Acta Chir Orthop Traumatol Cech. 2019; 86(1):33-38 | DOI: 10.55095/achot2019/005

Rotational Knee Joint Kinematics before and after Unicompartmental Medial Arthroplasty, Comparison with a Healthy Knee JointOriginal papers

F. BUČEK1,*, M. KOMZÁK1, R. HART1,2
1 Ortopedicko-traumatologické oddělení, Nemocnice Znojmo
2 Klinika traumatologie, Lékařská fakulta Masarykovy Univerzity Brno

PURPOSE OF THE STUDY:
The authors in their study compare the knee joint kinematics in patients before and after medial unicompartmental knee arthroplasty (UKA) and in the group of healthy volunteers. This study aims to confirm or reject the hypothesis that UKA preserves the physiological knee joint kinematics.

MATERIAL AND METHODS:
In the course of 2015 and 2016 a total of 20 patients with grade III-IV medial knee joint osteoarthritis and 20 healthy volunteers were included in the study. In the first group of patients the standard Oxford™ unicompartmental knee prosthesis was implanted using kinematic navigation and the reference data were collected before and after the knee joint replacement. In the group of healthy volunteers an arthroscopic examination and subsequent data collection were performed in order to conduct a kinematic analysis. Subsequently, a statistical analysis of data was carried out and the groups were compared.

RESULTS:
In our study two parameters were compared. The first was the maximum rotational movement of the tibia relative to the femur (rotational stability) in each of the degrees of flexion (0°, 30°, 60°, 90°, and 120°). In this case, the knee joints prior to UKA showed laxity at all examined degrees. At 0° flexion the preoperative range was -14.3° to 8.2° and it improved to -3.4° to 7.3° postoperatively, at 30° it was -15.3° to 15.8° preoperatively and -13.3° to 8.2° postoperatively. At 90° flexion the rotation of the knee joint before the UKA was -24.2° to 13.2°, while after the implantation the rotation improved to -19.3° to 11.7°. The second monitored parameter was the position of tibia with respect to the femur during the passive flexion test. The position in full extension before the implantation is 5.6° internal rotation compared to 2.7° external rotation after the implantation. The knee joint before the implantation shows minimum flexion/internal rotation throughout the entire flexion range. The postimplant values of flexion get close to the values obtained in a healthy knee joint. The data collected from the healthy knee joints were used as reference data.

DISCUSSION:
The outcomes of our study correspond with the conclusions arrived at by other authors. The arthrotic process affects the knee joint kinematics by causing joint laxity and relative ACL insufficiency. This results in further progression of joint damage, the loss of the screw-home mechanism. In our study we benefit from the use of navigation in the intraosseous fixation, which compared to the other techniques enables more accurate data collection.

CONCLUSIONS:
The arthritic process affecting the knee joint results in altered kinematics and biomechanics of the affected knee joint. This is manifested at both the axial and sagittal plane, when the kinematics fails to equal that of the healthy joint. The implantation of the medial unicompartmental knee arthroplasty improves the kinematics of the knee joint and helps achieve the requested values and stabilises the knee joint.

Keywords: medial gonarthrosis, unicompartmental knee arthroplasty, knee joint kinematics

Published: February 1, 2019  Show citation

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BUČEK F, KOMZÁK M, HART R. Rotational Knee Joint Kinematics before and after Unicompartmental Medial Arthroplasty, Comparison with a Healthy Knee Joint. Acta Chir Orthop Traumatol Cech. 2019;86(1):33-38. doi: 10.55095/achot2019/005. PubMed PMID: 30843511.
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