BACKGROUND: Gas-filled microbubbles have been used as ultrasound contrast agents for some decades. More recently, such microbubbles have evolved as experimental tools for organ- and tissue-specific drug and gene delivery. When sonified with ultrasound near their resonance frequency, microbubbles oscillate. With higher ultrasound energies, oscillation amplitudes increase, leading to microbubble destruction. This phenomenon can be used to deliver a substance into a target organ, if microbubbles are co-administered loaded with drugs or gene therapy vectors before i.v. injection. OBJECTIVE: This review focuses on different experimental applications of microbubbles as tools for drug and gene delivery. Different organ systems and different classes of bioactive substances that have been used in previous studies will be discussed. METHODS: All the available literature was reviewed to highlight the potential of this non-invasive, organ-specific delivery system. CONCLUSION: Ultrasound targeted microbubble destruction has been used in various organ systems and in tumours to successfully deliver drugs, proteins, gene therapy vectors and gene silencing constructs. Many proof of principle studies have demonstrated its potential as a non-invasive delivery tool. However, too few large animal studies and studies with therapeutic aims have been performed to see a clinical application of this technique in the near future. Nevertheless, there is great hope that preclinical large animal studies will confirm the successful results already obtained in small animals.
BACKGROUND: Gas-filled microbubbles have been used as ultrasound contrast agents for some decades. More recently, such microbubbles have evolved as experimental tools for organ- and tissue-specific drug and gene delivery. When sonified with ultrasound near their resonance frequency, microbubbles oscillate. With higher ultrasound energies, oscillation amplitudes increase, leading to microbubble destruction. This phenomenon can be used to deliver a substance into a target organ, if microbubbles are co-administered loaded with drugs or gene therapy vectors before i.v. injection. OBJECTIVE: This review focuses on different experimental applications of microbubbles as tools for drug and gene delivery. Different organ systems and different classes of bioactive substances that have been used in previous studies will be discussed. METHODS: All the available literature was reviewed to highlight the potential of this non-invasive, organ-specific delivery system. CONCLUSION: Ultrasound targeted microbubble destruction has been used in various organ systems and in tumours to successfully deliver drugs, proteins, gene therapy vectors and gene silencing constructs. Many proof of principle studies have demonstrated its potential as a non-invasive delivery tool. However, too few large animal studies and studies with therapeutic aims have been performed to see a clinical application of this technique in the near future. Nevertheless, there is great hope that preclinical large animal studies will confirm the successful results already obtained in small animals.
Authors: Matti Adam; Nigel Geoffrey Kooreman; Ann Jagger; Markus U Wagenhäuser; Dennis Mehrkens; Yongming Wang; Yosuke Kayama; Kensuke Toyama; Uwe Raaz; Isabel N Schellinger; Lars Maegdefessel; Joshua M Spin; Jaap F Hamming; Paul H A Quax; Stephan Baldus; Joseph C Wu; Philip S Tsao Journal: Arterioscler Thromb Vasc Biol Date: 2018-08 Impact factor: 8.311
Authors: Francois Vignon; William T Shi; Jeffry E Powers; E Carr Everbach; Jinjin Liu; Shunji Gao; Feng Xie; Thomas R Porter Journal: IEEE Trans Ultrason Ferroelectr Freq Control Date: 2013-04 Impact factor: 2.725