The effects of albumin-coated microbubbles in DNA delivery mediated by therapeutic ultrasound.

The application of therapeutic ultrasound (TUS) in combination with contrast agents (USCA) to mediate gene delivery relies on the understanding of the bioeffects involved. The objective of this study was to evaluate the various bioeffects generated by albumin-coated microbubbles: Optison, an USCA, when applied with TUS operated for 10-30 min, on cells and on DNA transfection. This study reveals that Optison microbubbles were still acoustically active after long-term TUS application of 30 min. Optison enhances TUS-gene transfection by increasing the number of plasmids in the cells and also by distributing the plasmids to more cells, without significant decrease in cell viability. Optison also interacts with the DNA to further enhance transfection in a mechanism not necessarily involving cavitation. However, Optison affects mainly the cell cytoplasmatic membrane, without interfering with DNA intracellular trafficking. Using high-resolution scanning electron microscopy (HRSEM), the bioeffects on cell membrane induced by TUS-Optison were observed, demonstrating that Optison lead to a rougher surface, characterized by depressions that are reversible within 24-h post TUS. These effects are different from those observed when only TUS was applied. The findings from this study suggest that albumin-coated microbubbles enhances transfection when using TUS for 10-30 min, and that microbubbles play a major role in elevating cell transfection level and efficiency.     

Therapeutic ultrasound optimization for gene delivery: a key factor achieving nuclear DNA localization.

When applying therapeutic-ultrasound (TUS) for gene-delivery, there is a great need to understand the contribution of different parameters to the transfection process. The aim of this study is to optimize a wide range of parameters associated with the TUS system concurrent with parameters associated with the transfection, achieving high transfection level and efficiency (total number of cells), while localizing the DNA in the nucleus. Exposure of different cell-types (BHK, LNCaP, BCE) to TUS resulted in high gene expression (1200 fold) and efficiency (28%) with minimal loss in cell viability (<20%). The optimal transfection level and efficiency was achieved using TUS at 2 W/cm2 (0.159 MPa), 30% duty cycle (DC) for 30 min (1080 J/cm2), by placing the transducer above the cells. Long-term TUS application was found to overcome the rate-limiting step of this technology-driving DNA to the cell nucleus. The effect of cell density and DNA concentrations were studied. Increasing DNA concentration contributes to the increase in total gene expression, but not necessarily to transfection efficiency. Our findings support the feasibility of TUS to deliver genes to cells and contribute to the understanding of wide range of parameters that affect the capability of TUS to efficiently deliver genes.     

Therapeutic ultrasound facilitates antiangiogenic gene delivery and inhibits prostate tumor growth

Gene therapy clinical trials are limited due to several hurdles concerning the type of vector used, particularly, the viral vectors, and transfection efficacy when non-viral vectors are used. Therapeutic ultrasound is a promising non-viral technology that can be used in the clinical setting. Here, for the first time, we show the efficacy of therapeutic ultrasound to deliver genes encoding for hemopexin-like domain fragment (PEX), an inhibitor of angiogenesis, to prostate tumors in vivo. Moreover, the addition of an ultrasound contrast agent (Optison) to the transfection process was evaluated. Prostate cancer cells and endothelial cells (EC) were transfected in vitro with cDNA-PEX using therapeutic ultrasound alone (TUS + pPEX) or with Optison (TUS + pPEX + Optison). The biological activity of the expressed PEX was assessed using proliferation, migration, and apoptosis assays done on EC and prostate cancer cells. TUS + pPEX + Optison led to the inhibition of EC and prostate cancer cell proliferation (<65%), migration (<50%), and an increase in apoptosis. In vivo, C57/black mice were inoculated s.c. with prostate cancer cells. The tumors were treated with TUS + pPEX and TUS + pPEX + Optison either once or repeatedly. Tumor growth was evaluated, after which histology and immunohistochemistry analyses were done. A single treatment of TUS + pPEX led to a 35% inhibition in tumor growth. Using TUS + PEX + Optison led to an inhibition of 50%. Repeated treatments of TUS + pPEX + Optison were found to significantly (P < 0.001) inhibit prostate tumor growth by 80%, along with the angiogenic indices, with no toxicity to the surrounding tissues. These results depict the efficacy of therapeutic ultrasound as a non-viral technology to efficiently deliver genes to tumors in general, and to deliver angiogenic inhibitors to prostate cancer in particular.     

治疗性超声介导体外基因转染的参数优化

目的 探讨不同治疗性超声(TUS)参数对基因转染的作用,优化TUS参数以实现高效率的转染,减少对细胞活力和质粒完整性的影响.方法 将质粒和SonoVue微泡加入培养的Hela细胞后行超声辐照,改变超声强度、占空比以及辐照时间等参数,比较不同的TUS辐照策略对细胞活力及红色荧光蛋白(DsRed)表达效率的影响,以确定最佳辐照参数,并对质粒完整性进行分析.结果 低超声强度(0.4 W/cm2、1.0 W/cm2)、低占空比(10%和20%)时,细胞存活率较高(>80%),辐照1 min和3min之间的细胞活力差异不明显(P>0.05).当增加超声强度(1.6 W/cm2、2.2 W/cm2)和占空比(50%)时,细胞活力显著下降(P<0.05).当20%占空比,1.0 W/cm2的TUS辐照3min时,可实现最高的转染率.质粒DNA结构的完整性不受优化的TUS参数影响.结论 TUS是一种有效的基因输送方法 ,优化的参数在无显著细胞死亡和DNA损伤的前提下增加转染,这种非侵袭性的基因转染方法 可能是临床基因疗法的一种有用工具.     

Development of safe and efficient novel nonviral gene transfer using ultrasound: enhancement of transfection efficiency of naked plasmid DNA in skeletal muscle

Although clinical trials of stimulation of angiogenesis by transfection of angiogenic growth factors using naked plasmid DNA or adenoviral vector have been successful, there are still unresolved problems for human gene therapy such as low transfection efficiency and safety. From this viewpoint, it is necessary to develop safe and efficient novel nonviral gene transfer methods. As therapeutic ultrasound induces cell membrane permeabilization, ultrasound irradiation might increase the transfection efficiency of naked plasmid DNA into skeletal muscle. Thus, we examined the transfection efficiency of naked plasmid DNA using ultrasound irradiation with echo contrast microbubble (Optison) in vitro and in vivo experiments. First, we examined the feasibility of ultrasound-mediated transfection of naked plasmid DNA into skeletal muscle cells. Luciferase plasmid mixed with or without Optison was transfected into cultured human skeletal muscle cells using ultrasound (1 MHz; 0.4 W(2)) for 30 s. Interestingly, luciferase activity was markedly increased in cells treated with Optison, while little luciferase activity could be detected without Optison (P < 0.01). Electron microscopy demonstrated the transient formation of holes (less than 5 microM) in the cell surface, which could possibly explain the rapid migration of the transgene into the cells. Next, we studied the in vivo transfection efficiency of naked plasmid DNA using ultrasound with Optison into skeletal muscle. Two days after transfection, luciferase activity in skeletal muscle transfected with Optison using ultrasound was significantly increased about 10-fold as compared with plasmid alone. Successful transfection was also confirmed by beta-galactosidase staining. Finally, we examined the feasibility of therapeutic angiogenesis using naked hepatocyte growth factor (HGF) plasmid in a rabbit ischemia model using the ultrasound-Optison method. Five weeks after transfection, the angiographic score and the number of capillary density in rabbits transfected with Optison using ultrasound was significantly increased as compared with HGF plasmid alone (P < 0.01), accompanied by a significant increase in blood flow and blood pressure ratio (P < 0.01). Overall, the ultrasound transfection method with Optison enhanced the transfection efficiency of naked plasmid DNA in vivo as well as in vitro. Transfection of HGF plasmid by the ultrasound-Optison method could be useful for safe clinical gene therapy to treat peripheral arterial disease without a viral vector system.     

超声造影剂Optison介导质粒GFP转染小鼠骨骼肌细胞的实验研究

目的 探讨微泡造影剂Optison介导基因转染小鼠骨骼肌细胞的作用.方法 采用质粒GFP作为目的基因,超声(1 MHz脉冲波,20%工作周期,空间时间峰值强度1 W/cm2)结合Optison作用于小鼠体外H2K成肌细胞,照射时间分别为10、20、30、40、50及60 s,流式细胞仪测定GFP阳性细胞率,台盼蓝染色测定细胞生存率.超声结合Optison作用于小鼠胫前肌,1周后处死小鼠,荧光显微镜检测GFP阳性肌纤维数,HE染色后计算肌肉损伤面积.结果 活体外细胞实验结果显示,与阳性对照组相比,Optison结合超声作用于H2K细胞10、20及30 s时,显著增强GFP基因表达水平(P＜0.01),但于40、50及60 s时基因表达水平显著降低(P＜0.01),细胞死亡率总体显著增加(P＜0.01).动物实验结果显示,Optison单独或结合超声均显著增强GFP基因表达水平,且Optison单独作用显著减少肌肉损伤面积.结论 Optison可显著增强活体小鼠骨骼肌细胞基因表达水平,同时具有肌肉保护作用.     

Physical parameters influencing optimization of ultrasound-mediated DNA transfection

Ultrasound (US) has been shown to transiently disrupt cell membranes and, thereby, facilitate the loading of drugs and genes into viable cells. To address optimization of gene therapy applications, the aim of this work was to systematically determine the influence of physical parameters on transfection and viability of DU145 prostate cancer cells by two different DNA plasmids (pEGFP-N1 and pGL3). By sonicating cells in vitro in the presence of naked DNA, we found that transfection efficiency was increased by: 1. optimizing acoustic energy at 10 to 30 J/cm(2) (for our apparatus, at pressures above the cavitation threshold); 2. using 500-kHz US in the presence of Optison to nucleate cavition, rather than 24-kHz US without Optison; 3. increasing cell concentration from 10(6) to 10(7) cells/mL; and 4. changing temperature during sonication from 21 to 37 degrees C. The best conditions in this study increased transfection by almost 100-fold in the absence of significant DNA damage. Additional measurements indicated that less than one fourth of cells with DNA plasmid uptake into the cytosol showed DNA expression, which suggests that further optimizing transfection by US may require facilitating intracellular DNA trafficking.     

Measurement and correlation of acoustic cavitation with cellular bioeffects

Using broadband noise as a measure of cavitation activity, this study determined the kinetics of cavitation during sonication of Optison contrast agent and tested whether cellular bioeffects can be predicted by cavitation dose. Cell suspensions were exposed to ultrasound at varying acoustic frequency, pressure, exposure time, Optison concentration and cell type to obtain a broad range of bioeffects, i.e., intracellular uptake and loss of viability, as quantified by flow cytometry. We found that cavitation activity measured by broadband noise increased and peaked within 20 ms and then decayed with a half-life of tens to hundreds of milliseconds. Intracellular uptake and loss of viability correlated well with the cavitation dose determined by the time integral of broadband noise magnitude. These results demonstrate that broadband noise correlates with bioeffects over a broad range of experimental conditions, which suggests a noninvasive feedback method to control ultrasound's bioeffects in real time.     

Ultrasound-microbubble mediated cavitation of plant cells: effects on morphology and viability

The interaction between ultrasound pulses and microbubbles is known to generate acoustic cavitation that may puncture biological cells. This work presents new experimental findings on the bioeffects of ultrasound-microbubble mediated cavitation in plant cells with emphasis on direct observations of morphological impact and analysis of viability trends in tobacco BY-2 cells that are widely studied in higher plant physiology. The tobacco cell suspensions were exposed to 1 MHz ultrasound pulses in the presence of 1% v/v microbubbles (10% duty cycle; 1 kHz pulse repetition frequency; 70 mm between probe and cells; 1-min exposure time). Few bioeffects were observed at low peak negative pressures (<0.4 MPa) where stable cavitation presumably occurred. In contrast, at 0.9 MPa peak negative pressure (with more inertial cavitation activities according to our passive cavitation detection results), random pores were found on tobacco cell wall (observed via scanning electron microscopy) and enhanced exogenous uptake into the cytoplasm was evident (noted in our fluorescein isothiocyanate dextran uptake analysis). Also, instant lysis was observed in 23.4% of cells (found using trypan blue staining) and programmed cell death was seen in 23.3% of population after 12 h (determined by terminal deoxynucleotidyl transferase-mediated deoxyuridine triphosphate nick end labeling [TUNEL]). These bioeffects generally correspond in trend with those for mammalian cells. This raises the possibility of developing ultrasound-microbubble mediated cavitation into a targeted gene transfection paradigm for plant cells and, conversely, adopting plant cells as experimental test-beds for sonoporation-based gene therapy in mammalian cells.     

Microbubble ultrasound improves the efficiency of gene transduction in skeletal muscle in vivo with reduced tissue damage

Intramuscular injection of naked plasmid DNA is a safe approach to the systemic delivery of therapeutic gene products, but with limited efficiency. We have investigated the use of microbubble ultrasound to augment naked plasmid DNA delivery by direct injection into mouse skeletal muscle in vivo, in both young (4 weeks) and older (6 months) mice. We observed that the albumin-coated microbubble, Optison (licensed for echocardiography in patients), significantly improves the transfection efficiency even in the absence of ultrasound. The increase in transgene expression is age related as Optison improves transgene expression less efficiently in older mice than in younger mice. More importantly, Optison markedly reduces muscle damage associated with naked plasmid DNA and the presence of cationic polymer PEI 25000. Ultrasound at moderate power (3 W/cm2 1 MHz, 60 s exposure, duty cycle 20%), combined with Optison, increases transfection efficiency in older, but not in young, mice. The safe clinical use of microbubbles and therapeutic ultrasound and, particularly, the protective effect of the microbubbles against tissue damage provide a highly promising approach for gene delivery in muscle in vivo.     

Transfection effect of microbubbles on cells in superposed ultrasound waves and behavior of cavitation bubble

The combination of ultrasound and ultrasound contrast agents (UCAs) is able to induce transient membrane permeability leading to direct delivery of exogenous molecules into cells. Cavitation bubbles are believed to be involved in the membrane permeability; however, the detailed mechanism is still unknown. In the present study, the effects of ultrasound and the UCAs, Optison on transfection in vitro for different medium heights and the related dynamic behaviors of cavitation bubbles were investigated. Cultured CHO-E cells mixed with reporter genes (luciferase or beta-gal plasmid DNA) and UCAs were exposed to 1 MHz ultrasound in 24-well plates. Ultrasound was applied from the bottom of the well and reflected at the free surface of the medium, resulting in the superposition of ultrasound waves within the well. Cells cultured on the bottom of 24-well plates were located near the first node (displacement node) of the incident ultrasound downstream. Transfection activity was a function determined with the height of the medium (wave traveling distance), as well as the concentration of UCAs and the exposure time was also determined with the concentration of UCAs and the exposure duration. Survival fraction was determined by MTT assay, also changes with these values in the reverse pattern compared with luciferase activity. With shallow medium height, high transfection efficacy and high survival fraction were obtained at a low concentration of UCAs. In addition, capillary waves and subsequent atomized particles became significant as the medium height decreased. These phenomena suggested cavitation bubbles were being generated in the medium. To determine the effect of UCAs on bubble generation, we repeated the experiments using crushed heat-treated Optison solution instead of the standard microbubble preparation. The transfection ratio and survival fraction showed no additional benefit when ultrasound was used. These results suggested that cavitation bubbles created by the collapse of UCAs were a key factor for transfection, and their intensities were enhanced by the interaction of the superpose ultrasound with the decreasing the height of the medium. Hypothesizing that free cavitation bubbles were generated from cavitation nuclei created by fragmented UCA shells, we carried out numerical analysis of a free spherical bubble motion in the field of ultrasound. Analyzing the interaction of the shock wave generated by a cavitation bubble and a cell membrane, we estimated the shock wave propagation distance that would induce cell membrane damage from the center of the cavitation bubble.     

Effects of ultrasound-targeted microbubble destruction on cardiac gene expression

Ultrasound (US) contrast agents are increasingly used in diagnostic echocardiography. Recent studies have suggested unanticipated effects of microbubble destruction. This study was designed to evaluate gene regulation caused by US-mediated destruction of microbubbles in the heart. During IV infusion of Optison trade mark, triggered US was applied to rat hearts to destroy microbubbles. A control group received only saline and US. RNA was isolated from hearts 24 and 72 h after treatment. Analysis with a deeply representative murine cardiac-specific microarray was used to identify regulated genes. Real-time polymerase chain reaction (PCR) was then applied to verify regulated genes. Microarray analysis revealed only 5 regulated genes in the 24-h group and 4 in the 72-h group. Of these genes, only carbonic anhydrase was significantly upregulated in the 24-h Optison trade mark group (4.3 fold; p = 0.0005) when examined in individual animals by real-time PCR. By this very sensitive technique, the bioeffects of microbubble destruction are negligible.     

Inertial cavitation dose and hemolysis produced in vitro with or without Optison

Gas-based contrast agents (CAs) increase ultrasound (US)-induced bioeffects, presumably via an inertial cavitation (IC) mechanism. The relationship between IC dose (ICD) (cumulated root mean squared [RMS] broadband noise amplitude; frequency domain) and 1.1-MHz US-induced hemolysis in whole human blood was explored with Optison; the hypothesis was that hemolysis would correlate with ICD. Four experimental series were conducted, with variable: 1. peak negative acoustic pressure (P-), 2. Optison concentration, 3. pulse duration and 4. total exposure duration and Optison concentration. P- thresholds for hemolysis and ICD were approximately 0.5 MPa. ICD and hemolysis were detected at Optison concentrations >/= 0.01 V%, and with pulse durations as low as four or two cycles, respectively. Hemolysis and ICD evolved as functions of time and Optison concentration; final hemolysis and ICD values depended on initial Optison concentration, but initial rates of change did not. Within series, hemolysis was significantly correlated with ICD; across series, the correlation was significant at p < 0.001.     

Lithotripter shock waves with cavitation nucleation agents produce tumor growth reduction and gene transfer in vivo

Cavitation nucleation agents (CNA) can greatly enhance DNA transfer and cell killing for therapeutically useful applications of nonthermal bioeffects of ultrasound (US). Renal carcinoma (RENCA) tumor cells were implanted and grown to about 400 microL tumor volumes on the hind legs of syngeneic Balb/c mice. Before treatment, mice were anesthetized, the tumor region was shaved and depilated, and a DNA plasmid coding for marker proteins was injected into the tumor. Two sets of tests were completed: the first set involved measurement of tumor growth for 4 days and use of a beta-galactosidase marker plasmid for localization of transfection, and the second set involved 2 days of growth and use of a luciferase marker plasmid for assessing overall protein expression. Either saline, Optison US contrast agent, a vaporizing perfluoropentane droplet suspension (SDS) or air bubble was also injected intratumorally at 10% of tumor volume as a CNA. In some tests, droplets or contrast agent were injected IV. Shock waves (SW) were generated from a spark-gap lithotripter at 7.4 MPa peak negative pressure amplitude. For sham exposure, tumor volume increased by a factor of 3.6 in 4 days. With 500-SW treatment, all the CNA reduced 4-day tumor growth about the same amount (to factors of 1.2 to 1.9). Marker gene expression was generally localized to the region around the needle injection path. All the agents, except saline, produced statistically significant increases of 11.8- to 14.6-fold in luciferase expression after 2 days, relative to sham exposure. IV injection of Optison or droplet nucleation agents before SW treatment reduced tumor growth to factors of 1.0 and 0.7, but did not increase transfection. These results demonstrate the efficacy of CNA in vivo and should lead to improved strategies for simultaneous SW tumor ablation and cancer gene therapy.     

共聚物P85和微泡造影剂对小鼠骨骼肌超声介导基因转染的影响

目的 探讨共聚物P85、微泡造影剂和超声在质粒DNA对小鼠骨骼肌基因转染中的影响.方法 应用共聚物P85、微泡造影剂Optison与DNA混合后直接小鼠胫前肌(TA)注射,并辐照超声.1周后取出胫前肌并快速冰冻切片,荧光显微镜计数表达GFP转染的肌纤维数,HE染色评价肌肉损伤情况.结果 共聚物P85和微泡造影剂Optison均可促进质粒DNA的基因转染(P<0.01,P<0.05).辐照超声可使P85介导的基因转染效率显著提高(P<0.01),但对微泡造影剂介导的基因转染却无显著提高(P>0.05),并且P85所介导的基因转染效率高于微泡造影剂介导的基因转染效率(P<0.01).微泡造影剂和P85耦合并辐照超声可使质粒的基因转染效率显著提高,与所有各组的差异有统计学意义(P<0.01).同时辐照超声显著增加含微泡造影剂组骨骼肌的损伤面积(P<0.01).结论 共聚物P85和微泡造影剂可介导质粒DNA的基因转染,辐照超声对其有促进作用,三者联合应用具有协同作用.     

Use of ultrasound to enhance nonviral lung gene transfer in vivo

We have assessed if high-frequency ultrasound (US) can enhance nonviral gene transfer to the mouse lung. Cationic lipid GL67/pDNA, polyethylenimine (PEI)/pDNA and naked plasmid DNA (pDNA) were delivered via intranasal instillation, mixed with Optison microbubbles, and the animals were then exposed to 1 MHz US. Addition of Optison alone significantly reduced the transfection efficiency of all three gene transfer agents. US exposure did not increase GL67/pDNA or PEI/pDNA gene transfer compared to Optison-treated animals. However, it increased naked pDNA transfection efficiency by approximately 15-fold compared to Optison-treated animals, suggesting that despite ultrasound being attenuated by air in the lung, sufficient energy penetrates the tissue to increase gene transfer. US-induced lung haemorrhage, assessed histologically, increased with prolonged US exposure. The left lung was more affected than the right and this was mirrored by a lesser increase in naked pDNA gene transfer, in the left lung. The positive effect of US was dependent on Optison, as in its absence US did not increase naked pDNA transfection efficiency. We have thus established proof of principle that US can increase nonviral gene transfer, in the air-filled murine lung.     

新型阳离子磷酸胆碱聚合物可作为反义寡核苷酸基因的运输载体

背景：病毒类基因载体虽然具有较高的转染效率,其安全性一直受到人们的质疑。目的：以阳离子磷酸胆碱聚合物作为基因药物运输的载体,研究其对人类c-myc反义寡核苷酸（AS-ODN）的负载和运输能力,并对其安全性和有效性进行评价,方法：应用原子转移自由基聚合法合成具有高度生物相容性的双嵌段磷酸胆碱聚合物MPC30-DEA70,并对其溶液进行表征。用DNA凝胶电泳法对MPC30-DEA70与针对AS-ODN生成不同N/P比值的基因复合物进行表征。将MPC30-DEA70/AS-OD基因复合物转染至体外培养的HEK293细胞,检测其细胞相容性、转染效率和细胞内转运机制。结果与结论：MPC30-DEA70在pH=4.0-11.0范围内的0.01 mol/L PBS中显示出高度水溶性,其正电性随pH值降低而增强。MPC30-DEA70/AS-ODN基因复合物在DNA凝胶电泳中显示出不同程度的电泳迟滞,随电性增强而显著。MTT法检测显示MPC30-DEA70对HEK293细胞株的毒性呈剂量依赖性,高浓度下细胞毒性显著增强。流式细胞术检测发现复合物的转染随N/P比值增加而显著增强;共聚焦显微镜观察到AS-ODN分子在细胞核内的转运,提示其有效的核定位。证实新型阳离子磷酸胆碱聚合物可以有效负载和运输反义寡核苷酸,是一种高效安全的非病毒类转基因载体。     

Lack of bioeffects of ultrasound energy after intravenous administration of FS069 (Optison) in the anesthetized rabbit.

The current study was designed to provide a sensitive in vivo model to maximize the potential bioeffects (measured by hemolysis) of B-mode ultrasound energy in combination with FS069 (Optison). B-mode ultrasound energy was delivered to anesthetized male New Zealand white rabbits with a phased array 5 MHz transducer on a Hewlett-Packard Sonos 1500 ultrasonograph, with transmit level set to maximum (40 dB, approx 135 W/cm2). FS069 (Optison), latex particles in human albumin, or human albumin alone (vehicle) was infused via an ear vein at 0.6 mL/kg. No statistically significant changes were noted in serum free hemoglobin or lactate dehydrogenase either over time or between groups.     

Novel dextran-spermine conjugates as transfecting agents: comparing water-soluble and micellar polymers

Recently, a novel cationic polymer, dextran-spermine (D-SPM) was developed for gene delivery. An efficient transfection was obtained using this polycation for a variety of genes and cell lines in serum-free or serum-poor medium. However, transfection using the water-soluble D-SPM-based polyplexes decreased with increasing serum concentration in cell culture in a concentration-dependent manner, reaching 95% inhibition at 50% serum in the cell growth medium. In order to overcome this obstacle, oleyl derivatives of D-SPM (which form micelles in aqueous phase) were synthesized at 1, 10, and 20 mol% of oleyl moiety to polymer epsilon-NH2 to form N-oleyl-D-SPM (ODS). Polyplexes based on ODS transfected well in medium containing 50% serum. Comparison with polyplexes based on well-established polymers (branched and linear polyethyleneimine) and with DOTAP/Cholesterol lipoplexes showed that regarding beta-galactosidase transgene expression level and cytotoxicity in tissue culture, the D-SPM and ODS compare well with the above polyplexes and lipoplexes. Intracellular trafficking using FITC-labeled ODS and Rhodamine-labeled pGeneGrip plasmid cloned with hBMP2 monitored by confocal microscopy revealed that during the transfection process the fluorescent-labeled polymer concentrates in the Golgi apparatus and around the nucleus, while the cell cytoplasm was free of fluorescent particles, suggesting that the polyplexes move in the cell toward the nucleus by vesicular transport through the cytoplasm and not by a random diffusion. We found that the plasmids penetrate the cell nucleus without the polymer. Preliminary results in zebra fish and mice demonstrate the potential of ODS to serve as an efficient nonviral vector for in vivo transfection.