低强度超声联合微泡通过提高ROS水平促进甲状腺癌细胞自噬性死亡

目的:探讨低强度超声联合微泡造影剂对甲状腺癌细胞自噬性死亡的作用,并分析自噬的激活机制及其对细胞活力的影响。方法:采用频率20 k Hz、功率80 m W的低强度超声联合微泡造影剂处理人甲状腺癌TPC1细胞,处理细胞60、120和240 s后,采用Live/Dead实验和CCK-8实验分析细胞死亡和活力;Western blot分析微管相关蛋白1轻链3Ⅱ(microtubule-associated protein 1 light chain 3-Ⅱ,LC3-Ⅱ)、自噬相关蛋白5(autophagy-related protein 5,ATG5)和SQSTM1/P62的蛋白水平变化;单丹磺酰戊二胺(monodansylcadaverine,MDC)染色、绿色荧光蛋白(green fluorescent protein,GFP)-LC3转染和透射电镜观察细胞内自噬体的数量;2',7'-二氯二氢荧光素二乙酸脂(DCFDA)染色分析细胞活性氧簇(reactive oxygen species,ROS)的水平,用N-乙酰半胱氨酸(N-acetyl-L-cysteine,NAC)抑制氧化应激水平,分析ROS在自噬激活中的作用;ATG5 siRNA转染抑制自噬水平并分析自噬性死亡的作用。结果:低强度超声联合微泡显著促进TPC1细胞死亡,抑制TPC1细胞活力(P0.05),并与处理时间显著相关。相对于单纯低强度超声组和微泡组,超声联合微泡显著升高LC3-Ⅱ和ATG5蛋白水平,抑制P62蛋白水平(P0.05)。MDC染色、GFP-LC3转染和透射电镜观察发现,超声联合微泡明显增加TPC1细胞中自噬体的数量。超声联合微泡与单纯低强度超声组和微泡组相比,提高了细胞的ROS水平,而NAC显著降低超声联合微泡提高的LC3-Ⅱ蛋白水平(P0.05)。ATG5 siRNA抑制自噬并显著增加细胞活力(P0.05)。结论:本研究说明低强度超声联合微泡可能通过提高甲状腺癌细胞中的ROS水平促进细胞的自噬性死亡,从而引起甲状腺癌细胞死亡。     

Superparamagnetic iron oxide nanoparticle-embedded encapsulated microbubbles as dual contrast agents of magnetic resonance and ultrasound imaging

An encapsulated microbubble (EMB) of a novel construct is proposed to enhance the magnetic resonance imaging contrast by introducing superparamagnetic iron oxide (SPIO) nanoparticles (mean diameter is 12 nm) into the polymer shell of the microbubble. Such microbubble vesicle has nitrogen gas in the core and its mean diameter is 3.98 μm. An in vitro MR susceptibility experiment using a phantom consisting EMBs has shown that the relationship between the transverse relaxation rate R₂ and the Fe₃O₄ nanoparticle concentration in the shell (the volume fraction of EMBs is kept constant) can be fitted to a linear function and an exponentially growth function is observed between R₂ and the SPIO-inclusion microbubble concentration. The in vivo MRI experiments also show that the SPIO-inclusion microbubbles have longer contrast-enhancement duration time in rat liver than non-SPIO-inclusion microbubbles. An in vitro ultrasound imaging experiment of SPIO-inclusion microbubbles also shows that they can enhance the ultrasound contrast significantly. Additionally, the interaction between the SPIO-inclusion microbubbles and cells indicates that such microbubble construct can retain the acoustic property under the ultrasound exposure by controlling the SPIO concentration in the shell. Therefore, the proposed SPIO nanoparticle-embedded EMBs potentially can become effective MR susceptibility contrast agents while also can be good US contrast agents.     

The use of folate-PEG-grafted-hybranched-PEI nonviral vector for the inhibition of glioma growth in the rat

Combined treatment using nonviral agent-mediated enzyme/prodrug therapy and immunotherapy had been proposed as a powerful alternative method of cancer therapy. The present study was aimed to evaluate the cytotoxicity in vitro and the therapeutic efficacy in vivo when the cytosine deaminase/5-fluorocytosine (CD/5-FC) and TNF-related apoptosis-inducing ligand (TRAIL) genes were jointly used against rat C6 glioma cells. The potency of the FA-PEG-PEI used as a nonviral vector was tested in the FR-expressed C6 glioma cells and Wistar rats. The C6 glioma cells and animal model were treated by the combined application of FA-PEG-PEI/pCD/5-FC and FA-PEG-PEI/pTRAIL. The antitumor effect was evaluated by survival assays and tumor volume. This study revealed a significant increase of cytotoxicity in vitro following the combined application of FA-PEG-PEI/pCD/5-FC and FA-PEG-PEI/pTRAIL treatments in C6 glioma cells. Animal studies showed a significant growth inhibition of the C6 glioma xenografts using the combined treatment. These results demonstrated that the combined treatment generated additive cytotoxic effect in C6 glioma cells in both in vitro and in vivo conditions, and indicated that such treatment method using both enzyme/prodrug therapy and TRAIL immunotherapy might be a promising therapeutic strategy in treating glioma.     

白蛋白微泡促进报告基因在细胞表达的实验研究

目的: 探讨白蛋白微泡作为非病毒载体在基因传输中的作用。方法:6孔板培养脐静脉内皮细胞(EC)和血管平滑肌细胞(VSMC),每孔加pcDNA3.1/His/LacZ质粒20 μg,加不同浓度微泡或不加微泡,超声条件为连续波,频率2MHz,机械指数1.8,照射时间1 min,48 h后计算蓝染细胞百分率和β-半乳糖苷酶活性。另以不同浓度微泡及超声照射时间处理细胞,测定细胞增殖情况。结果:与单纯超声质粒组相比,含微泡组蓝染细胞率增加约10-15倍(其中内皮细胞组11.6倍,平滑肌细胞组15.2倍),报告基因表达定量增加近8倍。微泡浓度为10％时细胞转染效率最高。超声照射对细胞增殖无影响,微泡浓度为50％时有明显的细胞毒作用。结论:白蛋白微泡在超声作用下能明显增加基因的传输效率,有可能成为一种安全有效的基因治疗的载体。     

PLK1shRNA and doxorubicin co-loaded thermosensitive PLGA-PEG-PLGA hydrogels for osteosarcoma treatment

Combination cancer therapy has emerged as crucial approach for achieving superior anti-cancer efficacy. In this study, we developed a strategy by localized co-delivery of PLK1shRNA/polylysine-modified polyethylenimine (PEI-Lys) complexes and doxorubicin (DOX) using biodegradable, thermosensitive PLGA-PEG-PLGA hydrogels for treatment of osteosarcoma. When incubated with osteosarcoma Saos-2 and MG-63 cells, the hydrogel containing PLK1shRNA/PEI-Lys and DOX displayed significant synergistic effects in promoting the apoptosis of osteosarcoma cells in vitro. After subcutaneous injection of the hydrogel containing PLK1shRNA/PEI-Lys and DOX beside the tumors of nude mice bearing osteosarcoma Saos-2 xenografts, the hydrogels exhibited superior antitumor efficacy in vivo compared to the hydrogels loaded with PLK1shRNA/PEI-Lys or DOX alone. It is noteworthy that the combination treatment in vivo led to almost complete suppression of tumor growth up to 16 days, significantly enhanced PLK1 silencing, higher apoptosis of tumor masses, as well as increased cell cycle regulation. Additionally, ex vivo histological analysis of major organs of the mice indicated that the localized treatments showed no obvious damage to the organs, suggesting lower systemic toxicity of the treatments. Therefore, the strategy of localized, sustained co-delivery of PLK1shRNA and DOX by using the biodegradable, injectable hydrogel may have potential for efficient clinical treatment of osteosarcoma.     

In vitro and in vivo studies of pirarubicin-loaded SWNT for the treatment of bladder cancer

Intravesical chemotherapy is an important part of the treatment for superficial bladder cancer. However, the response to it is limited and its side effects are extensive. Functional single-walled carbon nanotubes (SWNT) have shown promise for tumor-targeted accumulation and low toxicity. In the present study, we performed in vivo and in vitro investigations to determine whether SWNT-based drug delivery could induce high tumor depression in rat bladder cancer and could decrease the side effects of pirarubicin (tetrahydropyranyl-adriamycin, THP). We modified SWNT with phospholipid-branched polyethylene glycol and constructed an SWNT-THP conjugate via a cleavable ester bond. The cytotoxicity of SWNT-THP against the human bladder cancer cell line BIU-87 was evaluated in vitro. Rat bladder cancer in situ models constructed by N-methyl-N-nitrosourea intravesical installation (1 g/L, 2 mg/rat once every 2 weeks for 8 weeks) were used for in vivo evaluation of the cytotoxicity of SWNT and SWNT-THP. Specific side effects in the THP group including urinary frequency (N = 12), macroscopic hematuria (N = 1), and vomiting (N = 7) were identified; however, no side effects were observed with SWNT-THP treatment. Flow cytometry was used to assess the cytotoxicity in vitro and in vivo. Results showed that SWNT alone did not yield significant tumor depression compared to saline (1.74 ± 0.56 and 1.23 ± 0.42%) in vitro. SWNT-THP exhibited higher tumor depression than THP-saline in vitro (74.35 ± 2.56 and 51.24 ± 1.45%) and in vivo (52.46 ± 2.41 and 96.85 ± 0.85%). The present findings indicate that SWNT delivery of THP for the treatment of bladder cancer leads to minimal side effects without loss of therapeutic efficacy. Therefore, this nanotechnology may play a crucial role in the improvement of intravesical treatment of bladder cancer. Key words: Single-walled carbon nanotubes; Bladder cancer; Drug vehicle; THP; Intravesical chemotherapy     

Polymeric Microbubbles for Ultrasonic Molecular Imaging and Targeted Therapeutics

Gas-filled microbubbles ultrasound agent have received wide attention, not only because they can improve ultrasound signals, but also they can be used as drug/gene carriers. Among all types of microbubbles fabricated by different membrane materials and core gases, polymer-shell microbubbles are highly promising. Polymeric microbubbles are more stable than other soft shell microbubbles in vivo. Under destructive ultrasound, polymer-stabilized microbubbles disintegrate and emit a strong non-linear signal, which enables ultrasound imaging with superior sensitivity. Except for ultrasound imaging, polymeric microbubbles could also be applied as drug/gene-delivery system. The thick polymeric shells allow loading a large amount of drugs. Meanwhile, site-specific targeting and controlled drug release in the area of interest can be realized through chemical and physical modification. In this review, we highlight some of the recent examples on polymeric microbubbles and their applications in ultrasound molecular imaging and drug delivery.     

基质细胞衍生因子1靶向超声对比剂在体内可与血管内皮细胞紧密结合

背景：基质细胞衍生因子1是心肌梗死区域微环境中效力最强的趋化因子,在趋化干细胞修复梗死心肌以及在促进血管新生方面起到重要的作用。微泡和声学活性物质携带靶向配基,可制备成超声成像靶向对比剂并与活体细胞结合,用于分子成像,超声分子成像的关键是寻找“成像靶点”,并成功制备能与“成像靶点” 特异、高效结合的靶向超声对比剂。 目的：实验制备和评价携基质细胞衍生因子1单克隆抗体的靶向微泡超声对比剂。 方法：采用“生物素-亲和素”桥接法构建携基质细胞衍生因子1单克隆抗体的靶向微泡超声对比剂,并从外观、pH值、粒径测定、光镜及荧光显微镜下观、流式细胞仪检测等多个方面对靶向对比剂进行评价。4头中华小型猪均结扎左冠状动脉前降支第一对角支制备心肌梗死模型,2头开胸但不结扎左冠状动脉前降支第一对角支,均注入靶向超声对比剂,心肌组织冰冻切片后采用免疫荧光法检测靶向微泡的体内稳定性。 结果与结论：通过生物素-亲和素桥接法可将基质细胞衍生因子1抗体和超声微泡两者结合。体外实验中对比剂外观：表现为半透明的淡黄或绿色,静置后分层。非靶向对比剂pH值为7.02±0.12,靶向微泡对比剂的pH值为6.10±0.19。荧光显微镜下观察靶向微泡明亮且呈指环状绿色荧光环绕外壳周边,剧烈震荡后表面荧光无明显改变。靶向对比剂在携带基质细胞衍生因子1抗体之后微泡粒径大小为(2 422.62±238.82) nm。流式细胞仪检测显示,靶向对比剂在不同时间段的基质细胞衍生因子1携带率稳定,静置1 h后携带率稳定且剧烈震荡前后差异无显著性意义。在体内实验中可见靶向微泡在心梗部位血管内皮细胞处聚集。结果证实,经生物素-亲和素桥接法制备的携基质细胞衍生因子1单克隆抗体靶向微泡超声对比剂体内可与血管内皮细胞结合,在体外结合率高而且结合稳定。     

超声联合微泡作用下即时产生非酶化一氧化氮的实验

背景：一氧化氮是体内重要的气体信号分子,近年来研究发现一氧化氮可以在无一氧化氮合成酶存在的条件下合成,即非酶化一氧化氮合成,而非酶化途径合成一氧化氮,可能是许多生物学效应的机制之一。 目的：观察超声联合微泡是否可以实现或者增效一氧化氮非酶途径的产生。 方法：将L-精氨酸和H2O2按照1︰1,10︰1,10︰0.1,1︰10的比例混合,应用频率为1 MHz,输出功率为0.5,1.0,1.5 W/cm²的超声分别持续辐射60 s,论证最优的L-精氨酸和H₂O₂的浓度比例以及最适的超声输出功率。确定最适浓度比和超声输出功率后,实验设立4组,分别进行超声联合微泡、单纯超声、微泡进行干预,空白对照组不进行干预,比较各组一氧化氮生成量。 结果与结论：体外试验中,L-精氨酸和H₂O₂的浓度比例以10︰1为最佳,选择1.5 W/cm²声强作为超声最优值。以此最适浓度比和超声输出功率干预,超声联合微泡组的一氧化氮生成量多于超声组(P < 0.01);超声组一氧化氮生成量优于空白对照组(P < 0.01);而微泡组的一氧化氮生成量与空白对照组没有差异。结果表明超声联合微泡可以增效一氧化氮的非酶合成。     

Cluster versus ROI analysis to assess combined antiangiogenic therapy and radiotherapy in the F98 rat‐glioma model

For glioblastoma (GBM), current therapeutic approaches focus on the combination of several therapies, each of them individually approved for GBM or other tumor types. Many efforts are made to decipher the best sequence of treatments that would ultimately promote the most efficient tumor response. There is therefore a strong interest in developing new clinical in vivo imaging procedures that can rapidly detect treatment efficacy and allow individual modulation of the treatment. In this preclinical study, we propose to evaluate tumor tissue changes under combined therapies, tumor vascular normalization under antiangiogenic treatment followed by radiotherapy, using a voxel‐based clustering approach. This approach was applied to a rat model of glioma (F98). Six MRI parameters were mapped: apparent diffusion coefficient, vessel wall permeability, cerebral blood volume fraction, cerebral blood flow, tissue oxygen saturation and vessel size index. We compared the classical region of interest (ROI)‐based analysis with a cluster‐based analysis. Five clusters, defined by their MRI features, were sufficient to characterize tumor progression and tumor changes during treatments. These results suggest that the cluster‐based analysis was as efficient as the ROI‐based analysis to assess tumor physiological changes during treatment, but also gave additional information regarding the voxels impacted by treatments and their localization within the tumor. Overall, cluster‐based analysis appears to be a powerful tool for subtle monitoring of tumor changes during combined therapies.     

High-frequency ultrasound-guided disruption of glycoprotein VI-targeted microbubbles targets atheroprogressison in mice

Targeted contrast-enhanced ultrasound (CEU) using microbubble agents is a promising non-invasive imaging technique to evaluate atherosclerotic lesions. In this study, we decipher the diagnostic and therapeutic potential of targeted-CEU with soluble glycoprotein (GP)-VI in vivo. Microbubbles were conjugated with the recombinant fusion protein GPVI-Fc (MB_GPVI) that binds with high affinity to atherosclerotic lesions. MB_GPVI or control microbubbles (MB_C) were intravenously administered into ApoE^−/− or wild type mice and binding of the microbubbles to the vessel wall was visualized by high-resolution CEU. CEU molecular imaging signals of MB_GPVI were substantially enhanced in the aortic arch and in the truncus brachiocephalicus in ApoE^−/− as compared to wild type mice. High-frequency ultrasound (HFU)-guided disruption of MB_GPVI enhanced accumulation of GPVI in the atherosclerotic lesions, which may interfere with atheroprogression. Thus, we establish targeted-CEU with soluble GPVI as a novel non-invasive molecular imaging method for atherosclerosis. Further, HFU-guided disruption of GPVI-targeted microbubbles is an innovate therapeutic approach that potentially prevents progression of atherosclerotic disease.     

Urinary bladder smooth muscle engineered from adipose stem cells and a three dimensional synthetic composite

Human adipose stem cells were cultured in smooth muscle inductive media and seeded into synthetic bladder composites to tissue engineer bladder smooth muscle. 85:15 Poly-lactic-glycolic acid bladder dome composites were cast using an electropulled microfiber luminal surface combined with an outer porous sponge. Cell-seeded bladders expressed smooth muscle actin, myosin heavy chain, calponinin, and caldesmon via RT-PCR and immunoflourescence. Nude rats (n = 45) underwent removal of half their bladder and repair using: (i) augmentation with the adipose stem cell-seeded composites, (ii) augmentation with a matched acellular composite, or (iii) suture closure. Animals were followed for 12 weeks post-implantation and bladders were explanted serially. Results showed that bladder capacity and compliance were maintained in the cell-seeded group throughout the 12 weeks, but deteriorated in the acellular scaffold group sequentially with time. Control animals repaired with sutures regained their baseline bladder capacities by week 12, demonstrating a long-term limitation of this model. Histological analysis of explanted materials demonstrated viable adipose stem cells and increasing smooth muscle mass in the cell-seeded scaffolds with time. Tissue bath stimulation demonstrated smooth muscle contraction of the seeded implants but not the acellular implants after 12 weeks in vivo. Our study demonstrates the feasibility and short term physical properties of bladder tissue engineered from adipose stem cells.     

Novel ultrasound contrast agent based on microbubbles generated from surfactant mixtures of Span 60 and polyoxyethylene 40 stearate

In this study, novel perfluorocarbon-filled microbubbles as ultrasound contrast agent were fabricated using ultrasonication of a surfactant mixture of sorbitan monostearate (Span 60) and polyoxyethylene 40 stearate (PEG40S) in aqueous media. The microbubbles generated from a 1:9 mixture of PEG40S/Span 60 exhibited an average diameter of 2.08 ± 1.27 μm. More than 99% of the microbubbles had a mean particle diameter less than 8 μm, indicating that they were appropriately sized for intravenous administration as ultrasound contrast agent. The stabilization mechanism of the microbubbles was investigated by the Langmuir–Blodgett technique including the measurements of surface pressure–area (π–A) isotherms and compression–decompression cycles with a two-dimensional monolayer of Span 60 and PEG40S. The dependence on molar fraction of PEG40S in π–A isotherms of mixed monolayers provided a strong evidence of interactions between the two microbubble-forming materials. It is suggested that the monolayer shell imparts good stability to the microbubbles by three means: (1) a low surface tension monolayer hinders dissolution through the reduction of surface tension, which introduces a mechanical surface pressure that counters the Laplace pressure; (2) the presence of a monolayer shell imparts a significant barrier to gas escaping from the core into the aqueous medium; and (3) encapsulation elasticity stabilizes microbubbles against diffusion-driven dissolution and explains the long shelf-life of microbubble contrast agent. The preliminary in vivo ultrasound imaging study showed that such stabilized microbubbles demonstrated excellent enhancement under grey-scale pulse inversion harmonic imaging and power Doppler imaging.     

Human decellularized adipose tissue scaffold as a model for breast cancer cell growth and drug treatments

Human adipose tissue extracellular matrix, derived through decellularization processing, has been shown to provide a biomimetic microenvironment for adipose tissue regeneration. This study reports the use of human adipose tissue-derived extracellular matrix (hDAM) scaffolds as a three-dimensional cell culturing system for the investigation of breast cancer growth and drug treatments. The hDAM scaffolds have similar extracellular matrix composition to the microenvironment of breast tissues. Breast cancer cells were cultured in hDAM scaffolds, and cell proliferation, migration, morphology, and drug responses were investigated. The growth profiles of multiple breast cancer cell lines cultured in hDAM scaffolds differed from the growth of those cultured on two-dimensional surfaces and more closely resembled the growth of xenografts. hDAM-cultured breast cancer cells also differed from those cultured on two-dimensional surfaces in terms of cell morphology, migration, expression of adhesion molecules, and sensitivity to drug treatment. Our results demonstrated that the hDAM system provides breast cancer cells with a biomimetic microenvironment in vitro that more closely mimics the in vivo microenvironment than existing two-dimensional and Matrigel three-dimensional cultures do, and thus can provide vital information for the characterization of cancer cells and screening of cancer therapeutics.     

Anthocyanin Induces Apoptosis of DU-145 Cells In Vitro and Inhibits Xenograft Growth of Prostate Cancer

Purpose

To investigate the effects of anthocyanins extracted from black soybean, which have antioxidant activity, on apoptosis in vitro (in hormone refractory prostate cancer cells) and on tumor growth in vivo (in athymic nude mouse xenograft model).

Materials and Methods

The growth and viability of DU-145 cells treated with anthocyanins were assessed using the 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) assay and apoptosis was assessed by DNA laddering. Immunoblotting was conducted to evaluate differences in the expressions of p53, Bax, Bcl, androgen receptor (AR), and prostate specific antigen (PSA). To study the inhibitory effects of anthocyanins on tumor growth in vivo, DU-145 tumor xenografts were established in athymic nude mice. The anthocyanin group was treated with daily oral anthocyanin (8 mg/kg) for 14 weeks. After 2 weeks of treatment, DU-145 cells (2×10⁶) were inoculated subcutaneously into the right flank to establish tumor xenografts. Tumor dimensions were measured twice a week using calipers and volumes were calculated.

Results

Anthocyanin treatment of DU-145 cells resulted in 1) significant increase in apoptosis in a dose-dependent manner, 2) significant decrease in p53 and Bcl-2 expressions (with increased Bax expression), and 3) significant decrease in PSA and AR expressions. In the xenograft model, anthocyanin treatment significantly inhibit tumor growth.

Conclusion

This study suggests that anthocyanins from black soybean inhibit the progression of prostate cancer in vitro and in a xenograft model.     

Theranostic Gd(III)-lipid microbubbles for MRI-guided focused ultrasound surgery

We have synthesized a biomaterial consisting of Gd(III) ions chelated to lipid-coated, size-selected microbubbles for utility in both magnetic resonance and ultrasound imaging. The macrocyclic ligand DOTA-NHS was bound to PE headgroups on the lipid shell of pre-synthesized microbubbles. Gd(III) was then chelated to DOTA on the microbubble shell. The reaction temperature was optimized to increase the rate of Gd(III) chelation while maintaining microbubble stability. ICP-OES analysis of the microbubbles determined a surface density of 7.5 × 10⁵ ± 3.0 × 10⁵ Gd(III)/μm² after chelation at 50 °C. The Gd(III)-bound microbubbles were found to be echogenic in vivo during high-frequency ultrasound imaging of the mouse kidney. The Gd(III)-bound microbubbles also were characterized by magnetic resonance imaging (MRI) at 9.4 T by a spin-echo technique and, surprisingly, both the longitudinal and transverse proton relaxation rates were found to be roughly equal to that of no-Gd(III) control microbubbles and saline. However, the relaxation rates increased significantly, and in a dose-dependent manner, after sonication was used to fragment the Gd(III)-bound microbubbles into non-gas-containing lipid bilayer remnants. The longitudinal (r₁) and transverse (r₂) molar relaxivities were 4.0 ± 0.4 and 120 ± 18 mM⁻¹s⁻¹, respectively, based on Gd(III) content. The Gd(III)-bound microbubbles may find application in the measurement of cavitation events during MRI-guided focused ultrasound therapy and to track the biodistribution of shell remnants.     

Vascular endoluminal delivery of mesenchymal stem cells using acoustic radiation force

Restoration of functional endothelium is a requirement for preventing late stent thrombosis. We propose a novel method for targeted delivery of stem cells to a site of arterial injury using ultrasound-generated acoustic radiation force. Mesenchymal stem cells (MSCs) were surface-coated electrostatically with cationic gas-filled lipid microbubbles (mb-MSC). mb-MSC was characterized microscopically and by flow cytometry. The effect of ultrasound (5?MHz) on directing mb-MSC movement toward the vessel wall under physiologic flow conditions was tested in vitro in a vessel phantom. In vivo testing of acoustic radiation force-mediated delivery of mb-MSCs to balloon-injured aorta was performed in rabbits using intravascular ultrasound (1.7?MHz) during intra-aortic infusion of mb-MSCs. Application of ultrasound led to marginalization and adhesion of mb-MSCs to the vessel phantom wall, whereas no effect was observed on mb-MSCs in the absence of ultrasound. The effect was maximal when there were 7±1 microbubbles/cell (n=6). In rabbits (n=6), adherent MSCs were observed in the ultrasound-treated aortic segment 20?min after the injection (334±137?MSCs/cm(2)), whereas minimal adhesion was observed in control segments not exposed to ultrasound (2±1?MSCs/cm(2), p<0.05). At 24?h after mb-MSC injection and ultrasound treatment, the engrafted MSCs persisted and spread out on the luminal surface of the artery. The data demonstrate proof of principle that acoustic radiation force can target delivery of therapeutic cells to a specific endovascular treatment site. This approach may be used for endoluminal cellular paving and could provide a powerful tool for cell-based re-endothelialization of injured arterial segments.     

The inhibition of glioma growth in vitro and in vivo by a chitosan/ellagic acid composite biomaterial

This study has developed a chitosan-based delivery system to locally administer ellagic acid for brain cancer treatment. We fabricated chitosan/ellagic acid composite films with various concentrations of ellagic acid. In vitro release study was performed by using a UV spectrophotometer, and enzymatic degradation rate was determined by analyzing the increased free amino groups. Viability of brain cancer cells (human U87 glioblastomas and rat C6 glioma cells) was measured via direct and indirect cell culture on the films by MTS assay. Caspase-3 activation, Western blot for p53, and anti-angiogenesis assays were also examined. In the in vivo study, GFP-tagged rat C6 glioma cells were implanted subcutaneously at the right flank region of nude mice and treatments were initiated by implanting the films subcutaneously. Tumor growth was evaluated by measuring tumor volume using a caliper, an ultrasound machine, and an optical imaging system. The chitosan/ellagic acid composite films were enzymatically degradable and exhibited a sustained slow release of ellagic acid. These materials could inhibit the cancer cell growth in an ellagic acid concentration-dependent manner by inducing apoptosis of cancer cells as well as suppressing angiogenesis. These materials also significantly suppressed tumor tissue growth in vivo.