Compared to the previous TE module assembled by the same materials, the conversion efficiency is enhanced by 33%, while the power density is almost the same. Given the excellent mechanical robustness and thermal stability, matchable thermal expansion coefficient and TE properties of NbFeSb and ZrNiSn based HH alloys, this work demonstrates their great promise for power generation with both high conversion efficiency and high power density.     

重庆地区人类免疫缺陷病毒携带者的微孢子虫感染情况调查

目前我国关于微孢子虫感染人的研究相对较少,更没有关于重庆地区人类免疫缺陷病毒(HIV)携带者感染微孢子虫的数据统计。对重庆市公共卫生医疗救治中心收治的22例HIV抗体阳性,但尚未接受抗病毒治疗的患者进行研究。将22例患者粪便样本分别提取总DNA,通过聚合酶链反应(PCR)法和DNA测序等技术对微孢子虫在患者中的感染情况进行检测,并对微孢子虫种类进行鉴定。同时对22例患者的免疫细胞亚群进行计数和分析。结果显示,微孢子虫的感染率为36.3%(8/22),主要由脑炎微孢子虫属(Encephalitozoon spp)的海伦脑炎微孢子虫(E. hellem)和肠脑炎微孢子虫(E. intestinalis)引起。22例患者的免疫细胞亚群分析显示,平均淋巴细胞数0.93±0.13×10⁹/L,CD4^＋T细胞数132±22 个/mL,CD8^＋T细胞数495±91 个/mL,CD4/CD8细胞比值0.37±0.1,表明患者免疫功能受到严重抑制。进一步将微孢子虫感染患者与未感染患者的免疫细胞亚群进行比较发现,感染患者淋巴细胞数为0.51±0.1×10⁹/L,未感染患者为1.17±0.17 ×10⁹/L,两者具有显著差异(P<0.05);感染患者CD4^＋T细胞数为71±27 个/mL,未感染患者为167±28 个/mL,两者具有显著差异(P<0.05);感染患者CD8^＋T细胞数为209±35 个/mL,未感染患者为658±123 个/mL,两者具有显著差异(P<0.05),以上表明微孢子虫感染组的免疫功能受损情况更严重。本研究结果提示微孢子虫的机会性感染与患者免疫功能受损情况密切相关,脑炎微孢子虫属在重庆地区有较高的感染率,这为进一步阐明微孢子虫与宿主相互作用关系奠定基础,也为公共卫生健康管理提供重要参考。     

我院2015-2018年度抗菌药物的使用强度与鲍曼不动杆菌的耐药性的关系研究

摘要 目的：分析我院2015-2018年度抗菌药物的使用强度与鲍曼不动杆菌的耐药性的关系。方法：统计2015年1月～2018年12月北京中医医院顺义医院抗菌药物的应用情况以及鲍曼不动杆菌的耐药性。鲍曼不动杆菌的耐药性资料来源于检验科临床送检的伤口分泌物、痰液、血液、尿液等病原学标本。结果：2015年～2018年,共分离到菌株13246株,其中分离到鲍曼不动杆菌株1927株,分离率为14.55 %。其中 2015 年的分离率为3.11 %,2016年的分离率为4.51 %,2017 年的分离率为5.15 %,2018 年的分离率为2.11 %;鲍曼不动杆菌标本分离率最高的为痰液,占78.83 %,其次为伤口分泌物,占12.51 %,尿液标本占5.81 %,血液标本占2.85 %;鲍曼不动杆菌在我院所有致病菌中的排序均为第一位或者第二位;2015年～2018年抗菌药物的使用强度逐年升高,2018年有所降低;2015年～2018年鲍曼不动杆菌对哌拉西林钠他唑巴坦钠、美洛培南以及亚胺培南的耐药率均逐年升高,2018年有所降低;哌拉西林钠他唑巴坦钠、美洛培南以及亚胺培南的耐药性与抗菌药物使用强度之间具有明显的相关性（P<0.05）。结论：哌拉西林钠他唑巴坦钠、美洛培南以及亚胺培南的使用,是造成鲍曼不动杆菌耐药的重要原因之一,临床应加以重视。     

Long Term Culture of Human Kidney Proximal Tubule Epithelial Cells Maintains Lineage Functions and Serves as an Ex vivo Model for Coronavirus Associated Kidney Injury

The mechanism of how SARS-CoV-2 causes severe multi-organ failure is largely unknown. Acute kidney injury(AKI) is one of the frequent organ damage in severe COVID-19 patients. Previous studies have shown that human renal tubule cells could be the potential host cells targeted by SARS-CoV-2. Traditional cancer cell lines or immortalized cell lines are genetically and phenotypically different from host cells. Animal models are widely used, but often fail to reflect a physiological and pathogenic status because of species tropisms. There is an unmet need for normal human epithelial cells for disease modeling. In this study, we successfully established long term cultures of normal human kidney proximal tubule epithelial cells(KPTECs) in 2 D and 3 D culture systems using conditional reprogramming(CR) and organoids techniques.These cells had the ability to differentiate and repair DNA damage, and showed no transforming property. Importantly, the CR KPTECs maintained lineage function with expression of specific transporters(SLC34 A3 and cubilin). They also expressed angiotensin-converting enzyme 2(ACE2), a receptor for SARS-CoV and SARS-CoV-2. In contrast, cancer cell line did not express endogenous SLC34 A3, cubilin and ACE2. Very interestingly, ACE2 expression was around twofold higher in 3 D organoids culture compared to that in 2 D CR culture condition. Pseudovirion assays demonstrated that SARS-CoV spike(S) protein was able to enter CR cells with luciferase reporter. This integrated 2 D CR and 3 D organoid cultures provide a physiological ex vivo model to study kidney functions, innate immune response of kidney cells to viruses, and a novel platform for drug discovery and safety evaluation.     

Establishment of Murine Infection Models with Biological Clones of Dengue Viruses Derived from a Single Clinical Viral Isolate

Virologica Sinica - Dengue virus (DENV) is a single-stranded RNA virus transmitted by mosquitoes in tropical and subtropical regions. It causes dengue fever, dengue hemorrhagic fever and dengue...