OverviewThulioDual is a thulium fiber laser (TFL) system designed for urology (lithotripsy) and surgical applications, offering high stone fragmentation capability and precise soft tissue handling. It complements holmium lasers by providing a different technical approach for stone treatment and diversified surgical solutions.
Key advantages- Higher water absorption efficiency leading to precise energy delivery and shallow penetration depth
- Improved surgical safety through reduced thermal damage and more precise tissue interaction
- Strong performance in stone fragmentation and soft tissue handling
Why choose Thulium Laser for Lithotripsy and Urological SurgeryThulium lasers operate around 1900–1940 nm, a wavelength range close to the peak absorption of water. Because biological tissues and urine contain a high percentage of water, laser energy is efficiently absorbed and converted into heat, enabling precise energy delivery with shallow penetration depth. This results in more precise tissue interaction, reduced thermal damage, and improved surgical safety.
FiberSix different fiber core diameters are available to accommodate various clinical applications:
- 200 μm
- 272 μm
- 365 μm
- 550 μm
- 800 μm
- 1000 μm
Distributor advantages- Premium product positioning
- Strong differentiation from standard diode systems
- Higher margin potential
- Suitable for advanced and emerging markets
MultimediaProduct presentation includes a product video and visual graphics illustrating wavelength absorption and fiber options (multimedia available on the product page).
caractéristiques / spécifications techniques- Model name: ThulioDual
- Laser type: Thulium fiber laser (TFL)
- Nominal power (from product title): 600 W
- Operating wavelength range: ~1900–1940 nm (peak water absorption region)
- Clinical applications: Lithotripsy (stone fragmentation), urological surgery, soft tissue procedures, veterinary applications (variants)
- Available fiber core diameters: 200 μm, 272 μm, 365 μm, 550 μm, 800 μm, 1000 μm
- Primary benefits: precise energy delivery, shallow penetration depth, reduced thermal damage, improved surgical safety