PURPOSE: The ability of remotely tagging tissues in a controlled and three-dimensional manner during preoperative imaging could greatly help surgeons to identify targets for resection. The authors' objective is to selectively and noninvasively deposit markers under image guidance for such internal tattooing. METHODS: This study describes the production of new ultrasound-inducible droplets carrying large payloads of fluorescent markers and the in vivo proof of concept of their remote and controlled deposition via focused ultrasound. The droplets are monodispersed multiple emulsions produced in a microfluidic system, consisting of aqueous fluorescein in perfluorocarbon in water. Their conversion (either by vaporization or cavitation) is performed remotely using a clinical ultrasonic imaging probe. RESULTS: When submitted to 5 MHz imaging pulses, the droplets vaporize in vitro at 1.4 MPa peak-negative pressure and eject their content. After several seconds, a brightly fluorescent spot (0.5 mm diameter) is observed at the focus of the transducer. Experiments in the chorioallantoique membrane of chicken eggs and chicken embryo demonstrate that the spot is stable and is easily seen by naked eye. CONCLUSIONS: These ultrasound-inducible multiple emulsions could be used to deliver large amounts of contrast agents, chemotherapy, and genetic materials in vivo using a conventional ultrasound scanner.
PURPOSE: The ability of remotely tagging tissues in a controlled and three-dimensional manner during preoperative imaging could greatly help surgeons to identify targets for resection. The authors' objective is to selectively and noninvasively deposit markers under image guidance for such internal tattooing. METHODS: This study describes the production of new ultrasound-inducible droplets carrying large payloads of fluorescent markers and the in vivo proof of concept of their remote and controlled deposition via focused ultrasound. The droplets are monodispersed multiple emulsions produced in a microfluidic system, consisting of aqueous fluorescein in perfluorocarbon in water. Their conversion (either by vaporization or cavitation) is performed remotely using a clinical ultrasonic imaging probe. RESULTS: When submitted to 5 MHz imaging pulses, the droplets vaporize in vitro at 1.4 MPa peak-negative pressure and eject their content. After several seconds, a brightly fluorescent spot (0.5 mm diameter) is observed at the focus of the transducer. Experiments in the chorioallantoique membrane of chicken eggs and chicken embryo demonstrate that the spot is stable and is easily seen by naked eye. CONCLUSIONS: These ultrasound-inducible multiple emulsions could be used to deliver large amounts of contrast agents, chemotherapy, and genetic materials in vivo using a conventional ultrasound scanner.
Authors: Xiaofang Lu; Hai Jin; Carole Quesada; Easton C Farrell; Leidan Huang; Mitra Aliabouzar; Oliver D Kripfgans; J Brian Fowlkes; Renny T Franceschi; Andrew J Putnam; Mario L Fabiilli Journal: Acta Biomater Date: 2020-06-14 Impact factor: 8.947
Authors: Elizabeth Hipp; Xiaobing Fan; Ari Partanen; James Vosicky; Charles A Pelizzari; Christopher M Straus; Sham Sokka; Gregory S Karczmar Journal: Phys Med Date: 2014-05-17 Impact factor: 2.685
Authors: Oleksandr Shpak; Martin Verweij; Hendrik J Vos; Nico de Jong; Detlef Lohse; Michel Versluis Journal: Proc Natl Acad Sci U S A Date: 2014-01-21 Impact factor: 11.205
Authors: Alexander Moncion; Keith J Arlotta; Eric G O'Neill; Melissa Lin; Lily A Mohr; Renny T Franceschi; Oliver D Kripfgans; Andrew J Putnam; Mario L Fabiilli Journal: Acta Biomater Date: 2016-09-27 Impact factor: 8.947
Authors: Mario L Fabiilli; Christopher G Wilson; Frédéric Padilla; Francisco M Martín-Saavedra; J Brian Fowlkes; Renny T Franceschi Journal: Acta Biomater Date: 2013-03-25 Impact factor: 8.947
Authors: Mario L Fabiilli; Morand R Piert; Robert A Koeppe; Phillip S Sherman; Carole A Quesada; Oliver D Kripfgans Journal: Contrast Media Mol Imaging Date: 2013 Jul-Aug Impact factor: 3.161