Introduction: Our research group is studying a noninvasive transcutaneous ultrasound device to expel small kidney stones or residual post-treatment stone fragments from the kidney.1-3 The purpose of this study was to evaluate the efficacy and safety of ultrasonic propulsion in a live porcine model. Materials and Methods: In domestic female swine (50-60 kg), human stones (calcium oxalate monohydrate) and metalized glass beads (2-8 mm) were ureteroscopically implanted.4 Target stones and beads were placed in the lower half of the kidney and a reference bead was placed in the upper pole. Ultrasonic propulsion was achieved through a single ultrasound system that allowed targeting, stone propulsion, and ultrasound imaging using a Philips HDI C5-2 commercial imaging transducer and a Verasonics diagnostic ultrasound platform. Stone propulsion was achieved through the delivery of 1-second bursts of focused, ultrasound pulses, which consist of 250 finely focused pulses 0.1 milliseconds in duration. Stone propulsion was then observed using fluoroscopy, ultrasound, and visually with the ureteroscope. The kidneys were then perfusion-fixed with glutaraldehyde, embedded in paraffin, sectioned, and stained. Samples were histologically scored for injury by a blinded independent expert. Using the same pulsing scheme, while varying acoustic intensities, an injury threshold and patterns of injury were determined in additional pigs.5,6 Results: Stones were successfully implanted in 14 kidneys. Overall, 17 of 26 (65)% stones/beads were moved the entire distance to the renal pelvis, ureteropelvic junction (UPJ), or proximal ureter. The average procedure time for successfully repositioned stones was 14.2±7.9 minutes with 23±16 push bursts. No gross or histologic damage was identified from the ultrasound propulsion procedure. Under this pulsing scheme, a maximum exposure of 2400 W/cm2 was delivered during each treatment. An intensity threshold of 16,620 W/cm2 was determined at which, above this level, tissue injury consistent with emulsification, necrosis, and hemorrhage appeared to be dose dependent. Conclusions: Ultrasonic propulsion is effective with most stones being relocated to the renal pelvis, UPJ, or proximal ureter in a timely fashion. The procedure appears safe with no evidence of injury. The acoustic intensities delivered at maximum treatment settings are well below the threshold at which injury is observed. The angle and alignment of directional force are the most critical factors determining the efficacy of stone propulsion. We are now pursuing FDA approval for a human feasibility study. No competing financial interests exist. Runtime of video: 5 mins 44 secs Acknowledgments: This work was supported by NIH DK43881, DK092197, NSBRI through NASA NCC 9-58, the Coulter Foundation, and the University of Washington. This material is the result of work supported by resources from the VA Puget Sound Health Care System, Seattle, Washington. We are very grateful for the help of a large team at the University of Washington and the Consortium for Shock Waves in Medicine, which we cannot list in detail. Copyright 2013, Mary Ann Liebert, Inc.
Introduction: Our research group is studying a noninvasive transcutaneous ultrasound device to expel small kidney stones or residual post-treatment stone fragments from the kidney.1-3 The purpose of this study was to evaluate the efficacy and safety of ultrasonic propulsion in a live porcine model. Materials and Methods: In domestic female swine (50-60 kg), human stones (calcium oxalate monohydrate) and metalized glass beads (2-8 mm) were ureteroscopically implanted.4 Target stones and beads were placed in the lower half of the kidney and a reference bead was placed in the upper pole. Ultrasonic propulsion was achieved through a single ultrasound system that allowed targeting, stone propulsion, and ultrasound imaging using a Philips HDI C5-2 commercial imaging transducer and a Verasonics diagnostic ultrasound platform. Stone propulsion was achieved through the delivery of 1-second bursts of focused, ultrasound pulses, which consist of 250 finely focused pulses 0.1 milliseconds in duration. Stone propulsion was then observed using fluoroscopy, ultrasound, and visually with the ureteroscope. The kidneys were then perfusion-fixed with glutaraldehyde, embedded in paraffin, sectioned, and stained. Samples were histologically scored for injury by a blinded independent expert. Using the same pulsing scheme, while varying acoustic intensities, an injury threshold and patterns of injury were determined in additional pigs.5,6 Results: Stones were successfully implanted in 14 kidneys. Overall, 17 of 26 (65)% stones/beads were moved the entire distance to the renal pelvis, ureteropelvic junction (UPJ), or proximal ureter. The average procedure time for successfully repositioned stones was 14.2±7.9 minutes with 23±16 push bursts. No gross or histologic damage was identified from the ultrasound propulsion procedure. Under this pulsing scheme, a maximum exposure of 2400 W/cm2 was delivered during each treatment. An intensity threshold of 16,620 W/cm2 was determined at which, above this level, tissue injury consistent with emulsification, necrosis, and hemorrhage appeared to be dose dependent. Conclusions: Ultrasonic propulsion is effective with most stones being relocated to the renal pelvis, UPJ, or proximal ureter in a timely fashion. The procedure appears safe with no evidence of injury. The acoustic intensities delivered at maximum treatment settings are well below the threshold at which injury is observed. The angle and alignment of directional force are the most critical factors determining the efficacy of stone propulsion. We are now pursuing FDA approval for a human feasibility study. No competing financial interests exist. Runtime of video: 5 mins 44 secs Acknowledgments: This work was supported by NIH DK43881, DK092197, NSBRI through NASA NCC 9-58, the Coulter Foundation, and the University of Washington. This material is the result of work supported by resources from the VA Puget Sound Health Care System, Seattle, Washington. We are very grateful for the help of a large team at the University of Washington and the Consortium for Shock Waves in Medicine, which we cannot list in detail. Copyright 2013, Mary Ann Liebert, Inc.
Authors: Yak-Nam Wang; Julianna C Simon; Bryan Cunitz; Frank Starr; Marla Paun; Denny Liggitt; Andrew Evan; James McAteer; James Williams; Ziyue Liu; Peter Kaczkowski; Ryan Hsi; Mathew Sorensen; Jonathan Harper; Michael R Bailey Journal: Proc Meet Acoust Date: 2013-06
Authors: Mathew D Sorensen; Michael R Bailey; Ryan S Hsi; Bryan W Cunitz; Julianna C Simon; Yak-Nam Wang; Barbrina L Dunmire; Marla Paun; Frank Starr; Wei Lu; Andrew P Evan; Jonathan D Harper Journal: J Endourol Date: 2013-09-14 Impact factor: 2.942
Authors: Anup Shah; Jonathan D Harper; Bryan W Cunitz; Yak-Nam Wang; Marla Paun; Julianna C Simon; Wei Lu; Peter J Kaczkowski; Michael R Bailey Journal: J Urol Date: 2011-12-16 Impact factor: 7.450
Authors: Jonathan D Harper; Mathew D Sorensen; Bryan W Cunitz; Yak-Nam Wang; Julianna C Simon; Frank Starr; Marla Paun; Barbrina Dunmire; H Denny Liggitt; Andrew P Evan; James A McAteer; Ryan S Hsi; Michael R Bailey Journal: J Urol Date: 2013-04-09 Impact factor: 7.450