Role of endocytosis in sonoporation-mediated membrane permeabilization and uptake of small molecules: a electron microscopy study.

Sonoporation is a physical method that has been successfully used to deliver drugs into living cells both in vitro and in vivo for experimental and therapeutic purposes. Despite numerous studies on this topic, often reporting successful outcomes, very little is known about the mechanisms involved in the hypothesized membrane permeabilization processes. In this study, electron microscopy was used to investigate the ultra-structural modifications of cell membranes, induced by sonoporation. Here, we demonstrate that sonoporation in the presence of microbubbles induces the formation of a significant number of transient and permeant structures at the membrane level. These structures were transient with a half-life of 10 min and had a heterogeneous size distribution ranging from a few nanometers to 150 nm. We demonstrated that the number and the size of these structures were positively correlated with the enhanced intracellular uptake of small molecules. In addition, we showed that these structures were associated with caveolae-dependent endocytosis for two thirds of the recorded events, with the remaining one third related to non-specific routes such as membrane disruptions as well as caveolae-independent endocytosis. In conclusion, our observations provide direct evidences of the involvement of caveolae-endocytosis in cell membrane permeabilization to small molecules after sonoporation.

Evaluation of chirp reversal power modulation sequence for contrast agent imaging.

Over the last decade, significant research effort has been focused on the use of chirp for contrast agent imaging because chirps are known to significantly increase imaging contrast-to-noise ratio (CNR). New imaging schemes, such as chirp reversal (CR), have been developed to improve contrast detection by increasing non-linear microbubble responses. In this study we evaluated the contrast enhancement efficiency of various chirped imaging sequences in combination with well-established imaging schemes such as power modulation (PM) and pulse inversion (PI). The imaging schemes tested were implemented on a fully programmable open scanner and evaluated by ultrasonically scanning (excitation frequency of 2.5 MHz; amplitude of 350 kPa) a tissue-mimicking flow phantom comprising a 4 mm diameter tube through which aqueous dispersions (dilution fraction of 1/2000) of the commercial ultrasound contrast agent, SonoVue(®) were continuously circulated. The recovery of non-linear microbubble responses after chirp compression requires the development and the optimization of a specific filter. A compression filter was therefore designed and used to compress and extract several non-linear components from the received microbubble responses. The results showed that using chirps increased the image CNR by approximately 10 dB, as compared to conventional Gaussian apodized sine burst excitation but degraded the axial resolution by a factor of 1.4, at -3 dB. We demonstrated that the highest CNR and contrast-to-noise ratio (CTR) were achievable when CR was combined with PM as compared to other imaging schemes such as PI.

Focused ultrasound mediated drug delivery from temperature-sensitive liposomes: in-vitro characterization and validation.

Nanomedicine-based delivery with non-invasive techniques is a promising approach to increase local drug concentration and to reduce systemic side effects. Focused ultrasound (FUS) has become a promising strategy for non-invasive local drug delivery by mild hyperthermia. In this study, traditional temperature-sensitive liposomes (TTSLs) encapsulating doxorubicin (DOX) were evaluated for FUS-mediated drug delivery with an in-vitro FUS setup. In-vitro studies showed quantitative release of the DOX from the lumen of the temperature-sensitive liposomes when heated to 42 °C with FUS using 1 MHz sinusoidal waves at 1.75 MPa for 10 min. No release was observed when heated at 37 °C. Moreover, we showed that DOX released from TTSLs by FUS is as efficiently internalized by glioblastoma cells as free DOX at 37 °C. In-vitro therapeutic evaluation showed that exposure of a cell monolayer to FUS-activated TTSLs induced a 60% and a 50% decrease in cell viability compared to cell medium and to TTSLs preheated at 37 °C, respectively. Using an in-vitro 3D cell culture model, the results showed that after FUS-mediated hyperthermia, preheated liposomes induced a 1.7-fold decrease in U-87 MG spheroid growth in comparison to the preheated liposomes at 37 °C. In conclusion, our results show that in-vitro FUS allows the evaluation of TTSLs and does not modify the cellular uptake of the released DOX nor its cytotoxic activity.

Irinotecan delivery by microbubble-assisted ultrasound: in vitro validation and a pilot preclinical study.

Irinotecan is a powerful anticancer drug with severe systemic side effects that limit its clinical application. Drug-targeted delivery with noninvasive methods is required to enhance the drug concentration locally and to reduce these undesirable events. Microbubble-assisted ultrasound has become a promising method for noninvasive targeted drug delivery. The aim of this study is to evaluate the therapeutic effectiveness of in vitro and in vivo irinotecan delivery based on the combination of ultrasound and microbubbles. In the present study, in vitro results showed that the irinotecan treatment with microbubble-assisted ultrasound induced a significant decrease in cell viability of human glioblastoma cells. Moreover, using subcutaneous glioblastoma xenografts, the in vivo preclinical study in nude mice demonstrated that this therapeutic protocol led to a decrease in tumor growth and perfusion and an increase of tumor necrosis. The conclusions drawn from this study demonstrate the promising potential of this therapeutic approach for the anticancer targeted therapy.

New insights into uteroplacental perfusion: quantitative analysis using Doppler and contrast-enhanced ultrasound imaging.

OBJECTIVE: To monitor and quantify uteroplacental perfusion in rat pregnancies by Doppler ultrasound (DUS) and contrast-enhanced ultrasound (CEUS). METHODS: Fourteen rats were randomized in two groups (the CEUS group and the control group). On days 8, 11, 14, 17, 19 and 20 of gestation, we used DUS to measure the resistance index (RI), pulsatility index and blood velocity in the uterine, arcuate and umbilical arteries in both groups. On days 14, 17 and 20, one group was also examined by CEUS. Quantitative perfusion parameters were calculated in 4 compartments (mesometrial triangle, placenta, umbilical cord and fetus) and compared. RESULTS: The DUS measurement showed that the RI of the uterine and arcuate arteries decreased (p < 0.01) from day 14 to day 17, while velocity increased each of these arteries (p < 0.01 and p < 0.05, respectively). Quantification of uteroplacental perfusion by CEUS in bolus mode revealed that blood volume and local blood flow increased from day 14 to day 20 in the mesometrial triangle (p < 0.01) and the placenta (p < 0.05). In the CEUS destruction-replenishment mode, the perfusion parameters showed trends similar to those observed in bolus mode. No microbubbles were detected in the umbilical vein or fetal compartments. The weights of pups in the two groups did not differ significantly. CONCLUSIONS: CEUS estimates of placental perfusion complement the data provided by DUS.

Bleomycin delivery into cancer cells in vitro with ultrasound and SonoVue® or BR14® microbubbles.

BACKGROUND: Cell exposure to ultrasound (US) in the presence of contrast agent microbubbles (MBs) can result in cell sonoporation that can be exploited for drug or gene delivery. Anticancer drug bleomycin (BLM), used in sonoporation, can effectively eliminate tumor cells in vitro and in vivo. Nevertheless, sonoporation mechanism is not known, thus different US parameters and MB types are used. Recently, we proposed that efficiency of cell sonoporation can be related to the efficiency of MB sonodestruction. PURPOSE: We analyzed human tumor cells viability in response to BLM, US and MB treatment. METHODS: Human glioblastoma astrocytoma (U-87 MG) or colon cancer (HCT-116) cells were exposed to US in the presence of BLM and either SonoVue® or BR14® MBs. MB sonodestruction was evaluated according to US signal attenuation. RESULTS: Both HCT-116 and U-87 MG cell viability following US exposure decreased up to 30%. Decrease in cell viability followed similar tendency as MB sonodestruction, which suggests direct relationship between MB sonodestruction and BLM intracellular delivery. CONCLUSION: Sonoporation is a feasible method to deliver BLM in to several types of human cancer cell lines. Efficiency of cell sonoporation correlated well with MB sonodestruction, providing a possibility to optimize US parameters by measuring MB sonodestruction.

Drug delivery by electropulsation: Recent developments in oncology.

Electro-permeabilisation allows the free access of polar compounds to the cytoplasm by a reversible alteration of the cell membrane. It is now used in clinics for the eradication of cutaneous solid tumors. New developments predict its future applications for other anti-cancer treatments.

Direct visualization at the single-cell level of siRNA electrotransfer into cancer cells.

The RNA interference-mediated gene silencing approach is promising for therapies based on the targeted inhibition of disease-relevant genes. Electropermeabilization is one of the nonviral methods successfully used to transfer siRNA into living cells in vitro and in vivo. Although this approach is effective in the field of gene silencing by RNA interference, very little is known about the basic processes supporting siRNA transfer. In this study, we investigated, by direct visualization at the single-cell level, the delivery of Alexa Fluor 546-labeled siRNA into murine melanoma cells stably expressing the enhanced green fluorescent protein (EGFP) as a target gene. The electrotransfer of siRNA was quantified by time lapse fluorescence microscopy and was correlated with the silencing of egfp expression. A direct transfer into the cell cytoplasm of the negatively charged siRNA was observed across the plasma membrane exclusively on the side facing the cathode. When added after electropulsation, the siRNA was inefficient for gene silencing because it did not penetrate the cells. Therefore, we report that an electric field acts on both the permeabilization of the cell plasma membrane and on the electrophoretic drag of the negatively charged siRNA molecules from the bulk phase into the cytoplasm. The transfer kinetics of siRNA are compatible with the creation of nanopores, which are described with the technique of synthetic nanopores. The mechanism involved was clearly specific for the physico-chemical properties of the electrotransferred molecule and was different from that observed with small molecules or plasmid DNA.

Doxorubicin delivery into tumor cells with ultrasound and microbubbles.

Doxorubicin is a potent chemotherapeutic whose severe side effects limit its application. Drug-targeted delivery with noninvasive techniques is required to increase the drug concentration locally and to reduce systemic side effects. Microbubble-assisted ultrasound has become a promising strategy for noninvasive local drug delivery. The aim of this study is to evaluate the applicability and the effectiveness of administration of doxorubicin combined with microbubble-assisted ultrasound in human U-87MG glioblastoma and MDA-MB-231 breast cancer cells. In the present study, the doxorubicin delivery aided by microbubble-assisted ultrasound enhanced the death of breast cancer and glioblastoma cells, including the induction of apoptosis. Various microbubbles were evaluated including Vevo Micromarker, BR14, SonoVue and experimental polymer shelled microbubbles. The results showed that Vevo Micromarker microbubble-assisted ultrasound could induce an enhancement of doxorubicin in glioblastoma and breast cancer cell death. Polylactide-Shelled PEG and Vevo Micromarker microbubbles were the best microbubbles for efficient doxorubicin delivery in the U-87 MG and MDA-MB-231 cells, respectively. Moreover, the induction of apoptosis by doxorubicin and Vevo Micromarker microbubble-assisted ultrasound was examined and results showed a positive increment for acoustic pressures above 600 kPa. The conclusions drawn from in vitro study show the potential of this strategy for an in vivo application.

In vitro gene transfer by electrosonoporation.

Among the nonviral methods for gene delivery in vitro, electroporation is simple, inexpensive and safe. To upregulate the expression level of transfected gene, we investigated the applicability of electrosonoporation. This approach consists of a combination of electric pulses and ultrasound assisted with gas microbubbles. Cells were first electroporated with plasmid DNA encoding-enhanced green fluorescent protein and then sonoporated in presence of contrast microbubbles. Twenty-four hours later, cells that received electrosonoporation demonstrated a four-fold increase in transfection level and a six-fold increase in transfection efficiency compared with cells having undergone electroporation alone. Although electroporation induced the formation of DNA aggregates into the cell membrane, sonoporation induced its direct propulsion into the cytoplasm. Sonoporation can improve the transfer of electro-induced DNA aggregates by allowing its free and rapid entrance into the cells. These results demonstrated that in vitro gene transfer by electrosonoporation could provide a new potent method for gene transfer.

A 3D in vitro spheroid model as a way to study the mechanisms of electroporation.

Electropermeabilization is a physical method to deliver molecules into cells and tissues. Clinical applications have been successfully developed for antitumoral drug delivery and clinical trials for gene electrotransfer are currently underway. However, little is known about the mechanisms involved in this transfer. The main difficulties stem from the lack of single cell models which reliably replicate the complex in vivo environment. In order to increase our understanding of the DNA electrotransfer process, we exploited multicellular tumor spheroids as an ex vivo model of tumor. We used confocal microscopy to visualize the repartition of permeabilized cells in spheroids subjected to electric pulses. Our results reveal that even if cells can be efficiently permeabilized with electric fields, including those cells present inside the spheroids, gene expression is by contrast limited to the external layers of cells. Taken together, these results, in agreement with the ones obtained in tumors, indicate that the spheroid model is more relevant to an in vivo situation than cells cultured as monolayers. They validate the spheroid model as a way to study electro-mediated gene delivery processes.

Membrane perturbation by an external electric field: a mechanism to permit molecular uptake.

Electropermeabilisation is a well established physical method, based on the application of electric pulses, which induces the transient permeabilisation of the cell membrane. External molecules, otherwise nonpermeant, can enter the cell. Electropermeabilisation is now in use for the delivery of a large variety of molecules, as drugs and nucleic acids. Therefore, the method has great potential in the fields of cancer treatment and gene therapy. However many open questions about the underlying physical mechanisms involved remain to be answered or fully elucidated. In particular, the induced changes by the effects of the applied field on the membrane structure are still far from being fully understood. The present review focuses on questions related to the current theories, i.e. the basic physical processes responsible for the electropermeabilisation of lipid membranes. It also addresses recent findings using molecular dynamics simulations as well as experimental studies of the effect of the field on membrane components.