ABSTRACT
Aim:
Basicervical fractures of the femur are a unique type of unstable hip fracture, usually treated with sliding hip screw (SHS) or cephalomedullary nail (CMN). The aim of this randomized, prospective study was to evaluate the outcomes and complications of the two different treatment methods, SHS and CMN, in the management of basicervical fractures of the femur in the elderly osteoporotic bones.
Methods:
Patients aged over 65 years, who presented to our clinic with basicervical fracture of the femur between January 2016 and January 2018, were included in the study. The permuted block randomization method was used to randomize the participants into groups. The patients were allocated to one of two groups treated via CMN (n=29) or SHS (n=27). Functional and radiological evaluations included mobility score, Harris Hip score, modified Barthel index, Singh index, tip-apex distance, and fracture settling.
Results:
Continuous improvement in the Barthel index was seen over the 12-month period in either group (p<0.05). The average mobility score was found to be decreased at the 6th week follow-up visits in either group (p<0.05). The fracture settling measurements in SHS group was higher than in CMN group (p<0.01).
Conclusion:
The clinical and radiological outcomes of both CMN and SHS groups showed no superiority of one technique over the other in the treatment of basicervical fractures of the femur.
Introduction
Anatomically, basicervical fractures of the femur are intracapsular (1) but biomechanically, they are classified as extracapsular (2). Therefore, these fractures have been considered to be in the borderline category. However, clinically and biomechanically, these fractures behave like intertrochanteric hip fractures, which are usually treated with sliding hip screw (SHS) or cephalomedullary nail (CMN) instead of hemiarthroplasty (2-5).
Some studies have reported better results with the use of SHS in intertrochanteric fracture treatment and others have stated that CMN give better results (6-8). However, the current approach to the treatment of unstable intertrochanteric fractures is the use of CMN (9-11). It has been reported that basicervical fractures could also be evaluated as unstable fractures (12).
There are very little data in the literature regarding the comparison of clinical outcomes of CMN and SHS used in basicervical fractures of the femur (10). There have been several studies of the biomechanical properties of CMN and SHS, which have not shown any clear superiority of either implant in the treatment of these fractures (4,9,13). The objective of this randomized, prospective study was to evaluate the rate of basicervical fractures of the femur and to compare outcomes and complications of the two different treatment methods of SHS and CMN.
Methods
Study Design
Approval for the study was granted by the Local Ethics Review Board of Dr. Lütfi Kırdar Training and Research Hospital and all the procedures were performed in accordance with the principles of the Declaration of Helsinki (1964). The study was registered at ClinicalTrials.gov (NCT04240743). Patients with a basicervical femur fracture were identified on admission to the emergency department of our tertiary hospital from January 2016 to January 2018. Patients, who were scheduled for surgery, met the inclusion criteria and provided written informed consent, were included in the study.
The patients were randomly allocated to a study group by permuted blocks of randomly mixed sizes and stratification according to the type of surgery (CMN or SHS). Randomization was applied using pre-prepared randomization cards, which were placed in opaque, sealed envelopes and given to the surgeons to open just prior to surgery, and the designated procedure was then performed.
Preoperative Assessment
Eligible patients were prospectively enrolled over a two-year period. The inclusion criteria were a basicervical fracture, age ≥65 year, an isolated fracture, ability to walk independently (with or without an aid) before fracture, and a fracture that had occurred less than one week prior to admission. The exclusion criteria were a history of ipsilateral femoral fracture, a fracture due to malignancy, limited life expectancy due to medical comorbidities, any contraindication to surgery, diagnosed dementia, or any other traumatic fracture on admission.
Surgical Procedure
Closed reduction of the fracture was performed under fluoroscopic guidance on a traction table. Then the relevant surgical procedure was applied for implantation of CMN or SHS. Two senior surgeons (E.E, G.B.) with more than 10 years of surgical experience in treating basicervical fractures of the femur were familiar with both surgical techniques.
Cephalomedullary Nail Technique
For patients in the CMN group (Figure 1), an incision was made in the gluteal area from the tip of the greater trochanter in proximal orientation. A guidewire was placed into the medullary canal from slightly medial to the exact tip of the greater trochanter. The entry point of the greater trochanter and proximal medullary canal were reamed. The CMN was then inserted and fixed to the femoral head with a two lag screws. The nail was then locked distally using a guide arm. These CMNs were not locked proximally to maintain dynamization and to allow compression across the basicervical fracture line. In this study, all patients were treated with short nails (Profin®, TST).
Sliding Hip Screw Technique
For patients in the SHS group (Figure 2), a lateral incision was made over the lateral proximal aspect of the femur. Under fluoroscopic guidance, the lag screw was placed centrally in the femoral head over the guidewire. A side plate with three holes was then attached to the hip screw (DHS plate, TST).
Postoperative Follow-up
Postoperatively, all patients were allowed immediate weight-bearing as tolerated, regardless of the method of fixation. All patients were followed up clinically and radiologically for a period of 12 months. The clinical and radiological evaluations were performed immediately postoperatively, then at 6 weeks, 3, 6 and 12 months.
Functional outcomes were evaluated with a Mobility score (range: 0-9) (14), and the Harris Hip score (15). Functional independence in daily living (10 basic activities of daily living) was evaluated with the modified Barthel index (range: 0-100) (16). The clinical follow-up evaluations were performed by two independent orthopaedic surgeons who had access to all the patients’ files and documents. They were also blinded to the preceded treatment.
The Singh index was used to grade preoperative osteoporosis in the contralateral proximal femur from anteroposterior (AP) radiographs (17,18). AP and lateral radiographs were evaluated for any change in implant position, using the tip-apex distance, and fracture settling (19,20). The quality of reduction was evaluated on the postoperative radiographs, and graded as good (<10˚ varus/valgus and/or ante- or retroversion), acceptable (5-10˚ varus/valgus and/or ante- or retroversion), or poor (>10˚ varus/valgus and/or ante-or retro- version) (21). The radiographic evaluation was performed by two different independent orthopaedic surgeons.
Data Management
The convenient clinical and radiological data were collected. The data were entered into a Microsoft Office Excel sheet. All participants in the study were assigned a four-digit number and the radiographs were placed in digital folders. No personal data on the individual patients was transmitted.
Statistical Analysis
The statistical analysis was performed using the SPSS for Windows (SPSS Inc, Chicago, Illinois). Odds ratios and means were compared between the groups, with 95% confidence intervals and a p value of less than 0.05 was considered statistically significant.
In order to calculate the sample size, a comparison of proportions method was used. A total sample size of 100 patients was calculated to show a difference on the order of 25% between the treatment groups at 12 months follow-up, with 80% power and 5% significance level. Twenty-five percent was the predicted difference in functional and radiological outcomes between the two fixation methods, and based on the previous unit data, an attrition rate of 10% was assumed.
Results
A total of 64 patients, who met the inclusion and exclusion criteria, and were willing to participate, were included in the study. The flow diagram of the study according to the Consolidated Standards of Reporting Trials 2010 is presented in Figure 3 (22). Registration in the study was terminated when the planned sample size was reached. Of the 64 patients, 32 were treated with SHS and 32 with CMN. Eight patients, who did not attend the 12-month follow-up examination, were excluded as clinical information was not available. The reasons for loss to follow-up were mortality in six (unrelated to hip surgery) and non-attendance at the final follow-up in two. Thus, final evaluation was made of 56 patients. Implant removal/revision surgery was not required in any patient during the study period.
The total 56 patients comprised 13 male and 14 female patients in the SHS group, and 15 male and 14 female patients in the CMN group, with a mean overall age of 80.75±7.54 years. The detailed distributions of preoperative features are given in Table 1.
The average tip-apex distance was 19.2 mm in the CMN group and 17.9 mm in the SHS group. A statistically significant difference was found between tip-apex distance measurements according to the implant type (p<0.05); the tip-apex distances in patients who underwent CMN were longer than in the SHS group. There was a loss of neck length (fracture settling) in both groups of average 10.6 mm in the SHS group and 6.7 mm in the CMN group. A statistically significant difference was found between the fracture settling measurements according to the implant type (p<0.01); the measurements of SHS were higher than those of CMN. Fracture settling was determined in the first 6 weeks postoperatively but not thereafter.
The average Singh grade was 4 in the SHS group and 3.9 in the CMN group. Moderate or poor quality of reduction was determined in 22.2% of patients in the SHS group and in 13.9% of patients in the CMN group.
The pre-fracture Modified Barthel index was 94.5 in the SHS group and 93.0 in the CMN group, with no significant difference determined between the groups. The index was applied at every visit. Continuous improvement in the Barthel index was seen over the 12-month period, but the index did not return to pre-fracture values in either group (p<0.05). No difference was determined in Barthel index values between the groups at any of the measured time points. The average mobility score decreased from 8.4 points to 6.0 in the SHS group and from 8.5 points to 7.1 in the CMN group at the 6th week follow-up visit. These values were considered statistically significant (p<0.05). The average Harris Hip score of all the patients was 70.59±9.50. The preoperative Harris score was regained in the post-operative 3rd month by 40% of patients and by 80% at the final follow-up (12 months). The detailed distributions of functional and radiological outcomes are given in Table 2.
In one patient of the SHS group, implant cut-out developed despite adequate initial reduction and implant position. No implant cut-out was seen in the CMN group. No surgery-related infections or wound complications developed in any patient in this study.
Discussion
Proximal femoral fractures are one of the most commonly treated conditions by orthopaedic trauma surgeons. However, one of the least encountered fractures is basicervical fracture. These relatively rare fractures account for 1.8%-3.5% of all proximal femur fractures (2,4,23). In a 2-year period, 2207 patients were treated for proximal femur fractures in our institution and only 2.9% (n=64) had real basicervical fractures. This finding is comparable with the data of previous studies.
Many implants have been used to reconstruct the hip anatomy after basicervical fractures (10,24-26). Fixation of basicervical fractures is difficult, because of the unique nature of the anatomy and the best fixation implants are probably fixed-angle implants, such as SHS and CMN (24,27).
For many types of hip fractures, SHS is the preferred implant. Some authors have stated that a basicervical fracture should be treated as an extra-capsular fracture and they have recommended osteosynthesis with SHS (26,28). However, others have suggested that SHS alone would not provide sufficient rotational stability and it would be necessary to apply a derotation screw (26,29). Saarenpää et al. (2) retrospectively reviewed 1624 hip fractures in an 8-year period and found 30 (1.8%) basicervical fractures, of which 16 were treated as intracapsular hip fractures and 14 as extracapsular. The authors reported that when treated with SHS (like an extracapsular hip fracture), better results were obtained than with hemiarthroplasty (like an intracapsular hip fracture). However, some authors have stated that basicervical fractures were unstable extracapsular fractures and could show good outcomes when treated with CMN (30,31).
Statistically, modified Barthel index, Mobility score and Harris Hip score would seem to be age- and time-dependent, independent of other parameters and implant type.
The results of this study showed that treatment with CMN (average fracture settling 6.7 mm) caused significantly less femoral neck shortening, with almost 5 mm more shortening in the SHS group (average fracture settling 10.6 mm). However, this finding was not significantly correlated with any functional impairment in this study. Reindl et al. (20) reported similar results for unstable intertrochanteric fractures in a comparison between CMN and SHS.
A serious complication of these fractures is implant cut-out, for reasons including low bone density, unstable fracture, and insufficient reduction (32). Although the average Singh index value was 3.98±1.23 in the current study patients, no serious collapse or complications were detected. Furthermore, no implant cut-out or protrusion occurred in any patient. There was no significant difference between the SHS and CMN groups in respect of the Singh index and fracture settling.
Early post-operative mobilization of patients after hip fractures is fundamental to enable a return to normal life and to prevent medical complications (33). All the patients in the current study were mobilized on postoperative day 1 and weight-bearing was allowed as tolerated. Although radiological fracture healing was seen at mean 10 weeks in all patients, clinical healing was achieved in mean 6 weeks. There were no cases of implant cut-out, peri-implant femur fracture, and no wound site infections, despite weight-bearing permitted in the early post-operative period.
Study Limitation
The main limitation of this study was the loss of study participants, primarily because of mortality of almost 10% (n=6/64) within the first year after hip fracture, and a further two patients did not attend the last 2 follow-up visits. Another important limitation was the limited number of patients that preclude any definite conclusions being made.
Conclusion
The results of the current study regarding basicervical fracture treatment do not clearly favor one implant over another. CMN resulted in significantly less shortening across the fracture site compared to SHS, but this did not show any significant difference in the extremity or general function as measured with the Harris Hip score, Barthel index and mobility score. It can be considered that basicervical fractures should be classified as unstable intertrochanteric fractures, not as femoral neck fractures, as in the AO classification, because of the implants used and the nature of the fracture in response to treatment.