Personalised knee surgery

Changing the face of orthopaedics with JOURNEY II Total Knee Arthroplasty and CORI Surgical System.
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Personalise TKA surgery like never before

Plan knee arthroplasty for patients' unique anatomy and restore the joint line and normal kinematic patterns.

The future landscape will be built on the ability to personalise surgery to each patient. With the powerful combination of the CORI Surgical System and JOURNEY II TKA, you can start now.

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Normal shapes. Normal position. Normal motion

Reproduction of optimal kinematic patterns during TKA could be instrumental in improving patient satisfaction.1 The solution to providing patients with better overall satisfaction and functionality is to design an implant as close to the normal knee as possible.

The JOURNEY II System has been shown to restore anatomical shape, position and motion.2-6 This anatomical restoration can provide superior clinical outcomes that can lead to high patient satisfaction.*7-11

JOURNEY II TKA Matisse

Launch announcement: JOURNEY II CR has arrived in Australia

We are excited to announce the launch of JOURNEY II CR in Australia! To learn more, contact your Smith+Nephew representative, or contact us here.

Read the JOURNEY II CR evidence summary
JOURNEY II CR Website Overview

New AOA NJRR data demonstrates high long-term survivorship, lower risk of revision


Read the evidence summary

JOURNEY II TKA features

Smarter,* more efficient** handheld robotics

Our latest technology features image-free smart mapping to build 3D models of the joint in surgery (without the need for CT/MRI scans), real-time planning for personalised surgery, handheld precision milling and intra-operative gap balancing.

Designed with a small OR footprint, the CORI Surgical System uses Real Intelligence software to offer broad capabilities and an expanding range of joint reconstruction indications, such as:

  • Total and partial knee surgery: Designed to achieve accuracy in bone resection, alignment and soft tissue balance.
  • Revision knee surgery: The first system indicated for robotic-assisted revision knee surgery. Image-free smart mapping eliminates potential for image distortion caused by in-situ components, with 3D joint models registering anatomy and bony defects after implant extraction.
Hero 2 CORI Surgical System ANZ

CORI System Features

Resources

Medical education - Smith+Nephew Academy

Central to Smith+Nephew’s commitment to medical education and improving patient outcomes is providing a comprehensive accessible learning environment tailored to the needs of the healthcare professional.

Continue your professional development with the latest clinical data, expert discussions, online courses and more.

S+N Academy Online is the global medical education platform, used by healthcare professionals and caregivers to access the latest peer-to-peer scientific, education-based best practice; intended to deliver thought leadership and content across orthopaedic reconstruction, sports medicine, ENT (ear, nose and throat), trauma and extremities, and wound management.

Explore our Academy Online
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Want to learn more?

To learn more about joint line restoration and personalised surgery with JOURNEY II TKS and CORI Surgical System, simply fill out the form below. Our team is here to provide you with the support and information you need.

Citations
  1. Van Onsem S, et al. Clin Orthop Relat Res (2020) 478:255-263.
  2. Grieco T, et al. J Arthroplasty. 2018;33(2):565-571.
  3. Smith LA, et al. J Arthroplasty. 2021;36:1445-1454.
  4. Iriuchishima T, et al. J Knee Surg. 2018;31(6):568-572.
  5. Murakami K, et al. J Orthop. 2018;15(2):650-654.
  6. Carpenter RD, et al. Knee. 2009;16(5):332-336.
  7. Mayman DJ, et al. Poster presented at: ISPOR Symposium;19-23 May, 2018; Baltimore, Maryland, USA.
  8. Nodzo SR, et al. Techniques in Orthopaedics. 2018;33(1):37-41.
  9. Murakami K, et al. Int Orthop. 2018;42(11):2573-2581.
  10. Takubo A, et al. J Knee Surg. 2017;30(7):725-729.
  11. Noble PC, et al. Clin Orthop Relat Res. 2005(431):157-165.
  12. Australian Orthopaedic Association National Joint Replacement Registry (AOANJRR), Automated Industry Report System (AIRS), ID No.16955* for Smith & Nephew Australia, JOURNEY II OXINIUM Total Knee (Procedures from 1 September 1999 – 7 January 2025), Accessed 31 January 2025, report generated January 8, 2025, AOA, Adelaide: 1–16.
  13. Kaneko T, et al. J Orthop. 2017;14(1):201-206.
  14. Brilhault J, et al. Knee. 2010;17(2):148-151.
  15. Catani F, et al. J Orthop Res. 2009;27(12):1569-1575.
  16. Hyodo K, et al. Arthroplasty Today. 2020;6(3):338-342.
  17. Hada M, et al. Knee Surg Sports Traumatol Arthrosc. 2018;26(6):1709-1716.
  18. Smith+Nephew 2012. Internal report. JRN2 KneeSim Analysis Memo.
  19. Smith+Nephew 2020. Internal report. ER0488 Rev. B.

*Compared to conventional techniques.
**Compared to the NAVIO◊ Surgical System and previous software versions. 29% faster resection demonstrated in total knee cadaver studies.

 

Social Media Campaign references

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  1. Grieco TF, Sharma A, Dessinger GM, Cates HE, Komistek RD. In Vivo Kinematic Comparison of a Bicruciate Stabilized Total Knee Arthroplasty and
    the Normal Knee Using Fluoroscopy. J Arthroplasty. 2018;33(2):565-571.
  2. Iriuchishima T, Ryu K. A Comparision of Rollback Ratio between Bicruciate Substituting Total Knee Arthroplasty and Oxford Unicompartmental
    Knee Arthroplasty. J Knee Surg. 2018;31(6):568572.
  3. Murakami K, Hamai S, Okazaki K, et al. Knee kinematics in bi-cruciate stabilized total knee arthroplasty during squatting and stair-climbing
    activities. J Orthop. 2018;15(2):650-654.
  4. Murakami K, Hamai S, Okazaki K, et al. In vivo kinematics of gait in posterior-stabilized and bicruciate-stabilized total knee arthroplasties using
    image-matching techniques. Int Orthop. 2018;42(11):2573-2581.
  5. Carpenter RD, Brilhault J, Majumdar S, Ries MD. Magnetic resonance imaging of in vivo patellofemoral kinematics after total knee arthroplasty.
    Knee. 2009;16(5):332-336.
  6. Catani F, Ensini A, Belvedere C, et al. In vivo kinematics and kinetics of a bi-cruciate substituting total knee arthroplasty: a combined
    fluoroscopic and gait analysis study. J Orthop Res. 2009;27(12):1569-1575.
  7. Murakami K, Hamai S, Okazaki K, et al. In vivo kinematics of gait in posterior-stabilized and bicruciate-stabilized total knee arthroplasties using
    image-matching techniques. Int Orthop. 2018;42(11):2573-2581.
  8. Kaneko T, Kono N, Mochizuki Y, Hada M, Toyoda S, Musha Y. Bi-cruciate substituting total knee arthroplasty improved medio-lateral instability in
    mid-flexion range. J Orthop. 2017;14(1):201 206.
  9. Brilhault J, Ries MD. Measuring patellar height using the lateral active flexion radiograph: Effect of total knee implant design. Knee.
    2010;17(2):148-151.
  10. Smith+Nephew 2012. JRN2 KneeSim Analysis Memo. Data on File.
  11. Smith+Nephew CORI◊ Digital Tensioner for total knee arthroplasty (TKA): ligament  tensioning and assessment prior to bone resections

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