GE7导入系统介导抑癌基因NOEY2体内导入治疗人上皮性卵巢癌裸鼠网膜移植瘤的研究

目的 :研究GE7导入系统体内导入效率及介导抑癌基因NOEY2体内导入后对人上皮性卵巢癌裸鼠网膜移植瘤的治疗作用。方法 :将人上皮性卵巢癌细胞株Hey细胞种植于裸鼠皮下成瘤后半包埋缝于裸鼠脾区网膜建立网膜移植瘤模型。将GE7- β -gal四元复合体经腹腔注入荷瘤鼠体内用X -gal染色法检测基因导入效率 ,同法导入生理盐水、GE7-pcDNA3四元复合体及GE7-pcDNA3-NOEY2四元复合体 ,研究其抑制肿瘤生长的作用。结果 :人上皮性卵巢癌裸鼠网膜移植瘤的成瘤率达 10 0 % ,3周后瘤体达 3 68± 0 82g。GE7- β -gal四元复合体经腹腔注入荷瘤鼠体内 12h后 β -gal即有表达 ,4 8h后以瘤体、肝、脾表达率最高。GE7-pcDNA3-NOEY2四元复合体腹腔注射 3周后瘤体生长抑制率为 4 0 81% (P <0 0 5)。结论 :人上皮性卵巢癌裸鼠网膜移植瘤模型具有实用性。GE7导入系统体内导入基因效率高 ,具有相对肿瘤靶向性。GE7导入系统介导抑癌基因NOEY2体内导入后能有效抑制上皮性卵巢癌的生长。

GE7导入系统介导抑癌基因NOEY2体内导入治疗人上皮性卵巢癌裸鼠腹水瘤

目的 研究GE7导入系统介导抑癌基因NOEY2体内导入后对人上皮性卵巢癌裸鼠腹水瘤的治疗作用。方法 将人上皮性卵巢癌细胞株skov3ipl细胞种植于裸鼠腹腔内建立腹水瘤模型。将生理盐水、GE7 pcD NA3四元复合体及GE7 pcDNA3 NOEY2四元复合体导入荷瘤裸鼠体内研究其抑制肿瘤生长作用。结果 人上皮性卵巢癌裸鼠腹水瘤的成瘤率达 90 % ,GE7 pcDNA3 NOEY2四元复合体腹腔注射后第 2周裸鼠的体重较对照组明显减轻 (P <0 .0 5) ,但第 3周起 3组体重无明显差异。 3组裸鼠的生存期无明显差异。结论 GE7导入系统介导抑癌基因NOEY2体内导入后能延缓但不能抑制上皮性卵巢癌腹水的生长 ,且对腹水瘤裸鼠的生存期无明显延长作用。人上皮性卵巢癌裸鼠腹水瘤模型具有实用性。

GE7导入系统介导I型单纯疱疹病毒胸腺嘧啶核苷激酶基因联合5-FU治疗卵巢癌的研究

目的 :观察HSV1 tk/GCV基因治疗系统与 5 FU序贯应用 ,对卵巢上皮癌SKOV3细胞的体内杀伤效应。方法 :建立裸鼠卵巢癌皮下移植瘤模型 ,免疫组化检测移植瘤组织中表皮生长因子受体 (EGFR)的表达 ;于瘤周分别注射GE7 β gal、GE7 HSV1 tk复合物 ,用X gal及RT PCR检测两种基因的表达 ;取 2 4只荷瘤裸鼠随机分成空白对照组、5 FU组、GE7 HSV1 tk/GCV组及GE7 HSV1 tk/GCV/5 FU组进行实验 ,观察肿瘤体积及重量的变化 ,计算各组抑瘤率。结果 :移植瘤中有较高的EGFR表达 ,β gal基因及HSV1 tk基因经瘤周注射导入移植瘤后均有不同程度的表达 ,5 FU组、GE7 HSV1 tk/GCV组及GE7 HSV1 tk/GCV/5 FU组抑瘤率分别为 14 .6 %、39.4 %和 6 0 .5 % (P <0 .0 5 )。结论 :HSV1 tk/GCV和 5 FU序贯治疗能有效地抑制肿瘤生长 ,并能有效地抑制单纯使用HSV1 tk/GCV系统治疗后的远期反跳作用 ,提高卵巢癌基因治疗的远期疗效。

GE7导入系统介导I型单纯疱疹病毒胸腺嘧啶核苷激酶基因联合5-FU治疗卵巢癌的临床研究

目的:在5-Fu治疗卵巢癌腹膜后转移的过程中序贯应用HSVl-tk/GCV基因治疗系统,观察探究联合应用的作用。方法:建立卵巢癌腹膜后转移动物模型,分成三组,试验组:HSVl-tk/GCV基因治疗系统与5-Fu序贯应用组(A)。对照组:应用同等剂量的5-F(uB组)。空白对照组:应用同等剂量的生理盐水组(C组),观察肿瘤的生物学行为和治疗效果。结果:A组的瘤体体积、重量相比B、C减轻。A组的生存状态提高。结论:HSVl-tk/GCV基因治疗系统与5-Fu序贯应用治疗卵巢癌腹膜后转移的效果优于对照组。

In vitro effect of p2l^(WAF-1/CIP1) gene on growth of human glioma cells mediated by EGFR targeted non-viral vector GE7 system

Objective: To construct the EGFR targeted non-viral vector GE7 system and explore the in vitro effect of p21WAF-1/CIPI gene on growth of human glioma cells mediated by the GE7 system. Methods: The EGFR targeted non-viral vector GE7 gene delivery system was constructed. The malignant human glioma cell line U251MG was transfected in vitro with β-galactosidase gene ( reporter gene) and p21WAF-1/CIPI gee (therapeutic gene) using the GE7 system. By means of X-gal staining, MTS and FACS, the transfection efficiency of exogenous gene and apoptosis rate of tumor cells were examined. The expression of p21WAF-1/ CIPI gene in transfected U251MG cell was examined by immunohistochemis-try staining. Results: The highest transfer rate of exogenous gene was 70% . After transfection with p21WAF-1/CIPI gene, the expression of WAF-1 increased remarkably and steadily; the growth of U251MG cells were inhibited evidently. FACS examination showed G1 arrest. The average apoptosis rate was 25.2%. Conclusion: GE7 system has the ability to transfer exogenous gene to targeted cells efficiently, and expression of p21WAF-1/CIPI gene can induce apoptosis of glioma cell and inhibit its growth.

Inhibition of the growth of human hepatoma cell line both in vitro and in vivo by transducing CKI gene p21^(WAF-1) with GE7 targeting gene delivery system

The EGF receptor-mediated targeting gene delivery system GE7 was used to transduce exogenous gene pCEP-p21WAF-1 into human hepatocellular carcinoma cell both in vitro and in vivo. After in vitro transduction of the exogenous gene, the growth of the cell lines SMMC-7721 and BEL-7402 was significantly inhibited compared with the control. On day 8 the inhibition rates of the above cell lines reached 56.0% and 66.7%, respectively. The in vivo experiment showed that the growth of human hepatoma transplanted in nude mice injected with GE7 gene delivery system subcutaneously once a week for 3 weeks was remarkably inhibited compared with that of untrans-fected control. The average tumor weight of the experiment group was (0.083 ?0.043) g, while that of the control group was (0.28110.173) g. The difference is significant (P<0.05). It was indicated that GE7 gene delivery system could efficiently transduce exogenous gene pCEP-p21WAF-1 into hepatoma cell with high EGF receptor expression, and inhibit the cell growth with high efficacy both in vivo and in vitro.

原子团簇Ge_7的结构与稳定性

用分子图形软件设计出多种锗原子团簇Ge7的模型,并进行B3LYP密度泛函几何构型优化和振动频率计算,得到8种稳定的同分异构体结构。在锗原子团簇中,大部分原子以三、四、五配位成键。根据分子的总能量,最稳定的Ge7构型为D5h构型。Ge7稳定结构中高配位原子越多,构型越稳定。

Cd_2Ge_7O_(16)中Tb的长余辉发光特性

本文研究了Cd2Ge7O16∶Tb3+材料的发光及其长余辉性质。指出Tb3+的发光是该离子的5D3鄄7FJ、5D4鄄7FJ两种跃迁产生的;随着掺杂浓度的增加5D4鄄7FJ跃迁增强,发光颜色由蓝变绿。并把该材料的长余辉性质归结为基质结构中有电子陷阱和空穴陷阱。提出余辉机理模型。

垂体生长激素腺瘤基因治疗的动物实验研究

目的利用GE7系统介导的生长激素启动子调控毒性基因治疗裸鼠垂体生长激素腺瘤,评价该系统的治疗效果。方法构建GE7系统介导的生长激素启动子调控基因治疗系统,对垂体生长激素腺瘤裸鼠模型进行治疗,并观察其治疗效果。结果治疗组裸鼠肿瘤体积缩小,而各对照组肿瘤体积均有不同程度的增加;基因治疗后荷瘤裸鼠生存期超过120d,明显超过对照组的40d左右(P<0.01)。结论GE7系统介导的生长激素启动子调控自杀基因治疗系统能有效治疗垂体腺瘤动物模型。

Pb在锗酸镉基质中的长余辉发光特性

通过高温固相反应在空气中制得单相 Cd2 Ge7O1 6 ∶ Pb2 +长余辉发光材料 .分析了 Cd2 Ge7O1 6 和Cd2 Ge7O1 6 ∶ Pb2 +的激发光谱和发射光谱 ,指出 Pb2 +的发光是该离子的 3P1 -1 S0 跃迁产生的 ;分析了Cd2 Ge7O1 6 ∶ Pb2 +的发光存在基质对 Pb2 +的能量传递 ;并把长余辉性质归结为基质中 Cd离子的挥发产生的空穴陷阱 .

Ge_(10)O_(28)单元构建的两个三维锗酸盐结构:(H_3O)_4Ge_7O_(16)·3H_2O和K_4Ge_9O_(20)

在半水溶剂热条件下 ,采用不同的合成条件合成了两个锗酸盐微孔分子筛 :(H3O) 4Ge7O16 ·3H2 O和K4 Ge9O2 0 .X射线单晶结构解析表明 ,两个晶体结构具有相同的“火箭状”二级结构单元 (SBU) ,SBU的不同的连接方式导致了完全不同的空间结构 .H4 Ge7O16 ·7H2 O的结晶学数据为Mr=894 2 7,P 43m ,a =0 7730 9( 18)nm ,V =0 462 0 5 ( 19)nm3,Z =1,MoKα ,λ =0 0 710 73nm ,R(F) =3 48% ,wR(F2 ) =8 39% .K4 Ge9O2 0 的结晶学数据为 :Mr=112 9 71,I4( 1) /a ,a =1 5 0 0 2 ( 3)nm ,c =0 7383( 2 )nm ,V =1 6618( 7)nm3,Z =4,MoKα ,R(F) =3 92 % ,wR(F2 ) =11 97% .

锗酸镉中镨的长余辉发光特性

通过高温固相法在空气条件下制得Cd2Ge7O16∶Pr3+长余辉发光材料。测其结构为一单相。分析了Cd2Ge7O16,Cd2Ge7O16∶Pr3+的激发光谱和发射光谱,指出Cd2Ge7O16∶Pr3+的发光是Cd2Ge7O16本身和Pr3+离子发射产生,基质的发光是Cd2Ge7O16中有陷阱能级,电子从导带跃迁到陷阱能级而产生,Pr3+的发光是该离子的4f-4f跃迁产生的;并把该材料的长余辉性质归结为基质结构中有电子陷阱和空穴陷阱,电子陷阱和空穴陷阱分别能储存电子和空穴,从而产生余辉。并提出余辉机理模型。

锗酸盐晶体压致非晶化的研究

高压拉曼散射研究表明．ＣｕＧｅＯ３，Ｌｉ２ＧｅＯ３和Ｌｉ６Ｇｅ２Ｏ７三种晶体分别在７，１２和１１ＧＰａ压力下转变为非晶。在高于起始转变压力以上一定范围压致非晶是可逆的，ＣｕＧｅＯ３，Ｌｉ２ＧｅＯ３和Ｌｉ６Ｇｅ２Ｏ７压致非晶的不可逆转变压力分别为１４．１，２０和２０ＧＰａ。压致非晶ＣｕＧｅＯ３的重新晶化温度在６００℃附近。锗酸及系列晶体的压致非晶化与它们的成份和结构有关，随着在这一系列晶体中Ｌｉ２Ｏ含量的增加，压致非晶化的压力趋于减小。

高质量单晶In_2Ge_2O_7纳米带的合成和生长机制探究

采用CVD法成功合成了高质量单晶In2Ge2O7纳米带,采用高分辨透射电子显微镜(HRTEM)图像以及X射线衍射(XRD),能谱元素分布图像等对产物进行了表征。结果表明,生长的纳米带长几十微米、厚度50 nm,几乎没有缺陷且In,Ge,O元素分布均匀。此外,基于热力学原理对单晶纳米带的生长机制进行了讨论。

In2Ge2O7薄膜制备及其紫外光敏特性研究

以In2O3和GeO2为原料,采用碳还原法制备了In2Ge2O7多晶薄膜,利用XRD和SEM对薄膜的结构和形貌进行了表征。对基于In2Ge2O7薄膜的金属-半导体-金属(MSM)紫外探测器进行了紫外光电导特性测量,结果显示:在波长为250nm的紫外光照射下,在5V偏压下,器件的光电流为727μA(暗电流为12μA),光响应度达到262.9A.W-1,光响应上升时间约为67s,下降时间约为15s。分析认为较长的响应时间是由于内部的缺陷与位错造成的。初步研究结果表明:In2Ge2O7薄膜可以作为一种良好的日盲紫外探测材料。

晶态Ge_1Sb_4Te_7的可逆阻变新机理的第一性原理研究

为了改良相变存储器的工作机理,采用第一性原理计算方法进行了理论研究。结果显示,相变存储材料三元硫系化合物Ge1Sb4Te7可通过特定原子的移动实现晶体对称性的部分打破与重建,伴随着这种结构转变,其电阻率会发生显著变化。该可逆相变引起的电阻转变效应可以归因于"类三中心四电子键"的形成与断裂。这种新相变机制相对于传统的相变存储机制,具有较多优点,有利于提高相变存储器的性能。

A novel receptor-targeted gene delivery system for cancer gene therapy

Some growth factor receptors, such as insulin like growth factor I and II receptor (IGF I R, IGF II R) and epidermal growth factor receptor (EGF R), have been proved to be over-expressed in a variety of human cancers derived from different tissue origins. Based on this molecular alteration, a polypeptide conjugate gene delivery system was designed and synthesized. It contains three essential moieties: a ligand oligopeptide (LOP) for receptor recognition, a polycationic polypeptide (PCP) such as protamine (PA) or poly-L-lysine (PL) as a backbone for DNA binding and an endosome-releasing oligopeptide (EROP) such as influenza haemagglutinin oligopeptide (HA20) for endosomol-ysis. These components are covalently conjugated as LOP-PCP-HA20 or in the form of a mixture of LOP-PCP and HA20-PCP. A 14 amino acid E5 was designed and synthesized as LOP for IGF I R and IGF II R, and a 16 amino acid GE7 as LOP for EGF R. Both E5 and GE7 systems could form stable complex with the plasmid DNA as E5-PCP/ DNA/PCP-HA20 and GE7-PCP/DNA/PCP-HA20. Using bacterial β-galactosidase gene (pSVβ-gal) as a reporter, the present system is able to efficiently target exogenous gene to human cancer cells of different tissue types with high efficiency both in vitro and in implanted tumors in nude mice. It was also demonstrated that the transduced genes were highly expressed in cancer cells both in vitro and in vivo . The present system will provide a novel effective vehicle to target therapeutic genes into cancer cells in gene therapy.