Clinical research progress on noise after ceramic-on-ceramic total hip arthroplasty
10.3760/cma.j.cn121113-20250123-00075
- VernacularTitle:陶瓷对陶瓷全髋关节置换术后异响的临床研究进展
- Author:
Hao LI
1
;
Xiangpeng KONG
;
Bohan ZHANG
;
Mingfeng LI
;
Ping SONG
;
Wei CHAI
Author Information
1. 解放军医学院,北京 100853
- Publication Type:Journal Article
- Keywords:
Arthroplasty, replacement, hip;
Postoperative complications;
Ceramic hip prosthesis;
Ceramic-on-ceramic;
Hip noise
- From:
Chinese Journal of Orthopaedics
2025;45(16):1082-1088
- CountryChina
- Language:Chinese
-
Abstract:
This article reviews the progress of clinical research on abnormal sounds after ceramic-on-ceramic total hip arthroplasty, with a focus on analyzing the differences between the third-generation and fourth-generation ceramic prostheses. Abnormal sounds generally refer to high-pitched audible sounds (such as creaking, clicking, etc.) during hip joint movement after surgery, which are considered possible precursors to prosthesis fragmentation (for example, patients with abnormal sounds have more ceramic particles in the joint fluid, and some are accompanied by prosthesis fragmentation). The fundamental frequency of abnormal sounds in the third-generation ceramic prostheses ranges from 400 to 7 500 Hz (approximately 1 500 Hz in males and 2 500 Hz in females), while the acoustic characteristics of the fourth-generation ones remain unclear. The reported occurrence time of abnormal sounds varies significantly among different studies, with an average of 6.4 to 40 months after surgery. This variation may be influenced by patient characteristics, surgical technique, and prosthesis type. Abnormal sounds are considered a possible early indicator of prosthesis fragmentation; for instance, higher concentrations of ceramic particles have been detected in the synovial fluid of affected patients, and some cases have been accompanied by prosthesis fracture. The incidence of abnormal sounds with the fourth-generation prostheses ranges from 3.8% to 46.6% (with a follow-up period exceeding 10 years), while the third-generation shows rates of 0% to 19.7% with no difference between the two generations. Although the fourth-generation prostheses are superior to the third-generation in material toughness (flexural strength>1 380 MPa) and hardness, they still fail to solve the problem of abnormal sounds, and the incidence may increase with the extension of the follow-up time (for example, in some studies, the incidence at 10-year follow-up is higher than that at 5-year follow-up). Abnormal sounds are mostly associated with movements such as extreme flexion (e.g., squatting) and walking. Different sound properties (such as friction sound) correspond to specific inducing movements and locations, among which friction sound requires vigilance against the risk of prosthesis fragmentation. The risk factors include patient-related factors (height, weight, activity level, etc.), surgical factors (prosthesis position angle), and prosthesis-related factors (design, diameter, neck length, etc.). Proposed mechanisms include abnormal edge loading, stripe wear, femoral neck impingement, wear particle generation, and prosthesis mismatch. Adverse outcomes include decreased patient satisfaction with life, revision surgery (with an incidence of 0.2% to 4.65%), and prosthesis fragmentation. Currently, there are still controversies in research. Future studies need to focus on special patient groups, surgical techniques (such as robot-assisted surgery), and the optimization of prosthesis materials and designs (such as gradient structures and surface coatings) to reduce the incidence of abnormal sounds.
