Search for other papers by Xiang-Dong Wu in
Google Scholar
PubMed
Search for other papers by Yixin Zhou in
Google Scholar
PubMed
Search for other papers by Hongyi Shao in
Google Scholar
PubMed
Search for other papers by Dejin Yang in
Google Scholar
PubMed
Search for other papers by Sheng-Jie Guo in
Google Scholar
PubMed
Search for other papers by Wei Huang in
Google Scholar
PubMed
components ( 1 , 2 , 3 , 4 , 5 , 6 ). Therefore, during the past decades, robotic-assisted total joint arthroplasty (TJA) has extensively been explored in this domain, with the expectation that robotic-assisted technology would significantly improve the
Search for other papers by Nanne Kort in
Google Scholar
PubMed
Search for other papers by Patrick Stirling in
Google Scholar
PubMed
Search for other papers by Peter Pilot in
Google Scholar
PubMed
Search for other papers by Jacobus Hendrik Müller in
Google Scholar
PubMed
as computer-assisted navigation systems, or robot-assisted systems. 2 Robotic systems, which are utilized across many surgical subspecialties, 3 can be classified as either active systems, which work autonomously to perform the planned bone
Department of Orthopaedics, Royal Infirmary of Edinburgh, Edinburgh, UK
South West of London Orthopaedic Elective Centre, Epsom, UK
Search for other papers by Nicholas D. Clement in
Google Scholar
PubMed
Search for other papers by Marwan Al-Zibari in
Google Scholar
PubMed
Search for other papers by Irrum Afzal in
Google Scholar
PubMed
Search for other papers by David J. Deehan in
Google Scholar
PubMed
Search for other papers by Deiary Kader in
Google Scholar
PubMed
Introduction Robotic-arm-assisted knee arthroplasty has been shown to enable more accurate implant positioning for both unicompartmental knee arthroplasty (UKA) and total knee arthroplasty (TKA) when compared to manual surgery. 1 , 2
Search for other papers by Jean-Pierre St Mart in
Google Scholar
PubMed
Search for other papers by En Lin Goh in
Google Scholar
PubMed
, with satisfaction rates ranging between 82% and 89%. 3 , 4 This can be attributed to poorer function, lower implant survivorship and need for revision surgery, resulting from component malalignment or soft tissue imbalance. 5 – 10 Robotic-assisted
Search for other papers by Jean-Pierre St Mart in
Google Scholar
PubMed
Search for other papers by En Lin Goh in
Google Scholar
PubMed
Search for other papers by Zameer Shah in
Google Scholar
PubMed
that suboptimal component positioning leads to joint instability, 9 increased wear, 10 and poorer function. 11 – 14 Robotic-assisted orthopaedic surgery has the potential to improve the accuracy of component positioning in THA, thus
Search for other papers by Wen-xi Sun in
Google Scholar
PubMed
Search for other papers by Wei-qiang Huang in
Google Scholar
PubMed
Search for other papers by Hua-yang Li in
Google Scholar
PubMed
Search for other papers by Hong-shen Wang in
Google Scholar
PubMed
Search for other papers by Sheng-li Guo in
Google Scholar
PubMed
Search for other papers by Jie Dong in
Google Scholar
PubMed
Search for other papers by Bo-lai Chen in
Google Scholar
PubMed
Search for other papers by Yong-peng Lin in
Google Scholar
PubMed
other complications ( 7 , 8 ). The pedicle screw misplacement rates of conventional techniques are 30% and 55% in the lumbar and thoracic spines, respectively ( 9 , 10 , 11 ). This contrasts the reported high success rate of robot-assisted pedicle
Search for other papers by Ahmed Siddiqi in
Google Scholar
PubMed
Search for other papers by Timothy Horan in
Google Scholar
PubMed
Search for other papers by Robert M. Molloy in
Google Scholar
PubMed
Search for other papers by Michael R. Bloomfield in
Google Scholar
PubMed
Search for other papers by Preetesh D. Patel in
Google Scholar
PubMed
Search for other papers by Nicolas S. Piuzzi in
Google Scholar
PubMed
over traditional human operators with added procedural value. 27 Robotic-assisted TKA (RA-TKA) has gained momentum within the past 10 years to better control surgical variables by mitigating technical errors caused by insecure cutting guides and
Search for other papers by Dominic Davenport in
Google Scholar
PubMed
Search for other papers by Venu Kavarthapu in
Google Scholar
PubMed
.5% of all revisions and 33% of acetabular revisions. 10 We outline the currently available methods of acetabular navigation, comparing freehand techniques with computer- and robotic-assisted navigation of the acetabular component. Acetabular
Department of Orthopaedic Surgery, University of Cape Town, South Africa
Search for other papers by Mark Anthony Roussot in
Google Scholar
PubMed
Search for other papers by Georges Frederic Vles in
Google Scholar
PubMed
Search for other papers by Sam Oussedik in
Google Scholar
PubMed
Operative plan for a robotic-assisted, kinematically aligned TKA. Note that the implant alignment is based on symmetrical 8 mm distal and posterior resections of the femoral condyles. The tibial resection is aligned to the native proximal tibial joint line
Princess Grace Hospital, London, UK
Search for other papers by Babar Kayani in
Google Scholar
PubMed
Princess Grace Hospital, London, UK
Search for other papers by Sujith Konan in
Google Scholar
PubMed
Princess Grace Hospital, London, UK
Search for other papers by Atif Ayuob in
Google Scholar
PubMed
Search for other papers by Elliot Onochie in
Google Scholar
PubMed
Search for other papers by Talal Al-Jabri in
Google Scholar
PubMed
Princess Grace Hospital, London, UK
Search for other papers by Fares S. Haddad in
Google Scholar
PubMed
, increased knee flexion at discharge, and reduced need for inpatient physiotherapy compared to conventional jig-based TKA. Median time to hospital discharge in robotic-arm-assisted TKA was 77 hours (interquartile range (IQR) 74 to 81) compared with 105 hours