Overexpression of the neuroglobin gene delivered by ultrasound-targeted microbubble destruction protects SH-SY5Y cells against cobalt chloride induced hypoxia

In this study, we examined the effects of neuroglobin gene （Ngb） transfection into SH-SY5Y cells, using ultrasound-targeted microbubble destruction （UTMD）, on cobalt chloride-induced hypoxia. With an ultrasound intensity of 0.8 W/cm2, a 60-second exposure duration, 50% duty cycle, and 20% microbubble concentration, pAcGFP1-C1-Ngb-transfected cells exhibited the highest cell viability and transfection efficiency. The efficiency of plasmid delivery was significantly higher with UTMD than transfection with plasmid alone, transfection with plasmid using microbubbles, or transfection of plasmid by ultrasound. In addition, during cobalt chloride-induced hypoxia, caspase-3 activity in pAcGFP1-C1-Ngb-transfected cells was significantly lower than in untransfected cells. Ngb protein and mRNA expression were significantly higher in cells transfected by UTMD than in cells transfected with the other methods. These results demonstrate that UTMD can very efficiently mediate exogenous gene delivery, and that Ngb overexpression protects cells against cobalt chloride-induced hypoxia.

Ultrasound-triggered microbubble destruction enhances the radiosensitivity of glioblastoma by inhibiting PGRMC1-mediated autophagy in vitro and in vivo

Background:Ultrasound-triggered microbubble destruction(UTMD) is a widely used noninvasive technology in both military and civilian medicine,which could enhance radiosensitivity of various tumors.However,little information is available regarding the effects of UTMD on radiotherapy for glioblastoma or the underlying mechanism.This study aimed to delineate the effect of UTMD on the radiosensitivity of glioblastoma and the potential involvement of autophagy.Methods:GL261,U251 cells and orthotopic glioblastoma-bearing mice were treated with ionizing radiation(IR) or IR plus UTMD.Autophagy was observed by confocal microscopy and transmission electron microscopy.Western blotting and immunofluorescence analysis were used to detect progesterone receptor membrane component 1(PGRMC1),light chain 3 beta 2(LC3B2) and sequestosome 1(SQSTM1/p62) levels.Lentiviral vectors or siRNAs transfection,and fluorescent probes staining were used to explore the underlying mechanism.Results:UTMD enhanced the radiosensitivity of glioblastoma in vitro and in vivo(P<0.01).UTMD inhibited autophagic flux by disrupting autophagosome-lysosome fusion without impairing lysosomal function or autophagosome synthesis in IR-treated glioblastoma cells.Suppression of autophagy by 3-methyladenine,bafilomycin A1 or ATG5 siRNA had no significant effect on UTMD-induced radiosensitization in glioblastoma cells(P<0.05).Similar results were found when autophagy was induced by rapamycin or ATG5 overexpression(P>0.05).Furthermore,UTMD inhibited PGRMC1expression and binding with LC3B2 in IR-exposed glioblastoma cells(P<0.01).PGRMC1 inhibitor AG-205 or PGRMC1siRNA pretreatment enhanced UTMD-induced LC3B2 and p62 accumulation in IR-exposed glioblastoma cells,thereby promoting UTMD-mediated radiosensitization(P<0.05).Moreover,PGRMC1 overexpression abolished UTMD-caused blockade of autophagic degradation,subsequently inhibiting UTMD-induced radiosensitization of glioblastoma cells.Finally,compared with IR plus UTMD group,PGRMC1 overexpression significantly increased tumor size [(3.8±1.1) mm^(2)vs.(8.0±1.9) mm^(2),P<0.05] and decreased survival time [(67.2±2.6) d vs.(40.0±1.2) d,P=0.0026] in glioblastoma-bearing mice.Conclusions:UTMD enhanced the radiosensitivity of glioblastoma partially by disrupting PGRMC1-mediated autophagy.

Ultrasound-triggered Microbubble Destruction in Combination with Cationic Lipid Microbubbles Enhances Gene Delivery

This study aimed to examine the preparation of cationic lipid microbubble（CLM）,and evaluate its physical and chemical properties and toxicity,measure the gene transfection efficiency by ultrasound triggered microbobble destruction（UTMD） in combination with CLM.The CLM was prepared by the method of the thin film hydration,and its morphology was observed under the electron microscopy at 1st,3rd,7th,10th,and 14th day after preparation,respectively.The size,Zeta potential and stability of CLM were tested.The acute toxicity of CLM was assessed.The green fluorescent protein gene（EGFP） transfection efficiency was evaluated.The experiment grouping was as follows：naked plasmid group（P group）,ultrasonic irradiation plus naked plasmid group（P-US group）,naked plasmid plus CLM group（P-CLM group）,naked plasmid plus ultrasound and CLM group（UTMD group）.The expression of EGFP was detected by fluorescent microscopy and flow cytometry.The results showed that CLMs were spherical in shape,with the similar size and good distribution degree under the light and electron microscopies.The size of CLMs was varied from 250.4±88.3 to 399.0±99.8 nm and the Zeta potential of CLMs from 18.80±4.97 to 20.1±3.1 mV.The EGFP expression was the strongest in the UTMD group,followed by the P-CLM group,P-US group and P group.Flow cytometry results were consistent with those of fluorescent microscopy.The transfection efficiency was substantially increased in the P-US group,P-CLM group and UTMD group as compared with that in the P group,almost 7 times,10 times and 30 times higher than that in the P group respectively.It is suggested that CLMs prepared by the method of thin film hydration are uniform in diameter,and proved non-toxic.UTMD combined with CLM can significantly increase the transfection efficiency of EGFP to targeted cells.

Antitumor effect of VEGFR2-targeted microbubble destruction with gemcitabine using an endoscopic ultrasound probe:In vivo mouse pancreatic ductal adenocarcinoma model

Background:Ultrasound-targeted microbubble destruction(UTMD)induces cellular inflow of drugs at low intensity,while high intensity eradicates tumor vessels.Since vascular endothelial growth factor receptor 2(VEGFR2)is highly expressed in pancreatic ductal adenocarcinoma(PDAC),VEGFR2-targeted microbubble(MB)might additionally increase the tissue specificity of drugs and thus improve antitumor effects.In addition,fixing the dual pulse intensity could maximize MB properties.This study evaluated the one-off(experiment 1)and cumulative(experiment 2)treatment effect of UTMD by regulating the dual pulse output applied to PDAC using VEGFR2-targeted MB.Methods:C57BL/6 mice inoculated with Pan-02 cells were allocated to five groups:VEGFR2-targeted MB+gemcitabine(GEM),VEGFR2-targeted MB,non-targeted MB+GEM,GEM,and control groups.After injection of GEM or GEM and either VEGFR2-targeted or non-targeted MB,UTMD was applied for several minutes at low intensity followed by high intensity application.In experiment 1,mice were treated by the protocol described above and then euthanized immediately or at the tumor diameter doubling time(TDT).In experiment 2,the same protocol was repeated weekly and mice were euthanized at TDT regardless of protocol completion.Histological analysis by CD31 and VEGFR2 staining provided microvascular density(MVD)and VEGFR2 expression along vessels(VEGFR2v)or intra/peripheral cells(VEGFR2c).Results:In experiment 1,TDT was significantly longer in the VEGFR2-targeted MB+GEM group compared to the non-targeted MB+GEM,GEM,and control groups,while the VEGFR2-targeted MB group showed no statistical significance.MVD and VEGFR2v in the immediate euthanasia was significantly lower in the VEGFR2-targeted MB+GEM and VEGFR2-targeted MB groups than other conditions.In experiment 2,the VEGFR2-targeted MB+GEM group produced significantly longer TDT than the GEM or control groups,whereas the VEGFR2-targeted MB group showed no significant difference.Histology revealed significantly reduced VEGFR2v and VEGFR2c in the VEGFR2-targeted and non-targeted MB+GEM groups,while only VEGFR2v was significantly less in the VEGFR2-targeted MB group.Conclusions:UTMD-mediated GEM therapy with the dual pulse application using VEGFR2-targeted MB substantially suppresses PDCA growth.

血小板膜仿生纳米靶向探针的制备及体外寻靶实验研究

目的制备血小板膜仿生纳米靶向探针(PLT-RAP@NPs),探讨其在体外的免疫逃逸、靶向和黏附能力,以及联合超声靶向微泡释放技术(UTMD)后的载药释放情况。方法采用单乳化-溶剂挥发法合成纳米探针RAP@NPs,梯度离心-反复冻融法提取血小板膜囊泡,超声震荡法制备PLT-RAP@NPs,检测其粒径、表面电位及稳定性,观察其微观形态,计算其包封率和载药率,确定雷帕霉素(RAP)负载的最佳方案。DiI荧光染料分别标记聚乳酸-羟基乙酸共聚物(PLGA,DiI@PLGA组)和PLT@PLGA(PLT-DiI@PLGA组),用于模拟RAP@NPs、PLT-RAP@NPs进行体外寻靶实验的荧光强度检测;将其分别与巨噬细胞、泡沫细胞和内皮细胞共孵育2 h,观察DiI@PLGA组与PLT-DiI@PLGA组橙红色荧光强度,分析各细胞对DiI@PLGA和PLT-DiI@PLGA的吞噬、摄取和黏附能力。细胞增殖-毒性实验观察不同浓度RAP(3.00μg/ml、6.25μg/ml、12.50μg/ml、25.00μg/ml、50.00μg/ml、100.00μg/ml)的游离RAP、RAP@NPs和PLT-RAP@NPs对细胞增殖活性的影响。体外药物控释实验观察PLT-RAP@NPs联合UTMD后载药释放效果。结果本实验制备的PLT-RAP@NPs呈球形,大小均匀,表面覆盖薄膜,“核-壳”结构清晰,平均粒径(286.83±5.25)nm,平均表面电位-(15.60±5.04)mV。当100 mg PLGA负载3 mg RAP时,包封率为60.35%,载药率为2.18%。体外寻靶实验结果显示,巨噬细胞与纳米靶向探针共孵育2 h后,DiI@PLGA组橙红色荧光强度约为PLT-DiI@PLGA组3倍;泡沫细胞与靶向纳米探针共孵育2 h后,PLT-DiI@PLGA组橙红色荧光强度约为DiI@PLGA组4倍;内皮细胞与纳米靶向探针共孵育2 h后,PLT-DiI@PLGA组橙红色荧光强度较DiI@PLGA组增强。细胞增殖-毒性实验结果显示,随着RAP浓度增高,游离RAP中细胞增殖活性下降,而RAP@NPs和PLT-RAP@NPs中细胞增殖活性变化较小。体外药物控释实验结果显示,RAP@NPs和PLT-RAP@NPs中RAP均缓慢释放,72 h积累药物释放量分别为42.12%和33.74%,联合UTMD后积累药物释放量分别提升至75.57%和67.54%。结论成功制备PLT-RAP@NPs,其可抑制巨噬细胞吞噬、增强泡沫细胞摄取和提高内皮细胞黏附,从而实现免疫逃逸及靶向能力,联合UTMD可进行RAP靶向控释。

超声靶向微泡破坏联合溶瘤腺病毒治疗胰腺癌的实验研究

目的探讨超声靶向微泡破坏(UTMD)联合溶瘤腺病毒(oAd)治疗胰腺癌的疗效及相关机制。方法在C57BL/6小鼠右前肢皮下注射Panc-02细胞(2×10^(6)个/只),选取肿瘤体积在100~150 mm3的小鼠55只,随机分为NC组(注射PBS 100μL)、UTMD组(注射微泡溶液100μL,并行超声微泡破坏处理5 min)、oAd组(注射10^(8)PFU/mL oAd溶液100μL)、oAd+微泡组(注射10^(8)PFU/mL微泡oAd混合液100μL)、oAd+UTMD组(注射10^(8)PFU/mL微泡oAd混合液100μL,并行超声微泡破坏处理5 min),每组11只。2 d给药1次,共给药5次,2 d记录1次肿瘤体积。第3次给药24 h后每组随机取6只小鼠颈椎脱臼法处死,剥离肿瘤制成肿瘤切片及肿瘤细胞悬液。肿瘤切片行HE染色比较各组肿瘤组织坏死情况并计算坏死面积,E1A抗体染色观察oAd在各组肿瘤组织内分布情况,CD3抗体染色比较各组肿瘤内CD3+T细胞数,Tunel染色及流式细胞术分析各组小鼠肿瘤细胞凋亡情况。当小鼠肿瘤体积超过2000 mm3时终止实验处死所有小鼠。结果在14 d时终止实验,oAd+UTMD组和oAd组相比肿瘤体积增长显著减缓(P<0.05)。oAd+UTMD组细胞质内oAd的E1A蛋白染色最深,oAd组染色最浅。oAd+UT-MD组和oAd组坏死面积与NC组比值分别是9.50±0.60和3.51±0.24,差异有统计学意义(P<0.05)。含oAd的3组小鼠肿瘤内CD3+T细胞数均增加,oAd+UTMD组肿瘤内的CD3+T细胞数(196.33±12.58)明显高于oAd组(120.67±12.90,P<0.05)。oAd+UTMD组的细胞总凋亡率及Tunel染色荧光分布比oAd组多。结论UTMD增强oAd对胰腺肿瘤细胞的杀伤作用,促进oAd在肿瘤内转染,协助CD3+T细胞在肿瘤内富集,同时诱导肿瘤细胞凋亡和坏死增加。

携双抗体纳米微泡对卵巢癌细胞增殖活性的影响

背景:免疫治疗可通过多种途径增强抗肿瘤免疫反应,联合免疫治疗是一个更好的选择。超声靶向微泡破坏技术可将药物、基因、抗体和细胞因子直接输送到免疫细胞的细胞质中,进一步增强免疫应答。然而,通过超声靶向微泡破坏技术将携趋化因子受体4抗体和细胞程序性死亡配体1抗体双靶向纳米微泡应用于卵巢癌的治疗尚未见报道。目的:探讨超声辐照携趋化因子受体4抗体和程序性死亡配体1抗体双靶向纳米微泡对卵巢癌细胞增殖、迁移的影响。方法:对IOSE-80正常卵巢上皮细胞及SKOV3、CAOV3卵巢癌细胞进行培养及扩增,采用双标记荧光免疫法对3种细胞中的趋化因子受体4和细胞程序性死亡配体1蛋白进行共定位,蛋白质印迹法检测3种细胞中趋化因子受体4和程序性死亡配体1蛋白相对表达量,并筛选出实验细胞。制备携不同配体的靶向纳米微泡后,即单纯的纳米微泡、携趋化因子受体4抗体的纳米微泡、携趋化因子受体4和程序性死亡配体1抗体的纳米微泡。取对数生长期的SKOV3卵巢癌细胞,分6组处理:A组加入McCoy’s 5A培养基,B组加入含基质细胞衍生因子1的McCoy’s 5A培养基,C组加入单纯的纳米微泡溶液与含基质细胞衍生因子1的McCoy’s 5A培养基,D组加入携趋化因子受体4抗体的纳米微泡溶液与含基质细胞衍生因子1的McCoy’s 5A培养基,E组加入携趋化因子受体4和程序性死亡配体1抗体的纳米微泡溶液与含基质细胞衍生因子1的McCoy’s 5A培养基,F组加入单纯的纳米微泡溶液,超声辐照120 s,孵育48 h后,采用CCK-8法检测细胞存活率,通过伤口愈合实验检测B-E组细胞的愈合迁移能力。结果与结论:①免疫荧光染色显示,3种细胞均可表达趋化因子受体4和程序性死亡配体1蛋白;蛋白质印迹法检测显示,SKOV3、CAOV3卵巢癌细胞中的趋化因子受体4和程序性死亡配体1蛋白表达量均高于IOSE-80正常卵巢上皮细胞(P<0.05);②CCK-8检测结果显示,B组细胞存活率高于A组(P<0.05),F组细胞存活率低于A组(P<0.05),B-E组细胞存活率逐渐降低,组间两两比较差异有显著性意义(P<0.05);③伤口愈合实验显示,B-E组细胞愈合率逐渐降低,组间两两比较差异有显著性意义(P<0.05);④结果表明,超声靶向微泡破坏技术联合携趋化因子受体4抗体和程序性死亡配体1抗体双靶向纳米微泡可显著抑制卵巢癌细胞的增殖迁移。

超声靶向微泡破坏介导的整合素亚基α3转染对乳腺癌生长和上皮间质转化的影响

目的探讨超声靶向微泡破坏(UTMD)介导的整合素亚基α3(ITGA3)过表达质粒转染对乳腺癌生长和上皮间质转化(EMT)的影响。方法基于GEPIA平台分析TCGA数据库中乳腺癌样本的ITGA3表达情况,绘制生存曲线评估ITGA3表达水平对乳腺癌患者生存的影响。将乳腺癌BT-549细胞分为LIP-NC组(脂质体介导的阴性对照质粒转染细胞)、LIP-ITGA3组(脂质体介导的ITGA3过表达质粒转染细胞)、UTMD-NC组(UTMD介导的阴性对照质粒转染细胞)和UTMD-ITGA3组(UTMD介导的ITGA3过表达质粒转染细胞),UTMD-NC组和UTMD-ITGA3组细胞在转染过程中均接受超声辐照(频率1 MHz,声强0.75 W/cm2,时间45 s)。于扫描电子显微镜下观察LIP-NC组、UTMD-NC组细胞形态;分别应用MTT法、划痕实验、Transwell实验检测各组细胞活力、迁移能力、侵袭能力;应用Western blot法分析BT-549细胞中ITGA3和EMT、STAT3通路相关基因蛋白的表达情况。通过裸鼠皮下肿瘤细胞注射法建立裸鼠乳腺癌异种移植瘤模型,移植35 d后处死裸鼠剥离异种移植瘤并称重;应用免疫组化检测各组异种移植瘤组织中ITGA3、N-cadherin和PCNA的表达情况。结果生物信息学分析显示,乳腺癌样本中ITGA3蛋白相对表达量明显低于正常乳腺样本,差异有统计学意义(P<0.05);ITGA3低表达与乳腺癌患者不良预后相关(HR=0.81,P=0.00072)。体外实验结果显示,扫描电子显微镜下LIP-NC组细胞呈球形,细胞膜表面无明显的凹坑或孔隙;UTMD-NC组细胞形态未见改变,但细胞膜表面可见粗糙区域和小凹坑。UTMD-ITGA3组、LIP-ITGA3组细胞活力、迁移能力、侵袭能力均分别较各自对照组(UTMD-NC组、LIP-NC组)降低,差异均有统计学意义(均P<0.05);且UTMD-ITGA3组细胞活力、迁移能力、侵袭能力均较LIP-ITGA3组更低(均P<0.05)。LIP-ITGA3组ITGA3蛋白相对表达量较LIP-NC组增高,UTMD-ITGA3组ITGA3蛋白相对表达量较UTMD-NC组、LIP-ITGA3组均增高,差异均有统计学意义(均P<0.01)。LIP-ITGA3组、UTMD-ITGA3组细胞Vimentin、N-cadherin、p-STAT3、c-Myc、CyclinD1和PCNA蛋白相对表达量均分别较UTMD-NC组、LIP-NC组降低,E-cadherin蛋白相对表达量均分别较UTMD-NC组、LIP-NC组增高,差异均有统计学意义(均P<0.01);且UTMD-ITGA3组细胞Vimentin、N-cadherin、p-STAT3、c-Myc、CyclinD1和PCNA蛋白相对表达量均较LIP-ITGA3组更低,E-cadherin蛋白相对表达量较LIP-ITGA3组更高(均P<0.05)。体内实验结果显示,UTMD-ITGA3组、LIP-ITGA3组裸鼠异种移植瘤质量均分别较UTMD-NC组、LIP-NC组降低,差异均有统计学意义(均P<0.01);且UTMD-ITGA3组裸鼠异种移植瘤质量较LIP-ITGA3组更低(P<0.01)。UTMD-ITGA3裸鼠异种移植瘤组织中ITGA3蛋白相对表达量较LIP-ITGA3组增高,差异有统计学意义(P<0.01);UTMD-ITGA3组、LIP-ITGA3组裸鼠异种移植瘤组织中N-cadherin、PCNA蛋白相对表达量均分别较UTMD-NC组、LIP-NC组降低,差异均有统计学意义(均P<0.01);且UTMD-ITGA3组N-cadherin、PCNA蛋白相对表达量较LIP-ITGA3组更低(均P<0.01)。结论UTMD介导的ITGA3过表达质粒转染可有效抑制乳腺癌生长和EMT,有望为今后乳腺癌治疗提供新的策略。

Ultrasound-mediated targeted microbubbles： a new vehicle for cancer therapy

With the hope of overcoming the serious side effects, great endeavor has been made in tumor-targeted chemotherapy, and various drug delivery modalities and drug carriers have been made to decrease systemic toxicity caused by chemotherapeutic agents. Scientists from home and abroad focus on the research of targeted microbubbles contrast agent, and the use of the targeted ultrasound microbubble contrast agent can carry gene drugs and so on to the target tissue, as well as mediated tumor cell apoptosis and tumor microvascular thrombosis block, etc., thus plays the role of targeted therapy. Recent studies have elucidated the mechanisms of drug release and absorption, however, much work remains to be done in order to develop a successful and optimal system. In this review, we summarized the continuing efforts in under-standing the usage of the ultrasound triggered target microbubbles in cancer therapy, from release mechanism to preparation methods. The latest applications of ultra-sound-triggered targeted microbubbles in cancer therapy, especially in gene therapy and antiangiogenic cancer therapy were discussed. Moreover, we concluded that as a new technology, ultrasound-triggered targeted microbubbles used as drug carriers and imaging agents are still energetic and are very likely to be translated into clinic in the near future.

超声联合超声微泡介导的药物递送策略在肿瘤治疗中的研究进展

超声除在成像方面的临床应用外,作为一种促进药物递送的工具也已得到深入研究。低频超声与微泡结合,可以透过不同的生物屏障,增强药物的靶向输送,这种能力有助于超声波与临床治疗结合。本文对超声波生物效应、超声微泡的特征及超声靶向微泡破坏技术在肿瘤治疗中的研究进展进行综述。

超声靶向微泡破坏技术介导基因转染在乳腺癌治疗中的研究进展

乳腺癌全球发病率逐年上升,严重威胁女性健康。近年来,随着生物技术的快速发展,基因治疗在乳腺癌中的研究日益增多。超声靶向微泡破坏作为一种潜在的基因或药物递送系统,既可作为载体,又可增加生物屏障的通透性,从而提高肿瘤的治疗效果,已广泛应用于乳腺癌基因治疗研究。考虑到常规基因载体的固有缺陷,研究者倾向将其与超声靶向微泡破坏技术联合应用以提高基因转染的安全性和有效性。本文对超声靶向微泡破坏技术及其与常规基因载体联合介导基因转染治疗乳腺癌的研究进展做一综述。

不同途径注射质粒微泡对超声微泡破碎技术介导EGFP基因在兔骨缺损处转染的影响

目的探讨超声微泡破碎技术介导增强型绿色荧光蛋白(enhanced green fluorescent protein,EGFP)基因在兔骨缺损处转染时,不同途径注射质粒微泡混悬液对转染效率及局部组织的影响。方法3月龄新西兰大白兔10只,制备右尺骨骨缺损模型,按照随机数字表法分为静脉组和断端间组(n=5)。静脉组和断端间组造模后第10天分别经耳缘静脉或骨缺损断端间向兔体内注射携带EGFP基因的质粒微泡混悬液(0.3 ml/kg)。在超声频率1 MHz,超声强度1.0 W/cm^(2),占空比20%条件下,对两组骨缺损部位超声辐照1 min,进行EGFP基因转染。在基因转染后1周时处死兔,于骨缺损处获取标本制作切片,荧光染色观察各组EGFP表达情况。采用病理图像分析软件分析计算平均光密度。HE染色观察断端间软组织病理特点。结果静脉组和断端间组均观察到绿色荧光蛋白表达。断端间组平均光密度高于静脉组,差异有统计学意义(0.0345±0.0028 vs 0.0004±0.0001,P<0.05)。表达绿色荧光蛋白的细胞主要为骨骼肌细胞,各组未见细胞坏死征象。结论超声微泡破碎技术介导EGFP基因在兔骨缺损处转染时,其效率受不同途径注射质粒微泡混悬液的影响,骨缺损断端间直接注射优于静脉注射。

超声微泡在阿霉素诱导的心脏毒性治疗中的研究进展

阿霉素(doxorubicin,DOX)作为多种癌症有效抗肿瘤药物在临床上受到心脏毒性风险的影响。因此,需要寻找更好的药物治疗或干预措施预防及改善DOX诱导的心脏毒性。超声靶向微泡破坏(ultrasound targeted microbubble destruction,UTMD)技术在增强治疗药物或基因的靶向性和限制副作用方面显示出巨大潜力。本文回顾了UTMD原理及其优势、阿霉素诱导的心脏毒性的作用机制及治疗,并对UTMD在阿霉素诱导的心脏毒性的研究进展进行综述。

超声微泡靶向治疗急性心肌梗死的研究进展

随着人们生活习惯和饮食结构的改变,急性心肌梗死(acute myocardial infarction,AMI)发病率逐年递增。如何有效减少心肌坏死并挽救缺血心肌是临床研究的重要目标,然而临床上常规应用的手术和药物治疗难以有效地挽救心肌细胞,避免不良事件发生。随着微泡技术的发展,超声靶向微泡破坏(ultrasound-targeted microbubble destruction,UTMD)作为一种安全有效的靶向递送系统在未来有望成为急性心肌梗死治疗的一种有效手段。本文就超声靶向微泡破坏在急性心肌梗死治疗中的作用机制及应用进展做一综述。

UTMD联合抑制CREB基因促进动脉粥样硬化斑块稳定性的实验研究

目的探究超声靶向微泡破坏(UTMD)联合抑制环磷腺苷效应元件结合蛋白(CREB)基因对动脉粥样硬化斑块稳定性的影响。方法将20只健康雄性新西兰兔(4~5月龄)随机分为空白组(n=5)、模型组(n=5)、对照组(单纯CREB质粒组,n=5)和治疗组(UTMD联合CREB质粒组,n=5),利用实时荧光定量PCR(qRT-PCR)和Western Blot实验分别评估CREB、血管内皮生长因子(VEGF)、基质金属蛋白酶-2/9(MMP-2/9)的RNA和蛋白水平;实时剪切波弹性杨氏模量值和超声造影峰值强度评估斑块;乳胶增强免疫比浊测定血清白介素(IL)-17A和超敏C反应蛋白(hs-CRP)含量;利用免疫组化染色评估斑块内VEGF、MMP-2/9的表达及定位。结果治疗组CREB、VEGF和MMP-2/9的mRNA水平和表达低于模型组和对照组(t≥4.59,均P<0.05)。与空白组相比模型组存在hs-CRP和IL-17A的高表达(t≥13.51,均P<0.05);对照组和治疗组hs-CRP和IL-17A的表达较模型组低,并且治疗组hs-CRP和IL-17A的表达低于对照组(t≥2.50,均P<0.05)。实时剪切波弹性成像及超声造影提示,与模型组和对照组相比,治疗组斑块杨氏模量值显著性升高,造影峰值强度值明显下降(t≥4.60,均P<0.05)。免疫组化显示,治疗组VEGF和MMP-2/9的表达阳性细胞数明显低于模型组和对照组。结论通过建立动脉粥样硬化动物模型和评估斑块的蛋白表达发现,UTMD联合CREB质粒具有比单纯CREB质粒更高的转染效率,有效降低斑块的CREB蛋白表达,使斑块更加稳定。

新型载药微泡联合超声靶向爆破技术治疗兔VX2肝癌

目的观察聚乳酸-羟基乙酸共聚物(PLGA)纳米药物微球-脂质微泡复合体靶向治疗兔VX2肝癌的效果。方法采用双乳化法制备包裹阿霉素的PLGA纳米药物微球(ADM-NP);然后通过碳二亚胺法将ADM-NP连接于氨基脂质微泡(MB-NH2)表面,制备载阿霉素PLGA纳米药物微球-脂质微泡复合体(ADM-NP-MB-NH2)。将30只新西兰大白兔肝VX2移植瘤模型随机分为3组,每组10只。A组为单纯ADM-NP辐照组,经耳缘静脉注入ADM-NP 5ml;B组为混合辐照组,注入5ml ADM-NP与脂质微泡混合溶液;C组为复合体辐照组,注入5ml ADM-NP-MB-NH2。在药物注射完毕的同时,对各组均采用频率1MHz、声强0.5W/cm2的超声波辐照120s。于末次治疗24h后处死荷瘤兔,固定标本并送检;比较各组的肿瘤生长率,计算肿瘤细胞增殖指数(PI)与凋亡指数(AI)。结果A、B、C组肿瘤的生长率分别为(80.13±4.34)%、(59.66±7.93)%及(50.47±9.69)%,C组与A、B组比较差异有统计学意义(P均<0.05);肿瘤PI分别为(74.82±7.25)%、(60.77±8.48)%及(55.94±6.97)%,C组与A、B组比较差异均有统计学意义(P均<0.05);AI分别为(31.70±6.42)%、(50.35±3.82)%及(72.47±5.93)%,C组AI与A、B组比较差异有统计学意义(P均<0.05)。结论采用ADM-NP与脂质微泡复合体联合UTMD治疗兔VX2肝癌可显著提高疗效。

超声靶向转染缺氧诱导因子干扰基因治疗大鼠肝癌的研究

目的利用超声靶向转染缺氧诱导因子干扰基因(HIF-1αshRNA),观察其对肝癌的治疗效果。方法构建Wistar大鼠肝癌种植瘤模型。随机将大鼠分为两组:假手术组,开腹后不进行超声辐照治疗;超声靶向基因转染(UTMD)组,开腹后将基因与微泡混合后经尾静脉匀速注入,同时进行超声靶向辐照。分别于治疗后第3天、第7天、第14天行超声造影检测肿瘤大小的变化(计算公式为体积=长×宽×高×π/6),qPCR检测HIF-1αmRNA的变化,Western和免疫组化检测肿瘤细胞内HIF-1α蛋白的表达。结果治疗前两组的肿瘤大小差异无统计学意义。治疗后第3天两组肿瘤均有一定的增大,两组肿瘤大小差异有统计学意义(P<0.05);治疗后第7天,假手术组肿瘤继续增大,UTMD组肿瘤大小保持稳定,两组间差异有统计学意义(P<0.05);治疗后第14天,假手术组肿瘤仍继续增大,UTMD组肿瘤开始缩小,两组间差异有统计学意义(P<0.05)。与假手术组相比,各时间点UTMD组HIF-1αmRNA表达均明显降低,HIF-1α蛋白水平明显下调。结论 UTMD介导HIF-1αshRNA基因转染能有效干扰HIF-1α的表达,使肿瘤组织缺氧、缺血坏死并诱发凋亡,达到抑制肿瘤生长、甚至治愈肿瘤的目的。

超声辐照超声微泡介导siRNA转染膀胱癌T24细胞的实验研究

目的探讨超声辐照超声微泡介导siRNA转染人膀胱癌T24细胞的有效性。方法使用超声辐照超声微泡的方法介导FITC-siRNA转染人膀胱癌T24细胞,通过荧光显微镜及流式细胞学方法观察siRNA的转染效率,使用MTT方法观察细胞活力。结果与各阴性对照组相比,超声辐照超声微泡的方法可以明显增加siRNA向T24细胞中的转染效率。随着超声辐照强度的增加,siRNA的转染效率在一定范围内有所提高,同时也增加了对T24细胞毒性。与脂质体介导的siRNA体外转染相比,超声辐照超声微泡介导的siRNA转染效率仍然较低。结论超声辐照超声微泡能够有效提高siRNA转染膀胱癌细胞的效率,有可能为膀胱癌的基因靶向治疗提供新的转染手段。

应用UTMD技术联合脂质体转染介导人肝癌细胞表达miRNA-122的研究

目的:探讨应用超声靶向微泡破坏(UTMD)技术和脂质体介导质粒miRNA-122在人肝癌HCCLM3细胞表达后细胞增殖、迁移和侵袭能力以及耐药性的变化。方法:构建pLMP-miR-122质粒。将对数期肝癌细胞株HCCLM3分组转染:A组(对照组)、B组(脂质体+质粒组)、C组(超声微泡+质粒+超声辐照组)、D组(脂质体+超声微泡+质粒+超声辐照组)。采用荧光定量PCR法检测pre-miRNA-122表达水平比较各组细胞转染效率,以CCK-8法检测细胞活性,应用划痕实验和Transwell实验检测细胞的体外迁移和侵袭能力,蛋白质免疫印迹检测蛋白表达情况。结果:HCCLM3细胞miRNA-122过表达后,细胞的增殖、迁移、侵袭能力与对照组比较均显著受到抑制,且对化疗药物敏感性增加,抗凋亡蛋白Bcl2表达下调。结论:UTMD技术结合脂质体转染法可以提高质粒转染人肝癌细胞HCCLM3效率,并且miRNA-122上调后可以明显抑制HCCLM3增殖、迁移和侵袭能力,有可能成为肝癌基因治疗的新靶点。

超声靶向微泡破坏技术介导基因转染的研究进展

基因转染技术的高速发展不仅革新了生物学和医学许多基本问题的研究,也推动了诊断和治疗的进步。基因作为核酸类生物活性大分子,极易在体内降解,因此传递基因的载体尤为重要。超声靶向微泡破坏(UTMD)技术利用超声波和微泡之间的相互作用,以及其产生的生物学效应,使微泡携基因进行转染,并与多种载体联合应用,为疾病的治疗提供了有效手段。本文就UTMD技术介导基因转染的研究进展进行综述。