共载依克立达和阿霉素的PBM-Hz-PEG纳米粒制备与性能研究

摘要 目的：研究不同比例依克立达（ELC）和阿霉素（DOX）的联合抗肿瘤效果,确定最佳联用比例。以生物可降解材料聚苹果酸苄基酯（PBM）为载体包封两种药物,得到一种酸敏感纳米胶束。方法：以L-天冬氨酸为原料通过内酯开环法制备PBM,并以酸敏感的腙键（Hz）连接PEG,得到嵌段聚合物PBM-Hz-PEG,红外光谱和核磁氢谱对其结构进行表征。动态透析法制备纳米胶束,测定纳米胶束的粒度、分散系数（PDI）、临界胶束浓度（CMC）及其载药量（DL）、包封率（EE）。动态透析法模拟胶束的体外释药性能,采用三阴性乳腺癌MDA-MB-231细胞系考察载药纳米胶束的体外细胞毒性。结果：①ELC能够增敏DOX,二者摩尔比为1:3时有最强肿瘤抑制作用。②经红外光谱和核磁共振氢谱表征,嵌段共聚物PBM-Hz-PEG成功合成。③空白纳米胶束的粒径为69.67±11.55 nm,PDI为0.245 ± 0.026,CMC值为3.9 μg?mL^-1;载药纳米胶束粒径略大,粒径在96.92 ~ 113.47 nm之间,ELC和DOX的载药量与投料比一致。④载药纳米胶束在pH 7.4和pH 6.0时的药物释放率曲线和体外细胞毒性试验证实载药胶束具有良好的酸敏特性。结论：ELC和DOX联用有较强的肿瘤抑制作用,PBM是二者的优良载体。该PBM-Hz-PEG纳米胶束载药率高,其特有的酸敏性能够有效降低药物对正常组织的毒副作用,具有肿瘤组织富集释放特性,有望成为一种新型智能释药平台。     

双模态纳米诊疗一体药物在肝癌动物模型中的应用

摘要 目的：构建一种肿瘤诊断和治疗一体化药物，并利用肝癌动物模型开展诊疗效能评价。方法：利用多孔金属有机骨架材料ZIF-8，通过配位作用同时对化疗药物阿霉素（DOX）和近红外荧光染料IR-820进行负载。而后，利用超声的方法在ZIF-8-IR-820-DOX表面修饰了红细胞膜以提高载药体系的生物安全性和稳定性，得到具有生物伪装特性的pH响应型ZIF-8-IR-820-DOX@RM纳米颗粒。最后，通过对该药物体系的粒径、表面电位、形貌等理化性质进行表征，并利用肝癌动物模型验证该药物的诊断和治疗效能。结果：成功构建了一款红细胞伪装的金属框架纳米诊疗一体试剂，该试剂具有较好的pH相应性，在肿瘤pH 5.5 条件下，药物的释放率达到98.4 %，而在机体正常pH 7.4条件下，释放率仅为15.3 %。在小鼠肝癌动物模型的诊疗过程中，能通过近红外荧光较好的识别肿瘤的位置和大小，且对小鼠肿瘤具有较好的治疗效果。结论：本研究所构建的ZIF-8-IR-820-DOX @RM能通过肿瘤处增强的渗透性和保留（EPR）效应，精准的到达肿瘤部位，并利用pH响应性，在肿瘤酸性环境中精准释放携带的抗肿瘤药物和近红外荧光成像试剂，实现对肿瘤的诊断和治疗一体化设计。为肿瘤治疗的相关研究提供了一种思路和借鉴。     

胆甾醇基γ-聚谷氨酸负载阿霉素纳米胶束的制备与体内外释药性能评价

笔者制备了胆甾醇基γ-聚谷氨酸负载阿霉素纳米胶束(DOX/NPs),并考察了该载药纳米胶束体系的形态与粒径、载药量、包封率以及体内外释药的特性。结果表明:DOX/NPs的最佳载药量为22.4%,包封率为90.2%,平均粒径为(312.3±7.2)nm,电镜下观察呈现明显的核壳结构。体外释药结果显示,DOX/NPs能延缓阿霉素的释放,并具有p H敏感的释药特性。小鼠体内释药结果表明:阿霉素经包埋后其消除半衰期(t1/2)、药时曲线下面积(AUC)、平均滞留时间(MRT)均明显大于游离阿霉素,达到了药物缓释的目的。     

巨噬细胞膜仿生纳米铁颗粒制备及多形性胶质母细胞瘤MRI成像的初步实验研究

摘要 目的：探讨巨噬细胞膜仿生的纳米铁颗粒（Fe3O4 NCs@MM）对多形性胶质母细胞瘤MRI成像的研究。方法：制备巨噬细胞膜仿生的纳米铁颗粒Fe₃O₄ NCs@MM,利用动态光散射（Dynamic Light Scattering,DLS）和透射电子显微镜（Transmission Electron Microscope,TEM）对其水合动力学粒径、表面电势和形态进行表征。采用SDS-聚丙烯酰胺凝胶电泳（sodium dodecyl sulphate-polyacrylamide gel electrophoresis,SDS-PAGE）评价巨噬细胞膜的完整包覆;紫外可见光谱测定巨噬细胞膜仿生的纳米铁颗粒抗蛋白吸附能力。通过MRI成像系统,分析了含不同浓度的Fe元素（0.1-1.6 mM）的Fe₃O₄ NCs@MM在GSH存在或不存在时的T₁弛豫效应。采用细胞增殖-毒性实验（Cell Counting Kit-8,CCK-8）,测定巨噬细胞膜仿生纳米铁颗粒处理肿瘤细胞24 h后的细胞活性。尾静脉注射巨噬细胞膜仿生纳米铁颗粒至原位胶质母细胞瘤模型中,观察成像效果。结果：巨噬细胞膜仿生的纳米铁颗粒Fe₃O₄ NCs@MM的水合动力学粒径和表面电势分别为 286.5±7.6 nm和-20.7±3.5 mV,且在水溶液中分布均匀,具有较好的单分散性。包覆巨噬细胞膜的纳米铁颗粒具备抗蛋白吸附的能力。MRI成像显示,制备的巨噬细胞膜仿生的纳米铁颗粒Fe₃O₄ NCs@MM为GSH响应型MRI对比剂,具有较好的T₁-加权磁共振成像效果,在尾静脉注射巨噬细胞膜的纳米铁颗粒0.5 h后,肿瘤部位的信号可见增强。结论：巨噬细胞膜仿生的纳米铁颗粒Fe₃O₄ NCs@MM可实现多形性胶质母细胞瘤的MRI成像。     

还原可降解聚磺酸甜菜碱型纳米水凝胶的制备及载药研究

目的:制备与表征还原可降解的聚磺酸甜菜碱型纳米水凝胶,利用该纳米递药系统包载阿霉素(DOX)并初步评价其抗肿瘤性能。方法:利用回流沉淀聚合的方法合成含二硫键的聚磺酸甜菜碱甲基丙烯酸酯(PSBMA)纳米水凝胶及不含二硫键的PSBMA纳米凝胶(nd-PSBMA);通过粒度仪和透射电镜考察两种纳米水凝胶的粒径、形态以及稳定性;通过考察谷胱甘肽(GSH)对纳米凝胶溶液相对浊度的影响以评价还原环境对两种纳米凝胶的还原可降解性;利用纳米凝胶包载阿霉素(DOX),考察载药凝胶在GSH中的释药行为,并初步评价其对A549肿瘤细胞的杀伤作用。结果:以N, N'-双丙烯酰胱胺为交联剂制备了含二硫键的PSBMA纳米凝胶,其粒径在180～200 nm;同时以N, N'-双丙烯酰胺为交联剂制备了不含二硫键的n-PSBMA纳米凝胶。两种纳米凝胶与小鼠血清共孵育7天水合粒径仍无明显变化,表明磺酸甜菜碱型纳米凝胶具有良好的抗蛋白吸附能力。此外,PSBMA纳米凝胶在GSH溶液中迅速地降解,且降解速度与GSH浓度呈正相关;而nd-PSBMA纳米凝胶在GSH溶液中几乎不降解。载DOX的PSBMA纳米凝胶可在GSH作用下快速的释放药物而载DOX的nd-PSBMA纳米凝胶在GSH作用下缓慢的释放药物;体外细胞实验显示空白纳米凝胶和载药nd-PSBMA对A549细胞无明显毒性作用,但载DOX的PSBMA纳米凝胶可高效地杀死A549肿瘤细胞,其药效与游离DOX相仿。结论:还原可降解的PSBMA纳米水凝胶有望成为智能型控释药物载体。     

马利亚霉菌(Mariannaeasp.) HJ合成金属硒化物及机理研究

[背景] 金属硒化物因其优异的光电和催化特性,近年来在半导体、电化学及抗癌等领域成为了研究热点。相较于传统的化学还原法,生物合成金属硒化物具有环境友好、耗能较低等优势。然而,目前有关生物合成金属硒化合物的微生物资源较少且相关合成机理尚不明晰。[目的] 利用马利亚霉菌（Mariannaea sp.） HJ合成了3种金属硒化物并对其合成机理进行了初步探索。[方法] 利用X射线衍射（X-Ray Diffraction,XRD）和傅里叶转换红外线光谱（Fourier Transform Infrared Spectroscopy,FTIR）对菌株HJ合成的金属硒化物进行了初步的表征,考察了纳米材料合成过程中总巯基含量、总抗氧化性能及自由基含量变化,并且验证了转运蛋白DMT1在金属硒化物合成中所起的关键性作用。[结果] XRD结果表明菌株HJ能够在Bi³⁺、Pb²⁺、Co²⁺与SeO₃^2-作用下分别合成Bi₄Se₃、PbSe和CoSe₂纳米颗粒,其合成的最优pH条件分别为6.0、7.0、8.0。FTIR结果表明,合成的金属硒化物表面含有氨基、羧基、羟基等官能团。3种金属硒化物的合成反应体系与空白对照组相比,总巯基含量明显下降,而总抗氧化性能却有所提高,这表明巯基等酶促体系或氨基酸金属蛋白类的非酶促体系可能参与了SeO₃^2-的还原过程。苄基异硫脲盐酸盐屏蔽实验表明,转运蛋白DMT1在SeO₃^2-转运和金属硒化物分泌过程中起到关键作用。此外,Bi³⁺、Pb²⁺和Co²⁺的加入使得菌株HJ产生氧化应激反应,在胞外分泌了大量的过氧化氢、羟基自由基和超氧自由基,而上述自由基可通过诱导热激效应的方式增强金属离子或纳米颗粒的转运过程。[结论] 利用马利亚霉菌（Mariannaeasp.） HJ合成了Bi₄Se₃、PbSe和CoSe₂纳米颗粒,为研究金属硒化物的生物合成及机理提供了一定的理论参考。     

聚乙二醇连接荧光Cy5.5构建超小超顺磁性氧化铁成像探针的制备与表征

摘要 目的：以超小超顺磁性氧化铁颗粒为载体通过聚乙二醇连接荧光Cy5.5构建核磁/荧光分子探针并表征。方法：取Cy5.5-NHS荧光粉末溶于二甲基甲砜（Dimethyl sulfoxide,DMSO）溶液,将PEG四氧化三铁颗粒离心超滤之后用磷酸盐缓冲液（Phosphate Buffered Saline,PBS）重悬纳米颗粒改变PEG化四氧化三铁纳米颗粒溶液pH。将配置好的Cy5.5荧光加入到四氧化三铁颗粒中,恒温摇床孵育,通过离心过滤器去除较大铁离子与未结合的荧光,静置后检测水合粒径及Zeta电位,纽麦小核磁检测其驰豫率,CCK-8实验检测其细胞毒性,激光共聚焦显微镜观察探针被细胞摄取情况。结果：合成Cy5.5-PEG-FeO₄探针,透射电镜（Transmission electron microscope,TEM）显示探针粒径为16.8±2.4nm,纳米颗粒的水合径为43.4±17.6 nm,Zeta电位为-18.0 mV。驰豫率为39.5 mM^-1?s^-1,R²为0.98。细胞毒性实验结果显示对细胞有轻微毒性,且毒性与浓度呈依赖性。激光共聚焦结果显示此款探针可顺利被细胞摄取。结论：成功合成Cy5.5-PEG-FeO₄探针。     

原位可注射壳聚糖基温敏水凝胶的制备及其在预防ESD术后食管狭窄中分阶段释药应用研究

摘要 目的：构建一种可以分阶段释放药物的原位可注射水凝胶，通过直接注射在ESD（Endoscopic Submucosal Dissection，内镜黏膜下剥离术）术后伤口处，形成水凝胶敷料，起到保护伤口的作用。同时凝胶中的两种药物通过分阶段释放的方式，更好地促进伤口的无瘢痕愈合，为ESD术后食管狭窄的预防提供一种新的参考方案。方法：在壳聚糖/β-甘油磷酸钠（CS/β-GP）温敏水凝胶的体系中加入聚多巴胺（PDA），制备壳聚糖/β-甘油磷酸钠/聚多巴胺（CS/?β-GP/PDA）水凝胶。通过在载药水凝胶中加入聚乙二醇-聚乳酸-羟基乙酸（PEG-PLGA）纳米载药微粒制备CS/β-GP/PDA/NPs双载药水凝胶，通过两种载药体系的复合，实现药物的分阶段释放。通过流变学实验测定CS/β-GP、CS/β-GP/PDA、CS/β-GP/PDA/NPs凝胶体系的相转变温度以及凝胶强度。通过高效液相色谱法检测CS/β-GP/PDA/NPs水凝胶中两种药物的释放动力学特征。通过CCK-8细胞增殖实验评价CS/β-GP/PDA、CS/β-GP/PDA/NPs温敏水凝胶的生物相容性。在体外猪食管中，模拟ESD术后创口，通过内镜辅助将水凝胶母液注射在伤口处，并通过内镜观察水凝胶的凝胶状态。结果：得到了粘附性显著增强的壳聚糖/β-甘油磷酸钠/聚多巴胺（CS/β-GP/PDA）凝胶体系。流变学实验证明聚多巴胺（PDA）的加入可以显著降低水凝胶的凝胶温度，缩短原位成胶时间。CCK-8实验显示CS/β-GP/PDA、CS/β-GP/PDA/NPs凝胶体系无潜在的细胞毒性。在体外猪食管模拟实验中，将其凝胶母液注射在伤口处后，可原位形成凝胶，且凝胶贴合伤口，具有较强的粘附性。通过体外释药速率测定，验证了CS/β-GP/PDA/NPs水凝胶中所载两种药物释放速率存在明显差异，可实现药物的分阶段释放。结论：设计的CS/β-GP/PDA/NPs凝胶体系适用于ESD术后的伤口修复，并能够实现分阶段释药，对于预防ESD术后食管狭窄具有潜在的应用价值。     

缺氧对椭圆囊毛细胞谷氨酸递质合成及释放的影响

摘要 目的：探讨缺氧对豚鼠前庭耳石器椭圆囊毛细胞内兴奋性神经递质谷氨酸的合成及释放的影响。方法：分离4周龄豚鼠双侧椭圆囊进行体外培养,分别置于常氧（21% O₂）和低氧（1% O₂）环境下处理30 min,利用Western blotting、酶活性检测等方法检测前庭外周感受器椭圆囊斑毛细胞中谷氨酰胺酶的活性和表达水平,评价谷氨酸合成变化情况;利用ELISA、免疫荧光等方法检测椭圆囊组织中谷氨酸含量和毛细胞内谷氨酸分布情况。结果：在给予缺氧处理后,豚鼠椭圆囊毛细胞中谷氨酸合成关键酶谷氨酰胺酶的表达、酶活性均未发生显著性变化（P>0.05）;ELISA结果提示,相较于对照组,低氧组椭圆囊组织中谷氨酸水平降低5.6%（对照组vs.缺氧组：15.86±2.19 vs.13.02±1.21,P<0.05）;免疫荧光结果提示,相较于对照组,低氧组椭圆囊毛细胞内的谷氨酸更加广泛的分布于毛细胞基底部,而在纤毛一侧分布较少。结论：在体外培养的椭圆囊组织中,低氧处理并未影响毛细胞谷氨酸的合成过程,但会显著增加毛细胞内兴奋性神经递质谷氨酸的释放。     

用于核酸递送的GSH响应型纳米粒构建

摘要 目的：核酸治疗近年来越来越受到关注,但是核酸药物易被快速清除、易被核酸酶降解、非特异性生物分布、以及不易被细胞摄取的缺点使其在体内难以发挥效果。本文提供了一种具有谷胱甘肽（GSH）响应性释放的纳米粒,能够进行有效核酸药物递送。方法：使用十六烷基三甲基氯化铵（CTAC）制备介孔硅纳米粒,在介孔硅纳米粒表面进行巯基修饰并活化,使其与巯基修饰的聚丙烯亚胺和聚乙二醇反应,形成具有GSH响应的介孔硅纳米粒,通过静电吸附进行核酸荷载。马尔文粒度仪测量表面电位、粒径,透射电镜观察纳米粒形态。核酸电泳检测其核酸负载效率,通过体外检测GSH响应释放聚乙烯亚胺（PEI）情况,共聚焦显微镜观察细胞摄取以及溶酶体逃逸情况。结果：成功构建了具有GSH响应的纳米粒,粒径为76.44±1.68 nm,表面电位为33.93±0.59 mV;通过透射电镜观察到纳米粒呈圆形带孔颗粒状;琼脂糖核酸负载试验观察到当氮磷比大于20时,能够有效进行核酸负载。共聚焦显微镜显示该纳米粒能够成功被MDA-MB-231乳腺癌细胞摄取。在溶酶体逃逸试验中观察到纳米粒进入细胞后3 h,Cy5-siRNA与溶酶体的荧光分离,证明构建的纳米粒成功从溶酶体逃脱。结论：成功构建了具有GSH响应的介孔硅纳米粒,能够有效用于核酸递送。     

Doxorubicin conjugated carbon dots as a drug delivery system for human breast cancer therapy

Objectives

Carbon dots (CDs) are one of the most promising carbon‐based materials in bioimaging and drug/gene delivery applications. In this study, we have attempted to study the drug carrying capacity of highly fluorescent CDs for delivery of doxorubicin (DOX) and investigate the therapeutic activity of the CDs‐DOX drug delivery system.

Materials and methods

Carbon dots were synthesized by means of a hydrothermal approach with mixing citric acid and ethylenediamine. The properties of CDs were characterized in respects of spectral property, zeta potential, particle morphology and chemical composition. The drug loading efficiency (DLE) and release profile of CDs‐DOX were determined by a fluorescence spectrophotometer. We investigated the cellular toxicity and pharmaceutical activity of CDs and CDs‐DOX in L929 cells and MCF‐7 cells by the CCK‐8 assay. We also studied the cellular uptake of CDs‐DOX with the methods of confocal microscopy and flow cytometry. In addition, the effect of CDs‐DOX on cell apoptosis was assessed by flow cytometry.

Results

The obtained CDs possessed good biocompatibility and showed a potential capacity of promoting proliferation. DOX was successfully conjugated to CDs through electrostatic interaction, and the results of the DLE and loading content (DLC) suggested a relatively high drug loading capacity of CDs. Compared with free DOX, the CDs‐DOX complex had a higher cellular uptake and better anti‐tumour efficacy on MCF‐7 cells.

Conclusions

The results of this study indicated that the CDs‐DOX drug delivery system had a potential value in cancer chemotherapeutic application.

     

Reduction/pH dual-sensitive PEGylated hyaluronan nanoparticles for targeted doxorubicin delivery

To minimize the side effect of chemotherapy, a novel reduction/pH dual-sensitive drug nanocarrier, based on PEGylated dithiodipropionate dihydrazide (TPH)-modified hyaluronic acid (PEG-SS-HA copolymer), was developed for targeted delivery of doxorubicin (DOX) to hepatocellular carcinoma. The copolymer was synthesized by reductive amination via Schiff's base formation between TPH-modified HA and galactosamine-conjugated poly(ethylene glycol) aldehyde/methoxy poly(ethylene glycol) aldehyde. Conjugation of DOX to PEG-SS-HA copolymer was accomplished through the hydrazone linkage formed between DOX and PEG-SS-HA, and confirmed by FTIR and ¹H NMR spectra. The polymer–DOX conjugate could self-assemble into spherical nanoparticles (∼150 nm), as indicated by TEM and DLS. In vitro release studies showed that the DOX-loaded nanoparticles could release DOX rapidly under the intracellular levels of pH and glutathiose. Cellular uptake experiments demonstrated that the nanoparticles could be efficiently internalized by HepG2 cells. These results indicate that the PEG-SS-HA copolymer holds great potential for targeted intracellular delivery of DOX.     

Ultrathin MoS2 Nanosheets as Anode Materials for Sodium‐Ion Batteries with Superior Performance

Few‐layer MoS₂ nanosheets are successfully synthesized using a simple and scalable ultrasonic exfoliation technique. The thicknesses of the MoS₂ nanosheets ares about 10 nm as measured by scanning electron microscopy (SEM) and atomic force microscopy (AFM). The unique nanosheet architecture renders the high‐rate transportation of sodium ions due to the short diffusion paths provided by ultrathin thickness and the large interlayer space within the MoS₂ crystal structure (d₍₀₀₂₎ = 6.38 Å). When applied as anode materials in sodium‐ion batteries, MoS₂ nanosheets exhibit a high, reversible sodium storage capacity and excellent cyclability. The MoS₂ nanosheets also demonstrate good electrochemical performance at high current densities.     

Hollow chitosan/poly(acrylic acid) nanospheres as drug carriers

The preparation, in-vitro release, in-vitro cytotoxicity, and in-vivo drug delivery of doxorubicin (DOX)-loaded chitosan (CS)-poly(acrylic acid) (PAA) hollow nanospheres were investigated. The loading was done by dissolving a certain amount of DOX in non-cross-linked CS-PAA nanospheres aqueous solution followed by cross-linking chitosan with glutaraldehyde. The drug-loading content was up to 4.3% and the size of drug-loaded hollow nanospheres, determined by dynamic light scattering, was 118 nm. The nanospheres showed a continuous release of the entrapped DOX up to 10 days in vitro and showed comparable in-vitro cytotoxicity against HepG2 cells compared to the free DOX. In-vivo DOX delivery of DOX-loaded CS-PAA nanospheres showed that DOX concentration in blood can be maintained for a longer period than free DOX solution, and the DOX concentration in mice liver can be maintained constantly at relatively high level. The interesting feature of DOX-loaded CS-PAA hollow nanopspheres is that the loaded DOX can be delivered into the mice brain. The confocal laser scanning microscopy analysis reveals that fluorescein isothiocyanate (FITC)-labeled CS-PAA can deposit in different organs including liver, spleen, and brain.     

巨噬细胞装载纳米颗粒用于药物递送

目的:活细胞药物递送系统具有主动靶向至肿瘤部位,防止被免疫系统清除等诸多优势。本文提供了一种巨噬细胞负载纳米颗粒的递送方法,并探讨不同载药量对巨噬细胞的活性以及运动性的影响。方法:通过超声乳化法制备包载阿霉素的DOX@PLGA纳米颗粒。纳米粒度分析仪测量粒径和表面电位,透射电镜观察纳米颗粒形态。将DOX@PLGA纳米颗粒与巨噬细胞共同孵育,即得到负载DOX@PLGA纳米颗粒的巨噬细胞用以药物递送。然后通过CCK-8法、LDH法以及细胞迁移实验检测不同载药量情况下细胞活力水平、细胞损伤程度以及细胞运动性。结果:制备的DOX@PLGA纳米颗粒呈圆形或椭圆形,粒径为109.2±2.3 nm;表面电位为-45.0±2.0 m V;载药量为4.61%。当单个巨噬细胞负载0.15 pg DOX时细胞存活率为:71.5±4.4(%);细胞损伤率为:26.3±1.8(%);迁移率为:61.6±5.7(%)。结论:成功制备巨噬细胞负载DOX@PLGA纳米颗粒的递药系统,载药量适当的情况下载体细胞依然具有良好的活性和运动性。     

Targeted Delivery of Doxorubicin-Loaded Poly (ε-caprolactone)-b-Poly (N-vinylpyrrolidone) Micelles Enhances Antitumor Effect in Lymphoma

Background

The present study was motivated by the need to design a safe nano-carrier for the delivery of doxorubicin which could be tolerant to normal cells. PCL₆₃-b-PNVP₉₀ was loaded with doxorubicin (6 mg/ml), and with 49.8% drug loading efficiency; it offers a unique platform providing selective immune responses against lymphoma.

Methods

In this study, we have used micelles of amphiphilic PCL₆₃-b-PNVP₉₀ block copolymer as nano-carrier for controlled release of doxorubicin (DOX). DOX is physically entrapped and stabilized in the hydrophobic cores of the micelles and biological roles of these micelles were evaluated in lymphoma.

Results

DOX loaded PCL₆₃-b-PNVP₉₀ block copolymer micelles (DOX-PCL₆₃-b-PNVP₉₀) shows enhanced growth inhibition and cytotoxicity against human (K-562, JE6.1 and Raji) and mice lymphoma cells (Dalton''s lymphoma, DL). DOX-PCL₆₃-b-PNVP₉₀ demonstrates higher levels of tumoricidal effect against DOX-resistant tumor cells compared to free DOX. DOX-PCL₆₃-b-PNVP₉₀ demonstrated effective drug loading and a pH-responsive drug release character besides exhibiting sustained drug release performance in in-vitro and intracellular drug release experiments.

Conclusion

Unlike free DOX, DOX-PCL₆₃-b-PNVP₉₀ does not show cytotoxicity against normal cells. DOX-PCL₆₃-b-PNVP₉₀ prolonged the survival of tumor (DL) bearing mice by enhancing the apoptosis of the tumor cells in targeted organs like liver and spleen.     

Fullerenol-Based Intracellular Delivery of Methotrexate: A Water-Soluble Nanoconjugate for Enhanced Cytotoxicity and Improved Pharmacokinetics

Derivatization of fullerenes to polyhydroxylated fullerenes, i.e., fullerenols (FLU), dramatically decreases their toxicity and has been reported to enhance the solubility as well as cellular permeability. In this paper, we report synthesis of FLU as nanocarrier and subsequent chemical conjugation of Methotrexate (MTX) to FLU with a serum-stable and intracellularly hydrolysable ester bond between FLU and MTX. The conjugate was characterized for physiochemical attributes, micromeritics, drug-loading, and drug-release and evaluated for cancer cell-toxicity, cellular-uptake, hemocompatibility, protein binding, and pharmacokinetics. The developed hemocompatible FL-MTX offered lower protein binding vis-à-vis naïve drug and substantially higher drug loading. The conjugate offered pH-dependent release of 38.20?±?1.19% at systemic pH and 85.67?±?3.39% at the cancer cell pH. FLU-MTX-treated cells showed significant reduction in IC₅₀ value vis-à-vis the cells treated with pure MTX. Analogously, the results from confocal scanning laser microscopy also confirmed the easy access of the dye-tagged FLU-MTX conjugate to the cell interiors. In pharmacokinetics, the AUC of MTX was enhanced by approx. 6.15 times and plasma half-life was enhanced by 2.45 times, after parenteral administration of single equivalent dose in rodents. FLU-MTX offered enhanced availability of drug to the biological system, meanwhile improved the cancer-cell cytotoxicity, sustained the effective plasma drug concentrations, and offered substantial compatibility to erythrocytes.     

超声靶向微泡破坏与载药/载基因纳米粒联合应用的生物物理学机制及应用研究进展

超声靶向微泡破坏(ultrasound-targeted microbubble destruction, UTMD)能够安全、高效、简便地递送药物与基因,是当前超声医学领域的研究热点,其机制主要涉及超声辐照微泡引起的空化效应及其二级效应、内吞作用与声辐射力。近年来,随着生物医学材料科学迅猛发展,纳米载药系统取材更加广泛,制备方法愈发精良,载药量日益提高。将纳米载药系统与UTMD进行联合,可以扬长避短,为肿瘤等多种疾病的治疗带来新的思路与希望。本文旨在对UTMD与载药/载基因纳米粒联合应用的生物物理学机制及应用研究进行综述并提出展望。     

MoS2/Graphene Nanosheets from Commercial Bulky MoS2 and Graphite as Anode Materials for High Rate Sodium‐Ion Batteries

Tuning heterointerfaces between hybrid phases is a very promising strategy for designing advanced energy storage materials. Herein, a low‐cost, high‐yield, and scalable two‐step approach is reported to prepare a new type of hybrid material containing MoS₂/graphene nanosheets prepared from ball‐milling and exfoliation of commercial bulky MoS₂ and graphite. When tested as an anode material for a sodium‐ion battery, the as‐prepared MoS₂/graphene nanosheets exhibit remarkably high rate capability (284 mA h g^?1 at 20 A g^?1 (≈30C) and 201 mA h g^?1 at 50 A g^?1 (≈75C)) and excellent cycling stability (capacity retention of 95% after 250 cycles at 0.3 A g^?1). Detailed experimental measurements and density functional theory calculation reveal that the functional groups in 2D MoS₂/graphene heterostructures can be well tuned. The impressive rate capacity of the as‐prepared MoS₂/graphene hybrids should be attributed to the heterostructures with a low degree of defects and residual oxygen containing groups in graphene, which subsequently improve the electronic conductivity of graphene and decrease the Na⁺ diffusion barrier at the MoS₂/graphene interfaces in comparison with the acid treated one.