Original: $35.25
-65%$35.25
$12.34The Story
Synthes 401.511.96 2.4mm TI Cortex Screw Self-Tapping 11mm
Synthes
• Model: 401.511.96
• Diameter: 2.4mm
• Length: 11mm
This medical supply or implant item is securely packaged within its original manufacturer's packaging, which remains undamaged. The inner and outer packaging is intact, ensuring the product's integrity and suitability for medical use.
Precision Engineering for Optimal Performance
The Synthes 401.511.96 2.4mm TI Cortex Screw is engineered with precision that ensures reliability in orthopedic procedures. This self-tapping screw simplifies insertion, reducing the time surgical teams spend on implantation. Furthermore, its 11mm length makes it suitable for a variety of anatomical scenarios, allowing surgeons to adapt based on the needs of the specific case. This efficiency contributes significantly to positive patient outcomes, making it an excellent choice in medical settings.
High-Quality Materials for Enhanced Durability
Manufactured from high-quality titanium, the Synthes 401.511.96 cortex screw is not only lightweight but also exceptionally durable. This material choice minimizes the risk of rejection post-surgery and ensures a stable fixation. Because it is self-tapping, the screw creates its own threading in the bone, which minimizes trauma and promotes quicker healing. Surgeons and medical professionals appreciate this feature, as it streamlines the operation while enhancing patient comfort.
Versatile Applications in Orthopedic Surgery
The versatility of the Synthes 401.511.96 screw allows it to be employed in various orthopedic applications, such as fracture fixation and joint stabilization. This adaptability highlights its importance in the surgical toolkit, providing surgeons with a reliable option for various challenges they may face. Moreover, being self-tapping facilitates the secure placement of the screw in dense bone, which can lead to better overall surgical outcomes due to reduced operation time and increased implant stability.
Details & Craftsmanship
Every detail has been carefully considered to bring you the perfect product.
Details & Craftsmanship
Every detail has been carefully considered to bring you the perfect product.
Description
Synthes 401.511.96 2.4mm TI Cortex Screw Self-Tapping 11mm
Synthes
• Model: 401.511.96
• Diameter: 2.4mm
• Length: 11mm
This medical supply or implant item is securely packaged within its original manufacturer's packaging, which remains undamaged. The inner and outer packaging is intact, ensuring the product's integrity and suitability for medical use.
Precision Engineering for Optimal Performance
The Synthes 401.511.96 2.4mm TI Cortex Screw is engineered with precision that ensures reliability in orthopedic procedures. This self-tapping screw simplifies insertion, reducing the time surgical teams spend on implantation. Furthermore, its 11mm length makes it suitable for a variety of anatomical scenarios, allowing surgeons to adapt based on the needs of the specific case. This efficiency contributes significantly to positive patient outcomes, making it an excellent choice in medical settings.
High-Quality Materials for Enhanced Durability
Manufactured from high-quality titanium, the Synthes 401.511.96 cortex screw is not only lightweight but also exceptionally durable. This material choice minimizes the risk of rejection post-surgery and ensures a stable fixation. Because it is self-tapping, the screw creates its own threading in the bone, which minimizes trauma and promotes quicker healing. Surgeons and medical professionals appreciate this feature, as it streamlines the operation while enhancing patient comfort.
Versatile Applications in Orthopedic Surgery
The versatility of the Synthes 401.511.96 screw allows it to be employed in various orthopedic applications, such as fracture fixation and joint stabilization. This adaptability highlights its importance in the surgical toolkit, providing surgeons with a reliable option for various challenges they may face. Moreover, being self-tapping facilitates the secure placement of the screw in dense bone, which can lead to better overall surgical outcomes due to reduced operation time and increased implant stability.
