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Abstract

Background and Purpose:

Holmium:yttrium-aluminum-garnet (Ho:YAG) laser lithotripsy is the standard lithotrite in ureteroscopy. We investigated the influence of pulse frequency, energy and length on the fragmentation efficiency of Ho:YAG laser lithotripsy in non-floating artificial stones in vitro.

Materials and Methods:

Stone fragmentation efficiency of three different Ho:YAG laser devices were evaluated in vitro at different pulse energy (1.0 and 2.0 J) and frequency settings (5 and 10 Hz), resulting in a standardized output power of 10W, respectively. Where possible, pulse length was modified (350 vs 700 μsec). Each setting was performed with a 273 μm and a 365 μm fiber. Lithotripsy was conducted using non-repulsive stones consisting of soft stone (plaster of Paris) and hard stone composition (Fujirock type 4).

Results:

Our results showed an increased stone disintegration efficiency at higher pulse energy (2.0 J/5 Hz vs 1.0 J/10 Hz) independently of two fiber diameters and stone types applied in this study (P < 0.05 in 18 of 20 groups). Similarly, reduction of the pulse length from 700 to 350 μsec resulted in a higher stone disintegration (P < 0.05 in 13 of 16 groups). This effect was most prominent when applied to soft stones. Higher fiber diameter was not constantly associated with an increase in stone disintegration.

Conclusion:

We demonstrate that an increase of pulse energy and a reduction of pulse length at a standardized output power of 10W can improve Ho:YAG laser fragmentation efficiency in vitro in nonfloating stones. These results may potentially affect clinical practice of Ho:YAG laser lithotripsy in impacted or large stones, when retropulsion is excluded.

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References

Eisner

, Kurtz

, Dretler

. Ureteroscopy for the management of stone disease. Nat Rev Urol, 2010; 7:40–45.

Beiko

, Denstedt

. Advances in ureterorenoscopy. Urol Clin North Am, 2007; 34:397–408.

Gupta

. Is the holmium:YAG laser the best intracorporeal lithotripter for the ureter? A 3-year retrospective study. J Endourol, 2007; 21:305–309.

Teichman

, Rao

, Rogenes

, Harris

. Ureteroscopic management of ureteral calculi: Electrohydraulic versus holmium:YAG lithotripsy. J Urol, 1997; 158:1357–1361.

Leveillee

, Lobik

. Intracorporeal lithotripsy: Which modality is best? Curr Opin Urol, 2003; 13:249–253.

Vassar

, Teichman

, Glickman

. Holmium:YAG lithotripsy efficiency varies with energy density. J Urol, 1998; 160:471–476.

Lee

, Box

, Abraham

et al. In vitro evaluation of nitinol urological retrieval coil and ureteral occlusion device: Retropulsion and holmium laser fragmentation efficiency. J Urol, 2008; 180:969–973.

Spore

, Teichman

, Corbin

et al. Holmium:YAG lithotripsy: Optimal power settings. J Endourol, 1999; 13:559–566.

Finley

, Petersen

, Abdelshehid

et al. Effect of holmium:YAG laser pulse width on lithotripsy retropulsion in vitro. J Endourol, 2005; 19:1041–1044.

10.

Teichman

, Vassar

, Glickman

. Holmium:yttrium-aluminum-garnet lithotripsy efficiency varies with stone composition. Urology, 1998; 52:392–397.

11.

Leone

, Garcia-Roig

, Bagley

. Changing trends in the use of ureteroscopic instruments from 1996 to 2008. J Endourol, 2010; 24:361–365.

12.

Geavlete

, Georgescu

, Nita

. et al. Complications of 2735 retrograde semirigid ureteroscopy procedures: A single-center experience. J Endourol, 2006; 20:179–185.

13.

Sofer

, Watterson

, Wollin

et al. Holmium:YAG laser lithotripsy for upper urinary tract calculi in 598 patients. J Urol, 2002; 167:31–34.

14.

Preminger

, Tiselius

, Assimos

et al. 2007 Guideline for the management of ureteral calculi. Eur Urol, 2007; 52:1610–1631.

15.

Grasso

, Chalik

. Principles and applications of laser lithotripsy: Experience with the holmium laser lithotrite. J Clin Laser Med Surg, 1998; 16:3–7.

16.

Teichman

, Vassar

, Bishoff

, Bellman

. Holmium:YAG lithotripsy yields smaller fragments than lithoclast, pulsed dye laser or electrohydraulic lithotripsy. J Urol, 1998; 159:17–23.

17.

Michel

, Knoll

, Ptaschnyk

et al. Flexible ureterorenoscopy for the treatment of lower pole calyx stones: Influence of different lithotripsy probes and stone extraction tools on scope deflection and irrigation flow. Eur Urol, 2002; 41:312–317.

18.

Nazif

, Teichman

, Glickman

, Welch

. Review of laser fibers: A practical guide for urologists. J Endourol, 2004; 18:818–829.

19.

Mues

, Teichman

, Knudsen

. Evaluation of 24 holmium:YAG laser optical fibers for flexible ureteroscopy. J Urol, 2009; 182:348–354.

20.

Chan

, Pfefer

, Teichman

, Welch

. A perspective on laser lithotripsy: the fragmentation processes. J Endourol, 2001; 15:257–273.

21.

Pierre

, Preminger

. Holmium laser for stone management. World J Urol, 2007; 25:235–239.

22.

Fuh

, Haleblian

, Norris

et al. The effect of frequency doubled double pulse Nd:YAG laser fiber proximity to the target stone on transient cavitation and acoustic emission. J Urol, 2007; 177:1542–1545.

23.

Zhong

, Tong

, Cocks

et al. Transient cavitation and acoustic emission produced by different laser lithotripters. J Endourol, 1998; 12:371–378.

24.

Vassar

, Chan

, Teichman

et al. Holmium:YAG lithotripsy: Photothermal mechanism. J Endourol, 1999; 13:181–190.

25.

Miroglu

, Horasanli

, Tanriverdi

et al. Operative failure during ureteroscopic pneumatic lithotripsy: Factors affecting successful outcome. Urol Int, 2006; 77:148–151.

26.

Marguet

, Sung

, Springhart

et al. In vitro comparison of stone retropulsion and fragmentation of the frequency doubled, double pulse nd:yag laser and the holmium:yag laser. J Urol, 2005; 173:1797–1800.

27.

Kang

, Lee

, Teichman

et al. Dependence of calculus retropulsion on pulse duration during Ho: YAG laser lithotripsy. Lasers Surg Med, 2006; 38:762–772.

28.

Lee

, Ryan

, Teichman

et al. Stone retropulsion during holmium:YAG lithotripsy. J Urol, 2003; 169:881–885.

29.

McAteer

, Williams JC

, Cleveland

et al. Ultracal-30 gypsum artificial stones for research on the mechanisms of stone breakage in shock wave lithotripsy. Urol Res, 2005; 33:429–434.

30.

Hersek

, Canay

, Akça

, Ciftçi

. Tensile strength of type IV dental stones dried in a microwave oven. J Prosthet Dent, 2002; 87:499–502.

Effect of Pulse Energy,Frequency and Length on Holmium:Yttrium-Aluminum-Garnet Laser Fragmentation Efficiency in Non-Floating Artificial Urinary Calculi

Abstract

Background and Purpose:

Materials and Methods:

Results:

Conclusion:

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References