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In vitro fragmentation efficiency of holmium: yttrium‐aluminum‐garnet ( YAG ) laser lithotripsy – a comprehensive study encompassing different frequencies, pulse energies, total power levels and laser fibre diameters
Author(s) -
Kronenberg Peter,
Traxer Olivier
Publication year - 2014
Publication title -
bju international
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.773
H-Index - 148
eISSN - 1464-410X
pISSN - 1464-4096
DOI - 10.1111/bju.12567
Subject(s) - lithotripsy , laser , laser lithotripsy , holmium , materials science , pulse duration , fragmentation (computing) , optics , surgery , physics , medicine , computer science , operating system
Objective To assess the fragmentation (ablation) efficiency of laser lithotripsy along a wide range of pulse energies, frequencies, power settings and different laser fibres, in particular to compare high‐ with low‐frequency lithotripsy using a dynamic and innovative testing procedure free from any human interaction bias. Materials and Methods An automated laser fragmentation testing system was developed. The unmoving laser fibres fired at the surface of an artificial stone while the stone was moved past at a constant velocity, thus creating a fissure. The lithotripter settings were 0.2–1.2 J pulse energies, 5–40 Hz frequencies, 4–20 W power levels, and 200 and 550 μm core laser fibres. Fissure width, depth, and volume were analysed and comparisons between laser settings, fibres and ablation rates were made. Results Low frequency‐high pulse energy ( LoFr ‐ HiPE ) settings were (up to six times) more ablative than high frequency‐low pulse energy ( HiFr ‐ LoPE ) at the same power levels ( P < 0.001), as they produced deeper ( P < 0.01) and wider ( P < 0.001) fissures. There were linear correlations between pulse energy and fragmentation volume, fissure width, and fissure depth (all P < 0.001). Total power did not correlate with fragmentation measurements. Laser fibre diameter did not affect fragmentation volume ( P = 0.81), except at very low pulse energies (0.2 J), where the large fibre was less efficient ( P = 0.015). Conclusions At the same total power level, LoFr ‐ HiPE lithotripsy was most efficient. Pulse energy was the key variable that drove fragmentation efficiency. Attention must be paid to prevent the formation of time‐consuming bulky debris and adapt the lithotripter settings to one's needs. As fibre diameter did not affect fragmentation efficiency, small fibres are preferable due to better scope irrigation and manoeuvrability.

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