Human natural killer cells for targeting delivery of gold nanostars and bimodal imaging directed photothermal/photodynamic therapy and immunotherapy

Objective:To construct a novel nanoplatform GNS@CaCO3/Ce6-NK by loading the CaCO3-coated gold nanostars(GNSs)with Chlorin e6 molecules(Ce6)into human peripheral blood mononuclear cells(PBMCs)-derived NK cells for tumor targeted therapy.Methods:GNS@CaCO3/Ce6 nanoparticles were prepared and characterized by TEM and UV-vis.The cell surface markers and cytokines secretion of NK cells before and after loading the GNS@CaCO3/Ce6 nanoparticles were detected by Flow Cytometry(FCM)and ELISA.Effects of the GNS@CaCO3/Ce6-NK cells on A549 cancer cells was determined by FCM and CCK-8.Intracellular fluorescent signals of GNS@CaCO3/Ce6-NK cells were detected via Confocal laser scanning microscopic(CLSM)and FCM at different time points.Intracellular ROS generation of GNS@CaCO3/Ce6-NK cells under laser irradiation were examined by FCM.The distribution of GNS@CaCO3/Ce6-NK in A549 tumor-bearing mice were observed by fluorescence imaging and PA imaging.The combination therapy of GNS@CaCO3/Ce6-NK under laser irradiation were investigated on tumor-bearing mice.Results:The coated CaC03 shell on the surface of GNSs exhibited prominent delivery and protection effect of Ce6 during the cellular uptake process.The as-prepared multifunctional GNS@CaCO3/Ce6-NK cells possessed bimodal functions of fluorescence imaging and photoacoustic imaging.The as-prepared multifunctional GNS@CaCO3/Ce6-NK cells could actively target tumor tissues with the enhanced photothermal/photodynamic therapy and immunotherapy.Conclusions:The GNS@CaCO3/Ce6-NK shows effective tumor-targeting ability and prominent therapeutic efficacy toward lung cancer A549 tumor-bearing mice.Through fully utilizing the features of GNSs and NK cells,this new nanoplatform provides a new synergistic strategy for enhanced photothermal/photodynamic therapy and immunotherapy in the field of anticancer development in the near future.

Laser Pulse Duration Optimization for Photothermal Therapy with Gold Nanostars

Photothermal therapy (PTT), which utilizes light radiation to create localized heating effect in the targeted areas, is a promising solution for highly specific yet minimally invasive cancer therapy. PTT uses photothermal agents, which are usually nanoparticles that absorb strongly in the near-infrared optical window where minimal tissue absorption occurs. Photothermal agents are also highly functionalized to target at specific tumor sites. Gold nanostar is an ideal candidate for photothermal agents, because it not only has a Surface Plasmon Resonance in the near-infrared, but also can be easily produced and purified, and is extremely versatile in the drug delivery process. In order to achieve maximum amount of localized heating, pulse lasers are usually used in laser ablation processes like photothermal therapy. However, intensive laser radiation can cause damage to regular tissues as well the nanostructures themselves. Therefore, identifying the optimal pulse duration to effectively generate localized heating in the tumorous tissues while keeping the normal tissues and the nanostructures intact is important to achieving optimal photo-therapeutic results. This manuscript provides a numerical calculation method with Comsol Multiphysics to optimize the pulse condition of the gold nanostars under photothermal therapy settings. Based on results, gold nanostar displays significant temperature heterogeneity under femtosecond and picosecond laser radiation, while nanosecond laser only induces rather uniform heating effects across the entire gold nanostar particle. This finding indicates that femtosecond laser, which is the most common type of laser used for ablation, is likely to melt the tip of the gold nanostar before the nanostar body reaches a reasonably high temperature. Picosecond and nanosecond lasers are much less likely to induce such dramatic morphology change. This study offers important insight into finding the optimal condition for photothermal therapy with maximal efficacy and minimal damage.

Real-time in situ observation of P53-mediated cascade activation of apoptotic pathways with nucleic acid multicolor fluorescent probes based on symmetrical gold nanostars

T-2 toxin,one of the most dangerous natural pollutants,induces apoptosis through multiple pathways.Amongst,P53 mediated apoptosis pathway,an important collection of molecules,plays a key role in cell vital activity.Real-time monitoring of upstream and downstream activation relationships of P53 mRNA,Bax mRNA,and cytochrome c(Cyt c)in signaling pathways is of great significance for understanding the apoptotic machinery in human physiology.In this work,a novel nucleic acid multicolor fluorescent probe,based on silica-coated symmetric gold nanostars(S-AuNSs@SiO_(2)),was developed for highly sensitive in situ real-time imaging of P53 mRNA,Bax mRNA,and Cyt c during T-2 toxin-induced apoptosis.The nucleic acid chains modified with carboxyl groups were modified on the surface of S-AuNSs@SiO_(2)by amide reaction.The complementary chains of targeted mRNA and the aptamer of targeted Cyt c were modified with different fluorophores,respectively,and successfully hybridized on S-AuNSs@SiO_(2)surface.When targets were present,the fluorescent chains bound to the targets and detached from the material,resulting in the quenched fluorescence being revived.The probes based on S-AuNSs showed excellent performance is partly ascribed to the presence of 20 symmetric“hot spots”.Notably,the amide-bonded probe exhibited excellent anti-interference capability against biological agents(nucleases and biothiols).During the real-time fluorescence imaging of T-2 toxin-induced apoptosis,the corresponding fluorescence signals of P53 mRNA,Bax mRNA,and Cyt c were observed sequentially.Therefore,S-AuNSs@SiO_(2)probe not only provides a novel tool for real-time monitoring of apoptosis pathways cascade but also has considerable potential in disease diagnosis and pharmaceutical medical.

Passively Q-switched erbium doped fiber laser using a gold nanostars based saturable absorber

In this paper, we propose and demonstrate an all-fiber passively Q-switched erbium doped fiber laser(EDFL) by using gold nanostars(GNSs) as a saturable absorber(SA) for the first time, to the best of our knowledge. In comparison with other gold nanomorphologies, GNSs have multiple localized surface plasmon resonances, which means that they can be used to construct wideband ultrafast pulse lasers. By inserting the GNS SA into an EDFL cavity pumped by a 980 nm laser diode, a stable passively Q-switched laser at 1564.5 nm was achieved for a threshold pump power of 40 mW. By gradually increasing the pump power from 40 to 120 mW, the pulse duration decreases from 12.8 to 5.3 μs and the repetition rate increases from 10 to 17 kHz. Our results indicate that the GNSs are a promising SA for constructing pulse lasers.

Integrin α_(v)β_(3)-targeted polydopamine-coated gold nanostars for photothermal ablation therapy of hepatocellular carcinoma

Photothermal therapy(PTT)has emerged as a promising cancer therapeutic method.In this study,Arg-Gly-Asp(RGD)peptide-conjugated polydopamine-coated gold nanostars(Au@PDA-RGD NPs)were prepared for targeting PTT of hepatocellular carcinoma(HCC).A polydopamine(PDA)shell was coated on the surface of gold nanostars by the oxidative self-polymerization of dopamine(termed as Au@PDA NPs).Au@PDA NPs were further functionalized with polyethylene glycol and RGD peptide to improve biocompatibility as well as selectivity toward the HCC cells.Au@PDARGD NPs showed an intense absorption at 822 nm,which makes them suitable for near-infraredexcited PTT.Our results indicated that the Au@PDA-RGD NPs were effective for the PTT therapy of the α_(v)β_(3) integrin receptor-overexpressed HepG2 cells in vitro.Further antitumor mechanism studies showed that the Au@PDA-RGD NPs-based PTT induced human liver cancer cells death via the mitochondrial-lysosomal and autophagy pathways.In vivo experiments showed that Au@PDARGD NPs had excellent tumor treatment efficiency and negligible side effects.Thus,our study showed that Au@PDA-RGD NPs could offer an excellent nanoplatform for PTT of HCC.

Controllable Preparation of Plasmonic Gold Nanostars for Enhanced Photothermal and SERS Effects

Gold nanostars(Au NSs)are asymmetric anisotropic nanomaterials with sharp edge structure.As a promising branched nanomaterial,Au NS has excellent plasmonic absorption and scattering properties.In order to tune the plasmonic photothermal and surface-enhanced Raman scattering(SERS)activity of Au NSs to obtain the desired characteristics,the ffects of reagents on the local surface plasmon resonance(LSPR)bands of Au NSs were studied and the morphology and size were regulated.Nanoparticles with different sharp edges were synthesized to make their local plasmon resonance mode tunable in the visible and near-infrared region.The effects of the number and sharpness of different tips under the control of AgNO3 on the photothermal response of Au NSs and the SERS ac-tivity and their mechanism were discussed in detail.The results show that as the length of the branch tip becomes longer and the sharpness increases,the plasmonic photothermal effect of Au NSs is strengthened,and the photother-mal conversion efficiency is the highest up to 40%when the length of Au NSs is the longest.Au NSs with high SERS activity are used for the Raman detection substrate.Based on this property,the quantitative detection of the pesticide thiram is achieved.

Synthesis of different-sized gold nanostars for Raman bioimaging and photothermal therapy in cancer nanotheranostics

Gold nanoparticles(AuNPs) have been attractive for nanomedicine because of their pronounced optical properties.Here,we customerized the methods to synthesize two types of gold nanostars,Au nanostars-1 and Au nanostars-2,which have different spire lengths and optical properties,and also spherical AuNPs.Compared to nanospheres,gold nanostars were less toxic to a variety of cells,including macrophages.Au nanostars-1 and Au nanostars-2 also manifested a similar pattern of tissue distribution upon in vivo administration in mice to that of nanospheres,and but reveled less liver retention than nanospheres.Due to their strong absorption in the near-infrared(NIR),Au nanostars-2 induced a strong hyperthermia effect in vitro upon excitation at 808 nm,and elicited a robust photothermal therapy(PTT) efficacy in ablating tumors in a mouse model of orthotopic breast cancer using 4T1 breast cancer cells.Meanwhile,Au nanostars-1 showed a great capability to enhance the Raman signal through surface-enhanced Raman spectroscopy(SERS) in 4T1 cells.Our combined results opened a new avenue to develop Au nanostars for cancer imaging and therapy.

Hierarchical Nanogold Labels to Improve the Sensitivity of Lateral Flow Immunoassay

Lateral flow immunoassay(LFIA) is a widely used express method and offers advantages such as a short analysis time, simplicity of testing and result evaluation.However, an LFIA based on gold nanospheres lacks the desired sensitivity, thereby limiting its wide applications.In this study, spherical nanogold labels along with new types of nanogold labels such as gold nanopopcorns and nanostars were prepared, characterized, and applied for LFIA of model protein antigen procalcitonin. It was found that the label with a structure close to spherical provided more uniform distribution of specific antibodies on its surface, indicative of its suitability for this type of analysis.LFIA using gold nanopopcorns as a label allowed procalcitonin detection over a linear range of 0.5–10 ng mL^(-1) with the limit of detection of 0.1 ng mL^(-1), which was fivefold higher than the sensitivity of the assay with gold nanospheres. Another approach to improve the sensitivity of the assay included the silver enhancement method,which was used to compare the amplification of LFIA for procalcitonin detection. The sensitivity of procalcitonin determination by this method was 10 times better the sensitivity of the conventional LFIA with gold nanosphere as a label. The proposed approach of LFIA based on gold nanopopcorns improved the detection sensitivity without additional steps and prevented the increased consumption of specific reagents(antibodies).

Hot spots enriched plasmonic nanostructure-induced random lasing of quantum dots thin film

Here,a plasmon-enhanced random laser was achieved by incorporating gold nanostars（NS） into disordered polymer and Cd Se/Zn S quantum dots（QDs） gain medium films,in which the surface plasmon resonance of gold NS can greatly enhance the scattering cross section and bring a large gain volume.The random distribution of gold NS in the gain medium film formed a laser-mode resonator.Under a single-pulse pumping,the scattering center of gold NS-based random laser exhibits enhanced performance of a lasing threshold of 0.8 m J/cm^2 and a full width as narrow as 6 nm at half maximum.By utilizing the local enhancement characteristic of the electric field at the sharp apexes of the gold NS,the emission intensity of the random laser was increased.In addition,the gold NS showed higher thermal stability than the silver nanoparticles,withstanding high temperature heating up to 200？C.The results of metal nanostructures with enriched hot spots and excellent temperature stability have tremendous potential applications in the fields of biological identification,medical diagnostics,lighting,and display devices.

紫杉醇温敏脂质体与siRNA金纳米星载药系统的构建与表征

用种子生长法制备金纳米星(gold nanostar,GNS),构建聚乙二醇(polyethylene glycol,PEG)、氨基葡萄糖(2-amino-2-deoxy-D-glucose,DG)和九聚精氨酸(9-D-arginine,9R)修饰的载COX-2 siRNA(siCOX-2)的GNS复合纳米粒[siCOX-2(9R/DG-GNS)];以薄膜分散法制备载紫杉醇温敏脂质体(paclitaxel temperature sensitive liposome,PTX-TSL);最后将siCOX-2(9R/DG-GNS)与PTX-TSL体通过巯基配位得到PTX-TSL与siCOX-2(9R/DG-GNS)共载药系统PTX-TSL-[siCOX-2(9R/DG-GNS)]。采用核磁共振、聚丙烯酰胺凝胶电泳、紫外分光光度法、琼脂糖凝胶电泳法验证了siCOX-2(9R/DG-GNS)成功构建,马尔文电位粒度仪测得PTX-TSL-[siCOX-2(9R/DG-GNS)]粒径电位分别为(292±14)nm、-(2.59±0.12)m V,透射电子显微镜结果显示其结构呈包裹磷脂双分子层的星型,808 nm激光照射下表现出良好的光热转换效率。差示扫描量热法测试PTX-TSL相变温度约为42.6℃,透析法测得其载药量为7.5%,包封率为95.4%,具有良好的温敏释药性能。因此,本复合物纳米载药系统可作为PTX与siCOX-2的共载药体系,用以抗肿瘤耐药治疗。

金种子生长法制备小尺寸金纳米星

本研究采用金种子生长法,通过优化氯金酸溶液用量、生长液pH值以及反应温度等条件,制备出一种全新的小尺寸金纳米星(Au-NSs)颗粒,方法具有可控、稳定、简单、Au-NSs粒径均一等优点。紫外-可见-近红外(UV-Vis-NIR)光谱和透射电子显微镜(TEM)检测表明,该方法制备出的Au-NSs的粒径在40nm左右,远小于常规方法制得的Au-NSs(~80nm)。最终制备条件确定为:生长液、金种溶液和抗坏血酸(AA)的体积比为600∶9∶7;生长液的pH≈3.05;制备Au-NSs的温度条件为先冰浴加入金种,回升至室温后加入AA还原。

金纳米星负载二氢卟吩e6对肺癌A549细胞的光动力效应

目的:制备负载光敏剂二氢卟吩e6(chlorin e6,Ce6)的金纳米星(gold nanostars,GNS),研究其对肺癌A549细胞的光动力作用效果。方法:GNS经巯基聚乙二醇(SH-PEG-NH2)修饰后与光敏剂Ce6振荡过夜,制备出具有光动力治疗效应的探针GNS-PEG@Ce6,检测其表征、形态和包封率,通过激光共聚焦显微镜比较A549细胞对探针GNS-PEG@Ce6与Ce6的吞噬作用。应用MTT法检测探针GNS-PEG@Ce6对A549细胞增殖的抑制效果,通过流式细胞仪检测探针GNS-PEG@Ce6与Ce6对A549细胞凋亡的影响。结果:探针GNS-PEG@Ce6的粒径为100 nm左右,具有良好的分散性和稳定性,Ce6的包封率为50%左右。探针GNS-PEG@Ce6以胞吞方式进入细胞,主要分布于细胞质内,且较Ce6能更有效地进入细胞。探针GNS-PEG@Ce6对A549细胞的增殖抑制作用强于Ce6(P<0.05),流式细胞仪检测证明了探针对细胞有极为明显的致凋亡效果。结论:以GNS作为载体能有效地增加肺癌A549细胞对Ce6的摄取,从而进一步增强Ce6对肺癌A549细胞的杀伤效果。

基于纳米金星的层析试纸条用于检测HIV-DNA（英文）

构建了基于纳米金星(AuNSs)的快速、简单且可视化的横向流层析试纸条(LFTS),并用于检测人类免疫缺陷病毒的DNA。采用一步法合成AuNSs,并对其进行生物功能化,目标物与DNA修饰的AuNSs结合。该复合物通过碱基互补配对原则被捕获在测试线上,依据测试线上纳米金星颜色的变化进行定性和半定量分析,使用便携式读条器在最佳实验条件下进行定量分析。该方法的线性范围为0.2～50 nmol/L,检出限为0.14 nmol/L。相同条件下,该方法比传统纳米金试纸条的灵敏度约高5倍。该方法可用于人血清中HIV DNA的检测,结果良好。

金纳米星/双锥的可控制备、光热转换及体外光热治疗

采用种子生长法,分别制备了金纳米星和金纳米双锥,利用透射电子显微镜、紫外-可见(UV-Vis)分光光度计等对样品进行了表征,并评价了金纳米星和金纳米双锥的光热转换性能、生物相容性以及体外光热治疗性能。结果表明,金纳米星和金纳米双锥的UV-Vis吸收峰位于808 nm和815 nm左右。在808 nm激光辐照下,光热转换效率分别为48.43%和53.68%。细胞实验表明,金纳米星和金纳米双锥具有良好的生物相容性。808 nm激光辐照5 min后,MCF-7细胞存活率分别降至22.54%和13.73%;且在同等条件下,金纳米双锥具有更加优异的光热治疗性能,是一种安全、高性能的肿瘤光热治疗用纳米探针材料。

金纳米星诊疗剂的光热特性及其在光热治疗和光学相干层析成像中的应用研究

为了开发一种优异的用于光热治疗和光学相干层析成像的金纳米星诊疗剂,对金纳米星的制备、光热特性以及光热治疗和光学相干层析成像中的应用进行研究。利用尖端结构增强金纳米材料的局域表面等离子体共振特性,通过种子介导法制备了多枝化的金纳米星,多尖端的结构使其具有明显的光热效果,并探究了其作为光热治疗的诊疗剂和光学相干层析成像造影剂的效果。实验结果表明:多枝化的金纳米星诊疗剂相比于金纳米粒子具有较高的光热转换效率,达到42%;具有较好的生物兼容性,在100μg/mL浓度下,人乳腺癌细胞存活率为82%;而且具有较好的癌细胞光热治疗效果,在100μg/mL浓度下,经激光照射后,人乳腺癌细胞被有效杀死,其存活率降至37%;同时,金纳米星诊疗剂还具有较好的光学相干层析成像造影效果,可显著提高信号强度和造影深度。金纳米星诊疗剂既具有高效光热治疗能力,又具备优异光学相干层析成像造影成像能力,是一种非常有前景的多功能诊疗剂。

双糖聚合物接枝金纳米星的制备及光热性能研究

通过酶促反应和可逆加成-断裂链转移聚合(RAFT)聚合得到温度敏感性的双糖无规聚合物聚(二聚乙二醇单甲醚甲基丙烯酸酯-6-O-乙烯基己二酸-D-吡喃型葡萄糖/半乳糖酯)[Poly(DEGMA-co-OVNGmix)];利用还原剂将聚合物末端的硫酯键还原,得到末端为-SH的聚合物分子以S-Au键修饰到金纳米星表面。采用傅里叶红外光谱仪、透射电镜和核磁氢谱等手段对聚合物和复合金纳米星的理化性质和光热转化能力进行研究。结果表明:AuNSs@Poly(DEGMA-co-OVNGmix)成功制备,该复合粒子的平均粒径为50~100nm,并且具有良好的稳定性。光热性能测试结果表明,复合粒子的光热转换效率达到50.54%,说明经修饰的金纳米星具有优异的光热转换能力。

金纳米材料的合成方法进展

本文综述了金纳米材料的合成方法,主要对一维金纳米粒子中的金纳米线和零维金纳米粒子中的金纳米星的合成方法进行了简单介绍,并指出了其优点与不足。最后对未来金纳米材料的应用前景进行了展望。

金纳米星的光学性质在肿瘤诊治应用的研究进展

随着医学的不断发展,生物材料在医学领域的应用逐渐成为研究热点。金纳米颗粒具有优良的稳定性、物理化学性质及光学性质等,在生物医学诊断和治疗中的应用日益增多,如药物递送及光热治疗等。金纳米星(gold nanostars,GNSs)作为一种新型的金纳米材料,因其独特的星形结构和较大的比表面积,使其光热效应尤为突出,越来越受到科学家们的关注。笔者就GNSs的结构、光学性质进行评价,并指出其在医学领域尤其是肿瘤诊断与治疗方面的应用前景。

光辐照精确调控金纳米星枝杈长度及其光热性能探究

金纳米星是一种具有尖状结构的多分枝纳米颗粒.为了使金纳米星枝杈长度可控,利用HEPES作为体系的还原剂、稳定剂及形状诱导剂,在制备过程中进行光辐照,得到的金纳米星枝杈长度比无光辐照时的金纳米星枝杈长度短,而且不同波长光辐照得到的金纳米星枝杈长度有显著不同.在此基础上,分析了金纳米星枝杈长度变化的物理过程,提出光诱导金纳米星生长过程中枝杈长度变化的理论模型.测量了不同枝杈长度的金纳米星在光辐照下一定时间内的温度变化,计算了金纳米星的光热转换效率.实验结果表明,光辐照制备金纳米星能够精确控制金纳米星枝杈长度范围,从而调控金纳米星的光热转换效率.

各向异性金纳米粒子的制备及其在催化中的应用（英文）

尽管有关金纳米粒子催化的研究工作很多,但其中大多数都是采用传统的浸渍法将金盐负载到载体上、共沉淀或沉积-沉淀法制得负载的纳米粒子,但这些方法并未吸收最新的纳米技术.最近,金催化剂的研究者开发了在胶态悬浮液中制取金属纳米粒子,然后进行固载,从而使得单金属和双金属催化剂的催化活性和形貌控制取得较大进展.另一方面,最近十年出现了金纳米粒子合成的高级控制技术,得到了许多各向异性的金纳米粒子,且很容易制得新的形貌,可以控制纳米粒子的表面原子配位数和光学特性(可调的等离子体带),这些都与催化密切相关.这些形貌包括纳米棒、纳米星、纳米花、树枝状纳米结构或多面体纳米粒子等.除了高度关注各向异性金纳米粒子的最新开发的制备方法和性质,本综述也清楚地总结了这些纳米粒子独特的催化性能,以及通过提供更高催化性能的金催化剂、控制暴露的活性位,以及热、电和光催化的鲁棒性和可调性,从而给多相催化领域带来令人惊奇的潜在变革.