PURPOSE: To develop a novel and efficient, in vitro method for characterizing temporal and spatial heat generation of focused ultrasound exposures, and evaluate this method to compare a split focus and conventional single focus high intensity focused ultrasound transducer. MATERIALS AND METHODS: A HIFU tissue-mimicking phantom was validated by comparing respective temperature elevations generated in the phantoms and in murine tumors in vivo. The phantom was then used in combination with IR thermography to spatially and temporally characterize differences in low-level temperature elevation (e.g. 3-5 degrees C) produced by a single focus and split focus HIFU transducer, where the latter produces four simultaneous foci. In vivo experiments with heat sensitive liposomes containing doxorubicin were then carried out to determine if the larger beam width of the split focus transducer, compared to the single focus, could increase overall deployment of the drug from the liposome. RESULTS: Temperature elevations generated in the HIFU phantom were not found to be different from those measured in vivo when compensating for disparities in attenuation coefficient and specific heat, and between the two transducers by increasing the energy deposition. Exposures with the split focus transducer provided significant increases in the area treated compared to the single focus, which then translated to significant increases in drug deposition in vivo. CONCLUSIONS: Preliminary evidence was provided indicating the potential for using this novel technique for characterizing hyperthermia produced by focused ultrasound devices. Further development will be required for its suitability for correlating in vitro and in vivo outcomes.
PURPOSE: To develop a novel and efficient, in vitro method for characterizing temporal and spatial heat generation of focused ultrasound exposures, and evaluate this method to compare a split focus and conventional single focus high intensity focused ultrasound transducer. MATERIALS AND METHODS: A HIFU tissue-mimicking phantom was validated by comparing respective temperature elevations generated in the phantoms and in murinetumors in vivo. The phantom was then used in combination with IR thermography to spatially and temporally characterize differences in low-level temperature elevation (e.g. 3-5 degrees C) produced by a single focus and split focus HIFU transducer, where the latter produces four simultaneous foci. In vivo experiments with heat sensitive liposomes containing doxorubicin were then carried out to determine if the larger beam width of the split focus transducer, compared to the single focus, could increase overall deployment of the drug from the liposome. RESULTS: Temperature elevations generated in the HIFU phantom were not found to be different from those measured in vivo when compensating for disparities in attenuation coefficient and specific heat, and between the two transducers by increasing the energy deposition. Exposures with the split focus transducer provided significant increases in the area treated compared to the single focus, which then translated to significant increases in drug deposition in vivo. CONCLUSIONS: Preliminary evidence was provided indicating the potential for using this novel technique for characterizing hyperthermia produced by focused ultrasound devices. Further development will be required for its suitability for correlating in vitro and in vivo outcomes.
Authors: Eduardo G Moros; Petr Novak; William L Straube; Prashant Kolluri; Dmitriy A Yablonskiy; Robert J Myerson Journal: Phys Med Biol Date: 2004-03-21 Impact factor: 3.609
Authors: G Kong; G Anyarambhatla; W P Petros; R D Braun; O M Colvin; D Needham; M W Dewhirst Journal: Cancer Res Date: 2000-12-15 Impact factor: 12.701
Authors: Adrian F Prokop; Shahram Vaezy; Misty L Noble; Peter J Kaczkowski; Roy W Martin; Lawrence A Crum Journal: Ultrasound Med Biol Date: 2003-09 Impact factor: 2.998
Authors: Michael J Stone; Victor Frenkel; Sergio Dromi; Peter Thomas; Ryan P Lewis; King C P Li; McDonald Horne; Bradford J Wood Journal: Thromb Res Date: 2007-05-04 Impact factor: 3.944
Authors: Astrid Gasselhuber; Matthew R Dreher; Ari Partanen; Pavel S Yarmolenko; David Woods; Bradford J Wood; Dieter Haemmerich Journal: Int J Hyperthermia Date: 2012 Impact factor: 3.914
Authors: Shutao Wang; In Soo Shin; Hilary Hancock; Beom-su Jang; Hyung-sub Kim; Sang Myung Lee; Vesna Zderic; Victor Frenkel; Ira Pastan; Chang H Paik; Matthew R Dreher Journal: J Control Release Date: 2012-06-23 Impact factor: 9.776
Authors: Duo Chen; Rongmin Xia; Xin Chen; Gal Shafirstein; Peter M Corry; Robert J Griffin; Jose A Penagaricano; Ozlem E Tulunay-Ugur; Eduardo G Moros Journal: Med Phys Date: 2011-07 Impact factor: 4.071
Authors: Ari Partanen; Pavel S Yarmolenko; Antti Viitala; Sunil Appanaboyina; Dieter Haemmerich; Ashish Ranjan; Genevieve Jacobs; David Woods; Julia Enholm; Bradford J Wood; Matthew R Dreher Journal: Int J Hyperthermia Date: 2012 Impact factor: 3.914
Authors: Ali Mohammadabadi; Ruby N Huynh; Aniket S Wadajkar; Rena G Lapidus; Anthony J Kim; Christopher B Raub; Victor Frenkel Journal: Phys Med Biol Date: 2020-06-22 Impact factor: 3.609
Authors: Hilary A Hancock; Lauren H Smith; Julian Cuesta; Amir K Durrani; Mary Angstadt; Mark L Palmeri; Eitan Kimmel; Victor Frenkel Journal: Ultrasound Med Biol Date: 2009-07-17 Impact factor: 2.998