Carrier Cells for Delivery of Oncolytic Measles Virus into Tumors：Determinants of Efficient Loading

Oncolytic measles virus(OMV) is a promising antitumor agent. However, the presence of anti-measles neutralizing antibodies(NAbs) against the hemagglutinin(H) protein of OMV is a major barrier to the therapeutic application of OMV in clinical practice. In order to overcome this challenge, specific types of cells have been used as carriers for OMV.Differential loading strategies appear to result in different therapeutic outcomes; despite this, only few studies have reported practical ex vivo loading strategies required for effective treatment. To this end, we systematically evaluated the antitumor efficacy of OMV using different loading strategies; this involved varying the in vitro loading duration and loading dose of OMV. We found that improved oncolysis of carrier cells was achieved by a prolonged loading duration in the absence of NAbs. However, the enhanced oncolytic effect was abrogated in the presence of NAbs. Further, we found that the expression of H protein on the surface of carrier cells was predominantly determined by the loading duration rather than the loading dose. Finally, we showed that NAbs blocked viral transfer by targeting H protein prior to the occurrence of cell-to-cell interactions. Our results provide comprehensive information on the determinants of an effective loading strategy for carrier cell-based virotherapy; these results may be useful for guiding the application of OMV as an antitumor agent in clinical practice.

Sustained-release genistein from nanostructured lipid carrier suppresses human lens epithelial cell growth

AIM： To design and investigate the efficacy of a modified nanostructured lipid carrier loaded with genistein（Gen-NLC） to inhibit human lens epithelial cells（HLECs） proliferation.·METHODS： Gen-NLC was made by melt emulsification method. The morphology, particle size（PS）, zeta potentials（ZP）, encapsulation efficiency（EE） and in vitro release were characterized. The inhibition effect of nanostructured lipid carrier（NLC）, genistein（Gen） and Gen-NLC on HLECs proliferation was evaluated by cell counting kit-8（CCK-8） assay, gene and protein expression of the proliferation marker Ki67 were evaluated with real-time quantitative polymerase chain reaction（RT-q PCR） and immunofluorescence analyses.·RESULTS： The mean PS of Gen-NLC was 80.12±1.55 nm with a mean polydispersity index of 0.11±0.02. The mean ZP was-7.14 ±0.38 m V and the EE of Gen in the nanoparticles was 92.3% ±0.73%. Transmission electron microscopy showed that Gen-NLC displayed spherical-shaped particles covered by an outer-layer structure. In vitro release experiments demonstrated a prolonged drug release for 72 h. The CCK-8 assay results showed the NLC had no inhibitory effect on HLECs and Gen-NLC displayed a much more prominent inhibitory effect on cellular growth compared to Gen of the same concentration. The m RNA and protein expression of Ki67 in LECs decreased significantly in Gen-NLC group.·CONCLUSION： Sustained drug release by Gen-NLCs may impede HLEC growth.

Excess Carrier Lifetime Improvement in c-Si Solar Cells by YAG:Ce^(3+)-Yb^(3+)

Ce3＋-Yb3＋ doped Y3Al5O12 （YAG） is a luminescent down-conversion material which could convert visible pho- tons to near infrared photons. In this work, YAG：Ce3＋-Yb3＋ is applied on the front surface of mass-produced mono crystalline Si solar cells. For the coated cells, the external quantum efficiencv from the visible to the near infrared is improved, and the energy conversion efficiency enhances from 11.70% to 12.2% under AMI.SG. Furthermore, the phosphor down-conversion effect on the solar cell is characterized by the microwave detected photoconductivity technique on the n-type silicon wafer under the 977nm excitation. The down-conversion materials improve the average excess carrier lifetime from 22.5μs to 24.2#s and the average surface recombi- nation velocity reduces from 424.Scm/s to 371.6cm/s, which reveal the significant reduction in excess carrier recombination by the phosphors.

Human umbilical cord mesenchymal stem cells as cell carriers in the treatment of gliomas: research status and prospects

Human umbilical cord mesenchymal stem cells(HuMSCs)have the multi-difFerentiation potential to differentiate into various types of cells without immune rejection.They are considered to be an ideal source of neural stem cells and also an ideal cell carrier for gene therapy.Because of the invasive growth of brain gliomas,most of them have no obvious boundaries with normal brain tissues.It is difficult to completely remove them by surgery and the remaining cells become the main source of tumor recurrence.In recent years,gene therapy has become a new method for the treatment of gliomas.The vector carrying the target gene is introduced into HuMSCs in a certain way to correct gene defects or play other roles.The differentiation potential of HuMSCs makes it an ideal source of nerve cells to play a greater role in gene therapy of glioma.Therefore,this article reviews the current status and prospects of HuMSCs as cell carriers in the treatment of glioma.

Carrier transport via V-shaped pits in InGaN/GaN MQW solar cells

Carrier transport via the V-shaped pits （V-pits） in InGaN/GaN multiple-quantum-well （MQW） solar cells is numer- ically investigated. By simulations, it is found that the V-pits can act as effective escape paths for the photo-generated carriers. Due to the thin barrier thickness and low indium composition of the MQW on V-pit sidewall, the carriers entered the sidewall QWs can easily escape and contribute to the photocurrent. This forms a parallel escape route for the carries generated in the fiat quantum wells. As the barrier thickness of the fiat MQW increases, more carriers would transport via the V-pits. Furthermore, it is found that the V-pits may reduce the recombination losses of carriers due to their screening effect to the dislocations. These discoveries are not only helpful for understanding the carrier transport mechanism in the InGaN/GaN MQW, but also important in design of the structure of solar cells.

Effect of carrier mobility on performance of perovskite solar cells

The high carrier mobility and long diffusion length of perovskite material have been regarded because of its excellent photovoltaic performance. However, many studies have shown that a diffusion length longer than 1 μm and higher carrier mobility have no positive effect on the cells' performance. Studies of organic solar cells have demonstrated the existence of an optimal mobility value, while systematic research of the carrier mobility in the PSCs is very rare. To make these questions clear, the effect of carrier mobility on perovskite solar cells' performance is studied in depth in this paper by simulation.Our study shows that the optimal mobility value of the charge transportation layer and absorption layer are influenced by both doping concentration and layer thickness. The appropriate carrier mobility can reduce the carrier recombination rate and enhance the carrier concentration, thus improving the cells' performance. A high efficiency of 27.39% is obtained in the simulated cell with the combination of the optimized parameters in the paper.

Influence of optical interference and carrier lifetime on the short circuit current density of organic bulk heterojunction solar cells

Based on simple analytical equations, short circuit current density （Jsc） of the organic bulk heterojunction solar cells has been calculated. It is found that the optical interference effect plays a very important role in the determination of Jsc; and obvious oscillatory behaviour of Jsc was observed as a function of thickness. At the same time, the influence of the carrier lifetime on Jsc also cannot be neglected. When the carrier lifetime is relatively short, Jsc only increases at the initial stage and then decreases rapidly with the increase of active layer thickness. However, for a relatively long carrier lifetime, the exciton dissociation probability must be considered, and Jsc behaves wave-like with the increase of active layer thickness. The validity of this model is confirmed by the experimental results.

Photoluminescence Analysis of Electron Damage for Minority Carrier Diffusion Length in GaInP/GaAs/Ge Triple-Junction Solar Cells

Photoluminescence（PL） measurements are carried out to investigate the degradation of GaInP top cell and GaAs middle cell for GaInP/GaAs/Ge triple-junction solar cells irradiated with 1.0, 1.8 and 11.5 MeV electrons with fluences ranging up to 3 × 10^15, 1 × 10^15 and 3 × 10^14 cm^-2, respectively. The degradation rates of PL intensity increase with the electron fluence and energy. Furthermore, the damage coefficient of minority carrier diffusion length is estimated by the PL radiative efficiency. The damage coefficient increases with the electron energy. The relation of damage coefficient to electron energy is discussed with the non-ionizing energy loss（NIEL）, which shows a quadratic dependence between damage coefficient and NIEL.

负载紫杉醇和JAK2-STAT3抑制剂纳米载药系统对胃癌细胞生物活性的影响机制研究

目的研讨负载紫杉醇和JAK2-STAT3抑制剂纳米载药系统对胃癌细胞生物活性的抑制作用。方法选取胃癌细胞GBC-SD为研究对象,构建PLGA(TAXOL+AZD1480)纳米粒子,确定粒子的稳定性及释放药物速率稳定性;比较对照组、PLGA组、TAXOL+AZD1480组、PLGA(TAXOL+AZD1480组)各组胃癌细胞JAK2-STAT3信号通路活性、增殖、凋亡、迁移、侵袭能力。结果PLGA(TAXOL+AZD1480)纳米粒子120 h内呈现出缓慢、稳定释放;TAXOL+AZD1480组及PLGA(TAXOL+AZD1480)组JAK2、STAT3磷酸化蛋白水平均降低(P<0.05);与PLGA组相比,TAXOL组、AZD1480组均可以下调胃癌细胞增殖、迁移、侵袭能力,上调细胞凋亡能力,Cyclin D1、MMP-9蛋白表达受到抑制,Cleaved-caspase-3、Bax蛋白表达提升(P<0.05);与TAXOL组、AZD1480组相比,TAXOL+AZD1480组、PLGA(TAXOL+AZD1480)组进一步下调胃癌细胞增殖、迁移、侵袭能力,上调凋亡能力(P<0.05);TAXOL+AZD1480组、PLGA(TAXOL+AZD1480)组两组癌细胞增殖、凋亡、迁移、侵袭活性相近(P>0.05)。结论本研究成功构建了共载TAXOL和AZD1480的PLGA(TAXOL+AZD1480)载药传递系统,该纳米体系具有药物缓释以及抑制胃癌的作用,药效确切,值得在临床进一步推广。

T细胞免疫反应载体疫苗在人类疾病预防和治疗中的应用

人类疾病,特别是传染病和癌症,对公共卫生安全和全球经济构成前所未有的挑战。预防和治疗性疫苗的开发是应对人类疾病的优先对策。本文综述了疫苗载体的免疫学原理、T细胞载体疫苗设计策略及疫苗研究进展,为新型疫苗的设计提供新的思路。T细胞可以在机体发生感染后分化成不同的效应T细胞群,它们可以起到清除病原体的作用,关于效应T细胞功能和机制的研究对于设计能够引发基于T细胞免疫的疫苗至关重要。目前很多病毒(例如HIV、HCMV感染)和肿瘤疫苗的研发都侧重于T细胞类疫苗,在所有疫苗种类中,激活T细胞免疫反应的载体疫苗具有显著优势。许多来源的载体,包括病毒载体、细菌载体和核酸载体,它们在抗原提呈能力、免疫原性和保护效力方面都有良好的表现。此外,还总结了T细胞载体疫苗设计的策略,包括确定适当的抗原提呈途径和载体递送途径、确保生物安全性、如何选择合适的疫苗的载体、各种载体疫苗的优缺点等,尤其是mRNA疫苗在应对新冠疫情中发挥了重要的作用。疫苗载体的技术进步将会加速新型疫苗的研发,并且能促进人们对突发公共卫生事件的应对。

GTP酶激活蛋白SH3功能区结合蛋白1在非小细胞肺癌中的表达及其与放疗疗效的关系

【目的】探讨GTP酶激活蛋白SH3功能区结合蛋白1(G3BP1)在非小细胞肺癌(NSCLC)患者组织中的表达及其与放疗疗效的关系。【方法】检测133例NSCLC患者组织中G3BP1蛋白表达水平,并分析其与NSCLC临床病理参数及放疗疗效的关系。【结果】NSCLC患者组织中G3BP1蛋白水平在不同肿瘤直径、TNM分期及淋巴结转移患者中比较,差异均有统计学意义(P<0.05)。有效组NSCLC组织中G3BP1蛋白水平低于无效组,差异有统计学意义(P<0.05)。G3BP1评价疗效的受试者工作特征(ROC)曲线下面积(AUC)、最佳截断值、敏感度和特异度分别为0.802、2.33、86.54%和61.73%。Logistic多因素回归分析结果显示:肿瘤直径、TNM分期、淋巴结转移、急性放射性肺炎及G3BP1水平是影响NSCLC放疗疗效的独立危险因素(P<0.05)。【结论】G3BP1与NSCLC肿瘤直径、TNM分期及淋巴结转移有关,其水平可为评价患者的放疗疗效提供参考。

室内VLC-WiFi异构网络中多色载波资源分配

可见光通信接入点(VLC AP)在室内密集部署的方式在扩大VLC-WiFi系统容量的同时,增加了覆盖的小区间干扰。为了降低小区间干扰,提高系统的吞吐量和平均用户满意度,本文设计了多色载波分配与功率控制(MCAPC)的资源分配方法。该方法依据VLC AP的部署位置和信道特性,采用软频率复用方法确定各VLC AP的无干扰的主载波和多色副载波,并设计基于匹配博弈的载波和子频带分配算法为用户分配异构网络的频带资源;最后,设计基于功率控制效用值的干扰抑制的载波功率控制算法进一步抑制小区间干扰。研究结果表明,所提MCAPC方法能够提高室内多色VLC-WiFi异构网的系统吞吐量和用户的平均满意度。

聚合物纤维载体对L929细胞的增殖及毒性研究

研究了进口聚合物纤维载体(1#)与国产聚合物纤维载体(2#和3#)对L929细胞增殖与毒性的影响。用CCK-8法在不同浸提液含量、不同培养时间下检测L929细胞在聚合物纤维载体中的相对增殖率。按通用标准评价材料的细胞毒性,并对载体表面和内部的细胞黏附性进行表征。结果表明:浸提液质量分数在6.25%~100.00%时,1#组、2#组、3#组均没有潜在细胞毒性,1#组、2#组、3#组的细胞毒性级别分别为“1”“0”和“1”级。体外细胞培养试验表明:在24 h的培养时间内,2#组、3#组的细胞增殖率和1#组基本接近;48~72 h的培养时间内,2#组、3#组的细胞增殖率略低于1#组。细胞黏附试验表明:2#组、3#组的细胞增殖率高于1#组,且细胞倾向于在纤维载体的内部生长。国产聚合物纤维载体的生物相容性、细胞毒性以及细胞黏附性均达到理想效果,其中3#组聚合物纤维载体的细胞增殖和细胞黏附效果最理想。

中医药联合医用水凝胶治疗疾病的策略及意义

背景:医用水凝胶是具有三维结构网络的新型功能高分子材料,具有出色的生物相容性,目前已在组织工程领域、药物载体领域有广泛研究,但基于组织工程探究医用水凝胶与中医药结合治疗疾病的研究还处于初期探索阶段。因此,通过对医用水凝胶机制作用的剖析,整合医用水凝胶与中医药在研究中联合应用的文章,进而更好地为科研工作者提供思路,对中医药与医用水凝胶联合应用具有重要意义。目的:基于组织工程研究探讨中医药联合医用水凝胶治疗疾病的策略及意义。方法:利用PubMed和中国知网数据库,检索有关中医药联合医用水凝胶在组织工程中应用的文献,检索时间为2010年1月至2022年11月,英文检索词为“hydrogel,traditional Chinese medicine,drug carrier,tissue engineering”,中文检索词为“医用水凝胶、中医药、药物载体、组织工程”。根据纳入与排除标准对所有文章进行初筛后,最终纳入61篇文章进行综述。结果与结论:①中医药联合医用水凝胶的应用虽然在关节内、组织器官内、软组织伤口和组织工程等方面有所涉及,但除了中医药结合水凝胶敷料在临床应用治疗软组织损伤外,其他方面尚处于基础实验阶段。②中医药联合医用水凝胶的发展有着巨大潜力和发展前景,但对于性能要求较高的凝胶在制造方面存在一定难度,理化性质精确掌握难度较大。③目前综合来看可注射水凝胶凭借着简便易用的特点,其在与中医药联合使用可延伸范围较广,可用于关节、器官和组织工程相关疾病的治疗;智能水凝胶有较高的灵敏度和可逆转化性也可满足特殊环境下的使用;将两者结合的中医药使用过程中还需要明确中药成分的作用机制。④中医药联合医用水凝胶治疗疾病的策略应着手于中医药对器官、组织、细胞的治疗作用联合适当种类的医用水凝胶进行匹配,可弥补传统中医给药方式和频繁给药的不足,在组织工程方面可以用水凝胶负载中药干预后的干细胞,或者同时负载中药和干细胞用于相关疾病的治疗。⑤在中医药联合医用水凝胶应用的未来研究中,还需要考虑:应当确保医用水凝胶生物性能可以量化,以不同材料不同制造工艺把握水凝胶特性,制造出所需要的符合应用条件的医用水凝胶;在中医药方面需要对已知中药单体、中药复方提取物的治疗效果和应用机制全面了解剖析,在更明了的机制下实现中医药与医用水凝胶更多更完美的结合;借助医学科技创新能力的不断提高,医用水凝胶可以创新性地结合中医药其他传统治疗方法比如针灸、推拿和拔罐等方式进行多角度运用。

基于SnO_(2):DPEPO混合电子传输层的钙钛矿太阳能电池性能研究

电子传输层是钙钛矿太阳能电池的重要功能层,其表面及内部缺陷是限制钙钛矿太阳能电池性能提升的重要一环.双电子传输层(双ETL)策略虽然可以改善电子在功能层之间提取与传输,但是双ETL内部存在的独立界面以及不同ETL材料晶胞不匹配问题导致了额外的非辐射复合.基于此,本文提出了将二[2-((氧代)二苯基膦基)苯基]醚(DPEPO)引入到SnO_(2)中设计混合电子传输层的策略,该策略在钝化SnO_(2)中本征缺陷的同时,可以避免由于额外界面的存在而导致的缺陷态,有效改善了电子的提取与传输.并且进一步实现了对钙钛矿薄膜的结晶调控,提升钙钛矿太阳能电池性能,最终收获了基于宽带隙钙钛矿太阳能电池21.53%的功率转换率,其中开路电压(V_(OC))达到了1.220 V,短路电流(J_(SC))为23.19 mA/cm^(2),填充因子(FF)高达76.11%.研究表明混合电子传输层策略可以有效优化载流子传输动力学,促进钙钛矿高质量结晶,对制备高性能太阳能电池具有一定指导意义.

载柔红霉素球形B细胞淋巴瘤-2基因反义硫代磷酸寡脱氧核苷酸纳米药物的构建及抗白血病的疗效研究

目的设计合成一种新型的自载体球形核苷酸纳米药物用于白血病联合治疗,并对其形貌、理化性质、药物缓释行为及体内外疗效进行研究。方法利用化学反应偶联1,3-二亚麻酸甘油酯(1,3-dilinolenin)和B细胞淋巴瘤-2基因(Bcl-2)反义硫代磷酸寡脱氧核苷酸(G3139),通过自组装的方式形成具有纳米囊结构的球形核苷酸,并包载化学治疗药物——柔红霉素(DNR),以此构建联合治疗球形核苷酸自载体纳米药物(DBD NP)。通过琼脂糖凝胶电泳检测分子间偶联情况;利用马尔文纳米粒度仪和透射电子显微镜测定其粒径、电位、形貌和稳定性;通过酶标仪检测DBD纳米药物的缓释行为;利用激光共聚焦扫描显微镜观察DBD NP的摄取情况;通过小动物活体成像仪和流式细胞仪研究DBD NP对白血病模型大鼠的治疗效果。结果DBD NP是粒径为140.5 nm球形纳米颗粒,电位为(-26.34±2.66)mV。在模拟血液环境中DBD NP在7 d内具有良好的稳定性,且能持续缓释药物DNR,到第5天累计释放药物量达到76.53%±2.01%。在LT12细胞的摄取实验中,DBD NP组DNR的荧光强度为71.03×10^(5),约是游离DNR组的8倍,表明该纳米颗粒能够显著提高白血病细胞的药物摄取量。动物实验进一步证实DBD NP可显著提高药物的治疗效果,相比游离DNR组,其杀伤白血病细胞的能力提高了2~4倍,将荷瘤大鼠生存期从23 d延长到29 d。结论球形核苷酸纳米颗粒DBD NP能够显著提高药物治疗白血病的效果,延缓大鼠白血病的发病进程,是一种具有一定潜力的新型纳米药物。

血红蛋白类氧载体的研究进展及应用前景

红细胞输注已广泛应用于创伤救治、外科手术、输血治疗以及战伤急救等多个方面,但依然存在血液资源紧缺、储存期短、输前需交叉配型、可能经血传播病原体等问题。血红蛋白氧载体(hemoglobin-based oxygen carriers,HBOCs)是一类由无基质血红蛋白通过化学修饰等方法制备的可溶性纳米级具有携释氧功能的氧载体,能代替红细胞为体内各器官、组织输送氧气,且具有无血型和病毒传播风险、储存长,即时可用的特点,也称为红细胞代用品。本文旨在综述HBOCs研究的进展,同时探讨其在除替代红细胞输血治疗以外,针对其他如器官保存、脑缺血、肿瘤等治疗中的应用前景。

BaTiO_(3)掺杂调控内建电场提升钙钛矿太阳能电池性能

碳基无空穴传输层钙钛矿太阳能电池(C-PSCs)因其替换了昂贵的贵金属电极,以及去掉了稳定性差的空穴传输材料而受到广泛关注.但是C-PSCs内部载流子分离和传输性能差阻碍了效率的提高,而内建电场的增强可以改善载流子传输性能从而提升电池光电性能.本文将铁电材料钕酸钡(BaTiO_(3))粉末作为添加剂引入钙钛矿前驱液中制备C-PSCs,改善钙钛矿薄膜形态,降低薄膜缺陷密度及提高C-PSCs载流子传输性能.结果表明,当BaTiO_(3)质量分数为1.0%时,钙钛矿薄膜均匀致密,电池的光电转换效率最高.对薄膜施加正向电压极化处理后,铁电材料BaTiO_(3)剩余极化电场增大了内建电场,为载流子输运和萃取提供充足的动力,从而抑制非辐射复合的发生;同时耗尽层宽度增大,反向饱和电流减小,电池性能显著提升,优化后最佳器件效率为9.02%.本文为钙钛矿吸收层掺杂实现内建电场调控提供了一种有效策略.

肾透明细胞癌中双硫死亡核心基因SLC7A11的孟德尔随机化及生物信息学分析

目的分析溶质载体家族7成员11(SLC7A11)在肾透明细胞癌(ccRCC)发生、发展中的作用及其预后价值。方法采用两样本孟德尔随机化分析以识别与ccRCC风险存在因果关系的基因。使用来自UCSC Xena泛癌队列的RNA测序数据及临床数据分析SLC7A11的表达及预后意义。使用TCGA-KIRC数据(训练集)进行基因集富集分析(GSEA)。随后通过逐步Cox回归分析建立了基于SLC7A11的预后模型,并在E-MATB-1980队列(验证集)中进行了外部验证。结果孟德尔随机化分析显示,SLC7A11水平升高会加重ccRCC的患病风险(HR=1.27,95%CI:1.15~1.40,P<0.001)。SLC7A11在各种肿瘤中过表达,并与高T分期和较差的生存预后相关(P<0.05)。GSEA显示SLC7A11富集在增殖和转移相关通路,包括E2F和上皮-间质转化信号通路。SLC7A11预后模型在训练集(1、3、5年AUC=0.78、0.73、0.71)和验证集(1、3、5年AUC=0.70、0.71、0.72)中均显示出强大的预测性能。结论SLC7A11作为ccRCC的潜在生物标志物和治疗靶点,为精准医学提供了新视角。