Photodynamic Therapy Using Novel Zinc Phthalocyanine Derivatives and a Diode Laser for Superficial Tumors in Experimental Animals

Photodynamictherapy (PDT) using a photo sensitizing agent and several light sources has been shown to have nonspecific and noninvasive effects on superficial cancers. Phthalocyanine (Pc) derivatives as novel photosensitizers, trifluoroethoxy-coatedzinc Pcconjugated with β-cyclodextrin (βCD-4TFEO-Pc) was synthesized and its photodynamic effect in vitro and in vivo was evaluated. βCD-4TFEO-Pc alone was completely non-cytotoxic even at high concentrations, and showed excellentphotodynamic effects in B16-F10 and HT-1080 celllines. The in vivo antitumor effect of βCD-4TFEO-Pc against B16-F10 cells transplanted on to the chorioallantoic membranes of chickembryos was 52.7%, but that of laserirradiation alone and photosensitizer alone was 2 (50 mW). These data suggest that βCD-4TFEO-Pc is a useful photosensitizer for the treatment of superficial cancers. If a high-power LED with optimal wavelength is developed, excellent treatment of superficial cancers could be achieved by applying βCD-4TFEO-Pc for PDT.

Spectroscopic Properties of a Novel Zinc Phthalocyanine with four 17-Membered Crown Ether Voids

A zinc phthalocyanine containing (17-crown-5) ether subunits has been synthesized UV-visible absorption and fluorescence emission spectra and associated photophysical parameters have been determined. In addition to the fluorescence at 710 nm from S-1, a strong upper excited state emission around 424 nn has been detected. X-ray structural analysis showed that the crown ether unit is conformationally deformed and oblate like that accounted for the unusual spectroscopic properties.

Increased performance of an organic light-emitting diode by employing a zinc phthalocyanine based composite hole transport layer

We demonstrate that the electroluminescent performances of organic light-emitting diodes are significantly improved by employing a zinc phthalocyanine （ZnPc）-based composite hole transport layer （c-HTL）. The optimum ris-（8-hydroxyquinoline）aluminum （Alq3）-based organic light-emitting diode with a c-HTL exhibits a lower turn-on voltage of 2.8 V, a higher maximum current efficiency of 3.40 cd/A and a higher maximum power efficiency of 1.91 lm/W, which are superior to those of the conventional device （turn-on voltage of 3.8 V, maximum current efficiency of 2.60 cd/A, and maximum power efficiency of 1.21 lm/W）. We systematically studied the effects of different kinds of N’-diphenyl-N,N’-bis（1-naphthyl）（1,1’-biphenyl）-4,4’diamine （NPB）：ZnPc c-HTL. Meanwhile, we also investigate their mechanisms different from that in the case of using ZnPc as buffer layer. The specific analysis is based on the absorption spectra of the hole transporting material and current density–voltage characteristics of the corresponding hole-only devices.

Nonlinear Refraction of Peripheral-Substituted Zinc Phthalocyanines Investigated by Nanosecond and Picose-cond Z Scans

The singlet and triplet excited-state refraction cross-sections of dimethyl sulfoxide (DMSO) solutions of ten zinc phthalocyanine derivatives with mono-or tetra-peripheral substituents at 532 nm were obtained by simultaneous fitting of closed-aperture Z scans with both nanosecond and picosecond pulse widths. Self-focusing of both nanosecond and picosecond laser pulses was observed in all complexes at 532-nm wavelength. The complexes with tetra-substituents at the ?-position exhibit relatively larger refraction cross-sections than the other complexes. The wavelength dependence of the singlet refraction cross-section of a representative complex was observed to be non-monotonic in the range of 470 - 550 nm.

PHOTOINDUCED ELECTRON TRANSFER I.INTER-AND INTRAMOLECULAR QUENCHING OF ZINC PHTHALOCYANINE FLUORESCENCE BY ANTHRAQUINONE

Inter-and intramolecular quenching of zinc phthalocyanine fluorescence by anthraquinone has been studied.The diminutions of fluorescence quantum yield and life-time are due primarily to electron transfer.Apparent electron transfer rate constants were calculated depending on the chain length and solvent polarity.

不同激发波长下ZnPcSP的光敏化能力和抗癌活性

研究了激发光的波长对金属酞菁配合物ZnPcSP光敏化产生1O2的能力和光动力抗癌作用的影响．结果表明，激发波长对ZnPcSP配合物光敏化产生1O2的能力和光动力抗癌作用的影响显示了同样的规律性，波长为670um的光具有较佳的激发效率．研究结果同时说明ZnPcSP在光动力治癌中的主要光敏反应机制可能是产生1O2的Ⅱ型反应机制．

ZnPcS_2P_2介导的光动力疗法联合mGM-CSF、mB7.1基因修饰的瘤苗治疗小鼠淋巴瘤

目的研究两亲性酞菁锌光敏剂ZnPcS2P2介导的光动力疗法(ZnPc-PDT)联合GM-CSF、B7.1基因修饰的EL-4细胞,对小鼠淋巴瘤的抑制作用。方法应用反复多次转染的方法,分别将逆转录病毒pLXSN、pLXSNmGM-CSF、pLXS-NmB7.1导入EL-4细胞,分别命名为EL-4/pLXSN、EL-4/GM和EL-4/B7。进行ZnPc-PDT时,经荷瘤小鼠的尾静脉注射ZnPcS2P2,4h后局部用波长670nm的激光照射瘤体;光源为670nm的半导体激光仪。将40只荷瘤小鼠分为5组,每组8只,即对照组(不做任何处理)、EL-4/B7+EL-4/GM对照组、ZnPc-PDT对照组、ZnPc-PDT+EL-4/pLXSN对照组、ZnPc-PDT+EL-4/B7+EL-4/GM实验组。隔天测量瘤块的大小,观察荷瘤小鼠淋巴瘤的生长情况,并计算瘤块的相对体积(RTV)。观察荷瘤小鼠的生存期及瘤组织的病理学改变。结果实验组的生存率高于各个对照组(P<0.01)。Zn-Pc-PDT组小鼠的生存期略高于EL-4/B7+EL-4/GM组(P=0.01)。结论mB7.1、mGM-CSF基因修饰的瘤苗可显著增强ZnPc-PDT的抗肿瘤效应。

阳极修饰层ZnPc对OLED性能影响的研究

本文采用真空蒸镀法制备了不同厚度的酞菁锌(ZnPc)超薄膜,研究了不同厚度的ZnPc缓冲层对OLEDs器件发光性能的影响,测试了器件的一系列光电性能,对相关机理进行了探讨。结果表明:含有ZnPc修饰层的器件性能明显优于不含有修饰层的器件,加入ZnPc修饰层后器件发光稳定性也得到了改善,同时不同厚度的修饰层对器件性能的影响也有所不同。分析认为,ZnPc能有效改善ITO表面的平整度和降低空穴注入势垒的性质是提高器件性能的主要原因。

一种酞菁锌纳米粒的体外溶出度测定方法的建立与溶出曲线评价

体外溶出是纳米药物重要的质量控制指标,本文对酞菁锌纳米粒的体外溶出进行研究。首先,对比紫外可见和荧光分光光度计对酞菁锌纳米粒中酞菁锌测定的专属性,并建立其标准曲线及进行精密度、回收率实验。之后用透析法测试体外溶出,对比不同溶出介质及取样处理方法对酞菁锌纳米粒中酞菁锌溶出情况的影响并用软件模拟释放模型。结果显示以荧光分光光度计检测时,酞菁锌在0.4~1.9μg·mL^(-1)范围内线性关系良好,相关系数为0.9991。在0.5、1.0、1.5μg·mL^(-1)三个水平下,相对标准偏差(RSD)为1.16~2.32%,精密度良好,且在加样回收实验中回收率为99.40~106.23%。此外,以通常的磷酸缓冲液(PBS)加1%十二烷基硫酸钠(SDS)为溶出介质,将取样冻干后DMF稀释并用荧光分光度计检测。在84 h时,pH 5.0/50μM H_(2)O_(2)组累积溶出可达58.21%。该组体外释放曲线最符合Ritger-peppas方程模型,即药物扩散和骨架溶蚀的共同作用释放机制。

ZnPcH1介导的光动力疗法净化白血病SHI-1细胞

本研究探讨新型酞菁类光敏剂二磺基二邻苯二甲酰亚胺甲基酞菁锌(ZnPcH1)介导的光动力疗法(PDT)对急性单核细胞白血病SHI-1细胞的杀伤作用及其机制,为PDT应用于白血病自体骨髓体外净化提供理论依据。以SHI-1细胞作为研究对象,应用MTT比色法检测细胞增殖。采用AO/EB复合染色、TUNEL、DNA二倍体分析、An-nexin-Ⅴ-FITC/PI双染法等分析细胞的死亡方式。SHI-1细胞与正常骨髓单个核细胞(MNC)以1∶100-1∶10 000混合建立混合细胞模型,通过巢式RT-PCR检测SHI-1细胞融合基因MLL/AF6 mRNA的表达以研究ZnPcH1-PDT对骨髓MNC中所掺入的SHI-1细胞的净化效果。结果表明,ZnPcH1-PDT对SHI-1细胞有杀伤作用,且呈量效关系。Zn-PcH1-PDT能诱导细胞凋亡,且呈时间依赖性。0.5μmol/L ZnPcH1-PDT可完全杀灭模拟缓解骨髓中掺入的SHI-1细胞。结论:ZnPcH1-PDT有希望成为新的高效而简便的骨髓净化手段。

锌酞菁基多孔有机聚合物催化CO_(2)与环氧化物的环加成反应

以四氨基酞菁锌和均苯三甲醛为原料,通过席夫碱缩合反应,在溶剂热的条件下制备了锌酞菁基多孔有机聚合物(ZnPc-POP)。采用FTIR、^(13)CNMR、XPS、TEM和N_(2)吸附-脱附对其进行了表征,以环氧氯丙烷(ECH)和CO_(2)的环加成反应为模型,以四丁基溴化铵(TBAB)为助催化剂,考察了ZnPc-POP的催化性能、循环使用性和其催化不同环氧化物的底物适用性,并对催化机理进行了探究。结果表明,ZnPc-POP具有丰富的介孔结构(孔容约为0.64 cm^(3)/g,平均孔径约为20 nm)和大的比表面积(171.6 m^(2)/g)。ECH在100℃和1.0 MPa CO_(2)条件下生成环状碳酸酯的选择性>99%,产率为96%,转化频率(TOF)高达533.3 h^(-1)。ZnPc-POP循环使用5次后,其催化活性无明显降低。ZnPc-POP催化不同环氧化物的环加成反应的选择性≥96%。环氧化物中三元环氧原子与ZnPc-POP的Lewis酸位点锌中心发生配位作用而被有效活化,助催化剂TBAB中Br–通过亲核进攻促进环氧化物开环,该双重活化环氧化物开环是CO_(2)环加成反应的控速步骤。

室温下ZnPc/MWCNTs敏感膜检测NO_2

提出了一种以酞菁锌(ZnPc)掺杂多壁碳纳米管(MWCNTs)作为声表面波(SAW)传感器的敏感材料用于室温下检测二氧化氮(NO2)。通过超声振荡等方法将研磨的MWCNTs和ZnPc分散于N,N-二甲基中,然后运用微量移液器滴涂到SAW器件的敏感区。我们对ZnPc/MWCNTs薄膜用扫描式电子显微镜(SEM)进行了表面形态表征。实验结果表明,基于MWCNTs的ZnPc SAW器件能在常温下检测最低浓度为10-6的NO2。在3个月内对器件的灵敏度、稳定性、选择性也进行了评估。

Photogenerated carrier transfer mechanism and photocatalysis properties of TiO_2 sensitized by Zn(Ⅱ) phthalocyanine

The Zn(Ⅱ) phthalocyanine sensitized TiO2(ZnPc-TiO2) nanoparticles were prepared by hydrothermal method via impregnation with ZnPc.The as-prepared photocatalysts were characterized by X-ray diffractometry(XRD) and diffuse reflectance spectroscopy(DRS),and the surface photovoltage spectroscopy(SPS) and photocatalytic degradation of rhodamine B(RhB) were studied under illuminating.The experimental results indicate that TiO2 sensitized by ZnPc extends its absorption band into the visible region effectively,and the sensitized TiO2 has higher activity than TiO2(Degussa P-25) under the simulated solar light and the visible light.Based on the DRS and SPS results,the mechanism about the photogenerated carrier transfer between TiO2 and ZnPc is proposed.At a lower ZnPc content(≤0.20 μmol/g),ZnPc monomer acts as the electron donor,which provides the photoinduced electrons to the conduction band of TiO2.These photoinduced electrons can transfer to molecular oxygen(O2),leading to the formation of active species,such as superoxide/hydroxide radicals and singlet oxygen,which is beneficial to the photocatalytic reaction.While at a higher ZnPc content(>0.20 μmol/g),the formation of ZnPc dimer results in the decrease of photocatalytic activities of ZnPc-TiO2 photocatalyst.

ZnPc/PbPc共混蒸镀薄膜二极管的制备与工作特性

有机薄膜二极管选取酞菁锌和酞菁铅(ZnPc和PbPc)进行混合作为器件的有源层,利用多种镀膜方式,制备了结构为Cu/ZnPc+PbPc/Al的器件,其中,Zn Pc∶PbPc混合的质量比分别为1∶1、4∶5和5∶4,对二极管进行了输出特性测试和混合薄膜的吸收光谱测试。结果表明,3种混合方式的二极管均具有整流特性。通过实验分析可以得出:ZnPc∶Pb Pc的混合质量比为1∶1的器件的载流子的传输最快。实验结果表明:适当的ZnPc∶PbPc的混合质量比可以降低肖特基势垒的高度,从而使载流子的迁移率加大。由实验结果计算得出,ZnPc∶PbPc的混合质量比为1∶1的器件的势垒高度为0.355eV,影响因子n为18.21。

酞菁铜-氧化锌复合材料的制备及其气敏特性

将p型有机半导体材料酞菁铜(CuPc)和n型无机半导体材料氧化锌(ZnO)复合,得到p-n型的CuPc-ZnO复合材料,促进了目标气体在敏感层表面发生反应,提高了敏感层的气敏性能。在结晶度、形貌和结构等方面对制备的CuPc-ZnO敏感材料进行了详细表征,并对CuPc-ZnO复合材料的气敏性能进行了系统评估。结果表明无论是向CuPc中掺入少量的ZnO,还是向ZnO中掺入少量的CuPc,均可显著提高单一材料的气敏性能,这两种复合敏感材料对NO_(2)都展现了优异的选择性和良好的响应/恢复特性。其中,基于质量分数3%的CuPc/ZnO复合材料的传感器在150℃下对体积分数1×10^(-5)的NO_(2)的响应高达90,与基于纯ZnO的传感器相比,灵敏度明显提升,该传感器是检测NO_(2)的有利候选者。

锌酞菁接枝纤维素纳米纤维膜的制备及其染料降解性能

针对现有染料光催化降解技术中存在的难回收、循环性差、需紫外光照射等问题,本文制备了一种有机光敏剂接枝纳米纤维膜材料用于染料的高效可见光催化降解。首先利用静电纺丝技术制备纳米乙酸纤维素膜,然后在碱液中水解制备再生纤维素膜(HCA),接着将合成的四羧基锌酞菁光敏剂(CZnPc)通过酯化反应共价接枝到HCA,得到CZnPc功能化纤维素纳米纤维膜(CZnPc-HCA)。采用红外光谱、核磁共振氢谱、质谱与扫描电子显微镜等表征结构和表观形貌,并研究了CZnPc-HCA的光敏活性。结果表明:CZnPc-HCA具有优异的单线态氧产生性能;经氙灯照射90 min,亚甲基蓝初始质量浓度为4 mg/L时,CZnPc-HCA膜(3 cm×3 cm)对其降解率达到75%以上。

TAP酞菁锌光敏剂对大肠杆菌的抗菌活性

为探究TAP[2,4,6-三(二甲氨甲基)苯酚]酞菁锌光敏剂对大肠杆菌的抗菌活性,通过紫外OD检测法测定大肠杆菌的生长曲线图,确定大肠杆菌的最适生长期;利用紫外光谱法测定获得TAP酞菁光敏剂的紫外-浓度标准曲线;采用稀释涂板法、试剂盒检测法(CCK8)和探针法(DCFH-DA)等研究TAP酞菁锌光敏剂对大肠杆菌的抗菌作用。试验数据表明:大肠杆菌的对数生长期约在接种后4~10 h;TAP酞菁锌光敏剂对大肠杆菌具有显著的光动力抗菌活性,其抗菌作用与光敏剂浓度呈正比;TAP酞菁锌光敏剂可能是通过产生氢氧自由基型单线态氧发挥抗菌作用。研究证明TAP酞菁锌光敏剂对大肠杆菌有强光动力抗菌作用,为TAP酞菁锌光敏剂及其系列抗菌产品开发和利用提供参考。

两种四氨基锌酞菁异构体的简易合成及其表征

分别从 4 -硝基邻苯二甲酰亚胺和 3-硝基邻苯二甲酸酐出发 ,经过两步反应 ,不经色层分离 ,制得了纯净的 2 ,9,1 6 ,2 3-四氨基锌酞菁和 1 ,8,1 5 ,2 2 -四氨基锌酞菁两种异构体 .对所合成的产物进行了质谱、1 H NMR及紫外可见光谱表征 .结果表明 ,两种异构体在其 DMF溶液中有二聚现象 ,其分子上的氨基不易氧化 .前者分子上的氨基动力学稳定性强 ,后者分子上的氨基热力学稳定性强 ,且后者分子中存在分子内氢键 .

磺酸基邻苯二甲酰亚氨甲基酞菁锌的合成及光动力抗肿瘤活性研究

合成了含不同数目磺酸基（以Ｓ表示）和邻苯二甲酰亚氨甲基（以Ｐ表示）的酞菁锌配合物的混合物，采用反相高效液相色谱进行分离，得到的Ｄ组分，经元素分析其组成为ＺｎＰｃＳ２Ｐ２两亲性配合物，对该配合物进行了ＩＲ、ＵＶ／Ｖｉｓ光谱表征，并研究了其在体对Ｓ１８０和Ｕ１４实体瘤的光动力活性和机理。

新型单取代两亲性酞菁锌的制备及其光动力活性研究

设计并制备了一种组成和结构单一的新型两亲性酞菁锌光敏剂.采用固相合成法合成出2单-羧基取代酞菁锌,并使之与五聚赖氨酸偶联成五聚赖氨酸2-羰基酞菁锌.综合运用各种分析及光谱方法对所得化合物进行表征和确认.研究了在光照下五聚赖氨酸2-羰基酞菁锌对3种肿瘤细胞(人源肝癌细胞Bel7402、人源胃癌细胞BGC823和人源白血病细胞K562)与一种正常细胞(人源胚肺成纤维细胞HELF)的杀灭活性.该光敏剂不仅克服了酞菁锌在水中溶解度低的问题,且因所偶联的五聚赖氨酸对肿瘤细胞有靶向作用,具有较高的杀灭肿瘤细胞活性.