Developmental delays and subcellular stress as downstream effects of sonoporation

Posters: no. 2Control ID: 1672434OBJECTIVES: The biological impact of sonoporation has often been overlooked. Here we seek to obtain insight into the cytotoxic impact of sonoporation by gaining new perspectives on anti-proliferative characteristics that may emerge within sonoporated cells. We particularly focused on investigating the cell-cycle progression kinetics of sonoporated cells and identifying organelles that may be stressed in the recovery process. METHODS: In line with recommendations on exposure hardware design, an immersion-based ultrasound platform has been developed. It delivers 1 MHz ultrasound pulses (100 cycles; 1 kHz PRF; 60 s total duration) with 0.45 MPa peak negative pressure to a cell chamber that housed HL-60 leukemia cells and lipid-shelled microbubbles at a 10:1 cell-tobubble ratio (for 1e6/ml cell density). Calcein was used to facilitate tracking of sonoporated cells with enhanced uptake of exogenous molecules. The developmental trend of sonoporated cells was quantitatively analyzed using BrdU/DNA flow cytometry that monitors the cell population’s DNA synthesis kinetics. This allowed us to measure the temporal progression of DNA synthesis of sonoporated cells. To investigate whether sonoporation would upset subcellular homeostasis, post-exposure cell samples were also assayed for various proteins using Western blot analysis. Analysis focus was placed on the endoplasmic reticulum (ER): an important organelle with multi-faceted role in cellular functioning. The post-exposure observation time spanned between 0-24 h. RESULTS: Despite maintaining viability, sonoporated cells were found to exhibit delays in cell-cycle progression. Specifically, their DNA synthesis time was lengthened substantially (for HL-60 cells: 8.7 h for control vs 13.4 h for the sonoporated group). This indicates that sonoporated cells were under stress: a phenomenon that is supported by our Western blot assays showing upregulation of ER-resident enzymes (PDI, Ero1), ER stress sensors (PERK, IRE1), and ER-triggered pro-apoptotic signals (CHOP, JNK). CONCLUSIONS: Sonoporation, whilst being able to facilitate internalization of exogenous molecules, may inadvertently elicit a cellular stress response. These findings seem to echo recent calls for reconsideration of efficiency issues in sonoporation-mediated drug delivery. Further efforts would be necessary to improve the efficiency of sonoporation-based biomedical applications where cell death is not desirable.postprin

A study on the change in plasma membrane potential during sonoporation

Posters: no. 4Control ID: 1680329OBJECTIVES: There has been validated that the correlation of sonoporation with calcium transients is generated by ultrasound-mediated microbubbles activity. Besides calcium, other ionic flows are likely involved in sonoporation. Our hypothesis is the cell electrophysiological properties are related to the intracellular delivery by ultrasound and microbubbles. In this study, a real-time live cell imaging platform is used to determine whether plasma membrane potential change is related to the sonoporation process at the cellular level. METHODS: Hela cells were cultured in DMEM supplemented with 10% FBS in Opticell Chamber at 37 °C and 5% CO2, and reached 80% confluency before experiments. The Calcein Blue-AM, DiBAC4(3) loaded cells in the Opticell chamber filled with PI solution and Sonovue microbubbles were immerged in a water tank on a inverted fluorescence microscope. Pulsed ultrasound (1MHz freq., 20 cycles, 20Hz PRF, 0.2-0.5MPa PNP) was irradiated at the angle of 45° to the region of interest for 1s.The real-time fluorescence imaging for different probes was acquired by a cooled CCD camera every 20s for 10min. The time-lapse fluorescence images were quantitatively analyzed to evaluate the correlation of cell viability, intracellular delivery with plasma membrane potential change. RESULTS: Our preliminary data showed that the PI fluorescence, which indicated intracellular delivery, was immediately accumulated in cells adjacent to microbubbles after exposure, suggesting that their membranes were damaged by ultrasound-activated microbubbles. However, the fluorescence reached its highest level within 4 to 6 minutes and was unchanged thereafter, indicating the membrane was gradually repaired within this period. Furthermore, using DIBAC4(3), which detected the change in the cell membrane potential, we found that the loss of membrane potential might be associated with intracellular delivery, because the PI fluorescence accumulation was usually accompanied with the change in DIBAC4 (3) fluorescence. CONCLUSIONS: Our study suggests that there may be a linkage between the cell membrane potential change and intracellular delivery mediated by ultrasound and microbubbles. We also suggest that other ionic flows or ion channels may be involved in the cell membrane potential change in sonoporation. Further efforts to explore the cellular mechanism of this phenomenon will improve our understanding of sonoporation.postprin

Investigations of the Cavitation and Damage Thresholds of Histotripsy and Applications in Targeted Tissue Ablation.

Histotripsy is a noninvasive ultrasound therapy that controls acoustic cavitation to mechanically fractionate soft tissue. This dissertation investigates the physical thresholds to initiate cavitation and produce tissue damage in histotripsy and factors affecting these thresholds in order to develop novel strategies for targeted tissue ablation. In the first part of this dissertation, the effects of tissue properties on histotripsy cavitation thresholds and damage thresholds were investigated. Results demonstrated that the histotripsy shock scattering threshold using multi-cycle pulses increases in stiffer tissues, while the histotripsy intrinsic threshold using single-cycle pulses is independent of tissue stiffness. Further, the intrinsic threshold slightly decreases with lower frequencies and significantly decreases with increasing temperature. The effects of tissue properties on the susceptibility to histotripsy-induced tissue damage were also investigated, demonstrating that stiffer tissues are more resistant to histotripsy. In the second part of this dissertation, the feasibility of using histotripsy for targeted liver ablation was investigated in an intact in vivo porcine model, with results demonstrating that histotripsy was capable of non-invasively creating precise lesions throughout the entire liver. Additionally, a tissue selective ablation approach was developed, where histotripsy completely fractionated the liver tissue surrounding the major hepatic vessels and gallbladder while being self-limited at the boundaries of these critical structures. In the final part of this dissertation, a novel ablation method combining histotripsy with acoustically sensitive nanodroplets was developed for targeted cancer cell ablation, demonstrating the potential of using nanodroplet-mediated histotripsy (NMH) for targeted, multi-focal ablation. Studies demonstrated that lower frequency and higher boiling point perfluorocarbon droplets can improve NMH therapy. The role of positive and negative pressure on cavitation nucleation in NMH was also investigated, showing that NMH cavitation nucleation is caused directly from the peak negative pressure of the incident wave, similar to histotripsy bubbles generated above the intrinsic threshold. Overall, the results of this dissertation provide significant insight into the physical mechanisms underlying histotripsy tissue ablation and will help to guide the future development of histotripsy for clinical applications such as the treatment of liver cancer.PhDBiomedical EngineeringUniversity of Michigan, Horace H. Rackham School of Graduate Studieshttp://deepblue.lib.umich.edu/bitstream/2027.42/113591/1/evlaisav_1.pd

Simulation Based Strategies for Clinical Translation of Magnetic Nanoparticle Hyperthermia

Magnetic nanoparticles have gained significant importance in the recent past for their use in biomedical applications such as drug delivery, imaging, diagnosis, and therapy. Magnetic nanoparticle hyperthermia is the selective heating of tumor tissue using magnetic nanoparticles which generate heat when exposed to an alternating magnetic field. It is a minimally invasive method which can cause effective and localized tumor thermal damage. The challenge to achieve consistent heating with this modality is the variable distribution upon delivery, which results in variable heat distribution in the tumor and surrounding normal tissue. In this thesis, using computational methods we explore optimization strategies to modulate magnetic field amplitude using limited temperature feedback to achieve clinically effective thermal dose in tumor and minimize healthy tissue damage. The magnetic field amplitude is modulated by using a Proportional-Integral-Derivative (PID) controller based on temperature feedback from tumor-healthy tissue boundary. We consider nanoparticle distributions obtained from animal studies and idealized mathematical constructs. Two and three dimensional (2D & 3D) models of tumor and healthy tissue were considered. Temperature effects on perfusion were considered. Results of thermal damage, temperature distributions and thermal dose obtained from modulated power heating were then compared to constant power heating. It is shown that controlling the tumor-healthy tissue boundary temperature by modulating the heating power of the nanoparticles can compensate for variable nanoparticle distributions to deliver effective treatment. The strategy was then implemented in mouse models of liver cancer. Two nanoparticle distributions were generated by using two injection methods. It was shown that the temperature at the tumor-healthy tissue boundary can be consistently controlled for the two nanoparticle distributions. The challenges associated with implementation of our proposed strategy have been identified and future steps for further accurate testing have been presented. Another challenge for magnetic nanoparticle hyperthermia is the onset of eddy current heating when the treatment modality is applied to tumors in large organs. Monitoring of eddy current heating in in vivo studies is challenging. Hence, we developed a computational tool which couples thermal and electromagnetic modeling to predict the temperatures achieved due to eddy current heating. The model was verified with the analytical solution and validated with gel phantom experiments. We then implemented it to generate 3D liver model from computed tomography (CT) images of rabbit liver. The temperatures attained due to eddy current heating from exposure to alternating magnetic fields were calculated to demonstrate the utility of the model in estimating temperature during magnetic nanoparticle hyperthermia of large organs. In the last chapter, we characterized the thermal and magnetic properties of dual contrast nanoparticle formulations used in image guided thermal therapy of liver cancer. Dual contrast nanoparticle formulations are magnetic iron oxide nanoparticles combined with lipiodol. The heating potential of these lipiodol nanoparticle formulations was extensively characterized by measuring their thermal properties at fixed frequency with different magnetic field amplitudes. These were then compared to original aqueous formulations for assessing the differences between both the formulations. Bulk magnetic properties of both the formulations was measured and compared. It is observed that when nanoparticles are mixed with lipiodol, the specific loss power of these particles is reduced. These results highlight the importance of evaluating the heating performance of new nanoparticle formulations