Wrist osteoarthrosis cases are part of the hand surgeons' daily practice. The etiology of osteoarthrosis may be post-traumatic, degenerative, infectious or rheumatological. Symptoms are progressive pain and decreased wrist function.

When the etiology is non-traumatic, there is no pattern to the way in which the joints are impaired, since the consequences of this condition have various effects on radial and midcarpal joints. Post-traumatic osteoarthrosis, however, shows a predictable standardized progression, and thus treatment depends on the stage of evolution of this condition. The etiology of post-traumatic wrist osteoarthrosis is usually secondary to ligament injuries or carpal fractures.1-5 In post-traumatic wrist arthrosis cases, 95% are located around the scaphoid, and in 55% of the patients with arthrosis the most common pattern is called scapholunate advanced collapse (SLAC) of the wrist, which results from ligament ruptures. The evolution of this type of arthrosis is divided into the following three stages:2,6 (1) arthrosis between the styloid process of the radius and the scaphoid; (2) arthrosis in the radial scaphoid fossa, (3) arthrosis between the capitate and the lunate.

The osteoarthrosis can also result from pseudoarthrosis of the scaphoid (scaphoid non-union advanced collapse (SNAC)).7 In this degenerative pattern, pseudoarthrosis of the scaphoid acts biomechanically in the same way as injuries to the scapholunate interosseous ligament; as observed in cases of SLAC wrist, butradial scaphoid fossa was preserved when pseudoarthrosis of the scaphoid occurred.8 The SNAC stages are: (1) arthrosis between the styloid process of the radius and the scaphoid; (2) arthrosis between the scaphoid and the capitate and (3) arthrosis between the capitate and the lunate.

Several surgical approaches for the treatment of post-traumatic osteoarthrosis of the carpal bones have been reported—namely, proximal row carpectomy, four-corner fusion, selective denervation of the wrist, partial styloidectomy of the styloid process of the radius, fusion of the scaphoid–trapezium–trapezoid joint, fusion of the scaphoid–capitate joint, “atlas” fusion (lunate–capitate) and the complete fusion of the wrist.4,5,8–22

This study aimed to compare the functional results of proximal row carpectomy and four-corner fusion for the treatment of post-traumatic wrist osteoarthrosis with no effect on the midcarpal joint.

Twenty-three patients were selected based on the inclusion and non-inclusion criteria for this study (see below). All patients presented wrist osteoarthrosis, with a diagnosis of SLAC or SNAC, but without involvement of the midcarpal joint. All patients were operated on by the same surgeon at the same hospital, between August 2004 and September 2007. All patients included in this study presented had a range of wrist motion. Three patients did not attend two postoperative assessments and were excluded. Of the 20 patients included, 16 had SNAC and 4 had SLAC.

The evolutional stages of SNAC/SLAC were evaluated by radiography and computed tomography.

The inclusion criteria were the presence of wrist osteoarthrosis grade I or II SLAC/SNAC and acceptance of the statement of free and informed consent. The exclusion criteria were presence of gross deformities in other limbs; rheumatological conditions; infections; involvement of the midcarpal joints, diseased condition in the contralateral wrist and previous fractures of the distal extremity of the radius or the carpal bones. The only other exclusion criterion was patients' non-attendance at two postoperative functional assessments.

The subjective analysis was based on the disabilities of the arm, shoulder or the hand (DASH) questionnaire and an analog pain scale.23,24

In the objective evaluation, the following were observed: wrist goniometry, grip force (Jamar), grip force of pulp–pulp, lateral (key) and three-finger (tripod) pinches, discrimination between two points on the pulp of the second and fifth fingers, and on the dorsum of the first web, measurements of the hand and wrist volumes and the Jebsen–Taylor functional test.25

Patients underwent preoperative and postoperative assessments and the latter were done 3, 6 and 12 months after the surgical procedure. All assessments were made by the same occupational therapist. Randomization was carried out by a draw on the day of the surgery. All operations were done by the same surgeon at the same institution. Patients who underwent proximal row carpectomy and those who had four-corner fusion started their rehabilitation with kinesiotherapy and physical means 3 weeks and 2 months after the operation, respectively.

The mean ages of the fusion and the carpectomy groups were 42±10.6 and 43.4±10.1 years, respectively. There was no difference in the handedness of the affected limbs between the two groups.

The data were divided into a direct evolutional analysis and comparative analysis within the same group and between the groups.

The mean age (40–52 years) of patients in this study is similar to that in other studies.8,16-22 A period of 5–10 years between the trauma and the start of signs and symptoms of arthrosis implies a condition that occurs in patients who are around 35 year old.7

Rigor in applying the non-inclusion criteria was fundamental for obtaining a homogeneous group of patients. The use of computed tomography to evaluate the joints, particularly the midcarpal joint, contributed greatly towards homogenizing the study groups.

Twelve months after the operation, the overall range of wrist motion was smaller in relation to the preoperative values in both procedures (p≤0.05). The arc of flexion–extension was, on average, 25% and 17% less in the cases of four-corner fusion and in proximal row carpectomy, respectively. The radial–ulnar deviation, on average, was, 0.3% and 10% less in fusion patients and carpectomy patients, respectively.

The radial deviation in cases of four-corner fusion was the only goniometry parameter that had improved 12 months after the operation. The postoperative pronation–supination movements were not statistically different in either group. Decreases in the overall range of motion in relation to preoperative values in proximal row carpectomy5,26–28 and four-corner fusion5,29 has been reported. In our study, horizontal analysis within each group showed proportional range-of-motion results favoring proximal row carpectomy, except for radial deviation, for which fusion was favored (p ≤ 0.05). The results presented here are consistent with other published results.8,16–19,22 However, others found that the arc of flexion–extension in cases of four-corner fusion was greater than the arc in cases of proximal row carpectomy.20

Vertical analysis of the four-corner fusion group showed that the grip force recovered to preoperative values (p≤0.05). In the carpectomy group, 95% of the preoperative grip force was recovered (p ≤ 0.05).

A loss of carpal height in the proximal row carpectomy procedure owing to relative stretching of the flexor and extensor tendons has been reported.2 The improvement in grip force after the operation can be credited to pain relief.27,28

Horizontal data from a series of proximal row carpectomy cases with longer follow-up duration have shown that between 60% and 80% of the grip force in the contralateral wrist is achieved.4,26–28 In contrast, only 47% of the grip force was achieved in this study. Patients undergoing proximal row carpectomy may take up to 1 year to achieve complete rehabilitation.28 Horizontal analysis of the grip force in patients undergoing four-corner fusion provided the best defense of this technique, to the detriment of proximal row carpectomy, because of the preservation of grip force in relation to the non-operated side.2,16

A 10% increase in relative grip force may occur over a 3-year period between postoperative evaluations in cases of four-corner fusion.30 Grip force values of between 70% and 87%, in relation to the contralateral wrist have been reported.8,17-20,30 In this study, the grip force was 73% of the contralateral wrist in patients who underwent four-corner fusion and 47% in patients undergoing proximal row carpectomy compared with the non-operated side (p≤0.05). These comparative values between groups were not statistically significant.

Evaluation of the grip force was done by finger pinches (key pinch, pulp–pulp pinch and tripod pinch), together with a test to discriminate between two points. This was done to determine whether surgical procedures might have caused lesions in the peripheral nerves.23 The results obtained proved that both surgical procedures were safe.

The universal analog pain scale was applied to the study patients. In the four-corner fusion group, there was a 33% reduction in pain, compared with preoperative values (p≥0.05). In the proximal row carpectomy group, there was a 41% reduction in pain (p≤0.05). The comparative values between groups were not statistically significant.

In the vertical DASH analysis, the patients who underwent four-corner fusion or proximal row carpectomy achieved 30% and 28% evolution, respectively, compared with preoperative values (p≥0.05). In the vertical analysis of the Jebsen–Taylor test,25 the patients who underwent four-corner fusion achieved, on average, 28% evolution over the task duration, whereas the value was 12% in patients who underwent proximal row carpectomy (p≥0.05). In the horizontal analysis, almost all patients recovered their function compared with the contralateral side; 98% in four-corner fusion group and 99% in proximal row carpectomy group. Comparison of the results between groups was not statistically significant.

Both proximal row carpectomy and four-corner fusion surgical procedures provided similar functional results for treating degenerative conditions of SLAC/SNAC without the impairment of the midcarpal joint. Indication for the surgical technique should be based on several parameters, such as patient's age, duration of immobilization, risk of pseudoarthrosis, possibility of breakage of the synthetic material, infection, duration of rehabilitation and the experience of the surgical team.