In vitro investigation of stone ablation efficiency, char formation, spark generation, and damage mechanism produced by thulium fiber laser.
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2023-11
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To investigate stone ablation characteristics of thulium fiber laser (TFL), BegoStone phantoms were spot-treated in water at various fiber tip-to-stone standoff distances (SDs, 0.5 ~ 2 mm) over a broad range of pulse energy (Ep, 0.2 ~ 2 J), frequency (F, 5 ~ 150 Hz), and power (P, 10 ~ 30 W) settings. In general, the ablation speed (mm3/s) in BegoStone decreased with SD and increased with Ep, reaching a peak around 0.8 ~ 1.0 J. Additional experiments with calcium phosphate (CaP), uric acid (UA), and calcium oxalate monohydrate (COM) stones were conducted under two distinctly different settings: 0.2 J/100 Hz and 0.8 J/12 Hz. The concomitant bubble dynamics, spark generation and pressure transients were analyzed. Higher ablation speeds were consistently produced at 0.8 J/12 Hz than at 0.2 J/100 Hz, with CaP stones most difficult yet COM and UA stones easier to ablate. Charring was mostly observed in CaP stones at 0.2 J/100 Hz, accompanied by strong spark-generation, explosive combustion, and diminished pressure transients, but not at 0.8 J/12 Hz. By treating stones in parallel fiber orientation and leveraging the proximity effect of a ureteroscope, the contribution of bubble collapse to stone ablation was found to be substantial (16% ~ 59%) at 0.8 J/12 Hz, but not at 0.2 J/100 Hz. Overall, TFL ablation efficiency is significantly better at high Ep/low F setting, attributable to increased cavitation damage with less char formation.
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Chen, Junqin, Arpit Mishra, Robert Medairos, Jodi Antonelli, Glenn M Preminger, Michael E Lipkin and Pei Zhong (2023). In vitro investigation of stone ablation efficiency, char formation, spark generation, and damage mechanism produced by thulium fiber laser. Urolithiasis, 51(1). p. 124. 10.1007/s00240-023-01501-y Retrieved from https://hdl.handle.net/10161/31501.
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Scholars@Duke
Junqin Chen
Arpit Mishra
Dr. Arpit Mishra is a Postdoctoral Associate in the Department of Mechanical Engineering and Materials Science at Duke University, USA. His research focuses on laser lithotripsy for urolithiasis treatment, combining both experimental and simulation approaches to investigate laser interactions with fluids, bubbles, and solid surfaces. He earned his PhD and M.S. in Mechanical Engineering from the Indian Institute of Technology, Kharagpur, where his dissertation centred on the dynamics of interacting cavitation bubbles. His international research experience includes fellowships as an ETH4D Visiting Researcher at ETH Zurich and a Raman Charpak Fellow at CEA/UGA Grenoble. Dr. Mishra's expertise extends to cryogenic engineering, hydrodynamic cavitation, and laser thermal safety. He has been recognized with several prestigious awards, including the Milton Van Dyke Award from the APS Division of Fluid Dynamics, the T.H.K. Frederking Space Cryogenic Workshop Student Scholarship, and the ETH4D Visiting Student Grant. His work has been featured in the 1st Traveling Gallery of Fluid Motion by the Cultural Programs of the National Academy of Sciences (CPNAS).
Robert Medairos
Jodi Antonelli
Glenn Michael Preminger
- Minimally invasive management of urologic diseases
2. Minimally invasive management of renal and ureteral stones
3. Medical management of nephrolithiasis
4. Bioeffects of shock wave lithotripsy
5. Basic physics of shock wave lithotripsy
6. Intracorporeal lithotripsy for stone fragmentation
7. Minimally invasive management of urinary tract obstruction, including ureteropelvic junction obstruction and ureteral strictures
8. Enhanced imaging modalities for minimally invasive surgery
9. Digital video imaging during endoscopic surgery
10. 3-D imaging modalities for minimally invasive surgery
11. Holmium laser applications in urology
Michael Eric Lipkin
Pei Zhong
My research focuses on engineering and technology development with applications in the non-invasive or minimally invasive treatment of kidney stone disease via shock wave and laser lithotripsy, high-intensity focused ultrasound (HIFU) and immunotherapy for cancer treatment, acoustic and optical cavitation, and ultrasound neuromodulation via sonogenetics.
We are taking an integrated and translational approach that combines fundamental research with engineering and applied technology development to devise novel and enabling ultrasonic, optical, and mechanical tools for a variety of clinical applications. We are interested in shock wave/laser-fluid-bubble-solid interaction, and resultant mechanical and thermal fields that lead to material damage and removal. We also investigate the stress response of biological cell and tissue induced by cavitation and ultrasound exposure, mediated through mechanosensitive ion channels, such as Piezo 1. Our research activities are primarily supported by NIH and through collaborations with the medical device industry.
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