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16 results on '"Langeveld, Simone A.G."'

4. Microstructures in Theranostic Microbubbles

Author

Langeveld, Simone A.G., de Jong, Nico, van der Steen, Ton, Kooiman, Klazina, and Cardiology

Abstract

Microbubbles can be used in combination with ultrasound for local drug delivery, thereby achieving high therapeutic efficacy with limited systemic adverse effects. To produce microbubbles that are stable, effective, and respond uniformly to ultrasound, this thesis aimed to develop a new formulation of microbubbles focusing on the microstructures in the coating. Microstructures, acoustic behavior, and effect were studied using an ultra-high-speed camera coupled to a confocal microscope.

Published
2022

5. Dispersing and Sonoporating Biofilm-Associated Bacteria with Sonobactericide

Author

Lattwein, K.R. (author), Beekers, Inés (author), Kouijzer, Joop J.P. (author), Leon-Grooters, Mariël (author), Langeveld, Simone A.G. (author), van Rooij, Tom (author), van der Steen, A.F.W. (author), de Jong, N. (author), van Wamel, Willem J.B. (author), Kooiman, Klazina (author), Lattwein, K.R. (author), Beekers, Inés (author), Kouijzer, Joop J.P. (author), Leon-Grooters, Mariël (author), Langeveld, Simone A.G. (author), van Rooij, Tom (author), van der Steen, A.F.W. (author), de Jong, N. (author), van Wamel, Willem J.B. (author), and Kooiman, Klazina (author)

Abstract

Bacteria encased in a biofilm poses significant challenges to successful treatment, since both the immune system and antibiotics are ineffective. Sonobactericide, which uses ultrasound and microbubbles, is a potential new strategy for increasing antimicrobial effectiveness or directly killing bacteria. Several studies suggest that sonobactericide can lead to bacterial dispersion or sonoporation (i.e., cell membrane permeabilization); however, real-time observations distinguishing individual bacteria during and directly after insonification are missing. Therefore, in this study, we investigated, in real-time and at high-resolution, the effects of ultrasound-induced microbubble oscillation on Staphylococcus aureus biofilms, without or with an antibiotic (oxacillin, 1 µg/mL). Biofilms were exposed to ultrasound (2 MHz, 100–400 kPa, 100–1000 cycles, every second for 30 s) during time-lapse confocal microscopy recordings of 10 min. Bacterial responses were quantified using post hoc image analysis with particle counting. Bacterial dispersion was observed as the dominant effect over sonoporation, resulting from oscillating microbubbles. Increasing pressure and cycles both led to significantly more dispersion, with the highest pressure leading to the most biofilm removal (up to 83.7%). Antibiotic presence led to more variable treatment responses, yet did not significantly impact the therapeutic efficacy of sonobactericide, suggesting synergism is not an immediate effect. These findings elucidate the direct effects induced by sonobactericide to best utilize its potential as a biofilm treatment strategy., ImPhys/Medical Imaging

Published
2022
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6. Dispersing and Sonoporating Biofilm-Associated Bacteria with Sonobactericide

Author

Lattwein, Kirby R., Beekers, Inés, Kouijzer, Joop J.P., Leon-Grooters, Mariël, Langeveld, Simone A.G., van Rooij, Tom, van der Steen, Antonius F.W., de Jong, Nico, van Wamel, Willem J.B., Kooiman, Klazina, Lattwein, Kirby R., Beekers, Inés, Kouijzer, Joop J.P., Leon-Grooters, Mariël, Langeveld, Simone A.G., van Rooij, Tom, van der Steen, Antonius F.W., de Jong, Nico, van Wamel, Willem J.B., and Kooiman, Klazina

Abstract

Bacteria encased in a biofilm poses significant challenges to successful treatment, since both the immune system and antibiotics are ineffective. Sonobactericide, which uses ultrasound and microbubbles, is a potential new strategy for increasing antimicrobial effectiveness or directly killing bacteria. Several studies suggest that sonobactericide can lead to bacterial dispersion or sonoporation (i.e., cell membrane permeabilization); however, real-time observations distinguishing individual bacteria during and directly after insonification are missing. Therefore, in this study, we investigated, in real-time and at high-resolution, the effects of ultrasound-induced microbubble oscillation on Staphylococcus aureus biofilms, without or with an antibiotic (oxacillin, 1 µg/mL). Biofilms were exposed to ultrasound (2 MHz, 100–400 kPa, 100–1000 cycles, every second for 30 s) during time-lapse confocal microscopy recordings of 10 min. Bacterial responses were quantified using post hoc image analysis with particle counting. Bacterial dispersion was observed as the dominant effect over sonoporation, resulting from oscillating microbubbles. Increasing pressure and cycles both led to significantly more dispersion, with the highest pressure leading to the most biofilm removal (up to 83.7%). Antibiotic presence led to more variable treatment responses, yet did not significantly impact the therapeutic efficacy of sonobactericide, suggesting synergism is not an immediate effect. These findings elucidate the direct effects induced by sonobactericide to best utilize its potential as a biofilm treatment strategy.

Published
2022

7. Vancomycin-decorated microbubbles as a theranostic agent for Staphylococcus aureus biofilms

Author

Kouijzer, Joop J.P., primary, Lattwein, Kirby R., additional, Beekers, Inés, additional, Langeveld, Simone A.G., additional, Leon-Grooters, Mariël, additional, Strub, Jean-Marc, additional, Oliva, Estefania, additional, Mislin, Gaëtan L.A., additional, de Jong, Nico, additional, van der Steen, Antonius F.W., additional, Klibanov, Alexander L., additional, van Wamel, Willem J.B., additional, and Kooiman, Klazina, additional

Published
2021
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9. Vancomycin-decorated microbubbles as a theranostic agent for Staphylococcus aureus biofilms

Author

Kouijzer, Joop J.P. (author), Lattwein, Kirby R. (author), Beekers, Inés (author), Langeveld, Simone A.G. (author), Leon-Grooters, Mariël (author), Strub, Jean Marc (author), Oliva, Estefania (author), de Jong, N. (author), van der Steen, A.F.W. (author), Kouijzer, Joop J.P. (author), Lattwein, Kirby R. (author), Beekers, Inés (author), Langeveld, Simone A.G. (author), Leon-Grooters, Mariël (author), Strub, Jean Marc (author), Oliva, Estefania (author), de Jong, N. (author), and van der Steen, A.F.W. (author)

Abstract

Bacterial biofilms are a huge burden on our healthcare systems worldwide. The lack of specificity in diagnostic and treatment possibilities result in difficult-to-treat and persistent infections. The aim of this in vitro study was to investigate if microbubbles targeted specifically to bacteria in biofilms could be used both for diagnosis as well for sonobactericide treatment and demonstrate their theranostic potential for biofilm infection management. The antibiotic vancomycin was chemically coupled to the lipid shell of microbubbles and validated using mass spectrometry and high-axial resolution 4Pi confocal microscopy. Theranostic proof-of-principle was investigated by demonstrating the specific binding of vancomycin-decorated microbubbles (vMB) to statically and flow grown Staphylococcus aureus (S. aureus) biofilms under increasing shear stress flow conditions (0–12 dyn/cm2), as well as confirmation of microbubble oscillation and biofilm disruption upon ultrasound exposure (2 MHz, 250 kPa, and 5,000 or 10,000 cycles) during flow shear stress of 5 dyn/cm2 using time-lapse confocal microscopy combined with the Brandaris 128 ultra-high-speed camera. Vancomycin was successfully incorporated into the microbubble lipid shell. vMB bound significantly more often than control microbubbles to biofilms, also in the presence of free vancomycin (up to 1000 µg/mL) and remained bound under increasing shear stress flow conditions (up to 12 dyn/cm2). Upon ultrasound insonification biofilm area was reduced of up to 28%, as confirmed by confocal microscopy. Our results confirm the successful production of vMB and support their potential as a new theranostic tool for S. aureus biofilm infections by allowing for specific bacterial detection and biofilm disruption., ImPhys/Medical Imaging

Published
2021
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10. The impact of lipid handling and phase distribution on the acoustic behavior of microbubbles

Author

Langeveld, Simone A.G. (author), Beekers, Inés (author), Collado Lara, G. (author), van der Steen, A.F.W. (author), de Jong, N. (author), Kooiman, Klazina (author), Langeveld, Simone A.G. (author), Beekers, Inés (author), Collado Lara, G. (author), van der Steen, A.F.W. (author), de Jong, N. (author), and Kooiman, Klazina (author)

Abstract

Phospholipid-coated microbubbles are ultrasound contrast agents that can be employed for ultrasound molecular imaging and drug delivery. For safe and effective implementation, microbubbles must respond uniformly and predictably to ultrasound. Therefore, we investigated how lipid handling and phase distribution affected the variability in the acoustic behavior of microbubbles. Cholesterol was used to modify the lateral molecular packing of 1,2-distearoyl-sn-glycero-3phosphocholine (DSPC)-based microbubbles. To assess the effect of lipid handling, microbubbles were produced by a direct method, i.e., lipids directly dispersed in an aqueous medium or indirect method, i.e., lipids first dissolved in an organic solvent. The lipid phase and ligand distribution in the microbubble coating were investigated using confocal microscopy, and the acoustic response was recorded with the Brandaris 128 ultra-high-speed camera. In microbubbles with 12 mol% cholesterol, the lipids were miscible and all in the same phase, which resulted in more buckle formation, lower shell elasticity and higher shell viscosity. Indirect DSPC microbubbles had a more uniform response to ultrasound than direct DSPC and indirect DSPC-cholesterol microbubbles. The difference in lipid handling between direct and indirect DSPC microbubbles significantly affected the acoustic behavior. Indirect DSPC microbubbles are the most promising candidate for ultrasound molecular imaging and drug delivery applications., ImPhys/Medical Imaging

Published
2021
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11. Vancomycin-decorated microbubbles as a theranostic agent for Staphylococcus aureus biofilms

Author

Kouijzer, Joop J.P., Lattwein, Kirby R., Beekers, Inés, Langeveld, Simone A.G., Leon-Grooters, Mariël, Strub, Jean Marc, Oliva, Estefania, Mislin, Gaëtan L.A., de Jong, Nico, van der Steen, Antonius F.W., Klibanov, Alexander L., van Wamel, Willem J.B., Kooiman, Klazina, Kouijzer, Joop J.P., Lattwein, Kirby R., Beekers, Inés, Langeveld, Simone A.G., Leon-Grooters, Mariël, Strub, Jean Marc, Oliva, Estefania, Mislin, Gaëtan L.A., de Jong, Nico, van der Steen, Antonius F.W., Klibanov, Alexander L., van Wamel, Willem J.B., and Kooiman, Klazina

Abstract

Bacterial biofilms are a huge burden on our healthcare systems worldwide. The lack of specificity in diagnostic and treatment possibilities result in difficult-to-treat and persistent infections. The aim of this in vitro study was to investigate if microbubbles targeted specifically to bacteria in biofilms could be used both for diagnosis as well for sonobactericide treatment and demonstrate their theranostic potential for biofilm infection management. The antibiotic vancomycin was chemically coupled to the lipid shell of microbubbles and validated using mass spectrometry and high-axial resolution 4Pi confocal microscopy. Theranostic proof-of-principle was investigated by demonstrating the specific binding of vancomycin-decorated microbubbles (vMB) to statically and flow grown Staphylococcus aureus (S. aureus) biofilms under increasing shear stress flow conditions (0–12 dyn/cm2), as well as confirmation of microbubble oscillation and biofilm disruption upon ultrasound exposure (2 MHz, 250 kPa, and 5,000 or 10,000 cycles) during flow shear stress of 5 dyn/cm2 using time-lapse confocal microscopy combined with the Brandaris 128 ultra-high-speed camera. Vancomycin was successfully incorporated into the microbubble lipid shell. vMB bound significantly more often than control microbubbles to biofilms, also in the presence of free vancomycin (up to 1000 µg/mL) and remained bound under increasing shear stress flow conditions (up to 12 dyn/cm2). Upon ultrasound insonification biofilm area was reduced of up to 28%, as confirmed by confocal microscopy. Our results confirm the successful production of vMB and support their potential as a new theranostic tool for S. aureus biofilm infections by allowing for specific bacterial detection and biofilm disruption.

Published
2021

13. Ultrasound-Responsive Cavitation Nuclei for Therapy and Drug Delivery

Author

Kooiman, Klazina (author), Roovers, Silke (author), Langeveld, Simone A.G. (author), Kleven, Robert T. (author), Dewitte, Heleen (author), O'Reilly, Meaghan A. (author), Escoffre, Jean Michel (author), Bouakaz, Ayache (author), Verweij, M.D. (author), Kooiman, Klazina (author), Roovers, Silke (author), Langeveld, Simone A.G. (author), Kleven, Robert T. (author), Dewitte, Heleen (author), O'Reilly, Meaghan A. (author), Escoffre, Jean Michel (author), Bouakaz, Ayache (author), and Verweij, M.D. (author)

Abstract

Therapeutic ultrasound strategies that harness the mechanical activity of cavitation nuclei for beneficial tissue bio-effects are actively under development. The mechanical oscillations of circulating microbubbles, the most widely investigated cavitation nuclei, which may also encapsulate or shield a therapeutic agent in the bloodstream, trigger and promote localized uptake. Oscillating microbubbles can create stresses either on nearby tissue or in surrounding fluid to enhance drug penetration and efficacy in the brain, spinal cord, vasculature, immune system, biofilm or tumors. This review summarizes recent investigations that have elucidated interactions of ultrasound and cavitation nuclei with cells, the treatment of tumors, immunotherapy, the blood–brain and blood–spinal cord barriers, sonothrombolysis, cardiovascular drug delivery and sonobactericide. In particular, an overview of salient ultrasound features, drug delivery vehicles, therapeutic transport routes and pre-clinical and clinical studies is provided. Successful implementation of ultrasound and cavitation nuclei-mediated drug delivery has the potential to change the way drugs are administered systemically, resulting in more effective therapeutics and less-invasive treatments., ImPhys/Medical Imaging

Published
2020
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16. Combined Confocal Microscope and Brandaris 128 Ultra-High-Speed Camera

Author

Beekers, D.I. (author), Lattwein, Kirby R. (author), Kouijzer, Joop J.P. (author), Langeveld, Simone A.G. (author), Vegter, M. (author), Beurskens, Robert (author), Mastik, F. (author), Verduyn Lunel, Rogier (author), van der Steen, A.F.W. (author), de Jong, N. (author), Beekers, D.I. (author), Lattwein, Kirby R. (author), Kouijzer, Joop J.P. (author), Langeveld, Simone A.G. (author), Vegter, M. (author), Beurskens, Robert (author), Mastik, F. (author), Verduyn Lunel, Rogier (author), van der Steen, A.F.W. (author), and de Jong, N. (author)

Abstract

Controlling microbubble-mediated drug delivery requires the underlying biological and physical mechanisms to be unraveled. To image both microbubble oscillation upon ultrasound insonification and the resulting cellular response, we developed an optical imaging system that can achieve the necessary nanosecond temporal and nanometer spatial resolutions. We coupled the Brandaris 128 ultra-high-speed camera (up to 25 million frames per second) to a custom-built Nikon A1R+ confocal microscope. The unique capabilities of this combined system are demonstrated with three experiments showing microbubble oscillation leading to either endothelial drug delivery, bacterial biofilm disruption, or structural changes in the microbubble coating. In conclusion, using this state-of-the-art optical imaging system, microbubble-mediated drug delivery can be studied with high temporal resolution to resolve microbubble oscillation and high spatial resolution and detector sensitivity to discern cellular response. Combining these two imaging technologies will substantially advance our knowledge on microbubble behavior and its role in drug delivery., ImPhys/Acoustical Wavefield Imaging

Published
2019
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