Guidewire core: Difference between revisions
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==Overview== | ==Overview== | ||
The core of a coronary guidewire determines many of the performance characteristics of the device. The core of a coronary guidewire is usually ground to a taper towards the end and this is where the tip attaches to the core. If guidewire core starts tapering more towards the tip, the coronary guidewire as a whole becomes more rigid, steerable and torquable. The opposite happens when the core other coronary guidewire tapers more proximally allowing for a longer tip and a more flexible tip. The core may be either continuous or joined. If the core is joined then it is more likely to bend or prolapse when the guidewire is advanced. Coronary guidewire cores that are made of stainless steel are stiffer, provide greater support, and provide greater torque control. In contrast, coronary guidewire cores that are made of nitinol are much more flexible. | The core of a coronary guidewire determines many of the performance characteristics of the device. The core of a coronary guidewire is usually ground to a taper towards the end and this is where the tip attaches to the core. If guidewire core starts tapering more towards the tip, the coronary guidewire as a whole becomes more rigid, steerable and torquable. The opposite happens when the core other coronary guidewire tapers more proximally allowing for a longer tip and a more flexible tip. The core may be either continuous or joined. If the core is joined then it is more likely to bend or prolapse when the guidewire is advanced. Coronary guidewire cores that are made of stainless steel are stiffer, provide greater support, and provide greater torque control. In contrast, coronary guidewire cores that are made of nitinol are much more flexible. |
Latest revision as of 21:18, 28 January 2013
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Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]
To go back to the main page on Guidewires, click here.
Overview
The core of a coronary guidewire determines many of the performance characteristics of the device. The core of a coronary guidewire is usually ground to a taper towards the end and this is where the tip attaches to the core. If guidewire core starts tapering more towards the tip, the coronary guidewire as a whole becomes more rigid, steerable and torquable. The opposite happens when the core other coronary guidewire tapers more proximally allowing for a longer tip and a more flexible tip. The core may be either continuous or joined. If the core is joined then it is more likely to bend or prolapse when the guidewire is advanced. Coronary guidewire cores that are made of stainless steel are stiffer, provide greater support, and provide greater torque control. In contrast, coronary guidewire cores that are made of nitinol are much more flexible.
Guidewire Core Composition
The guidewire core can be composed of either nitinol, stainless steel or a similar metal.
Nitinol Guidewire Cores
Shown below is the structure of a guidewire with a nitinol core:
Advantages Of A Nitinol Core
- Super-elastic alloy designed for kink resistance
- Excellent flexibility and steering
- Probably more durable in nature
- Better trackability
- Reduced prolapse
Disadvantages Of A Nitinol Core
- A nitinol guidewire may be less torquable
- A nitinol guidewire core may store torque without necessarily transmitting the torque to the tip
- Wires with single nitinol cores sometimes "wind up" and store the torque
Clinical Scenarios In Which A Nitinol Core May Be Useful
- As a result of their flexibility and durability, coronary guidewires with a nitinol core are more likely to enter a retroflexed circumflex coronary artery.
Stainless Steel Guidewire Cores
Stainless steel was the original core material used in coronary guidewires. Shown below is the structure of a stainless steel guidewire core (Courtesy of Abbott Vascular)
Advantages Of A Stainless Steel Core
- The stainless steel core provides greater pushability, support, torquability, and good shapeability in “core-to-tip” wires.
Disadvantages Of A Stainless Steel Core
- Tendency to kink
- Less flexible than newer core materials
High Tensile Strength Stainless Steel
Shown below is the structure of a high tensile strength stainless steel guidewire core:
Advantages of the High Tensile Strength Stainless Steel Core
- More durable than regular stainless steel
- Retains shape more
- Improved flexibility
- Improved steering and tracking
Asahi Tru Torque Steel
Shown below is the structure of a Asahi Tru Torque Steel guidewire core: