Your search keyword '"ultrasound-mediated drug delivery"' showing total 35 results

1. Green synthesis of anti-cancer drug-loaded gold nanoparticles for low-intensity pulsed ultrasound targeted drug release.

Author

Jakhmola, Anshuman, Hornsby, Tyler K., Kashkooli, Farshad Moradi, Kolios, Michael C., Rod, Kevin, and Tavakkoli, Jahangir

Abstract

In the present work, we have designed a one-pot green protocol in which anti-cancer drugs (curcumin and doxorubicin) can be directly loaded on the surface of gold nanoparticles during their formation. We have further demonstrated that low-intensity pulsed ultrasound (LIPUS) can be used to effectively induce the release of anti-cancer drugs from the surface of gold nanoparticles in an ex vivo tissue model. With this protocol, gold nanoparticles can be easily loaded with different types of anticancer drugs, irrespective of their affinity towards water, and even hydrophobic molecules, like curcumin, can be attached onto the gold nanoparticles in an aqueous medium. The method is very simple and straightforward and does not require stirring or mechanical shaking. The drug molecules interact with the gold seeds formed during the reduction and growth process and modulate the final morphology into a spherical shape. A black-colored colloidal solution of gold nanowire networks is formed in the absence of these anti-cancer drug molecules in the reaction mixture. We used hyperspectral-enhanced dark field microscopy to examine the uptake of gold nanoparticles by breast cancer cells. Upon exposure to LIPUS, the release of the anti-cancer drug from the particle surface can be quantified by fluorescence measurements. This release of drug molecules along with trisodium citrate from the surface of gold nanoparticles by ultrasound resulted in their destabilization and subsequent aggregation, which could be visually observed through the change in the color of colloidal sol. Cancer cell viability was studied by MTT assay to examine the efficacy of this nanoparticle-based drug delivery system. Ultraviolet-visible spectroscopy, dynamic light scattering (DLS), and transmission electron microscope (TEM) analysis were used to characterize the nanoparticles and quantify anti-cancer drug release. [ABSTRACT FROM AUTHOR]

Published

2024

2. Efficient ultrasound-mediated drug delivery to orthotopic liver tumors – Direct comparison of doxorubicin-loaded nanobubbles and microbubbles.

Author

Nittayacharn, Pinunta, Abenojar, Eric, Cooley, Michaela B., Berg, Felipe M., Counil, Claire, Sojahrood, Amin Jafari, Khan, Muhammad Saad, Yang, Celina, Berndl, Elizabeth, Golczak, Marcin, Kolios, Michael C., and Exner, Agata A.

Subjects

*LIVER tumors, *MICROBUBBLES, *DOXORUBICIN, *ULTRASONIC therapy, *CORE materials, *LIVER metastasis

Abstract

Liver metastasis is a major obstacle in treating aggressive cancers, and current therapeutic options often prove insufficient. To overcome these challenges, there has been growing interest in ultrasound-mediated drug delivery using lipid-shelled microbubbles (MBs) and nanobubbles (NBs) as promising strategies for enhancing drug delivery to tumors. Our previous work demonstrated the potential of Doxorubicin-loaded C 3 F 8 NBs (hDox-NB, 280 ± 123 nm) in improving cancer treatment in vitro using low-frequency unfocused therapeutic ultrasound (TUS). In this study, we investigated the pharmacokinetics and biodistribution of sonicated hDox-NBs in orthotopic rat liver tumors. We compared their delivery and therapeutic efficiency with size-isolated MBs (hDox-MB, 1104 ± 373 nm) made from identical shell material and core gas. Results showed a similar accumulation of hDox in tumors treated with hDox-MBs and unfocused therapeutic ultrasound (hDox-MB + TUS) and hDox-NB + TUS. However, significantly increased apoptotic cell death in the tumor and fewer off-target apoptotic cells in the normal liver were found upon the treatment with hDox-NB + TUS. The tumor-to-liver apoptotic ratio was elevated 9.4-fold following treatment with hDox-NB + TUS compared to hDox-MB + TUS, suggesting that the therapeutic efficacy and specificity are significantly increased when using hDox-NB + TUS. These findings highlight the potential of this approach as a viable treatment modality for liver tumors. By elucidating the behavior of drug-loaded bubbles in vivo , we aim to contribute to developing more effective liver cancer treatments that could ultimately improve patient outcomes and decrease off-target side effects. [Display omitted] • Bubble size is a critical factor in ultrasound-mediated drug delivery to tumors. • Nanobubbles excited with ultrasound deliver more drugs to tumors than microbubbles. • Nanobubbles + ultrasound increase apoptotic cell death in tumors while sparing normal liver. [ABSTRACT FROM AUTHOR]

Published

2024

3. Ultrasound‐mediated nano‐sized drug delivery systems for cancer treatment: Multi‐scale and multi‐physics computational modeling.

Author

Moradi Kashkooli, Farshad, Hornsby, Tyler K., Kolios, Michael C., and Tavakkoli, Jahangir

Abstract

Computational modeling enables researchers to study and understand various complex biological phenomena in anticancer drug delivery systems (DDSs), especially nano‐sized DDSs (NSDDSs). The combination of NSDDSs and therapeutic ultrasound (TUS), that is, focused ultrasound and low‐intensity pulsed ultrasound, has made significant progress in recent years, opening many opportunities for cancer treatment. Multiple parameters require tuning and optimization to develop effective DDSs, such as NSDDSs, in which mathematical modeling can prove advantageous. In silico computational modeling of ultrasound‐responsive DDS typically involves a complex framework of acoustic interactions, heat transfer, drug release from nanoparticles, fluid flow, mass transport, and pharmacodynamic governing equations. Owing to the rapid development of computational tools, modeling the different phenomena in multi‐scale complex problems involved in drug delivery to tumors has become possible. In the present study, we present an in‐depth review of recent advances in the mathematical modeling of TUS‐mediated DDSs for cancer treatment. A detailed discussion is also provided on applying these computational models to improve the clinical translation for applications in cancer treatment. This article is categorized under:Nanotechnology Approaches to Biology > Nanoscale Systems in BiologyTherapeutic Approaches and Drug Discovery > Nanomedicine for Oncologic Disease [ABSTRACT FROM AUTHOR]

Published

2024

4. Ultrasound-mediated nano drug delivery for treating cancer: Fundamental physics to future directions.

Author

Moradi Kashkooli, Farshad, Jakhmola, Anshuman, Hornsby, Tyler K., Tavakkoli, Jahangir (Jahan), and Kolios, Michael C.

Subjects

*MICROBUBBLE diagnosis, *ULTRASONIC therapy, *DRUG delivery systems, *CELL physiology, *PHYSICS, *CANCER treatment

Abstract

The application of biocompatible nanocarriers in medicine has provided several benefits over conventional treatment methods. However, achieving high treatment efficacy and deep penetration of nanocarriers in tumor tissue is still challenging. To address this, stimuli-responsive nano-sized drug delivery systems (DDSs) are an active area of investigation in delivering anticancer drugs. While ultrasound is mainly used for diagnostic purposes, it can also be applied to affect cellular function and the delivery/release of anticancer drugs. Therapeutic ultrasound (TUS) has shown potential as both a stand-alone anticancer treatment and a method to induce targeted drug release from nanocarrier systems. TUS approaches have been used to overcome various physiological obstacles, including endothelial barriers, the tumor microenvironment (TME), and immunological hurdles. Combining nanomedicine and ultrasound as a smart DDS can increase in situ drug delivery and improve access to impermeable tissues. Furthermore, smart DDSs can perform targeted drug release in response to distinctive TMEs, external triggers, or dual/multi-stimulus. This results in enhanced treatment efficacy and reduced damage to surrounding healthy tissue or organs at risk. Integrating DDSs and ultrasound is still in its early stages. More research and clinical trials are required to fully understand ultrasound's underlying physical mechanisms and interactions with various types of nanocarriers and different types of cells and tissues. In the present review, ultrasound-mediated nano-sized DDS, specifically focused on cancer treatment, is presented and discussed. Ultrasound interaction with nanoparticles (NPs), drug release mechanisms, and various types of ultrasound-sensitive NPs are examined. Additionally, in vitro , in vivo , and clinical applications of TUS are reviewed in light of the critical challenges that need to be considered to advance TUS toward an efficient, secure, straightforward, and accessible cancer treatment. This study also presents effective TUS parameters and safety considerations for this treatment modality and gives recommendations about system design and operation. Finally, future perspectives are considered, and different TUS approaches are examined and discussed in detail. This review investigates drug release and delivery through ultrasound-mediated nano-sized cancer treatment, both pre-clinically and clinically. [Display omitted] • Evaluating different barriers against the effective delivery of US-triggered drug-loaded NPs. • Reviewing of the most representative US-sensitive nano-formulations for cancer therapy. • Examining the advancements and challenges facing in vitro , in vivo , and human clinical studies of this anticancer treatment. • Discussing advantages, challenges, safety concerns, and future outlook of US-triggered nano-sized DDSs in cancer treatment. [ABSTRACT FROM AUTHOR]

Published

2023

5. Low-Intensity Pulsed Ultrasound-Mediated Blood-Brain Barrier Opening Increases Anti-Programmed Death-Ligand 1 Delivery and Efficacy in Gl261 Mouse Model.

Author

Ahmed, Mohammed H., Hernández-Verdin, Isaias, Quissac, Emie, Lemaire, Nolwenn, Guerin, Coralie, Guyonnet, Lea, Zahr, Noël, Mouton, Laura, Santin, Mathieu, Petiet, Alexandra, Schmitt, Charlotte, Bouchoux, Guillaume, Canney, Michael, Sanson, Marc, Verreault, Maïté, Carpentier, Alexandre, and Idbaih, Ahmed

Subjects

*BLOOD-brain barrier, *LABORATORY mice, *IMMUNE checkpoint inhibitors, *ANIMAL disease models, *IMMUNE checkpoint proteins, *PROGRAMMED cell death 1 receptors, *MAGNETIC resonance imaging

Abstract

Therapeutic antibodies targeting immune checkpoints have shown limited efficacy in clinical trials in glioblastoma (GBM) patients. Ultrasound-mediated blood–brain barrier opening (UMBO) using low-intensity pulsed ultrasound improved drug delivery to the brain. We explored the safety and the efficacy of UMBO plus immune checkpoint inhibitors in preclinical models of GBM. A blood–brain barrier (BBB) opening was performed using a 1 MHz preclinical ultrasound system in combination with 10 µL/g microbubbles. Brain penetration of immune checkpoint inhibitors was determined, and immune cell populations were evaluated using flow cytometry. The impact of repeated treatments on survival was determined. In syngeneic GL261-bearing immunocompetent mice, we showed that UMBO safely and repeatedly opened the BBB. BBB opening was confirmed visually and microscopically using Evans blue dye and magnetic resonance imaging. UMBO plus anti-PDL-1 was associated with a significant improvement of overall survival compared to anti-PD-L1 alone. Using mass spectroscopy, we showed that the penetration of therapeutic antibodies can be increased when delivered intravenously compared to non-sonicated brains. Furthermore, we observed an enhancement of activated microglia percentage when combined with anti-PD-L1. Here, we report that the combination of UMBO and anti-PD-L1 dramatically increases GL261-bearing mice's survival compared to their counterparts treated with anti-PD-L1 alone. Our study highlights the BBB as a limitation to overcome in order to increase the efficacy of anti-PD-L1 in GBM and supports clinical trials combining UMBO and in GBM patients. [ABSTRACT FROM AUTHOR]

Published

2023

6. Advances in BBB on Chip and Application for Studying Reversible Opening of Blood–Brain Barrier by Sonoporation.

Author

Cai, Yicong, Fan, Kexin, Lin, Jiawei, Ma, Lin, and Li, Fenfang

Subjects

BLOOD-brain barrier, DRUG development, TIGHT junctions, MICROFABRICATION, DRUG utilization

Abstract

The complex structure of the blood–brain barrier (BBB), which blocks nearly all large biomolecules, hinders drug delivery to the brain and drug assessment, thus decelerating drug development. Conventional in vitro models of BBB cannot mimic some crucial features of BBB in vivo including a shear stress environment and the interaction between different types of cells. There is a great demand for a new in vitro platform of BBB that can be used for drug delivery studies. Compared with in vivo models, an in vitro platform has the merits of low cost, shorter test period, and simplicity of operation. Microfluidic technology and microfabrication are good tools in rebuilding the BBB in vitro. During the past decade, great efforts have been made to improve BBB penetration for drug delivery using biochemical or physical stimuli. In particular, compared with other drug delivery strategies, sonoporation is more attractive due to its minimized systemic exposure, high efficiency, controllability, and reversible manner. BBB on chips (BOC) holds great promise when combined with sonoporation. More details and mechanisms such as trans-endothelial electrical resistance (TEER) measurements and dynamic opening of tight junctions can be figured out when using sonoporation stimulating BOC, which will be of great benefit for drug development. Herein, we discuss the recent advances in BOC and sonoporation for BBB disruption with this in vitro platform. [ABSTRACT FROM AUTHOR]

Published

2023

7. Low-Intensity Pulsed Ultrasound-Mediated Blood-Brain Barrier Opening Increases Anti-Programmed Death-Ligand 1 Delivery and Efficacy in Gl261 Mouse Model

Author

Mohammed H. Ahmed, Isaias Hernández-Verdin, Emie Quissac, Nolwenn Lemaire, Coralie Guerin, Lea Guyonnet, Noël Zahr, Laura Mouton, Mathieu Santin, Alexandra Petiet, Charlotte Schmitt, Guillaume Bouchoux, Michael Canney, Marc Sanson, Maïté Verreault, Alexandre Carpentier, and Ahmed Idbaih

Subjects

SonoCloud, GL261 mouse model, ultrasound-mediated drug delivery, glioblastoma, immune checkpoint inhibitors, Pharmacy and materia medica, RS1-441

Abstract

Therapeutic antibodies targeting immune checkpoints have shown limited efficacy in clinical trials in glioblastoma (GBM) patients. Ultrasound-mediated blood–brain barrier opening (UMBO) using low-intensity pulsed ultrasound improved drug delivery to the brain. We explored the safety and the efficacy of UMBO plus immune checkpoint inhibitors in preclinical models of GBM. A blood–brain barrier (BBB) opening was performed using a 1 MHz preclinical ultrasound system in combination with 10 µL/g microbubbles. Brain penetration of immune checkpoint inhibitors was determined, and immune cell populations were evaluated using flow cytometry. The impact of repeated treatments on survival was determined. In syngeneic GL261-bearing immunocompetent mice, we showed that UMBO safely and repeatedly opened the BBB. BBB opening was confirmed visually and microscopically using Evans blue dye and magnetic resonance imaging. UMBO plus anti-PDL-1 was associated with a significant improvement of overall survival compared to anti-PD-L1 alone. Using mass spectroscopy, we showed that the penetration of therapeutic antibodies can be increased when delivered intravenously compared to non-sonicated brains. Furthermore, we observed an enhancement of activated microglia percentage when combined with anti-PD-L1. Here, we report that the combination of UMBO and anti-PD-L1 dramatically increases GL261-bearing mice’s survival compared to their counterparts treated with anti-PD-L1 alone. Our study highlights the BBB as a limitation to overcome in order to increase the efficacy of anti-PD-L1 in GBM and supports clinical trials combining UMBO and in GBM patients.

Published

2023

8. Advances in BBB on Chip and Application for Studying Reversible Opening of Blood–Brain Barrier by Sonoporation

Author

Yicong Cai, Kexin Fan, Jiawei Lin, Lin Ma, and Fenfang Li

Subjects

blood–brain barrier, microfluidics, ultrasound-mediated drug delivery, Mechanical engineering and machinery, TJ1-1570

Abstract

The complex structure of the blood–brain barrier (BBB), which blocks nearly all large biomolecules, hinders drug delivery to the brain and drug assessment, thus decelerating drug development. Conventional in vitro models of BBB cannot mimic some crucial features of BBB in vivo including a shear stress environment and the interaction between different types of cells. There is a great demand for a new in vitro platform of BBB that can be used for drug delivery studies. Compared with in vivo models, an in vitro platform has the merits of low cost, shorter test period, and simplicity of operation. Microfluidic technology and microfabrication are good tools in rebuilding the BBB in vitro. During the past decade, great efforts have been made to improve BBB penetration for drug delivery using biochemical or physical stimuli. In particular, compared with other drug delivery strategies, sonoporation is more attractive due to its minimized systemic exposure, high efficiency, controllability, and reversible manner. BBB on chips (BOC) holds great promise when combined with sonoporation. More details and mechanisms such as trans-endothelial electrical resistance (TEER) measurements and dynamic opening of tight junctions can be figured out when using sonoporation stimulating BOC, which will be of great benefit for drug development. Herein, we discuss the recent advances in BOC and sonoporation for BBB disruption with this in vitro platform.

Published

2022

9. Evaluation of Loading Strategies to Improve Tumor Uptake of Gemcitabine in a Murine Orthotopic Bladder Cancer Model Using Ultrasound and Microbubbles.

Author

Ruan, Jia-Ling, Browning, Richard J., Yildiz, Yesna O., Bau, Luca, Kamila, Sukanta, Gray, Michael D., Folkes, Lisa, Hampson, Alix, McHale, Anthony P., Callan, John F., Vojnovic, Borivoj, Kiltie, Anne E., and Stride, Eleanor

Subjects

*MICROBUBBLE diagnosis, *ULTRASONIC imaging, *MICROBUBBLES, *BLADDER cancer, *LIPOSOMES, *CELL lines

Abstract

In this study we compared three different microbubble-based approaches to the delivery of a widely used chemotherapy drug, gemcitabine: (i) co-administration of gemcitabine and microbubbles (Gem+MB); (ii) conjugates of microbubbles and gemcitabine-loaded liposomes (GemlipoMB); and (iii) microbubbles with gemcitabine directly bound to their surfaces (GembioMB). Both in vitro and in vivo investigations were carried out, respectively, in the RT112 bladder cancer cell line and in a murine orthotopic muscle-invasive bladder cancer model. The in vitro (in vivo) ultrasound exposure conditions were a 1 (1.1) MHz centre frequency, 0.07 (1.0) MPa peak negative pressure, 3000 (20,000) cycles and 100 (0.5) Hz pulse repetition frequency. Ultrasound exposure produced no significant increase in drug uptake either in vitro or in vivo compared with the drug-only control for co-administered gemcitabine and microbubbles. In vivo, GemlipoMB prolonged the plasma circulation time of gemcitabine, but only GembioMB produced a statistically significant increase in cleaved caspase 3 expression in the tumor, indicative of gemcitabine-induced apoptosis. [ABSTRACT FROM AUTHOR]

Published

2021

10. Nanoscale contrast agents: A promising tool for ultrasound imaging and therapy.

Author

Wang, Jieqiong, Wang, Yuanyuan, Zhong, Lin, Yan, Fei, and Zheng, Hairong

Subjects

*CONTRAST media, *ULTRASONIC imaging, *MEDICAL research

Abstract

[Display omitted] Nanoscale contrast agents have emerged as a versatile platform in the field of biomedical research, offering great potential for ultrasound imaging and therapy. Various kinds of nanoscale contrast agents have been extensively investigated in preclinical experiments to satisfy diverse biomedical applications. This paper provides a comprehensive review of the structure and composition of various nanoscale contrast agents, as well as their preparation and functionalization, encompassing both chemosynthetic and biosynthetic strategies. Subsequently, we delve into recent advances in the utilization of nanoscale contrast agents in various biomedical applications, including ultrasound molecular imaging, ultrasound-mediated drug delivery, and cell acoustic manipulation. Finally, the challenges and prospects of nanoscale contrast agents are also discussed to promote the development of this innovative nanoplatform in the field of biomedicine. [ABSTRACT FROM AUTHOR]

Published

2024

11. Ultrasound-mediated nano-sized drug delivery systems for cancer treatment: Multi-scale and multi-physics computational modeling.

Author

Moradi Kashkooli F, Hornsby TK, Kolios MC, and Tavakkoli JJ

Subjects

Humans, Nanoparticle Drug Delivery System, Drug Delivery Systems, Computer Simulation, Physics, Neoplasms diagnostic imaging, Neoplasms drug therapy, Nanoparticles

Abstract

Computational modeling enables researchers to study and understand various complex biological phenomena in anticancer drug delivery systems (DDSs), especially nano-sized DDSs (NSDDSs). The combination of NSDDSs and therapeutic ultrasound (TUS), that is, focused ultrasound and low-intensity pulsed ultrasound, has made significant progress in recent years, opening many opportunities for cancer treatment. Multiple parameters require tuning and optimization to develop effective DDSs, such as NSDDSs, in which mathematical modeling can prove advantageous. In silico computational modeling of ultrasound-responsive DDS typically involves a complex framework of acoustic interactions, heat transfer, drug release from nanoparticles, fluid flow, mass transport, and pharmacodynamic governing equations. Owing to the rapid development of computational tools, modeling the different phenomena in multi-scale complex problems involved in drug delivery to tumors has become possible. In the present study, we present an in-depth review of recent advances in the mathematical modeling of TUS-mediated DDSs for cancer treatment. A detailed discussion is also provided on applying these computational models to improve the clinical translation for applications in cancer treatment. This article is categorized under: Nanotechnology Approaches to Biology > Nanoscale Systems in Biology Therapeutic Approaches and Drug Discovery > Nanomedicine for Oncologic Disease., (© 2023 The Authors. WIREs Nanomedicine and Nanobiotechnology published by Wiley Periodicals LLC.)

Published

2024

12. Improving Release of Liposome-Encapsulated Drugs with Focused Ultrasound and Vaporizable Droplet-Liposome Nanoclusters

Author

Arvin Honari, Darrah A. Merillat, Aditi Bellary, Mohammadaref Ghaderi, and Shashank R. Sirsi

Subjects

acoustic droplet vaporization, acoustic targeting, ultrasound-mediated drug delivery, focused ultrasound, drug uncaging, phase-shift contrast agents, Pharmacy and materia medica, RS1-441

Abstract

Active targeted delivery of small molecule drugs is becoming increasingly important in personalized therapies, especially in cancer, brain disorders, and a wide variety of other diseases. However, effective means of spatial targeting and delivering high drug payloads in vivo are still lacking. Focused ultrasound combined with superheated phase-shift nanodroplets, which vaporize into microbubbles using heat and sound, are rapidly becoming a popular strategy for targeted drug delivery. Focused ultrasound can target deep tissue with excellent spatial precision and without using ionizing energy, thus can activate nanodroplets in circulation. One of the main limitations of this technology has been poor drug loading in the droplet core or the shell material. To address this need, we have developed a strategy to combine low-boiling point decafluorabutane and octafluoropropane (DFB and OFP) nanodroplets with drug-loaded liposomes, creating phase-changeable droplet-liposome clusters (PDLCs). We demonstrate a facile method of assembling submicron PDLCs with high drug-loading capacity on the droplet surface. Furthermore, we demonstrate that chemical tethering of liposomes in PDLCs enables a rapid release of their encapsulated cargo upon acoustic activation (>60% using OFP-based PDLCs). Rapid uncaging of small molecule drugs would make them immediately bioavailable in target tissue or promote better penetration in local tissue following intravascular release. PDLCs developed in this study can be used to deliver a wide variety of liposome-encapsulated therapeutics or imaging agents for multi-modal imaging applications. We also outline a strategy to deliver a surrogate encapsulated drug, fluorescein, to tumors in vivo using focused ultrasound energy and PDLCs.

Published

2021

13. Low-intensity Pulsed Ultrasound-mediated Blood-brain Barrier Opening Increases Anti-programmed Death-ligand 1 Delivery and Efficacy in Gl261 Mouse Model

Author

Mohammed H. Ahmed, Isaias Hernández-Verdin, Emie Quissac, Nolwenn Lemaire, Coralie Guerin, Lea Guyonnet, Noël Zahr, Laura Mouton, Mathieu Santin, Alexandra Petiet, Charlotte Schmitt, Guillaume Bouchoux, Michael Canney, Marc Sanson, Maïté Verreault, Alexandre Carpentier, and Ahmed Idbaih

Subjects

immune checkpoint inhibitors, ultrasound-mediated drug delivery, glioblastoma, Pharmaceutical Science, GL261 mouse model, SonoCloud, pharmacology_toxicology

Abstract

Therapeutic antibodies targeting immune checkpoints have shown limited efficacy in clinical trials in glioblastoma (GBM) patients. Ultrasound-mediated blood-brain barrier opening (UMBO) using low-intensity pulsed ultrasound improved drug delivery to the brain. We explored the safety and the efficacy of UMBO plus immune checkpoint inhibitors in preclinical models of GBM. A Blood-brain barrier (BBB) opening was performed using a 1 MHz preclinical ultrasound system in combination with 10µl/g microbubbles. Brain penetration of immune checkpoint inhibitors was determined, and immune cell populations were evaluated using flow cytometry. The impact of repeated treatments on survival was determined. In syngeneic GL261-bearing immunocompetent mice, we showed that UMBO safely and repeatedly open the BBB. BBB opening was confirmed visually and microscopically using Evans’s blue dye and magnetic resonance imaging. UMBO plus anti-PDL-1 was associated with a significant improvement of the overall survival compared to anti-PD-L1 alone. Using mass spectroscopy, we showed that the penetration of therapeutic antibodies can be increased when delivered intravenously compared to non-sonicated brains. Furthermore, we observed an enhancement of activated microglia percentage when combined with anti-PD-L1. Here, we report that the combination of UMBO and anti-PD-L1 dramatically increases GL261-bearing mice's survival compared to their counterparts treated with anti-PD-L1 alone. Our study highlights the BBB as a limitation to overcome to increase the efficacy of anti-PD-L1 in GBM and supports clinical trials combining UMBO and in GBM patients.

Published

2022

14. Efficient ultrasound-mediated drug delivery to orthotopic liver tumors - Direct comparison of doxorubicin-loaded nanobubbles and microbubbles.

Author

Nittayacharn P, Abenojar E, Cooley M, Berg F, Counil C, Sojahrood AJ, Khan MS, Yang C, Berndl E, Golczak M, Kolios MC, and Exner AA

Abstract

Liver metastasis is a major obstacle in treating aggressive cancers, and current therapeutic options often prove insufficient. To overcome these challenges, there has been growing interest in ultrasound-mediated drug delivery using lipid-shelled microbubbles (MBs) and nanobubbles (NBs) as promising strategies for enhancing drug delivery to tumors. Our previous work demonstrated the potential of Doxorubicin-loaded C 3 F 8 NBs (hDox-NB, 280 ± 123 nm) in improving cancer treatment in vitro using low-frequency ultrasound. In this study, we investigated the pharmacokinetics and biodistribution of sonicated hDox-NBs in orthotopic rat liver tumors. We compared their delivery and therapeutic efficiency with size-isolated MBs (hDox-MB, 1104 ± 373 nm). Results showed a similar accumulation of hDox in tumors treated with hDox-MBs and unfocused therapeutic ultrasound (hDox-MB+TUS) and hDox-NB+TUS. However, significantly increased apoptotic cell death in the tumor and fewer off-target apoptotic cells in the normal liver were found upon the treatment with hDox-NB+TUS. The tumor-to-liver apoptotic ratio was elevated 9.4-fold following treatment with hDox-NB+TUS compared to hDox-MB+TUS, suggesting that the therapeutic efficacy and specificity are significantly increased when using hDox-NB+TUS. These findings highlight the potential of this approach as a viable treatment modality for liver tumors. By elucidating the behavior of drug-loaded bubbles in vivo , we aim to contribute to developing more effective liver cancer treatments that could ultimately improve patient outcomes and decrease off-target side effects.

Published

2023

15. Defining optimal permeant characteristics for ultrasound-mediated gastrointestinal delivery.

Author

Schoellhammer, Carl M., Chen, Yiyun, Cleveland, Cody, Minahan, Daniel, Bensel, Taylor, Park, June Y., Saxton, Sarah, Lee, Young-Ah Lucy, Booth, Lucas, Langer, Robert, and Traverso, Giovanni

Subjects

*GASTROINTESTINAL system, *DRUG delivery systems, *HIGH-intensity focused ultrasound, *PHARMACOKINETICS, *NUCLEIC acids

Abstract

Ultrasound-mediated drug delivery in the gastrointestinal (GI) tract is a bourgeoning area of study. Localized, low-frequency ultrasound has recently been shown to enable significant enhancement in delivery of a broad set of active pharmaceutical ingredients including small molecules, proteins, and nucleic acids without any formulation or encapsulation of the therapeutic. Traditional chemical formulations are typically required to protect, stabilize, and enable the successful delivery of a given therapeutic. The use of ultrasound, however, may make delivery insensitive to the chemical formulation. This might open the door to chemical formulations being developed to address other properties besides the deliverability of a therapeutic. Instead, chemical formulations could potentially be developed to achieve novel pharmacokinetics, without consideration of that particular formulation's ability to penetrate the mucus barrier passively. Here we investigated the effect of permeant size, charge, and the presence of chemical penetration enhancers on delivery to GI tissue using ultrasound. Short ultrasound treatments enabled delivery of large permeants, including microparticles, deep into colonic tissue ex vivo . Delivery was relatively independent of size and charge but did depend on conformation, with regular, spherical particles being delivered to a greater extent than long-chain polymers. The subsequent residence time of model permeants in tissue after ultrasound-mediated delivery was found to depend on size, with large microparticles demonstrating negligible clearance from the local tissue 24 h after delivery ex vivo . The dependence of clearance time on permeant size was further confirmed in vivo in mice using fluorescently labeled 3 kDa and 70 kDa dextran. The use of low-frequency ultrasound in the GI tract represents a novel tool for the delivery of a wide-range of therapeutics independent of formulation, potentially allowing for the tailoring of formulations to impart novel pharmacokinetic profiles once delivered into tissue. [ABSTRACT FROM AUTHOR]

Published

2017

16. Making waves: how ultrasound-targeted drug delivery is changing pharmaceutical approaches.

Author

Delaney, Lauren J, Isguven, Selin, Eisenbrey, John R, Hickok, Noreen J, Forsberg, Flemming, Delaney, Lauren J, Isguven, Selin, Eisenbrey, John R, Hickok, Noreen J, and Forsberg, Flemming

Abstract

Administration of drugs through oral and intravenous routes is a mainstay of modern medicine, but this approach suffers from limitations associated with off-target side effects and narrow therapeutic windows. It is often apparent that a controlled delivery of drugs, either localized to a specific site or during a specific time, can increase efficacy and bypass problems with systemic toxicity and insufficient local availability. To overcome some of these issues, local delivery systems have been devised, but most are still restricted in terms of elution kinetics, duration, and temporal control. Ultrasound-targeted drug delivery offers a powerful approach to increase delivery, therapeutic efficacy, and temporal release of drugs ranging from chemotherapeutics to antibiotics. The use of ultrasound can focus on increasing tissue sensitivity to the drug or actually be a critical component of the drug delivery. The high spatial and temporal resolution of ultrasound enables precise location, targeting, and timing of drug delivery and tissue sensitization. Thus, this noninvasive, non-ionizing, and relatively inexpensive modality makes the implementation of ultrasound-mediated drug delivery a powerful method that can be readily translated into the clinical arena. This review covers key concepts and areas applied in the design of different ultrasound-mediated drug delivery systems across a variety of clinical applications.

Published

2022

17. Measuring the Compressibility of Cellulose Nanofiber-Stabilized Microdroplets Using Acoustophoresis

Author

Grishenkov, Ksenia Loskutova, Karl Olofsson, Björn Hammarström, Martin Wiklund, Anna J. Svagan, and Dmitry

Subjects

technology, industry, and agriculture, acoustofluidics, ultrasound contrast agent, acoustic contrast factor, radiation force, compressibility, droplet vaporization, ultrasound-mediated drug delivery

Abstract

Droplets with a liquid perfluoropentane core and a cellulose nanofiber shell have the potential to be used as drug carriers in ultrasound-mediated drug delivery. However, it is necessary to understand their mechanical properties to develop ultrasound imaging sequences that enable in vivo imaging of the vaporization process to ensure optimized drug delivery. In this work, the compressibility of droplets stabilized with cellulose nanofibers was estimated using acoustophoresis at three different acoustic pressures. Polyamide particles of known size and material properties were used for calibration. The droplet compressibility was then used to estimate the cellulose nanofiber bulk modulus and compare it to experimentally determined values. The results showed that the acoustic contrast factor for these droplets was negative, as the droplets relocated to pressure antinodes during ultrasonic actuation. The droplet compressibility was 6.6–6.8 ×10−10 Pa−1, which is higher than for water (4.4×10−10 Pa−1) but lower than for pure perfluoropentane (2.7×10−9 Pa−1). The compressibility was constant across different droplet diameters, which was consistent with the idea that the shell thickness depends on the droplet size, rather than being constant.

Published

2021

18. Measuring the Compressibility of Cellulose Nanofiber-Stabilized Microdroplets Using Acoustophoresis

Author

Ksenia Loskutova, Karl Olofsson, Björn Hammarström, Martin Wiklund, Anna J. Svagan, and Dmitry Grishenkov

Subjects

droplet vaporization, ultrasound-mediated drug delivery, acoustofluidics, ultrasound contrast agent, radiation force, TJ1-1570, technology, industry, and agriculture, compressibility, Mechanical engineering and machinery, acoustic contrast factor, Article

Abstract

Droplets with a liquid perfluoropentane core and a cellulose nanofiber shell have the potential to be used as drug carriers in ultrasound-mediated drug delivery. However, it is necessary to understand their mechanical properties to develop ultrasound imaging sequences that enable in vivo imaging of the vaporization process to ensure optimized drug delivery. In this work, the compressibility of droplets stabilized with cellulose nanofibers was estimated using acoustophoresis at three different acoustic pressures. Polyamide particles of known size and material properties were used for calibration. The droplet compressibility was then used to estimate the cellulose nanofiber bulk modulus and compare it to experimentally determined values. The results showed that the acoustic contrast factor for these droplets was negative, as the droplets relocated to pressure antinodes during ultrasonic actuation. The droplet compressibility was 6.6–6.8 ×10−10 Pa−1, which is higher than for water (4.4×10−10 Pa−1) but lower than for pure perfluoropentane (2.7×10−9 Pa−1). The compressibility was constant across different droplet diameters, which was consistent with the idea that the shell thickness depends on the droplet size, rather than being constant.

Published

2021

19. Measuring the Compressibility of Cellulose Nanofiber-Stabilized Microdroplets Using Acoustophoresis

Author

Loskutova, Ksenia, Olofsson, Karl, Hammarström, Björn, Wiklund, Martin, Svagan, Anna Justina, Grishenkov, Dmitry, Loskutova, Ksenia, Olofsson, Karl, Hammarström, Björn, Wiklund, Martin, Svagan, Anna Justina, and Grishenkov, Dmitry

Abstract

Droplets with a liquid perfluoropentane core and a cellulose nanofiber shell have the potential to be used as drug carriers in ultrasound-mediated drug delivery. However, it is necessary to understand their mechanical properties to develop ultrasound imaging sequences that enable in vivo imaging of the vaporization process to ensure optimized drug delivery. In this work, the compressibility of droplets stabilized with cellulose nanofibers was estimated using acoustophoresis at three different acoustic pressures. Polyamide particles of known size and material properties were used for calibration. The droplet compressibility was then used to estimate the cellulose nanofiber bulk modulus and compare it to experimentally determined values. The results showed that the acoustic contrast factor for these droplets was negative, as the droplets relocated to pressure antinodes during ultrasonic actuation. The droplet compressibility was 6.6-6.8 x10(-10) Pa-1, which is higher than for water (4.4x10(-10) Pa-1) but lower than for pure perfluoropentane (2.7x10(-9) Pa-1). The compressibility was constant across different droplet diameters, which was consistent with the idea that the shell thickness depends on the droplet size, rather than being constant., QC 20220118

Published

2021

20. Improving Release of Liposome-Encapsulated Drugs with Focused Ultrasound and Vaporizable Droplet-Liposome Nanoclusters

Author

Aditi Bellary, Shashank R. Sirsi, Mohammadaref Ghaderi, Arvin Honari, and Darrah A. Merillat

Subjects

Materials science, acoustic targeting, Pharmaceutical Science, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Article, Nanoclusters, chemistry.chemical_compound, Pharmacy and materia medica, ultrasound-mediated drug delivery, In vivo, phase-shift contrast agents, drug uncaging, Acoustic droplet vaporization, Liposome, Octafluoropropane, 021001 nanoscience & nanotechnology, Small molecule, 0104 chemical sciences, RS1-441, Targeted drug delivery, chemistry, Microbubbles, focused ultrasound, 0210 nano-technology, acoustic droplet vaporization

Abstract

Active targeted delivery of small molecule drugs is becoming increasingly important in personalized therapies, especially in cancer, brain disorders, and a wide variety of other diseases. However, effective means of spatial targeting and delivering high drug payloads in vivo are still lacking. Focused ultrasound combined with superheated phase-shift nanodroplets, which vaporize into microbubbles using heat and sound, are rapidly becoming a popular strategy for targeted drug delivery. Focused ultrasound can target deep tissue with excellent spatial precision and without using ionizing energy, thus can activate nanodroplets in circulation. One of the main limitations of this technology has been poor drug loading in the droplet core or the shell material. To address this need, we have developed a strategy to combine low-boiling point decafluorabutane and octafluoropropane (DFB and OFP) nanodroplets with drug-loaded liposomes, creating phase-changeable droplet-liposome clusters (PDLCs). We demonstrate a facile method of assembling submicron PDLCs with high drug-loading capacity on the droplet surface. Furthermore, we demonstrate that chemical tethering of liposomes in PDLCs enables a rapid release of their encapsulated cargo upon acoustic activation (&gt, 60% using OFP-based PDLCs). Rapid uncaging of small molecule drugs would make them immediately bioavailable in target tissue or promote better penetration in local tissue following intravascular release. PDLCs developed in this study can be used to deliver a wide variety of liposome-encapsulated therapeutics or imaging agents for multi-modal imaging applications. We also outline a strategy to deliver a surrogate encapsulated drug, fluorescein, to tumors in vivo using focused ultrasound energy and PDLCs.

Published

2021

21. Biologically and Acoustically Compatible Chamber for Studying Ultrasound-Mediated Delivery of Therapeutic Compounds.

Author

Carugo, Dario, Owen, Joshua, Crake, Calum, Lee, Jeong Yu, and Stride, Eleanor

Subjects

*ULTRASONIC imaging, *MICROBUBBLE diagnosis, *IN vitro studies, *PARAMETER estimation, *COMPARATIVE studies

Abstract

Ultrasound (US), in combination with microbubbles, has been found to be a potential alternative to viral therapies for transfecting biological cells. The translation of this technique to the clinical environment, however, requires robust and systematic optimization of the acoustic parameters needed to achieve a desired therapeutic effect. Currently, a variety of different devices have been developed to transfect cells in vitro , resulting in a lack of standardized experimental conditions and difficulty in comparing results from different laboratories. To overcome this limitation, we propose an easy-to-fabricate and cost-effective device for application in US-mediated delivery of therapeutic compounds. It comprises a commercially available cell culture dish coupled with a silicon-based “lid” developed in-house that enables the device to be immersed in a water bath for US exposure. Described here are the design of the device, characterization of the sound field and fluid dynamics inside the chamber and an example protocol for a therapeutic delivery experiment. [ABSTRACT FROM AUTHOR]

Published

2015

22. Advances in BBB on Chip and Application for Studying Reversible Opening of Blood-Brain Barrier by Sonoporation.

Author

Cai Y, Fan K, Lin J, Ma L, and Li F

Abstract

The complex structure of the blood-brain barrier (BBB), which blocks nearly all large biomolecules, hinders drug delivery to the brain and drug assessment, thus decelerating drug development. Conventional in vitro models of BBB cannot mimic some crucial features of BBB in vivo including a shear stress environment and the interaction between different types of cells. There is a great demand for a new in vitro platform of BBB that can be used for drug delivery studies. Compared with in vivo models, an in vitro platform has the merits of low cost, shorter test period, and simplicity of operation. Microfluidic technology and microfabrication are good tools in rebuilding the BBB in vitro. During the past decade, great efforts have been made to improve BBB penetration for drug delivery using biochemical or physical stimuli. In particular, compared with other drug delivery strategies, sonoporation is more attractive due to its minimized systemic exposure, high efficiency, controllability, and reversible manner. BBB on chips (BOC) holds great promise when combined with sonoporation. More details and mechanisms such as trans-endothelial electrical resistance (TEER) measurements and dynamic opening of tight junctions can be figured out when using sonoporation stimulating BOC, which will be of great benefit for drug development. Herein, we discuss the recent advances in BOC and sonoporation for BBB disruption with this in vitro platform.

Published

2022

23. Multimodal Perfluorocarbon Nanoemulsions for 19F MRI, Ultrasonography, and Catalysis of MRgFUS-Mediated Drug Delivery.

Author

Rapoport, N., Nam, K. -H., Christensen, D. A., Kennedy, A. M., Parker, D. L., Payne, A. H., Todd, N., Shea, J. E., and Scaife, C. L.

Subjects

*PERFLUOROCARBONS, *MAGNETIC resonance imaging, *DIAGNOSTIC ultrasonic imaging, *DRUG delivery systems, *TARGETED drug delivery

Abstract

Perfluorocarbon nanoemulsions can target lipophilic therapeutic agents to solid tumors and simultaneously provide for monitoring nanocarrier biodistribution via ultrasonography and/or 19F MRI. In the first generation of block copolymer stabilized perfluorocarbon nanoemulsions, perfluoropentane (PFP) was used as the droplet forming compound. Although manifesting excellent therapeutic and ultrasound imaging properties, PFP nanoemulsions were unstable at storage, difficult to handle, and underwent droplet-to-bubble transition upon injection that was hard to control. To solve the above problems, perfluoro-15-crown-5-ether (PFCE) was used as a core forming compound in the second generation of block copolymer stabilized perfluorocarbon nanoemulsions. In the present paper, acoustic, imaging, and therapeutic properties of unloaded and paclitaxel (PTX) loaded PFCE nanoemulsions are reported. The size of paclitaxel-loaded PFCE nanodroplets (300 nm to 500 nm depending on emulsification conditions) favors their passive accumulation in tumor tissue. PFCE nanodroplets manifest both ultrasound and 19F MR contrast properties, which allows the use of multimodal imaging to monitor nanodroplet biodistribution. Ultrasonography and 19F MRI produced consistent results on nanodroplet biodistribution. Sonication with 1-MHz therapeutic ultrasound triggered reversible droplet-to-bubble transition in PFCE nanoemulsions. Microbubbles formed by acoustic vaporization underwent stable cavitation. In a pilot study on ultrasound-mediated therapy of a large breast cancer tumor, paclitaxelloaded PFCE nanoemulsions combined with 1-MHz ultrasound (MI = 1.75) showed excellent therapeutic properties. Anticipated mechanisms of the observed effects are discussed. [ABSTRACT FROM AUTHOR]

Published

2011

24. Synthesis and Characterization of Transiently Stable Albumin-Coated Microbubbles via a Flow-Focusing Microfluidic Device.

Author

Chen, Johnny L., Dhanaliwala, Ali H., Dixon, Adam J., Klibanov, Alexander L., and Hossack, John A.

Subjects

*ALBUMINS, *PROTEIN synthesis, *MICROFLUIDIC devices, *SERUM albumin, *BLOOD plasma, *SMOOTH muscle, *LABORATORY rats

Abstract

Abstract: We describe a method for synthesizing albumin-shelled, large-diameter (>10 μm), transiently stable microbubbles using a flow-focusing microfluidic device (FFMD). The microfluidic device enables microbubbles to be produced immediately before insonation, thus relaxing the requirements for stability. Both reconstituted fractionated bovine serum albumin (BSA) and fresh bovine blood plasma were investigated as shell stabilizers. Microbubble coalescence was inhibited by the addition of either dextrose or glycerol and propylene glycol. Microbubbles were observed to have an acoustic half-life of approximately 6 s. Microbubbles generated directly within a vessel phantom containing flowing blood produced a 6.5-dB increase in acoustic signal within the lumen. Microbubbles generated in real time upstream of in vitro rat aortic smooth muscle cells under physiologic flow conditions successfully permeabilized 58% of the cells on insonation at a peak negative pressure of 200 kPa. These results indicate that transiently stable microbubbles produced via flow-focusing microfluidic devices are capable of image enhancement and drug delivery. In addition, successful microbubble production with blood plasma suggests the potential to use blood as a stabilizing shell. [Copyright &y& Elsevier]

Published

2014

25. Enhanced Intracellular Delivery of a Model Drug Using Microbubbles Produced by a Microfluidic Device.

Author

Dixon, Adam J., Dhanaliwala, Ali H., Chen, Johnny L., and Hossack, John A.

Subjects

*MICROBUBBLES, *MICROFLUIDIC devices, *DRUG delivery devices, *INTRAVASCULAR ultrasonography, *ATHEROSCLEROSIS treatment, *DRUG administration, *MUSCLE cells, *SMOOTH muscle

Abstract

Abstract: Focal drug delivery to a vessel wall facilitated by intravascular ultrasound and microbubbles holds promise as a potential therapy for atherosclerosis. Conventional methods of microbubble administration result in rapid clearance from the bloodstream and significant drug loss. To address these limitations, we evaluated whether drug delivery could be achieved with transiently stable microbubbles produced in real time and in close proximity to the therapeutic site. Rat aortic smooth muscle cells were placed in a flow chamber designed to simulate physiological flow conditions. A flow-focusing microfluidic device produced 8 μm diameter monodisperse microbubbles within the flow chamber, and ultrasound was applied to enhance uptake of a surrogate drug (calcein). Acoustic pressures up to 300 kPa and flow rates up to 18 mL/s were investigated. Microbubbles generated by the flow-focusing microfluidic device were stabilized with a polyethylene glycol-40 stearate shell and had either a perfluorobutane (PFB) or nitrogen gas core. The gas core composition affected stability, with PFB and nitrogen microbubbles exhibiting half-lives of 40.7 and 18.2 s, respectively. Calcein uptake was observed at lower acoustic pressures with nitrogen microbubbles (100 kPa) than with PFB microbubbles (200 kPa) (p < 0.05, n > 3). In addition, delivery was observed at all flow rates, with maximal delivery (>70% of cells) occurring at a flow rate of 9 mL/s. These results demonstrate the potential of transiently stable microbubbles produced in real time and in close proximity to the intended therapeutic site for enhancing localized drug delivery. [Copyright &y& Elsevier]

Published

2013

26. Evaluation of the temporal window for drug delivery following ultrasound-mediated membrane permeability enhancement.

Author

Yudina, Anna, Lepetit-Coiffé, Matthieu, Moonen, Chrit T. W., and Lepetit-Coiffé, Matthieu

Subjects

*DRUG delivery systems, *MEDICAL ultrasonics, *CELL culture, *CELL membranes, *MICROBUBBLES, *CONTRAST media, *CELL metabolism, *ANIMAL experimentation, *CELL lines, *CELL physiology, *COMPARATIVE studies, *ENDOCYTOSIS, *LIGHT, *RESEARCH methodology, *MEDICAL cooperation, *ORGANIC compounds, *RATS, *RESEARCH, *TIME, *ULTRASONICS, *THREE-dimensional imaging, *EVALUATION research, *FLUORESCENT dyes

Abstract

Purpose: Ultrasound-induced cavitation facilitates cellular uptake of drugs via increased membrane permeability. Here, the purpose was to evaluate the duration of enhanced membrane permeability following ultrasound treatment in cell culture.Procedures: Optical chromophores with fluorescence intensity increasing 100-1,000-fold upon intercalation with nucleic acids served as smart agents for reporting cellular uptake. Opticell chambers with a monolayer of C6 cells were subjected to ultrasound in the presence of microbubbles followed by varying delays between 0 and 24 h before addition of Sytox Green optical contrast agent. Micro- and macroscopic fluorescence were used for qualitative and quantitative analysis.Results: Up to 25% of viable cells showed uptake of contrast agent with a half time of 8 h, with cellular uptake persisting even at 24 h. Only cells exposed to ultrasound showed the effect.Conclusion: The temporal window of increased membrane permeability is much longer in these studies than previously suggested. This may have important repercussions for in vivo studies in which membrane permeability may be temporally separated from drug delivery. [ABSTRACT FROM AUTHOR]

Published

2011

27. Droplet-To-Bubble Transition in Phase-Shift Nanoemulsions for Tumor Chemotherapy.

Author

RAPOPORT, NATALYA and KWON-HO NAM

Subjects

*CANCER chemotherapy, *NANOPARTICLES, *PHASE shifters, *DRUG carriers, *DRUG delivery systems, *PERFLUOROCARBONS, *ULTRASONIC imaging

Abstract

Multifunctional nanoemulsion/microbubble nanoparticles that combined properties of drug carriers, ultrasound imaging contrast agents, and enhancers of ultrasound-mediated drug delivery have been developed. At room temperature, the formulations comprised perfluorocarbon nanoemulsions stabilized by biodegradable block copolymers. Under the action of therapeutic ultrasound, nanodroplets converted into microbubbles in the process called acoustic droplet vaporization (ADV). Drug-loaded nanoemulsions released their drug payload under the action of therapeutic ultrasound. The paper reports the results of nanotherapy of ovarian and breast cancerous tumors by paclitaxel-loaded nanoemulsions in combination with tumor-directed 1-MHz therapeutic ultrasound. Tumor accumulation of nanoemulsions was confirmed by ultrasound imaging. Dramatic regression of ovarian and breast cancerous tumors was observed signifying efficient ultrasound-triggered drug release from tumor-accumulated nanodroplets. No therapeutic effect from the nanodroplet/ultrasound combination was observed without the drug, indicating that therapeutic effect was induced by the ultrasound-enhanced chemotherapeutic action of the tumor-targeted drug, rather than the mechanical or thermal action of ultrasound itself. The mechanism of the ultrasound-mediated nanochemotherapy is discussed. [ABSTRACT FROM AUTHOR]

Published

2011

28. Measuring the Compressibility of Cellulose Nanofiber-Stabilized Microdroplets Using Acoustophoresis.

Author

Loskutova K, Olofsson K, Hammarström B, Wiklund M, Svagan AJ, and Grishenkov D

Abstract

Droplets with a liquid perfluoropentane core and a cellulose nanofiber shell have the potential to be used as drug carriers in ultrasound-mediated drug delivery. However, it is necessary to understand their mechanical properties to develop ultrasound imaging sequences that enable in vivo imaging of the vaporization process to ensure optimized drug delivery. In this work, the compressibility of droplets stabilized with cellulose nanofibers was estimated using acoustophoresis at three different acoustic pressures. Polyamide particles of known size and material properties were used for calibration. The droplet compressibility was then used to estimate the cellulose nanofiber bulk modulus and compare it to experimentally determined values. The results showed that the acoustic contrast factor for these droplets was negative, as the droplets relocated to pressure antinodes during ultrasonic actuation. The droplet compressibility was 6.6-6.8 ×10-10 Pa-1, which is higher than for water (4.4×10-10 Pa-1) but lower than for pure perfluoropentane (2.7×10-9 Pa-1). The compressibility was constant across different droplet diameters, which was consistent with the idea that the shell thickness depends on the droplet size, rather than being constant.

Published

2021

29. Improving Release of Liposome-Encapsulated Drugs with Focused Ultrasound and Vaporizable Droplet-Liposome Nanoclusters.

Author

Honari, Arvin, Merillat, Darrah A., Bellary, Aditi, Ghaderi, Mohammadaref, Sirsi, Shashank R., Pouliopoulos, Antonios N., Morse, Sophie V., and Sheybani, Natasha D.

Subjects

*MICROBUBBLE diagnosis, *ULTRASONIC imaging, *TARGETED drug delivery, *CORE materials, *LIPOSOMES, *SMALL molecules

Abstract

Active targeted delivery of small molecule drugs is becoming increasingly important in personalized therapies, especially in cancer, brain disorders, and a wide variety of other diseases. However, effective means of spatial targeting and delivering high drug payloads in vivo are still lacking. Focused ultrasound combined with superheated phase-shift nanodroplets, which vaporize into microbubbles using heat and sound, are rapidly becoming a popular strategy for targeted drug delivery. Focused ultrasound can target deep tissue with excellent spatial precision and without using ionizing energy, thus can activate nanodroplets in circulation. One of the main limitations of this technology has been poor drug loading in the droplet core or the shell material. To address this need, we have developed a strategy to combine low-boiling point decafluorabutane and octafluoropropane (DFB and OFP) nanodroplets with drug-loaded liposomes, creating phase-changeable droplet-liposome clusters (PDLCs). We demonstrate a facile method of assembling submicron PDLCs with high drug-loading capacity on the droplet surface. Furthermore, we demonstrate that chemical tethering of liposomes in PDLCs enables a rapid release of their encapsulated cargo upon acoustic activation (>60% using OFP-based PDLCs). Rapid uncaging of small molecule drugs would make them immediately bioavailable in target tissue or promote better penetration in local tissue following intravascular release. PDLCs developed in this study can be used to deliver a wide variety of liposome-encapsulated therapeutics or imaging agents for multi-modal imaging applications. We also outline a strategy to deliver a surrogate encapsulated drug, fluorescein, to tumors in vivo using focused ultrasound energy and PDLCs. [ABSTRACT FROM AUTHOR]

Published

2021

30. A Disposable Microfluidic Device for Controlled Drug Release from Thermal-Sensitive Liposomes by High Intensity Focused Ultrasound

Author

Zhiting Deng, Long Meng, Junru Wu, Fei Li, Fei Yan, Hairong Zheng, Lili Niu, and Feiyan Cai

Subjects

Materials science, Sonication, medicine.medical_treatment, Microfluidics, microfluidics, Medicine (miscellaneous), Nanotechnology, Microscopy, Atomic Force, Cell membrane, Mice, ultrasound-mediated drug delivery, Drug Delivery Systems, mechanical and thermal effects, Cell Line, Tumor, Lab-On-A-Chip Devices, medicine, Animals, Ultrasonics, Irradiation, Disposable Equipment, Pharmacology, Toxicology and Pharmaceutics (miscellaneous), Liposome, business.industry, Cell Membrane, Ultrasound, Temperature, High-intensity focused ultrasound, Drug Liberation, medicine.anatomical_structure, high intensity focused ultrasound, Liposomes, Drug delivery, business, Research Paper, Biomedical engineering

Abstract

The drug release triggered thermally by high intensity focused ultrasound (HIFU) has been considered a promising drug delivery strategy due to its localized energy and non-invasive characters. However, the mechanism underlying the HIFU-mediated drug delivery remains unclear due to its complexity at the cellular level. In this paper, micro-HIFU (MHIFU) generated by a microfluidic device is introduced which is able to control the drug release from temperature-sensitive liposomes (TSL) and evaluate the thermal and mechanical effects of ultrasound on the cellular drug uptake and apoptosis. By simply adjusting the input electrical signal to the device, the temperature of sample can be maintained at 37 °C, 42 °C and 50 °C with the deviation of ± 0.3 °C as desired. The flow cytometry results show that the drug delivery under MHIFU sonication leads to a significant increase in apoptosis compared to the drug release by incubation alone at elevated temperature of 42 °C. Furthermore, increased squamous and protruding structures on the surface membrane of cells were detected by atomic force microscopy (AFM) after MHIFU irradiation of TSL. We demonstrate that compared to the routine HIFU treatment, MHIFU enables monitoring of in situ interactions between the ultrasound and cell in real time. Furthermore, it can quantitatively analyze and characterize the alterations of the cell membrane as a function of the treatment time.

Published

2015

31. Pulsed ultrasound enhances the delivery of nitric oxide from bubble liposomes to ex vivo porcine carotid tissue

Author

MC Verleye, Christy K. Holland, Gail J. Pyne-Geithman, Jonathan T. Sutton, and Jason L. Raymond

Subjects

Materials science, Swine, Ultrasonic Therapy, Biophysics, Pharmaceutical Science, Bioengineering, Vasodilation, Biomaterials, chemistry.chemical_compound, ultrasound-mediated drug delivery, Drug Delivery Systems, nitric oxide, International Journal of Nanomedicine, Drug Discovery, medicine, Animals, Original Research, Liposome, Microbubbles, business.industry, Organic Chemistry, Ultrasound, Octafluoropropane, General Medicine, Anatomy, 3. Good health, Carotid Arteries, medicine.anatomical_structure, chemistry, Liposomes, Drug delivery, Sodium nitroprusside, business, bubble liposomes, Ex vivo, Biomedical engineering, medicine.drug, Artery

Abstract

JT Sutton,1 JL Raymond,1 MC Verleye,2 GJ Pyne-Geithman,3 CK Holland4 1University of Cincinnati, Biomedical Engineering Program, Cincinnati,OH, 2University of Notre Dame Department of Chemical Engineering, Notre Dame, IN, 3University of Cincinnati, College of Medicine, Department of Neurosurgery and the University of Cincinnati Neuroscience Institute, and Mayfield Clinic, Cincinnati, OH, 4University of Cincinnati, College of Medicine, Internal Medicine, Division of Cardiovascular Diseases, Cincinnati, OH, USA Abstract: Ultrasound-mediated drug delivery is a novel technique for enhancing the penetration of drugs into diseased tissue beds noninvasively. By encapsulating drugs into microsized and nanosized liposomes, the therapeutic can be shielded from degradation within the vasculature until delivery to a target site by ultrasound exposure. Traditional in vitro or ex vivo techniques to quantify this delivery profile include optical approaches, cell culture, and electrophysiology. Here, we demonstrate an approach to characterize the degree of nitric oxide (NO) delivery to porcine carotid tissue by direct measurement of ex vivo vascular tone. An ex vivo perfusion model was adapted to assess ultrasound-mediated delivery of NO. This potent vasodilator was coencapsulated with inert octafluoropropane gas to produce acoustically active bubble liposomes. Porcine carotid arteries were excised post mortem and mounted in a physiologic buffer solution. Vascular tone was assessed in real time by coupling the artery to an isometric force transducer. NO-loaded bubble liposomes were infused into the lumen of the artery, which was exposed to 1MHz pulsed ultrasound at a peak-to-peak acoustic pressure amplitude of 0.34MPa. Acoustic cavitation emissions were monitored passively. Changes in vascular tone were measured and compared with control and sham NO bubble liposome exposures. Our results demonstrate that ultrasound-triggered NO release from bubble liposomes induces potent vasorelaxation within porcine carotid arteries (maximal relaxation 31%±8%), which was significantly stronger than vasorelaxation due to NO release from bubble liposomes in the absence of ultrasound (maximal relaxation 7%±3%), and comparable with relaxation due to 12µM sodium nitroprusside infusions (maximal relaxation 32%±3%). This approach is a valuable mechanistic tool for assessing the extent of drug release and delivery to the vasculature caused by ultrasound. Keywords: ultrasound-mediated drug delivery, bubble liposomes, nitric oxide

Published

2014

32. Focused ultrasound-mediated drug delivery to pancreatic cancer in a mouse model

Author

Christopher Dillon, Jill E. Shea, Courtney L. Scaife, R Gupta, Natalya Rapoport, and Allison Payne

Subjects

Drug, Pathology, medicine.medical_specialty, media_common.quotation_subject, Perfluorocarbon nanoemulsions, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Pancreatic cancer, medicine, Radiology, Nuclear Medicine and imaging, media_common, medicine.diagnostic_test, MRgFUS, business.industry, Research, Ultrasound, Magnetic resonance imaging, medicine.disease, Extravasation, 3. Good health, Paclitaxel, chemistry, 030220 oncology & carcinogenesis, Drug delivery, Ultrasound-mediated drug delivery, business, Drug carrier, Biomedical engineering

Abstract

Background Many aspects of the mechanisms involved in ultrasound-mediated therapy remain obscure. In particular, the relative roles of drug and ultrasound, the effect of the time of ultrasound application, and the effect of tissue heating are not yet clear. The current study was undertaken with the goal to clarify these aspects of the ultrasound-mediated drug delivery mechanism. Methods Focused ultrasound-mediated drug delivery was performed under magnetic resonance imaging guidance (MRgFUS) in a pancreatic ductal adenocarcinoma (PDA) model grown subcutaneously in nu/nu mice. Paclitaxel (PTX) was used as a chemotherapeutic agent because it manifests high potency in the treatment of gemcitabine-resistant PDA. Poly(ethylene oxide)-co-poly(d,l-lactide) block copolymer stabilized perfluoro-15-crown-5-ether nanoemulsions were used as drug carriers. MRgFUS was applied at sub-ablative pressure levels in both continuous wave and pulsed modes, and only a fraction of the tumor was treated. Results Positive treatment effects and even complete tumor resolution were achieved by treating the tumor with MRgFUS after injection of nanodroplet encapsulated drug. The MRgFUS treatment enhanced the action of the drug presumably through enhanced tumor perfusion and blood vessel and cell membrane permeability that increased the drug supply to tumor cells. The effect of the pulsed MRgFUS treatment with PTX-loaded nanodroplets was clearly smaller than that of continuous wave MRgFUS treatment, supposedly due to significantly lower temperature increase as measured with MR thermometry and decreased extravasation. The time of the MRgFUS application after drug injection also proved to be an important factor with the best results observed when ultrasound was applied at least 6 h after the injection of drug-loaded nanodroplets. Some collateral damage was observed with particular ultrasound protocols supposedly associated with enhanced inflammation. Conclusion This presented data suggest that there exists an optimal range of ultrasound application parameters and drug injection time. Decreased tumor growth, or complete resolution, was achieved with continuous wave ultrasound pressures below or equal to 3.1 MPa and drug injection times of at least 6 h prior to treatment. Increased acoustic pressure or ultrasound application before or shortly after drug injection gave increased tumor growth when compared to other protocols.

Published

2013

33. A Disposable Microfluidic Device for Controlled Drug Release from Thermal-Sensitive Liposomes by High Intensity Focused Ultrasound.

Author

Meng L, Deng Z, Niu L, Li F, Yan F, Wu J, Cai F, and Zheng H

Subjects

Animals, Cell Line, Tumor, Cell Membrane drug effects, Cell Membrane ultrastructure, Mice, Microscopy, Atomic Force, Temperature, Disposable Equipment, Drug Delivery Systems, Drug Liberation, Lab-On-A-Chip Devices, Liposomes administration & dosage, Liposomes radiation effects, Ultrasonics methods

Abstract

The drug release triggered thermally by high intensity focused ultrasound (HIFU) has been considered a promising drug delivery strategy due to its localized energy and non-invasive characters. However, the mechanism underlying the HIFU-mediated drug delivery remains unclear due to its complexity at the cellular level. In this paper, micro-HIFU (MHIFU) generated by a microfluidic device is introduced which is able to control the drug release from temperature-sensitive liposomes (TSL) and evaluate the thermal and mechanical effects of ultrasound on the cellular drug uptake and apoptosis. By simply adjusting the input electrical signal to the device, the temperature of sample can be maintained at 37 °C, 42 °C and 50 °C with the deviation of ± 0.3 °C as desired. The flow cytometry results show that the drug delivery under MHIFU sonication leads to a significant increase in apoptosis compared to the drug release by incubation alone at elevated temperature of 42 °C. Furthermore, increased squamous and protruding structures on the surface membrane of cells were detected by atomic force microscopy (AFM) after MHIFU irradiation of TSL. We demonstrate that compared to the routine HIFU treatment, MHIFU enables monitoring of in situ interactions between the ultrasound and cell in real time. Furthermore, it can quantitatively analyze and characterize the alterations of the cell membrane as a function of the treatment time.

Published

2015

34. Pulsed ultrasound enhances the delivery of nitric oxide from bubble liposomes to ex vivo porcine carotid tissue.

Author

Sutton JT, Raymond JL, Verleye MC, Pyne-Geithman GJ, and Holland CK

Subjects

Animals, Carotid Arteries drug effects, Nitric Oxide chemistry, Nitric Oxide pharmacology, Swine, Vasodilation drug effects, Drug Delivery Systems methods, Liposomes chemistry, Microbubbles, Nitric Oxide pharmacokinetics, Ultrasonic Therapy methods

Abstract

Ultrasound-mediated drug delivery is a novel technique for enhancing the penetration of drugs into diseased tissue beds noninvasively. By encapsulating drugs into microsized and nanosized liposomes, the therapeutic can be shielded from degradation within the vasculature until delivery to a target site by ultrasound exposure. Traditional in vitro or ex vivo techniques to quantify this delivery profile include optical approaches, cell culture, and electrophysiology. Here, we demonstrate an approach to characterize the degree of nitric oxide (NO) delivery to porcine carotid tissue by direct measurement of ex vivo vascular tone. An ex vivo perfusion model was adapted to assess ultrasound-mediated delivery of NO. This potent vasodilator was coencapsulated with inert octafluoropropane gas to produce acoustically active bubble liposomes. Porcine carotid arteries were excised post mortem and mounted in a physiologic buffer solution. Vascular tone was assessed in real time by coupling the artery to an isometric force transducer. NO-loaded bubble liposomes were infused into the lumen of the artery, which was exposed to 1 MHz pulsed ultrasound at a peak-to-peak acoustic pressure amplitude of 0.34 MPa. Acoustic cavitation emissions were monitored passively. Changes in vascular tone were measured and compared with control and sham NO bubble liposome exposures. Our results demonstrate that ultrasound-triggered NO release from bubble liposomes induces potent vasorelaxation within porcine carotid arteries (maximal relaxation 31%± 8%), which was significantly stronger than vasorelaxation due to NO release from bubble liposomes in the absence of ultrasound (maximal relaxation 7%± 3%), and comparable with relaxation due to 12 μM sodium nitroprusside infusions (maximal relaxation 32%± 3%). This approach is a valuable mechanistic tool for assessing the extent of drug release and delivery to the vasculature caused by ultrasound.

Published

2014

35. Focused ultrasound-mediated drug delivery to pancreatic cancer in a mouse model.

Author

Rapoport N, Payne A, Dillon C, Shea J, Scaife C, and Gupta R

Abstract

Background: Many aspects of the mechanisms involved in ultrasound-mediated therapy remain obscure. In particular, the relative roles of drug and ultrasound, the effect of the time of ultrasound application, and the effect of tissue heating are not yet clear. The current study was undertaken with the goal to clarify these aspects of the ultrasound-mediated drug delivery mechanism., Methods: Focused ultrasound-mediated drug delivery was performed under magnetic resonance imaging guidance (MRgFUS) in a pancreatic ductal adenocarcinoma (PDA) model grown subcutaneously in nu/nu mice. Paclitaxel (PTX) was used as a chemotherapeutic agent because it manifests high potency in the treatment of gemcitabine-resistant PDA. Poly(ethylene oxide)-co-poly(d,l-lactide) block copolymer stabilized perfluoro-15-crown-5-ether nanoemulsions were used as drug carriers. MRgFUS was applied at sub-ablative pressure levels in both continuous wave and pulsed modes, and only a fraction of the tumor was treated., Results: Positive treatment effects and even complete tumor resolution were achieved by treating the tumor with MRgFUS after injection of nanodroplet encapsulated drug. The MRgFUS treatment enhanced the action of the drug presumably through enhanced tumor perfusion and blood vessel and cell membrane permeability that increased the drug supply to tumor cells. The effect of the pulsed MRgFUS treatment with PTX-loaded nanodroplets was clearly smaller than that of continuous wave MRgFUS treatment, supposedly due to significantly lower temperature increase as measured with MR thermometry and decreased extravasation. The time of the MRgFUS application after drug injection also proved to be an important factor with the best results observed when ultrasound was applied at least 6 h after the injection of drug-loaded nanodroplets. Some collateral damage was observed with particular ultrasound protocols supposedly associated with enhanced inflammation., Conclusion: This presented data suggest that there exists an optimal range of ultrasound application parameters and drug injection time. Decreased tumor growth, or complete resolution, was achieved with continuous wave ultrasound pressures below or equal to 3.1 MPa and drug injection times of at least 6 h prior to treatment. Increased acoustic pressure or ultrasound application before or shortly after drug injection gave increased tumor growth when compared to other protocols.

Published

2013