INTRODUCTION
Fractures of the medial epicondyle are a common pediatric injury, with an estimated
annual incidence of 40-60/100,000 per year. The typical mechanism is a fall onto an
outstretched hand, creating a valgus load at the elbow leading to avulsion of the
epicondyle from pull of either the flexor-pronator mass or ulnar collateral ligament.
This injury is most frequent in children between the ages of 9 and 14, and is 4 times
more likely in boys. Medial epicondyle fractures are associated with elbow dislocation in
about 50% of cases, and ulnar nerve dysfunction is reported to occur nearly 10% of the
time. No standard of care for medial epicondyle fractures exists, as similar outcomes
have been demonstrated in observational studies with both operative and nonoperative
treatment. Historically, most treatment has been nonsurgical, with immobilization of the
injured elbow in a long-arm cast until healing. Increasingly, however, these injuries are
being treated with surgical intervention, which in most cases consists of a single screw
affixing the bony piece back to its donor site on the humerus.
No prospective studies have previously been performed evaluating the treatment of medial
epicondyle fractures in children. All of the current literature on this issue has serious
methodological limitations, such as lack of appropriate controls, retrospective assembly
of cohorts, unstandardized assessment of outcomes, and irregular assessment of negative
outcomes and adverse events. A 2009 systematic review of the literature identified 14
studies in which a comparison between operative and nonoperative treatment of medial
epicondyle fractures in children or adolescents was performed. Of these, all were
retrospective and observational in nature, with varying outcome measures utilized in the
presentation of results.
There is considerable debate among clinicians as to the optimal management of medial
epicondyle fractures, however, despite the lack of clear evidence of benefit,
increasingly these injuries are being managed operatively. Explanations for the trend
toward surgery focus on the athletic demands of children and adolescents, and the
expectations of patients, parents, and coaches of early mobilization and return to sport.
Because of the ongoing uncertainty as to best practice, a randomized trial is both
ethical and indicated. High-quality data is necessary to better inform the decision
regarding surgery and ensure both safe and effective treatment.
SAFETY OVERSIGHT
Safety oversight will be under the direction of a Data and Safety Monitoring Board (DSMB)
composed of individuals with the appropriate expertise and knowledge of pediatric
orthopaedic surgery usually obtained via an accredited pediatric orthopaedic fellowship.
Members of the DSMB should be independent from the study conduct and free of conflict of
interest, or measures should be in place to minimize perceived conflict of interest. The
DSMB will meet at least semiannually to assess safety data on each arm of the study. The
DMSB will operate under the rules of an approved charter that will be written and
reviewed at the organizational meeting of the DSMB. At this time, each data element that
the DSMB needs to assess will be clearly defined. The DSMB will provide its input to
NIAMS.
QUALITY ASSURANCE AND QUALITY CONTROL
Quality control (QC) procedures will be implemented beginning with the data entry system
and data QC checks that will be run on the database will be generated. Any missing data
or data anomalies will be communicated to the site(s) for clarification/resolution.
Following written Standard Operating Procedures (SOPs), the monitors will verify that the
clinical trial is conducted and data are generated and biological specimens are
collected, documented (recorded), and reported in compliance with the protocol,
International Conference on Harmonisation Good Clinical Practice (ICH GCP), and
applicable regulatory requirements (e.g., Good Laboratory Practices (GLP), Good
Manufacturing Practices (GMP)).
The investigational site will provide direct access to all trial related sites, source
data/documents, and reports for the purpose of monitoring and auditing by the sponsor,
and inspection by local and regulatory authorities.
DATA HANDLING AND RECORD KEEPING
DATA COLLECTION AND MANAGEMENT RESPONSIBILITIES
Data collection is the responsibility of the clinical trial staff at the site under the
supervision of the site investigator. The investigator is responsible for ensuring the
accuracy, completeness, legibility, and timeliness of the data reported.
Clinical data and patient reported outcomes will be entered into REDCap, a 21 CFR Part
11-compliant data capture system provided by the DCRI. The data system includes password
protection and internal quality checks, such as automatic range checks, to identify data
that appear inconsistent, incomplete, or inaccurate. Clinical data will be entered
directly from the source documents.
STATISTICAL HYPOTHESES
• Primary Efficacy Endpoint(s):
The trial will employ a superiority framework. Specifically, the null hypothesis is that
there is no difference in PROMIS UE (CAT) at 1 year between arms. The alternative
hypothesis is that there is a difference between arms.
SAMPLE SIZE DETERMINATION
Sample size calculations were based on detecting a clinically meaningful difference in
the Patient Reported Outcomes Measurement Information System (PROMIS) Upper extremity
computer adaptive test (CAT) of 4 points. PROMIS measures use a T-score metric with a
mean of 50 and standard deviation of 10 in a reference population. A sample size of 133
per am, assuming a two-sided type I error rate of 0.05, will provide 90% power to detect
a difference between arms of 4 points.
To account for 20% lost-to-follow-up or missing data on the primary outcome at 12 months,
we have inflated our sample size to 167 per arm, for a total target enrollment of 334.
A blinded sample size re-estimation based on the standard deviation of the primary
outcome, after 50% of participants have completed the 6-month follow-up, will be
performed.
POPULATIONS FOR ANALYSES
Primary analyses will be based on an Intention-to-treat (ITT) principle. A per-protocol
analysis will be performed to assess the robustness of the ITT analysis. In the event of
minimal (<5%) missing outcome data, primary analyses will be based on complete cases,
reflecting a modified intent-to-treat analysis (mITT).
STATISTICAL ANALYSES
GENERAL APPROACH
Descriptive statistics will summarize all baseline variables by arm. Specifically,
continuous variables will be summarized using mean and standard deviation, for normally
distributed variables, and median and IQR, for non-normally distributed variables.
Categorical variables will be summarized with frequency and percentages. There will be no
formal hypothesis testing for comparison of baseline characteristics between treatment
arms.
Primary analyses of the primary outcome at 1 year will be assessed with a two-sided type
I error rate of 0.05. A false discovery rate (FDR) correction will be applied to analyses
of all secondary outcomes to account for multiplicity.
ANALYSIS OF THE PRIMARY EFFICACY ENDPOINT(S)
Analysis for the primary aim will utilize a mixed effect model for the primary outcome,
PROMIS Upper Extremity Function at 6 months, with a fixed effect for treatment arm and a
random effect for site. Fixed effects will also include variables considered in the
randomization (elbow dislocation status, age, sex) to control for imbalances in both the
design and analysis. Incorporation of a random center effect will allow for separation of
between site and within site variance components. Distributional assumptions will be
assessed, and transformations or inclusions of higher order terms may be considered, as
appropriate.
ANALYSIS OF THE SECONDARY ENDPOINT(S)
Secondary analyses will employ similar methods for all secondary continuous outcomes.
Generalized linear mixed modeling approaches will be used for secondary binary and count
outcomes, with appropriate link and distributional assumptions. All models will
incorporate a random center effect and fixed effects for additional covariate considered
in randomization, as described above.
Exploratory analyses may also consider trajectories of the primary outcome measured over
time. Fixed effects for baseline PROMIS Upper Extremity Function, time, treatment arm,
and the interaction will be included in a linear mixed effect model with random patient
nested in center effects.
A False Discovery Rate (FDR) correction will be applied to all secondary analyses to
account for multiplicity.