Operative versus non-operative management of pediatric medial epicondyle fractures: a systematic review

We found 14 studies that met all of our inclusion criteria and none of our exclusion criteria. Overall, there were 498 patients with a medial epicondyle fracture. Of those 498, there were 459 who were followed up and had enough data to be included in the individual studies. Table 1 highlights the demographics of the patients in the studies. There were 261 males and 132 female patients; the frequency-weighted average age was 11.93 years. The average follow-up in the various studies ranged between 6 and 216 months.

Table 2 highlights the findings of each individual study. Two hundred and sixty of 281 (92.5%) patients who received operative treatment had bony union at final follow-up. This was as compared to 60 of 122 (49.2%) patients treated non-operatively. This was statistically significant (P < 0.001). Pimpalnerkar et al. found the lowest rate of union in operatively treated fractures. Only six of 14 fractures (43%) went on to union; it is unclear why this was the case in this study. All other union rates for operatively treated medial epicondyle fractures were between 84.6 and 100% [5‐7, 10, 12, 109‐111, 113]. Non-operatively treated medial epicondyle fractures were associated with union rates of between 0 and 90% [3, 5, 10‐12, 110, 111, 113]. Seven studies [5, 10, 12, 110‐113] were eligible for pooling, because they had both operative and non-operative patients. Under the cumulative random effects model, the odds of union with operative fixation was 9.33 (2.54, 34.29) times the odds of union with non-operative treatment (P < 0.0001; see Fig. 1).

Thirty-seven of 246 (15%) patients who were operatively treated had pain or tenderness at final follow-up. This compares to ten of 115 (8.7%) patients who were treated non-operatively. The pooled difference in pain post-treatment was not significant (P = 0.140). Farsetti et al. had a subgroup of patients treated with excision of the osseous fragment and re-approximation of the soft tissues. Four out of six of these patients had persistent pain and two had osteoarthritis of the elbow [10]. Five studies [5, 10, 12, 111, 113] had both operative and non-operative patients and data about pain at final follow-up. A random effects model was constructed around these five studies. The odds of pain at final follow-up for patients treated operatively was 1.87 (0.21, 16.37) times the odds of those treated non-operatively; this was not statistically significant (P = 0.73).

Table 3 highlights the ulnar nerve symptoms reported in each study. For studies which followed ulnar nerve symptoms and specified pre-operative nerve status [3, 5, 6, 11, 12, 108, 109, 111, 113, 114], 37 of 384 (9.6%) patients had ulnar nerve symptoms. Twenty-five of 231 (10.8%) patients treated operatively had ulnar nerve symptoms pre-operatively; two of 103 (1.9%) patients treated non-operatively had ulnar nerve symptoms pre-operatively. At final follow-up, 16 of the 409 (3.9%) total number of patients, 13 of 287 (4.5%) patients treated operatively, and three of 122 (2.5%) patients treated non-operatively had ulnar nerve symptoms. The difference was not statistically significant (P = 0.412). Some authors treated patients with ulnar nerve symptoms with ulnar nerve transposition intra-operatively [5], while others did not routinely perform this treatment.

Eight studies reported functional outcomes in either outcome scores or by categorizing patients as ‘excellent,’ ‘good,’ ‘fair,’ or ‘poor’ based on various criteria. Haxhija et al. [108] used the criteria of axial deviation less than 9°, range-of-motion deficiency of less than 19°, minimal strength or functional loss, and no pain as their criteria for a good or excellent outcome; all patients in their study underwent open reduction and internal fixation with K-wires. Lee et al. used the Elbow Assessment Score of the Japanese Orthopedic Association, a 100-point score where 100 points corresponds to the best possible score. At final follow-up, the average score was 96.2 points (89–100). These authors used K-wires, screws, tension band wire, or suture to fix their fractures [109]. Farsetti et al. used the criteria of no symptoms, no atrophy, no osteoarthritis, negative valgus stress, and less than 10° motion loss as their criteria for good or excellent results. Sixteen of 19 non-operative patients and 15 of 17 operative patients had a good result. The remainder of the patients in these two groups had a fair result. Six patients were treated with excision of the osseous fragment and the repair of soft tissues. This was associated with two of six fair results and four of six poor results [10]. Bede et al. [3] classified results as good if, subjectively, the elbow was functional, pain-free, and free from instability or deformity, and, objectively, the range of motion was limited by 15° or less, there was less than 6° of cubitus valgus, and no ulnar neuritis. If these criteria were not met, the result was considered to be poor. Bede et al. [3] found that ten of 16 patients who had operative treatment had good results, compared to 27 of 34 patients who had non-operative treatment. The remainder of the results was poor. Hines et al. also used Bede’s criteria. However, they found 23 of 24 of their operatively treated patients to have experienced good outcomes [6]. The patient who did not have a good outcome was reported to have had a painful non-union [6]. Skak et al. [110] defined excellent outcomes as full range of motion, normal appearance, and no symptoms; good outcome as less than 15° of range of motion loss, minor deformity, and no arthritic or neurologic symptoms; poor outcome included disabling loss of motion, noticeable deformity, or any arthritic or neurologic symptoms. Eighteen of 21 of their operatively treated patients and two of three of non-operatively treated patients had good or excellent outcomes. The outcome was poor in the remainder of the patients [110]. The poor results were due to ulnar neuritis in two patients, an extension lag in one patient, and deformity due to a concomitant lateral condyle fracture [110]. Ip and Tsang [112] used the Mayo Clinic Score, which has 45 points for pain, 10 points for stability, 20 points for range of motion, and 25 points for activities of daily living. Four patients were treated conservatively; their Mayo scores at follow-up ranged from 90 to 100 (average 96.25). Overall, patients who underwent operative treatment had Mayo scores that ranged from 80 to 100 (average 93) [112].

Haxhija et al. [108] had two operative patients with flexion deficits of 5° at 1 year and one with 10° of flexion deficit; two patients had slight loss of strength. Bede et al. [3] reported 71% of patients with limited range of motion, though what was specifically meant by this was not indicated. The series by Fowles et al. [5] noted that eight of 19 patients treated non-operatively lost an average of 15° of elbow range of motion, and six of nine patients lost an average of 37° of range of motion. Dias et al. [11] found that eight of 20 patients lost less than 20° of flexion or extension and one lost more than 20°. Wilson et al. [12] found that two of 23 of their operative patients and six of 20 of their non-operative patients lost greater than 10° of extension, though this was not significantly different. Papavasiliou and Crawford [113] reported no loss of range of motion or strength in any patient. Hines et al. [6] only noted loss of motion (of less than 15°) in patients who required arthrotomy to remove the osseous fragment; the remainder of their operative and non-operative patients did not lose significant motion. Farsetti et al. [10], in their long-term follow-up, found two non-operative patients with limitations of elbow extension of 5 and 10°, two internal fixation patients with limitations of 5 and 20°, and one patient who had excision of their fragment with loss motion of 30° of extension. One of these non-operative patients had 1.5 cm of forearm atrophy; four patients who had excision of the fragment had 1–3.5 cm of forearm atrophy, and three lost grip strength [10]. In the van Niekerk and Severijnen [111] series, two non-operatively treated patients lost 5° of extension, and three patients had a loss of strength. Seven operative patients lost between 4 and 18° of motion, and three lost strength. Pimpalnerkar et al. [114] found that nine of 14 operative patients lost 5–15° of extension (mean 6.4°) at a mean follow-up of 17.2 months. Lee et al. [109] reported only one patient who had decreased motion post-operatively (arc of motion 110°). Duun et al. [7] reported that seven of their operatively treated patients lost extension (5–25°), one lost supination (10°), and two lost flexion (5°). Ip and Tsang [112] reported no loss in motion or strength in either operatively treated or non-operatively treated patients.

Haxhija et al. [108] had one patient with slight valgus deformity of 14° compared to the contralateral elbow (11°). Bede et al. [3] reported 35.5% cubitus valgus, though the specific parameters for this deformity were not indicated. Wilson et al. [12] found no cubitus valgus in any patient treated operatively or non-operatively. Hines et al. [6] had two of 19 patients with significant valgus deformity (15–20°) post-operatively; both of these patients required excision of the intra-articular osseous fragment, followed by internal fixation. Farsetti et al. [10], in their long-term follow-up, found two patients with a valgus deformity. Of interest, only two of 19 non-operative fractures united; one resulted in a carrying angle of 32°. Skak et al. reported on a variety of deformities, which ranged from radiologic findings such as double-contoured epicondyle, ulnar sulcus, pseudarthrosis, hypoplasia, or hyperplasia. Only one of these was classified as severe and was due to avascular necrosis of the trochlea. This patient had a concomitant lateral condyle fracture [110]; the investigators were unable to correlate the deformity to a specific treatment. Lee et al. [109], Pimpalnerkar et al. [114], Papavasiliou and Crawford [113], and van Niekerk and Severijnen [111] did not report any valgus deformities. Ip and Tsang [112] reported one patient treated with K-wires who developed cubitus varus and a patient with a displaced fracture who refused surgery who developed cubitus valgus. In the Duun et al. [7] series of operatively managed medial epicondyle fractures, one patient had a valgus deformity of 5°.

Eight studies reported no complications related to the treatment of the medial epicondyle fracture which were not previously discussed in other sections of this paper [7, 11, 108‐111, 113, 114]. Bede et al. [3] reported one patient with septic arthritis post-operatively and one patient with myositis ossificans. Wilson et al. [12] had two wound infections in their operative group and one keloid scar. One patient in Hines et al.’s [6] series of operatively treated fractures had pins which missed the fracture fragment; this patient had valgus instability post-operatively. Three patients in the same series had pin-tract infections that resolved with antibiotics and local wound care [6]. One patient from the Ip and Tsang [112] series had tension band wire and K-wires that developed a superficial wound infection.