Sage Journals: Discover world-class research

Abstract

Introduction:

Ureteral thermal injury has been reported in patients following ureteroscopy with laser lithotripsy due to overheating of fluid within the ureter. Proper understanding of this risk necessitates knowing the volume of fluid available to absorb laser energy. This can be approximated as the volume of fluid that mixes during laser activation, since energy transfer through fluid is dominated by convection. Objectives of this study were to determine the volume of fluid that mixes during laser activation at different irrigation rates and to characterize the temporal/spatial temperature distribution in a model ureter.

Methods:

The model ureter consisted of a plastic tube—160 mm length and 5.3 mm inner diameter. Irrigation was first applied with clear, then dyed, deionized water at rates from 8 to 40 mL/min. The laser was activated at 20 W (0.5 J/40 Hz). The distances the dyed fluid propagated were measured and volumes calculated. Temperatures were recorded from six thermocouples—five embedded within the tube and one affixed to the ureteroscope. Thermal dose was calculated using the Dewey and Sapareto methodology.

Results:

The volume of total fluid mixing in the model ureter was ≤1.26 ± 0.10 cm³, consistent with a sharp temperature increase after laser activation from −5 to 25 mm from the ureteroscope tip. With irrigation rates ≤12 mL/min, calculated thermal dose within the model ureter exceeded the threshold of tissue injury and extended greater distances along the ureter with lower irrigation rates.

Conclusion:

The volume of total fluid mixing within the model ureter was found to be small thus conferring a greater risk of ureteral thermal injury. A thermocouple positioned near the tip of the ureteroscope reasonably approximates temperature in front of the ureteroscope. Until temperature sensors are incorporated into ureteroscopic systems, laser power settings should be carefully selected to minimize risk of ureteral thermal injury.

Get full access to this article

View all access options for this article.

References

Oberlin

, Flum

, Bachrach

, et al. Contemporary surgical trends in the management of upper tract calculi. Urol J, 2015; 193(3):880–884; doi: 10.1016/j.juro.2014.09.006.

Feinstein

, Matlaga

. Urologic Diseases in America. US Department of Health and Human Services, Public Health Service, National Institutes of Health, National Institute of Diabetes and Digestive and Kidney Diseases. US Government Printing Office: Washington, DC; 2018; NIH Publication No. 12-7865:11–217.

Molina

, Silva

, Donalisio Da Silva

, et al. Influence of saline on temperature profile of laser lithotripsy activation. J Endourol, 2015; 29(2):235–239; doi: 10.1089/end.2014.0305.

Aldoukhi

, Ghani

, Hall

, et al. Thermal response to high-power holmium laser lithotripsy. J Endourol, 2017; 31(12):1308–1312; doi: 10.1089/end.2017.0679.

Wollin

, Carlos

, Tom

, et al. Effect of laser settings and irrigation rates on ureteral temperature during holmium laser lithotripsy, an in vitro model. J Endourol, 2018; 32(1):59–63; doi: 10.1089/end.2017.0658.

Sourial

, Ebel

, Francois

, et al. Holmium-YAG laser: Impact of pulse energy and frequency on local fluid temperature in an in-vitro obstructed kidney calyx model. J Biomed Opt, 2018; 23(10):1; doi: 10.1117/1.jbo.23.10.105002.

Hein

, Petzold

, Schoenthaler

, et al. Thermal effects of Ho:YAG laser lithotripsy: Real-time evaluation in an in vitro model. World J Urol, 2018; 36(9):1469–1475; doi: 10.1007/s00345-018-2303-x.

Winship

, Wollin

, Carlos

, et al. The rise and fall of high temperatures during ureteroscopic holmium laser lithotripsy. J Endourol, 2019; 33(10):794–799; doi: 10.1089/end.2019.0084.

Hein

, Petzold

, Suarez-Ibarrola

, et al. Thermal effects of Ho:YAG laser lithotripsy during retrograde intrarenal surgery and percutaneous nephrolithotomy in an ex vivo porcine kidney model. World J Urol, 2020; 38(3):753–760; doi: 10.1007/s00345-019-02808-5.

10.

William

, Goldsmith

, Moulton

, et al. A temperature model for laser lithotripsy. World J Urol, 2021; 39:1707–1716; doi: 10.1007/s00345-020-03357-y.

11.

Maxwell

, MacConaghy

, Harper

, et al. Simulation of laser lithotripsy-induced heating in the urinary tract. J Endourol, 2019; 33(2):113–119; doi: 10.1089/end.2018.0395.

12.

Aldoukhi

, Hall

, Ghani

, et al. Caliceal fluid temperature during high-power holmium laser lithotripsy in an in vivo porcine model. J Endourol, 2018; 32(8):724–729; doi: 10.1089/end.2018.0395.

13.

Class 2 Device Recall Olympus. U.S. Food & Drug Administration (FDA); 2021. Available from: https://www.accessdata.fda.gov/scripts/cdrh/cfdocs/cfRes/res.cfm?id=188172 [Last accessed: January 10, 2022].

14.

Dau

, Hall

, Khajeh

, et al. Vast majority of applied laser energy is converted to heat not stone ablation: In vitro assessment [MP20-11]. J Endourol, 2021; 35(S1):A223; doi: 10.1089/end.2021.35001.abstracts.

15.

Khajeh

, Hall

, Ghani

, et al. Pelvicalyceal volume and fluid temperature elevation during laser lithotripsy. J Endourol, 2022; 36(1):22–28; doi: 10.1089/end.2021.0383.

16.

King

, Katta

, Teichman

JMH

, et al. Mechanisms of pulse modulated holmium:YAG lithotripsy. J Endourol, 2021; 35(3):S29–S36; doi: 10.1089/end.2021.0742.

17.

Chan

, Pfefer

, Teichman

JMH

, et al. A perspective on laser lithotripsy: The fragmentation processes. J Endourol, 2001; 15(3):257–270; doi: 10.1089/089277901750161737.

18.

Sapareto

, Dewey

. Thermal dose determination in cancer therapy. Int J Radiat Oncol Biol Phys, 1984; 10(6):787–800; doi: 10.1016/0360-3016(84)90379-1.

19.

Zelenko

, Coll

, Rosenfeld

, et al. Normal ureter size on unenhanced helical CT. AJR, 2004; 182(4):1039–1041; doi: 10.2214/ajr.182.4.1821039.

20.

Pateman

, Mavrelos

, Hoo

, et al. Visualization of ureters on standard gynecological transvaginal scan: A feasibility study. Ultrasound Obstet Gynecol, 2013; 41(6):696–701; doi: 10.1002/uog.12468.

21.

Patel

, Babb

, Hindman

, et al. MDCT urography with high-volume low-concentration IV contrast material, peroral hydration, IV furosemide, and IV saline: Qualitative and quantitative assessment in 100 consecutive patients. AJR, 2012; 199(1):111–117; doi: 10.2214/AJR.11.7754.

22.

Yarmolenko

, Moon

, Landon

, et al. Thresholds for thermal damage to normal tissues: An update. Int J Hyperth, 2011; 27(4):320–343; doi: 10.3109/02656736.2010.534527.

23.

Aldoukhi

, Black

, Hall

, et al. Defining thermally safe laser lithotripsy power and irrigation parameters: In vitro model. J Endourol, 2020; 34(1):76–81. doi: 10.1089/end.2019.0499.

24.

Molina

, Carrera

, Chew

, et al. Temperature rise during ureteral laser lithotripsy: Comparison of super pulse thulium fiber laser (SPTF) vs high power 120 W holmium-YAG laser (Ho:YAG). World J Urol, 2021; 39(10):3951–3956; doi: 10.1007/s00345-021-03619-3.

25.

De Coninck

, Defraigne

, Traxer

. Watt determines the temperature during laser lithotripsy. World J Urol, 2021; 40(5):1257–1258; doi: 10.1007/s00345-021-03848-6.

26.

Louters

, Dau

, Hall

, et al. Laser operator duty cycle effect on temperature and thermal dose: In-vitro study. World J Urol, 2022; 40(6):1575–1580; doi: 10.1007/s00345-022-03967-8.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

9.60 MB

Characterization of Fluid Dynamics and Temperature Profiles During Ureteroscopy with Laser Activation in a Model Ureter

Abstract

Introduction:

Methods:

Results:

Conclusion:

Get full access to this article

References

Supplementary Material