- 作者:Randa K. Elmallah ; MDa ; Jaydev B. Mistry ; MDa ; Jeffrey J. Cherian ; DOb ; Morad Chughtai ; MDa ; Anil Bhave ; PTa ; Martin W. Roche ; MDc ; Michael A. Mont ; MDa ;
- 关键词:TKA ; total knee arthroplasty ; pressure ; gap-balancing ; sensor
- 刊名:The Journal of Arthroplasty
- 出版年:2016
- 出版时间:September 2016
- 年:2016
- 卷:31
- 期:9_supp_S
- 页码:102-105
- 全文大小:286 K
Methods
Patients received either sensor-guided soft tissue balancing (n = 10) or manual gap balancing (n = 12). Wireless, intraoperative sensor tibial inserts were used to measure intracompartmental loads. The surgeon was blinded to values in the manual gap-balancing cohort. In the sensor cohort, the surgeon was unblinded, and implant trials were placed after normal releases were performed to guide further ligament releases after femoral and tibial resections, as needed. Load measurements were taken at 10°, 45°, and 90°.
Results
The sensor cohort had lower medial and lateral compartment loading at 10°, 45°, and 90°. The sensor group had lower mean differences in intercompartment loading at 10° (−5.6 vs −51.7 lbs), 45° (−9.8 vs −45.9 lbs), and 90° (−4.3 vs −27 lbs) compared to manually balanced patients. There were 10 additional soft tissue releases in the sensor cohort (2 initial ones before sensor use), compared to 2 releases in the gap-balanced cohort. In the gap-balanced cohort, tibial trays were positioned at a mean 9° external rotation, compared to a mean 1° internal rotation in the sensor-guided cohort.
Conclusion
Sensor-balanced total knee arthroplasties provide objective feedback to perform releases and potentially improve knee balancing and rotational alignment. Future work may clarify whether these changes are beneficial for our patients.