News — quanta laser
From Abe to MoXy™ and Beyond Part 5: More Fibers of the 1990s
2000nm 2100nm 532nm BPH duet fiber Duotome GreenLight Holmium Fiber Holmium Laser holmium laser fiber KTP Laser Laser laser fiber Laser Lithotripsy LDD85 LDDduet LDDquartet LDDtrio MaxLight MaxLight 90 MoXy Prostate Surgery QuadraLase quanta laser Quartet fiber SideLite Thulium thulium laser thulium laser fiber Trimedyne trio fiber
John Brekke’s fiber design from 1994 is one of the few lateral fiber designs of the era that remains on the market today, marketed as Scatterfree™ by Laser Peripherals. As can be seen in figures 10 and 11 (below the next paragraph) taken from the first patent, the concept is simple and it does basically work. In contrast to Pon, however, Brekke failed to properly identify the true sources of the unwanted emissions from unfused fibers. Quoting the patent, in reference to figures 5 and 6 immediately below, “The reflected light 27 and light 29 are unwanted and potentially unsafe...
Introducing the ProView™ 30X SMA Inspection Microscope
2000nm 2100nm AccuFlex Accumax AccuTrac ACMI laser fiber BPH calculase dornier Duotome EndoBeam Fiber fiber inspection Flexiva Holmium Fiber Holmium Laser holmium laser fiber karl storz laser fiber Laser Lithotripsy Lasersafe litho laser Lumenis medilase medilase H20 OmniPulse optical fiber Optifiber ProFlex ProFlex LLF ProGlide ProGuard quanta laser reprocessing laser fiber richard wolf scope safe Scopesafe SideLite Slimline SMA inspection stonelight SureFlex Thulium thulium laser thulium laser fiber TracTip Trimedyne yellowstone
InnovaQuartz is pleased to offer a low cost but high performance solution for inspecting SMA (and Trimedyne in January 2017) terminated laser surgical fibers. This battery powered (batteries included) microscope is equipped with a thread-free SMA (or Trimedyne) port that positions the fiber input face within the field of view with acute angle illumination from below. Every detail of the connector face is exposed: scratches, dirt and burns are detected and may be corrected before risking the laser optics. Simply slip the connector ferrule into the aluminum adapter and flip on the light.
How to Cleave Surgical Fibers
AccuFlex Accumax AccuTrac ACMI laser fiber calculase chips Clean cut cutting fiber dornier EndoBeam Fiber Flexiva glass fragments high power fiber optics Holmium Fiber Holmium Laser holmium laser fiber karl storz laser fiber Laser Lithotripsy Lasersafe litho laser Lumenis medilase medilase H20 OmniPulse Optifiber ProFlex LLF ProGlide ProGuard quanta laser reprocessing laser fiber scope safe Scopesafe Slimline stonelight SureFlex TracTip Trimedyne yellowstone
How to Cleave Laser Surgical Fibers Purpose: Provide simple instructions for reprocessing flat tip bare fibers for laser surgery. Summary: Clean cut and flat optical faces are necessary for surgical efficacy in laser surgery. Badly cut fibers deliver energy to target tissue less efficiently and degrade more quickly than properly cut fibers. Step-by-step instructions…. Rationale: A.A. Griffith developed the first theoretical model for fractures during WWI, inaugurating the Science of Fracture Mechanics. As luck would have it, Griffith studied glass fibers. Telecommunications fibers are made of fused silica -- just like laser surgical fibers -- and more telecom fibers are...
The Power of Collimation IV: Going the Extra Mile
2100nm AccuFlex Accumax AccuTrac ACMI laser fiber calculase dornier Duotome EndoBeam Fiber Flexiva high power fiber optics Holmium Fiber Holmium Laser holmium laser fiber karl storz Laser laser fiber Laser Lithotripsy Lasersafe litho laser Lumenis medilase medilase H20 microlenses OmniPulse optical fiber Optifiber ProFlex ProFlex LLF ProGlide ProGuard quanta laser richard wolf scope safe Scopesafe Slimline stonelight SureFlex Thulium thulium laser thulium laser fiber TracTip Trimedyne yellowstone
This final Chapter in the blog series, "The Power of Collimation", explores the apparent paradox that ProFlex is able to reject potentially damaging, high angle laser energy within the focus while continuing to deliver more laser energy to the stone than any other holmium laser fiber.
The Power of Collimation III: Moses’ Enthalpy
2100nm AccuFlex Accumax AccuTrac ACMI laser fiber calculase dornier EndoBeam Fiber Flexiva fused silica high power fiber optics Holmium Fiber Holmium Laser holmium laser fiber karl storz Laser laser fiber Laser Lithotripsy Lasersafe litho laser Lumenis medilase medilase H20 microlenses optical fiber Optifiber ProFlex ProFlex LLF ProGlide ProGuard quanta laser richard wolf scope safe Scopesafe SideLite Slimline stonelight SureFlex tapered fibers TracTip Trimedyne yellowstone
At InnovaQuartz, we developed a method of making very precise, tiny lenses directly upon the face of an optical fiber. In this third Chapter of The Power of Collimation, I’ll describe just how important this subtle feature really is to the performance of holmium laser URS. In the first Chapter of this blog series, I discussed why holmium lasers launch light into fibers at a substantial fraction of their maximum propagation angle (near maximum NA). We’ll be using computer-generated ray traces to depict what happens with a typical laser focus condition (aka laser launch condition) when coupling to a series of...