Comparison of arthrodesis and arthroplasty of Chinese thumb carpometacarpal osteoarthritis

The thumb carpometacarpal (CMC) joint is a saddle joint with both concave and convex surfaces and a thin and loose capsule. Due to the effect of constant multidirectional forces during daily work and life activities, about 25% of females and 12% of males suffer from thumb CMC osteoarthritis in the west [1]. Symptoms of thumb CMC osteoarthritis include pain, swelling, deformity, and instability. Multiple methods are used to treat progressive thumb CMC osteoarthritis, among which trapeziometacarpal arthrodesis and trapezial excision with ligament reconstruction and tendon interposition (LRTI) are the most common. These two surgical treatment methods have received mixed reviews in previous studies in the west patients. This retrospective study studied the results of 39 Chinese patients of progressive thumb CMC osteoarthritis treated with either arthrodesis or arthroplasty. Through the evaluation of grip strength, pinch strength, thumb abduction angles (palmar and radial), Kapandji opposition scores, visual analog scale (VAS) scores, and Disabilities of the Arm, Shoulder, and Hand (DASH) scores, the two groups of data were compared to observe the degree of improvements of the two surgical treatments in strength, pain, range of motion, and overall satisfaction. The following is a report of this study.

Grip strength, pinch strength, abduction angles (palmar and radial), and Kapandji score were measured and recorded using a Biometrics E-LINK Hand Kit (H500 evaluation system, X4 data adapter). Distal-lateral phalangeal pinching was used in the pinch strength measurement. Each patient was measured 3 times and the average score was recorded. The VAS pain score and DASH score were evaluated using questionnaires.

The selection of treatment plans for thumb CMC osteoarthritis is primarily based on illness stage [5]. For early-stage CMC osteoarthritis, conservative treatments such as adjusting daily activities, splint fixation, and local corticosteroid injections can be utilized to relieve symptoms. Wrist arthroscopy can be used to clear intra-articular osteophytes and thickened synovial membranes, perform hemitrapeziectomy [6, 7] and soft tissue interposition [8], and conduct joint capsule thermal shrinkage therapy [9]. However, its long-term therapeutic outcomes are inconclusive. An elastic silicone prosthetic implant is currently rarely used in thumb CMC joint replacement due to reactive synovitis and prosthetic wear [10]. The use of Artelon implant is not recommended because of its high revision rate and worse outcomes compared with conventional techniques [11]. Similarly, spherical polymer implant failures have been reported [12]. Recently, a report of a pyrocarbon spherical (Pi2) implant demonstrated high complication rates and no identifiable benefit [13]. For progressive-stage (stage II or III) thumb CMC osteoarthritis, arthrodesis and arthroplasty are currently widely used and their effect is positive. Therefore, a comparison and evaluation of the effects of the two methods are necessary.

In this study, arthrodesis and arthroplasty were able to significantly improve patient grip and pinch strengths. Comparing the two methods resulted in no statistically significant difference in grip strength improvement (P = 0.18, P > 0.05), while lateral pinch strength showed better improvement after arthrodesis (P < 0.001). The force couple in gripping motion has a shorter moment arm, while the force couple in pinching motion has a longer moment arm that causes higher joint compression strength [14]. This result indirectly proved that arthrodesis tends to better improve joint stability than arthroplasty.

Arthrodesis can significantly relieve pain in cases of degenerative thumb CMC osteoarthritis [15]. The literature suggests its main disadvantage being decreased postoperative thumb range of motion, with the thumb unable to adduct and lay flat on the palm, as well as a certain rate of nonunion [16, 17]. We observed a decrease in thumb abduction angle postoperative; however, the joint was not completely fixed and was unable to move. Kapandji scores reached 6.7 postoperative, which was only a slight decrease from 7.2 prior to surgery. Other studies also indicated that simple CMC arthrodesis will not affect the motor functions of the thumb since the range of motion in the trapezium–first metacarpal joint postoperative is compensated for by the ranges of motion of the scaphoid–trapezium–trapezoid joint and first metacarpal–proximal phalanx joint. The majority (75%) of the compensation comes from the first metacarpal–proximal phalanx joint, while the other 25% comes from the scaphoid–trapezium–trapezoid joint [18]. In follow-up visits, we observed thumb adduction being affected due to CMC arthrodesis fixating the joint. However, it was rarely noticed by patients and did not affect their overall satisfaction.

After thumb trapeziometacarpal arthrodesis surgery, the surrounding joints will compensate for its movement, thereby increasing the rates of osteoarthritis in these joints [19]. In 22 arthrodesis patient follow-up visits, we discovered 2 cases of scaphoid–trapezium–trapezoid osteoarthritis and 1 case of thumb metacarpal–proximal phalanx osteoarthritis. However, they all presented only on X-ray radiographs without subjective symptoms; therefore, no further treatment was given [20].

Nonunion after trapeziometacarpal arthrodesis was once considered the major complication of arthrodesis. The literature has reported a 13–16% nonunion rate [17]. We utilized Cannulated screws in all 22 patients to fix the joint; stability and compression effectiveness of joint fusion were significantly increased compared with K-wires [21]. In some patients with lower bone quality, we used bone grafts harvested from the styloid process of the radius, further increasing the arthrodesis fusion rates. All patients in this group achieved 100% union.

LRTI can significantly relieve pain because it involves removal of the affected joint. In this study, the thumb abduction angle increased after arthroplasty surgery. Palmar abduction increased by 4°, radial abduction increased by 6°, and Kapandji score increased from 6.9 preoperative to 7.5 postoperative. Patients noted relatively flexible thumbs. However, although ligament reconstruction and suspension were utilized and tendon interposition was used to support the first metacarpal, postoperative thumb shortening and instability were present [22], affecting pinch strength (compared with pinch strength after arthrodesis, P < 0.01). Kapandji score did not reach the normal level of 10 (Figs. 3 and 4).

Thumb grip strength, abduction angle (palmar and radial), and Kapandji scores all evaluate hand functions from iatrogenic perspectives and thus cannot fully reflect patients’ subjective feelings. DASH scores evaluate upper-limb function from the patients’ subjective perspective; thus, they are more persuasive. In this study, DASH scores in both groups decreased from 41.2 ± 6.2 and 38.8 ± 6.7 preoperative to around 4 postoperative, respectively. No statistically significant difference was found in the comparison of final scores between the two groups (P = 0.23, P > 0.05), indicating that the patients were able to ignore the differences in joint mobility and thumb strength and were satisfied with the therapeutic outcomes of both surgical methods. This suggests that upper-limb function after arthrodesis and arthroplasty surgeries have no significant impact on daily life.

In this study, all the case data were from Chinese. Previous literature reported that Trapezial-metacarpal (TM) joint surfaces appear to be shallower in Asian than in white race, and the frequency of TM osteoarthritis seems to be substantially lower in Asian TM joints [23]. Due to different anatomical factors, the results of surgery may be different. The study represents the results of surgery in the Chinese population. This is a supplement to previous data.

In Chinese patients, although differences existed between the therapeutic outcomes of arthrodesis and arthroplasty on some objective evaluation indices, our results showed subjective patient satisfaction with both surgical treatments. Therefore, personalized treatment plans can be designed according to patients’ demands for strength and flexibility.