The primary objective of this pilot trial is to assess the feasibility of a definitive trial to determine the effect of lateral patient positioning versus supine positioning with fracture table use for reamed antegrade intramedullary fixation of femur fractures.
Femoral shaft fractures typically occur alongside other complex, high-energy injuries in the poly-traumatized patient. Femur fractures can cause extensive bleeding and surrounding muscle injury, and have a high global burden; occurring at a rate between 14 and 42.5 /100,000 person years, with approximately 1 in 10 road traffic accidents worldwide resulting in a femoral shaft fracture requiring surgery. Additionally, there is significant disparity in the burden of diaphyseal femur fractures, with 91% occurring in lower middle-class income countries, and the majority affecting younger males. To help mitigate the effects of ongoing pain, blood-loss, worsening inflammation from unstable fracture ends, femoral shaft fractures require urgent management using either an early total-care or damage-control orthopaedics approach. Associated injuries, markers of resuscitation, and overall patient stability guide operative decision making and the timing of surgical intervention. Definitive internal fixation using reamed, locked intramedullary nailing (IMN) has become the standard of care in an adequately resuscitated patient, as it provides fracture stability while facilitating nursing care and patient mobilization. Multiple femoral IMN techniques exist; however, most femoral shaft fractures can be treated with an antegrade nail using either supine (fracture table) or lateral (free-leg drape) positioning. Femoral Malrotation is a Common and Significant Complication Despite the adoption of femoral IMN, patient-reported function following femur fracture fixation varies widely. Incorrect positioning of the fracture fragments by more than 15° relative to the native limb rotation (femoral malrotation) is associated with poor functional recovery, low health-related quality of life, gait abnormalities, difficulty with stairs, and delayed return to pre-injury activity. Significant femoral malrotation (\>15°) occurs in up to 55% of patients following femoral shaft fracture IMN, as measured by post-operative computer tomography (CT) scans. Numerous intraoperative assessments have been used to judge rotation, including cortical diameter, lesser trochanter profile and others; though none are easily reproducible or reliable. The preferred technique by surgeons is the lesser trochanter profile, but this method requires a true anteroposterior view of the pelvis, which can be challenging to obtain with the fracture table in place. A Lack of Consensus On Operative Table and Patient Positioning While the orthopaedic surgery community agrees that femoral shaft fractures should be treated with IMN, there is a lack of agreement on whether the patient should be placed in the supine position on fracture table (SFT) or in the lateral position on a standard radiolucent operating table (LRT). Our research team recently conducted a survey of the Canadian Orthopaedic Association membership and found a clear divide on patient positioning, with 56% of respondents using supine position on fracture table and 44% using a form of lateral positioning. A recent comprehensive review identified only three studies on this specific topic. The best existing evidence of the previous literature comes from a prospective randomized trial led by Stephen et al. The authors described that supine positioning without use of fracture table yielded better post-operative rotation than patients treated with a fracture table. However, this study did not assess the utility of lateral positioning, which is more commonly used in isolated femoral shaft fractures. Moreover, the study was unable to associate malrotation with patient important outcomes or gait abnormalities. This clearly leaves much uncertainty surrounding optimal patient positioning during the definitive treatment of these critical injuries. Proponents of positioning femoral shaft fracture patients using SFT argue that the fracture table provides a constant traction force to stabilize the fractured limb and allows for better intraoperative imaging. This arguably allows surgeons to reduce operative time and minimize the need for surgical assistants. However, possible downsides of this technique include the need for more invasive surgical adjuncts if there is ongoing difficulty with fracture reduction. Furthermore, constant and prolonged traction poses known risks to neurovascular structures associated with the central post, and may overpower feedback from the natural resting tone of the surrounding thigh musculature, possibly leading to a higher incidence of fixation in a malrotated position. Additionally, fracture tables are expensive and require additional setup in the operating room prior to the procedure. Orthopedic surgeons who prefer the LRT believe it offers improved access to the start point for IMN as well as to the rest of the femur for manipulation, resulting in a better reduction of the fractured limb. With the entire limb free of traction, the thigh sits in a relatively adducted position at rest and the soft tissues tend to fall away from the operative field. The fracture fragments can be readily accessed and freely manipulated, with muscles returning to their resting tension as alignment is restored. It is believed that this leads to leads to improved limb alignment and less malrotation. Furthermore, there may be benefits to the overall patient, many of whom have other severe injuries that may also be impacted by intraoperative positioning. A recent cohort study, which was adjusted for associated injuries, found that patients treated using the LRT had shorter ICU stays and reduced number of days on a ventilator, indicating that there may be a protective effect from a respiratory standpoint. Additionally, the standard operating room table is readily available, less expense, and does not require additional setup prior to the procedure. However, there are concerns that lateral positioning may lead to longer operative times as additional positioning aids and reduction maneuvers may be required. Specifically, patients receiving delayed fixation may pose a challenge due to increased muscle shortening and tone that may be difficult to overcome with manual traction alone. Limited previous studies align with biomechanical principles, and suggest that lateral positioning holds potential to reduce the incidence of femoral malrotation and avoid complications associated with the use of a fracture table; leading to improved patient function. Addressing malrotation by using the LRT may represent a simple and reproducible intervention that may improve quality of life for the patient. NEED FOR A TRIAL Currently, the choice between the two techniques is dependent on surgeon preference, with very limited evidence to guide decision making. A large definitive trial is needed to answer this question and allow orthopaedic surgeons to make an evidence-based decision on how to treat patients with femoral shaft fractures, while reducing the incidence of malrotation and improving patient outcomes. Prior to embarking on a large definitive cluster randomized crossover trial (CRXO), a pilot study is needed to demonstrate feasibility. A pilot study would assess areas of uncertainty that may impact feasibility to perform the definitive trial, including achieving adequate recruitment, adherence to protocol, and minimal contamination.
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
TREATMENT
Masking
TRIPLE
Enrollment
100
Antegrade femoral nailing in Supine Position using a Fracture Table
Antegrade femoral nailing in Lateral Position using a Free drape
McMaster University
Hamilton, Ontario, Canada
RECRUITINGOttawa Civic Hospital
Ottawa, Ontario, Canada
RECRUITINGVall d'Hebron University Hospital
Barcelona, Spain
RECRUITINGFeasibility to conduct definitive Clinical Trial
Our primary outcome for the pilot trial is feasibility, which includes the following: * Recruitment (number of participants recruited across all sites over study period, goal of approximately 100 participants) * Cluster crossover randomization protocol adherence * Complete primary outcome collection (CT scans) on all enrolled patients. * Participant retention and follow-up data * Accuracy of 15 degrees as a cut off for malrotation
Time frame: Six Months
Postoperative femur alignment
Immediate (within 6 weeks of surgery) post-operative bilateral computer tomography (CT scan) of the operated patients' lower extremity will be obtained as per standard of care. Postoperative bilateral CT scans for femoral shaft fractures represents the standard of care across academic centres(13). A physician familiar with musculoskeletal imaging, who is blinded to treatment allocation, will evaluate every CT for each participant. The best available literature defines clinically significant malrotation as more than 15 degrees difference from the contralateral limb in either internal or external rotation (
Time frame: Within 6 weeks of injury
Health Related Quality of Life
Health-related quality of life will be assessed with the EQ-5D. The EQ-5D (27) questionnaire will be completed by participants at the time of consent and will ask about their pre-injury health status, as well as health status at the six weeks, three and six months follow up visits. The EQ-5D score represents patient reported health-related quality of life in five domains. The EQ-5D may be administered in person, over the telephone, standard mail, or electronically.
Time frame: up to 6 months
Modified Harris Hip Score
The modified Harris Hip Score is a limb specific functional score, which has been validated for use in other orthopedic populations, including those with total joint arthroplasty and hip fractures. The questionnaire will be completed by participants at each follow up appoints. The mHHS may be administered in person, electronically or by telephone.
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Time frame: up to 6 months
Operative Time, Fluoroscopy Time
Operative time will be defined as the time from induction of anaesthetic and ending once the patient has procedural wounds closed, documented through operative room records. Fluoroscopy time is defined as the total time that fluoroscopy is used and is recorded on the C-Arm used for intraoperative imaging. • The pain is in the study extremity * The pain began after surgery * The pain has persisted for at least three months after surgery * The pain is not better explained by an infection, malignancy, a pre-existing pain condition or any other alternative cause (as judged by the treating surgeon) * The severity of pain must be at least 4 on an 11-point NRS for average pain in the past week
Time frame: At time of Surgery
Need for Open Reduction
Need for open reduction is defined as any secondary incision at the fracture site \>5 cm. This incision facilitates open reduction and is viewed as a surrogate measure of difficulty achieving the appropriate reduction using closed manipulation.
Time frame: At time of Surgery
Use of Reduction Adjuncts
Use of additional reduction adjuncts is defined as use of less invasive reduction aids (e.g. reduction clamps, joystick pins, F tool, and femoral distractor) not requiring a secondary incision (\>5cm) at the fracture site
Time frame: At time of Surgery
Operative Table Complications
Standard operative table and fracture table complications include all potential neurological injuries (e.g. pudendal, peroneal and femoral nerve palsies, etc.) and skin injuries (e.g. skin blisters, ulceration, and skin tears, etc.) derived from use of the traction boot apparatus. These will also be documented in the medical record as per standard of care. Complications will be adjudicated by a blinded member of the study team, familiar with both the injury and nature of the operation.
Time frame: At time of Surgery, Up to 6 months
Length of Hospital, ICU Stay
Length of hospital stay will be defined as days from admission until the day of discharge to either home, rehabilitation care, or long-term care support. Days in ICU will be recorded according to medical records.
Time frame: At initial admission
Days of Ventilator Support
Days of ventilator support will be defined as discrete days spent receiving any form of positive pressure ventilation, including BiPAP while extubated.
Time frame: At initial admission