Conservative Treatment of Avulsion Injuries of the Lesser Trochanter in Adolescent Athletes.

BACKGROUND: Avulsion injuries of the lesser trochanter apophysis are relatively uncommon injuries and there have been no peer-reviewed case series dedicated to the evaluation and treatment of this injury. The purpose of this study is to characterize avulsion injuries of the lesser trochanter apophysis, review treatment protocols, and time to return to sport. 
Methods: We reviewed 30 confirmed avulsion fractures of the lesser trochanter. Clinical data were reviewed to evaluate treatment protocols, duration, and time to return to sport. Radiographs were reviewed to confirm lesser trochanter avulsion and fracture displacement.
RESULTS: There were 26 males and 4 females, with the average age at the time of injury being 14.2 years. Treatment modalities consisted of protective weight-bearing, discontinuation of the patient's sport in all cases, and formal physical therapy in 18 cases. The average treatment duration was 30.7 days. The mean follow-up time was 102 days. The radiographic assessment demonstrated an average fracture displacement of 5.1 mm. The average return to sport was 11 weeks.
CONCLUSION: This is the first large case series studying avulsion injuries of the lesser trochanter. We have shown that these athletes can be managed non-surgically and can successfully return back to sport within three months.

Introduction

Pelvic avulsion injuries are well described in the literature, and athletic injuries to the hip and groin can comprise up to 1 in 10 patient visits to sports medicine clinics [1-6]. Six common sites of pelvic avulsion injuries have been described with injuries to the ischial tuberosity, anterior inferior, and superior iliac spines occurring most commonly [2]. Avulsion injuries of the lesser trochanter apophysis are relatively uncommon but predominantly occur in adolescent male athletes [1,2,6-9]. It has been reported in the literature that isolated lesser trochanter avulsion fractures account for less than 1% of a sports medicine physician’s practice [8,10].

Avulsion fractures of the lesser trochanter occur typically during sport due to strong muscle contraction of the iliopsoas on an apophysis with an open growth plate. The cartilaginous growth plate may be at increased risk of trauma compared to the musculotendinous units [2,7,11]. The primary mechanism of acute injury is a sudden forceful eccentric contraction of the iliopsoas in an attempt to accelerate or decelerate the body, typically occurring during athletic activity [12]. An alternative mechanism of injury is a sudden excessive passive muscle stretching [7].

Given the relatively rare occurrence of this injury, there are a limited number of case studies describing this topic, and treatment methods and outcomes have been varied in the reported literature [7-10,13-15]. Historically, pelvic avulsion fractures have been treated nonoperatively most commonly with analgesics and physical rehabilitation [13,16]. However, some controversy exists whether operative treatment is beneficial in these types of injuries, either as primary treatment or secondary treatment after failed conservative management [17-19].

There are limited reports in the literature regarding sport-specific outcomes in lesser trochanter avulsion fractures. As we see more adolescents playing highly competitive sports, early and correct diagnosis is pivotal for a successful return to sports. The purpose of this study is to characterize avulsion injuries of the lesser trochanter apophysis, review treatment protocols, and correlate with a time to return to sport. We hypothesized that patients with lesser trochanter avulsion fractures can be treated with conservative management with a successful return to sport and function.

Materials and methods

A retrospective review was performed at a Level 1 Pediatric Trauma Center between 2007 and 2017. Institutional Review Board approval was obtained to conduct this retrospective review, and a database search within the electronic medical record was performed using keywords “lesser trochanter” and “avulsion injury.” Using these criteria, the search returned 138 patients between ages 2 and 18. Following a further review of radiographs and clinical documentation, 30 confirmed acute avulsion fractures of the lesser trochanter were included in this case series. Chronic or non-athletic injuries were excluded. Clinical data were reviewed retrospectively to determine demographic data, sport involved, weight-bearing status, therapy protocol, duration of treatment, and time to return to sport. Return to the sport was defined as when the patient returned to practice or gameplay without limitation or disability. Radiographs of all patients were reviewed. The amount of fracture displacement was measured on the AP pelvis and/or hip radiograph used to determine the type of avulsion fracture, and evaluate for concomitant injuries. Avulsion fractures were classified as type 1 if non-displaced, type 2 if there was a displacement of less than or equal to 2 cm, type 3 if displacement was greater than 2 cm, and type 4 if there was a symptomatic nonunion or painful exostosis [1,20]. A Pearson’s product-moment correlation coefficient was computed to assess the relationship between the following variables: BMI, age, weight-bearing status, sport involved, duration of treatment, radiologic displacement, and return to sport time were all statistically analyzed for correlation.

Results

During the study period, avulsion fractures of the lesser trochanter were found in 30 patients (26 male, 4 female). The average age at the time of injury was 14.2 years (range: 7.7-17.5 years) with an average body mass index (BMI) of 21.1 (range: 16.9- 29.7). The mean follow-up time was 102 days. The injuries were traumatic and sustained during sports in all 30 patients. The sports patients were involved in prior to the injury included hockey, soccer, basketball, baseball, track and field, football, and cheerleading (Table 1).

Table 1

Summary of data

Adolescents with acute avulsion fracture of the lesser trochanter.

WBAT: weight-bearing as tolerated, PWB: partial weight-bearing, TTWB: toe-touch weight-bearing, NWB: non-weight bearing, PT: physical therapy.

Patient number	Laterality	Age at injury	BMI	Sport involved	Displacement (mm)	Classification	Weight-bearing status	Treatment duration	Activities/PT/rehab	Return to sport time (days)
1	Left	12.4	29.7	Football	4	2	PWB	28	n/a	75
2	Left	17.5	21.1	Baseball	10	2	TTWB	21	Jogging, baseball	99
3	Right	16.5	20.9	Distance runner	5	2	PWB	28	n/a	80
4	Right	15.0	19.9	Baseball, basketball	17	2	WBAT	60	PT	75
5	Right	12.0	17.7	Hockey	6	2	WBAT	21	PT, no hockey	35
6	Right	16.0	18.4	Hockey	15	2	PWB	21	No stretching, PT, WBAT, gradual return to sport	186
7	Right	16.6	18.9	Soccer	7	2	WBAT	28	PT/ROM, no soccer	59
8	Right	15.3	25.8	Basketball	5	2	WBAT	28	PT, a gradual return to activity	70
9	Left	14.4	21	Basketball	4	2	WBAT	42	PT, no sports × 6 weeks	80
10	Right	14.6	24.7	Cheerleading	0	1	NWB	28	PT, wean back to sports	139
11	Left	15.7	17.4	Soccer	4	2	WBAT	28	No sport	125
12	Right	12.9	22	Football	5	2	PWB	35	n/a	80
13	Left	16.2	26.2	Basketball	6	2	WBAT	35	PT, no sport	75
14	Right	15.2	20.4	Soccer	5	2	WBAT	35	PT, no flexion, no sport	74
15	Right	13.5	24.2	Hockey	2	2	TTWB	28	No sport, TTWB	27
16	Right	13.2	20.2	Hockey	5	2	WBAT	42	No sport, WBAT w/crutches	42
17	Left	12.9	16.9	Baseball	6	2	PWB	21	No sport/run, ok to bike/swim	121
18	Right	18.1	19.7	Basketball	4	2	PWB	21	No sprinting/running	42
19	Right	13.7	21.9	Soccer	3	2	WBAT	49	PT, no painful activity	177
20	Right	12.9	21.0	Soccer	1	2	WBAT	35	No sport	42
21	Left	15.3	24.6	Football, wrestling	10	2	WBAT	56	PT, no sport	60
22	Right	15.5	18.1	Hockey	5	2	PWB	21	PT, no sport	80
23	Right	9.6	20.0	Soccer, frisbee	1	2	PWB	21	PT, no sport	28
24	Right	15.3	22	Soccer	1	2	WBAT	28	No sport	113
25	Left	14.0	21.4	Running, soccer	2	2	WBAT	28	PT, no sport	45
26	Right	7.7	17.8	Softball	1	2	NWB	21	PT, no sport	25
27	Right	13.8	18.5	Hockey	2	2	PWB	28	PT, no sport	79
28	Left	13.7	22.8	Soccer	5	2	WBAT	28	PT, no sport	74
29	Left	14.1	19.6	Basketball	7	2	WBAT	28	PT, no sport	82
30	Left	13.0	21.3	Soccer	5	2	WBAT	28	PT, no sport	61

All cases were treated with nonoperative treatment modalities, consisting of discontinuation of the patient’s sport in all cases and formal physical therapy in 18 (60%) cases. Weight-bearing status at the initial time of treatment included weight-bearing as tolerated (WBAT) in 17 cases (57%), partial weight bearing (PWB) in 9 cases (30%), toe-touch weight-bearing (TTWB) in 2 cases (6.67%), and non-weight-bearing (NWB) in 2 cases (6.67%). The average treatment duration was 30.7 days (range 21-60 days). Radiographic assessment (Figures 1 and 2) demonstrated an average fracture displacement of 5.1 mm (range 0-17 mm).

Figure 1

Anteroposterior pelvis radiograph of the patient with a significantly displaced avulsion fracture of a left lesser trochanter

All 30 athletes returned to their sport (100%), with the average time to return to the sport being 78.3 days (2.5 months, range). Throughout the follow-up period, there were no diagnoses of a delayed union based on the radiographic review (Figure 3).

Figure 3

Anteroposterior pelvis radiograph of the left hip at the time of initial lesser trochanter avulsion fracture diagnosis (left) and at six-week follow up after conservative treatment with activity modification for four weeks and weight-bearing as tolerated (right)

Of note, there was a statistically significant positive correlation between displacement and patient age (r=0.405, n=30, p=0.026). All other correlations between variables were found to be non-significant (Table 2).

Table 2

Summary of correlation analysis

Correlations between avulsion size, age, BMI, and four functional variables.

*P-values <0.05 were considered significant.

WBS: work breakdown structure.

	1	2	3	4	5	6
1. Age at Injury	---
2. Return to sport time	0.092	---
3. BMI	0.643	0.834	---
4. Displacement	0.026*	0.161	0.471	---
5. Sport of participation	0.073	0.704	0.97	0.275	----
6. Duration WBS	0.584	0.742	0.16	0.069	0.160	---
7. WBS	0.485	0.427	0.566	0.535	0.321	0.056

Discussion

This is the largest case series of avulsion injuries of the lesser trochanter. Given the relatively rare occurrence of this injury, there are a limited number of case studies describing this topic, and treatment methods and outcomes have been varied in the reported literature (Table 3) [7-10,14,15].

Table 3

Summary of case reports on lesser trochanter avulsion fractures

Paper	Number of cases	Age	Operative/non-operative treatment	Avulsion description	Outcome	Return to sport	Complications
Current Study	30	14.2 (7.7–17.5)	Non-operative, average treatment duration of four weeks (3–8.5 weeks)	5.1 mm (0–17 mm)	Full recovery	Yes (30/30), the average time to return 11 weeks (range 4–26.5 weeks)	None
Ruffing et al. [20]	5	13–15	Non-operative	Types 2 and 3	HHS score of 100, average 4.9-year follow up	Yes (5/5)	None
Khemka et al. [17]	3	15–16	Arthroscopically assisted fixation (K wire (three cases), cancellous screw (two cases), 5.5 mm suture anchor utilized in each case (one case), followed by WBAT × four weeks followed by PT).	All >2 cm, edema around the lesser trochanter with a capsular injury and partial tear of the iliopsoas. No heterotrophic ossification around the fragment.	Full recovery	Allowed to return 10–12 weeks post-op. Patients with acute injuries returned to impact activity.	One case of numbness on the medial side of the knee (anterior femoral cutaneous nerve of the thigh), resolved two weeks after surgery
Vazquez et al. [9]	1	15	Non-operative (NWB with crutches, analgesic, a gradual return to activity at six weeks)	Not reported	Full recovery	Not reported	None reported
Fasting [21]	1	13	Open reduction/fixation (wire), followed by six weeks NWB in a spica cast	Not reported	Full recovery, full bony union at two-year follow-up	Yes	None reported
Theologis et al. [10]	3	(1.2, 5.3, 8.8)	Non-operative (one was treated with hip spica, two with bed rest and crutches)	Not reported	Full recovery in all cases. Case 3 injured lateral thigh three years after a fracture, radiographs showed fibrous union with the lesser trochanter prox. Cases 1 and 2 were asymptomatic at seven and nine-year follow up.	Yes (3/3)	None
Papacostos et al. [15]	1	15	Non-operative, period of non-weight bearing and PT	Not reported	Full recovery	Yes	None
Obi et al. [22]	1 (bilateral injuries on separate occasions)	15	Non-operative (analgesia, WBAT with crutches with full weight-bearing at six weeks. Sport restricted for three months)	Not reported	Full recovery, asymptomatic within six weeks. Bilateral solid bony union at six-month follow-up.	Yes, three months	None
McMillan et al. [23]	1 (bilateral injuries following separate seizures)	16	Non-operative (rest, analgesia, WBAT, PT)	Not reported	Full recovery of both hips (seen at 12 months post-injury). No pain or functional defect.	Yes	None

All patients were successfully managed nonoperatively with no additional sequelae or treatments. All 30 patients involved in sports returned to the sport after non-operative treatment for approximately one month, resulting in an average return to sport in less than three months. Ruffing et al. recently published a case series of successful non-operative treatment of lesser trochanter avulsion injuries that resulted in a 100% return to sport rate. However this study had a sample size of 5, so the potential application of these findings is limited [20]. Eberbach et al. published a systematic review of operative versus nonoperative management in all apophyseal avulsion fractures of the pelvis [24]. Of the 596 patients included, approximately 10 (1.8%) had lesser trochanter avulsion fractures. Although the injury locations were not specified in the treatment intervention, the authors reported that patients had better overall outcome scores following surgical intervention, especially in those patients with fracture displacement greater than 15 mm. They also noted similar complication rates between the two groups, however, this was generalized between all pelvic avulsion injuries [11,24-26].

Metzmaker and Pappas published the first large series of general pelvic avulsion injuries treated nonoperatively in a specific five-phase rehabilitation protocol, lasting 60 days minimum [7]. Only three patients of the 27 had lesser trochanter avulsion injuries. Twenty-four of the 27 (88%) had a full return to sport. One of those patients had a lesser trochanter avulsion re-injury for returning to sport too early and had a delayed return to full activity. Eberbach et al. argued this treatment protocol of at least 60 days was too long a period of convalescence and would adversely disrupt regular training and fitness in young athletes. However, a return to sport too early can lead to re-injury of a lesser trochanter avulsion and overall delayed recovery as shown by Metzmaker and Pappas [7,24].

The results that are shown by Metzmaker and Pappas coincide with our retrospective review in which all patients returned to sports at an average of 78 days after nonoperative treatment in a specific rehabilitation protocol. However, in the present study, over half of the patients were allowed to be weight-bearing as tolerated at the initiation of treatment. In addition, formal physical therapy was only prescribed in 18 of 30 cases.

There are also reports in the literature regarding operative indications for pelvic avulsion injuries and guarded results in nonoperative treatment [2,8,10,17]. Although there are limited publications regarding the operative treatment of lesser trochanter avulsion injuries, Khemka et al. reported a case series of arthroscopically-assisted open reduction internal fixation of lesser trochanter avulsion injuries with cannulated screws in three patients with no complications [17]. Reported indications in the literature for surgical intervention of adolescent avulsion fractures include displacement of >2 cm, painful nonunion, exostosis, and inability to return to sport [17,27-32]. The concerns addressed by Khemka et al. regarding displaced lesser trochanter avulsion fractures were non-union and loss of strength secondary to muscle shortening. In their series of three patients, all of the patients had lesser trochanter avulsion fractures greater than 2 cm. In addition to the concerns listed above, Khemka et al. additionally noted ischiofemoral impingement (IFI) as a potential consideration when treating lesser trochanter avulsion fractures conservatively. IFI was first described in 1977 by Johnson, noting impingement symptoms when the distance between the lesser trochanter and ischium decreased, from a displaced fracture [17,33-35]. Khemka expanded on this by reporting the incidence of IFI may increase in lesser trochanter avulsion fractures displaced greater than 2 cm and with associated heterotopic ossification [17]. However, this article did not address the potentially greater risk of IFI that screw fixation can create by decreasing the size of the lesser trochanteric-ischial space. This potential risk should be seriously considered and addressed when discussing treatment options with patients and their families. Surgical intervention may also increase the risk of heterotopic ossification, as reported following both open and arthroscopic hip procedures, further increasing the risk of IFI [36-38].

However, Khemka et al. concluded that arthroscopically assisted fixation of displaced lesser trochanter fractures helps to minimize chances of non-union, loss of muscle strength, and potentially IFI [17]. Moreover, this study did not define what a “chronic” versus “acute” lesser trochanter avulsion fracture was defined as, and it does not appear that any healing time was allowed prior to moving forward with the surgical intervention. In the literature, lesser avulsion fractures have been grouped into the classification system used for all other avulsion fractures [1]. Reports of nonunion due to ischial tuberosity fractures leading to IFI have been published and used as an indication for surgical intervention [39]. However, to the best of our knowledge, there have not been any reports of non-unions in lesser trochanter avulsions in the literature or within the limited follow-up of our own case series. Therefore, performing surgery in order to prevent nonunion fractures as they describe does not appear to be a valid indication for surgery moving forward.

Regarding return to sport, their results are very similar to our study. Their three patients underwent a post-operative protocol of weight-bearing as tolerated with crutches for four weeks, with a return to sport at 10-12 weeks. This parallels our study showing 30 patients, treated conservatively for approximately four weeks and an average return to sport at 11 weeks. The key takeaway from the results of our study is that equivalent time to return to normal function and sport can be achieved using conservative treatment, therefore, avoiding the surgical risks and economic burden related to undergoing a procedure.

This study has several limitations. First, it is retrospective in nature. A prospective, randomized trial would yield the most precise analysis of treatment protocols; however, this may be difficult given the relatively uncommon nature of this injury. Second, only certain aspects of treatment were able to be analyzed, for example, duration of treatment and time of return to sport. We were unable to procure data such as hip range of motion, strength testing, or functional and sports-specific outcome scores. This was likely due to the retrospective nature of the study, and the variety of providers that the patients in this study were treated by. Pediatric orthopedic surgeons, pediatric sports medicine orthopedists, primary care sports medicine physicians, and general pediatricians all treated the patients included in this study, hence, the differing weight-bearing status and rehabilitation protocols.

Additional future directions include investigating the potential long-term effects of this injury, such as the development of IFI, as well as looking at potential predisposing factors of avulsion fractures such as lesser trochanter version. Schroder et al. have shown the lesser trochanter version to have a moderate correlation with the femoral version, supporting the finding that patients with increased femoral neck version are at higher risk for extra-articular impingement at the lesser trochanter and ischial tuberosity [40,41].

In summary, this retrospective case series demonstrates one of the largest cohorts of adolescent patients sustaining avulsion fractures of the lesser trochanter, with full return to sport in under three months’ time after undergoing nonoperative management. This study highlights that most patients were allowed to weight-bear as tolerated, and formal physical therapy was only required in eighteen of thirty patients. These data show that adolescent patients sustaining avulsion injuries of the lesser trochanter can reliably return to sport without surgical intervention, be allowed to weight bear as tolerated, and do not necessarily need formal physical therapy. Although this retrospective study demonstrates excellent results with non-operative management, prospective, randomized studies and assessment of functional and sports-specific outcome scores would further guide treatment strategies.

Conclusions

Lesser trochanter avulsion injuries in adolescent athletes can be treated conservatively with an average return to normal function and sports time of less than three months. This is the first large case series studying avulsion injuries of the lesser trochanter. We have shown that these athletes can be managed non-surgically and can successfully return back to sport within three months.