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INTREPID® Phaco Tips and INTREPID® Transformer I/A Handpiece

 

INTREPID Hybrid Tip, INTREPID Balanced Tip, and INTREPID Transformer I/A handpiece each on an individual blue circle background

INTREPID® Phaco Tips
and INTREPID® Transformer I/A Handpiece

 

INTREPID Hybrid Tip, INTREPID Balanced Tip, and INTREPID Transformer I/A handpiece each on an individual blue circle background

 

Want To Expand Your Cataract Surgery Practice?

INTREPID® Hybrid Tip

 

INTREPID® Hybrid Tip takes safety and confidence to the next level in the OR.1-4

  • Two trusted technologies in one innovative design
  • Based on fluidics performance advantage of the INTREPID® BALANCED Tip1,2 
INTREPID Hybrid Tip on a blue circle background.

For Efficient Nuclear Removal

 

  • More lateral movement at tip, less shaft movement at incision site2
  • Minimal heat production9,10

For Safety and Confidence

 

  • Polymer edge reduces the risk of capsular tears, PCR and capsule related problems5-8
  • Rounded edge is designed to ease occlusion5

Centurion® Vision System with ACTIVE SENTRY® Handpiece

 

Explore how to bring safety and confidence to the next level

CENTURION Vision System with an ACTIVE SENTRY Handpiece in front of a light-blue background.

Designed to reduce PCR likelihood by almost 70%8

A bar graph, measured in percentage, displaying the mean torsional power required for posterior capsule rupture between Hybrid Torsional Power and Metal Torsional Power.    Hybrid Torsional power is represented by the light-blue coloured bar and measures around 45%, while Metal Torsional Power is represented by the dark blue bar and measures around 12%.
 
 
INTREPID Balanced Tip on a blue circle background.
INTREPID Balanced Tip on a blue circle background.

INTREPID® BALANCED Tip

 

The combination of INTREPID® BALANCED Tip and OZil® Torisonal allows superior nuclear removal compared to Kelman® tip, thanks to increased torsional amplitude at the distal end.2,9,11

Optimised OZil® Torsional with the INTREPID® BALANCED Tip redefines nuclear removal.

 

The INTREPID® BALANCED Tip provides better fluidics performance, resulting in2,9,11:

  • Reduced cumulative dissipated energy (CDE)
  • Lower phaco time
  • Lower total aspiration time
  • Lower fluid use
OZil Torsional with an INTREPID Balanced Tip.

See the Data

Bar graph comparing the Kelman tip to the INTREPID BALANCED Tip based on reduced cumulative dissipated energy (CDE).   The graph emphasizes that the INTREPID BALANCED tip reduces CDE by 36.5% when compared to the Kelman tip.  Bar graph comparing the Kelman tip to the INTREPID BALANCED Tip based on reduced phaco time.    The graph emphasizes that the INTREPID BALANCED tip reduces phaco time by 21.5% when compared to the Kelman tip. Bar graph comparing the Kelman tip to the INTREPID BALANCED Tip based on reduced aspiration time.   The graph emphasizes that the INTREPID BALANCED tip reduces aspiration time by 14.4% when compared to the Kelman tip. Bar graph comparing the Kelman Tip to the INTREPID BALANCED Tip based on reduced fluid use.    The graph emphasizes that the INTREPID BALANCED tip reduces fluid use by 31.4% when compared to the Kelman tip.

INTREPID® BALANCED Tip reduces tip movement at the incision11

 

The INTREPID® BALANCED Tip reduces tip movement at the incision, lowering thermal risk during surgery, which can result in less tissue damage at the incision site.9,11

Graph comparing the INTREPID BALANCED Tip to the Mini Tip based on tip movement at the incision.

 

INTREPID® BALANCED
Tip Overview

 

Comparison with Kelman® Tip

 

INTREPID® BALANCED Tip Redefines Cutting Efficiency
 
 
INTREPID Transformer I/A Handpiece on a blue circle background.
INTREPID Transformer I/A Handpiece on a blue circle background.

INTREPID® Transformer I/A Handpiece

 

Transform I/A Performance to Enhance Safety and Confidence6,7,12,13

 

The Transformer I/A Handpiece is specifically engineered for an easy transition from either coaxial or bimanual cortical removal without the need to change handpieces, allowing for adaptability in a variety of cases.12

  • Enables versatile I/A technique
  • Features capsular-friendly polymer tips for reducing risk of PCR and capsule related problems
Coaxial Performance

 

Coaxial Performance
  • Enhanced irrigation flow13 
  • Accessibility to cortical material in almost all directions
Bimanual Performance

 

Bimanual Performance
  • Greater access to the subincisional cortex
  • Extractable aspiration port features polymer-tip

CENTURION® Vision System with ACTIVE SENTRY® Handpiece

 

The leading technology in phacoemulsification, offering a new baseline of safety, consistency and efficiency in every cataract procedure.2,10,14-19

CENTURION Vision System with ACTIVE SENTRY Handpiece in front of a light-blue background.

CENTURION® Silver System

 

The most advanced gravity system, with enhanced stability and efficiency during phacoemulsification.6,7,16,17,20-23

CENTURION Silver System in front of a light-blue background.

LEGION® System

 

A CENTURION®-based portable phacoemulsification system bringing stability, efficiency and convenience to the clinic.6,7,16,17,20,21

LEGION System in front of a light-blue background.

Instructions for Use (IFU)

 

For a full list of indications, contraindications and warnings, please visit ifu.alcon.com and refer to the relevant product’s instructions for use. 

Alcon Experience Academy

 

For relevant training content from industry thought leaders

References:

1. CENTURION® FMS Pack Directions for Use. 
2. Khokhar S, Aron N, Sen S, Pillay G, Agarwal E. Effect of balanced phacoemulsification tip on the outcomes of torsional phacoemulsification using an active-fluidics system. J Cataract Refract Surg. 2017;43(1):22-28.
3. Solomon et al. Clinical study using a new phacoemulsification system with surgical intraocular pressure control. J Cataract Refract Surg. 2016; 42:542–549.
4. Zacharias J. Comparative motion profile characterization of the miniflared and balanced phacoemulsification tips. ESCRS Annual Congress; 2015; Barcelona.
5. Alcon Data on File, REF-07136, 2019. 
6. Narendran N, et al. The Cataract National Dataset electronic multicentre audit of 55 567 operations: Risk stratification for posterior capsule rupture and vitreous loss. Eye. 2009;23:31–37.
7. Salowi MA, et al. The Malaysian Cataract Surgery Registry: Risk indicators for posterior capsular rupture. Br J Ophthalmol. 2017;101:1466–1470. 
8. Shumway C. Utility of a novel hybrid phacoemulsification tip to prevent posterior capsule rupture. Presentation at ASCRS 2019; 3-7 May; San Diego.
9. Zacharias J. Thermal characterization of phacoemulsification probes operated in axial and torsional modes. J Cataract Refract Surg. 2015;41(1):208-216. 
10. Zacharias J. Laboratory assessment of thermal characteristics of three phacoemulsification tip designs operated using torsional ultrasound. Clin Ophthalmol. 2016:10;1095–1101. 
11. Noguchi S, et al. Difference in torsional phacoemulsification oscillation between a balanced tip and a mini tip using an ultra-high-speed video camera. J Cataract Refract Surg. 2016;42:1511–1517.
12. Intrepid® Transformer I/A Handpiece Directions for use.
13. Alcon Data on File, REF-04313, 2013.
14. CENTURION® Vision System Operator's Manual.
15. Alcon Data on File, REF-02559, 2017.
16. Thorne A, Dyk DW, Fanney D, Miller KM. Phacoemulsifier occlusion break surge volume reduction. J Cataract Refract Surg. 2018 Dec;44(12):1491-1496.
17. Aravena C, Dyk DW, Thorne A, Fanney D, Miller KM. Aqueous volume loss associated with occlusion break surge in phacoemulsifiers from 4 different manufacturers. J Cataract Refract Surg. 2018 Jul;44(7):884-888.
18. Malik PK, Dewan T, Patidar AK, Sain E. Effect of IOP based infusion system with and without balanced phacotip on cumulative dissipated energy and estimated fluid usage in comparison to gravity fed infusion in torsional phacoemulsification. Eye Vis (Lond). 2017;4:22.
19. Vasavada AR, et al. Comparison of torsional and microburst longitudinal phacoemulsification: A prospective, randomized, masked clinical trial. Ophthalmic Surg Lasers Imaging. 2010;41(1):109-114.
20. Nicoli CM, Dimalanta R, Miller KM. Experimental anterior chamber maintenance in active versus passive phacoemulsification fluidics systems. J Cataract Refract Surg. 2016;42(1):157:162.
21. Dyk DW, Miller KM. Mechanical model of human eye compliance for volumetric occlusion break surge measurements. J Cataract Refract Surg.2018 Feb;44(2):231-236.
22. Alcon Data on File, REF-08357, 2020.
23. Sharif-Kashani P, Fanney D, Injev V. Comparison of occlusion break responses and vacuum rise times of phacoemulsification systems. BMC Ophthalmol. 2014;14:96.