Does the extent of prebending affect the stability of femoral shaft fractures stabilized by titanium elastic nails? A biomechanical investigation on an adolescent femur model

Novel Management of a Femoral Fracture in Klippel-Trenaunay Syndrome

Klippel-Trenaunay syndrome (KTS) is a rare congenital disorder with a clinical triad of capillary malformations, vascular abnormalities, and bone/soft tissue hypertrophy. This is the first case of closed femoral shaft fracture in a patient with KTS managed by flexible intramedullary nails.

A 34-year-old patient sustained a right femoral mid-shaft spiral fracture after slipping on the grass. Due to a very narrow femur and large venous malformations, nail or plate fixation was impossible. Surgery was conducted using flexible intramedullary (TENS) nails with good reduction but significant bleeding which was controlled with tranexamic acid and CELOX. The patient required 4 units of red blood cells, 3 units of fresh frozen plasma, and 900 mL of cell saver intraoperatively with a further 2 units of RBC post-op. Fracture union was achieved 14 months after the initial fracture with additional pulsed ultrasound therapy.

Bleeding from vascular malformations during surgery makes operative management challenging in KTS patients. Previous studies have reported a variety of management strategies to achieve fracture fixation and union including IM nailing, plate fixation, and external fixators, but encountered significant bleeding of up to 10 units and 15 units, respectively. Ultrasound therapy has been utilized as a useful adjunct in lower limb fracture with delayed therapy.

Management of fractures in patients affected by KTS is extremely challenging despite extensive workup and planning to evaluate the optimal fixation method and explore strategies to reduce the risk of intra-operative bleeding. Management strategies should be tailored to the patient with close follow-up to assess fracture union.

Biomechanical comparison of proximal interlocking screw constructs in different subtrochanteric fracture models

BACKGROUND

Depending on the size of the proximal bone segment, either a standard locking construct or a recon locking construct can be used in intramedullary nailing for a subtrochanteric fracture. However, the most appropriate construct for a given size of proximal bone segment has not yet been determined. Therefore, this study aimed to identify the appropriate construct using biomechanical testing.

METHODS

Fourteen intramedullary nails for each locking construct (standard and recon) were inserted into 28 synthetic femurs. Fourteen subtrochanteric fracture models were developed by creating parallel defects (2 cm in size) 2 cm distal to the lower edge of the lesser trochanter (low fracture group), and 14 fracture models were developed with identical defects situated 1 cm distal to the lower edge of the lesser trochanter (high fracture group). An axial load experiment was conducted to measure the stiffness and failure load for each proximal interlocking screw construct.

RESULTS

There were no statistically significant differences in the stiffness and failure load between the locking constructs in the low fracture group. However, the stiffness and failure load were significantly greater for the recon locking construct than for the standard locking construct in the high fracture group.

CONCLUSION

The standard locking system allows for sufficient fixation strength when performing intramedullary nailing for subtrochanteric fractures located 2 cm distal to the lower edge of the lesser trochanter.

Quadruple Versus Double Flexible Intramedullary Nails to Treat Pediatric Distal-third Tibial Shaft Fractures: A Biomechanical Comparison

BACKGROUND

The vast majority of pediatric distal-third tibial shaft fractures can be treated with closed reduction and casting. If conservative measures fail, then these fractures are usually treated with 2 antegrade flexible intramedullary nails. A postoperative cast is usually applied because of the tenuous fixation of the 2 nails. Recent studies have described the use of 4 nails to increase the stability of the fixation, a technique that may preclude the need for postoperative casting. The purpose of this biomechanical study is to quantify the relative increase in stiffness and load to failure when using 4 versus 2 nails to surgically stabilize these fractures.

METHODS

Short, oblique osteotomies were created in the distal third of small fourth-generation tibial sawbones and stabilized with 2 (double) or 4 (quadruple) flexible intramedullary nails. After pilot testing, 5 models per fixation method were tested cyclically in axial compression, torsion, and 4-point bending in valgus and recurvatum. At the end of the study, each model was loaded to failure in valgus. Stiffness values were calculated, and yield points were recorded. The data were compared using Student's t tests. Results are presented as mean±SD. The level of significance was set at P≤0.05.

RESULTS

Stiffness in valgus 4-point bending was 624±231 and 336±162 N/mm in the quadruple-nail and double-nail groups, respectively (P=0.04). There were no statistically significant differences in any other mode of testing.

CONCLUSIONS

The quadruple-nail construct was almost 2 times as stiff as the double-nail construct in resisting valgus deformation. This provides biomechanical support for a previously published study describing the clinical success of this fixation construct.

External fixator-augmented flexible intramedullary nailing of an unstable pediatric femoral shaft fracture model: a biomechanical study

The objective of this study was to test the compressive strength and torsional stiffness provided by the addition of a two-pin external fixator to an unstable pediatric femoral shaft fracture model after being instrumented with flexible intramedullary nailing (FIMN), and to compare this to bridge plating and FIMN alone. A length-unstable oblique diaphyseal fracture was created in 15 pediatric sized small femur models. Fracture stabilization was achieved by three constructs: standard retrograde FIMN with two 3.5-mm titanium (Ti) nails (Group 1), FIMN augmented with a two-pin external fixator (Group 2), and a 4.5-mm bridge plate (Group 3). Groups I and II were tested in 10 cycles of axial rotation to 10° in both directions at 0.1 Hz under 36 kg of compression. Torsional stiffness was calculated. Compressive strength was calculated by applying an axial load of 5 mm/min until failure was encountered. Failure was defined as the force required to achieve 10° varus at the fracture site or shortening of 2 cm. Group II demonstrated a greater compressive strength compared to Group I (1067.32 N vs 453.49 N, P < 0.001). No significant difference in torsional stiffness was found between Groups I and II (0.45 vs 0.38 Nm/deg, P = 0.18). Group III showed superior compressive strength and rotational stiffness compared to Groups I and II. In an unstable pediatric femoral shaft fracture model, augmenting FIMN with a two-pin external fixator increased the compressive strength by 147%, but did not increase torsional stiffness. Bridge plating with a 4.5-mm plate provided superior compressive strength and torsional stiffness.

End caps prevent nail migration in elastic stable intramedullary nailing in paediatric femoral fractures: a biomechanical study using synthetic and cadaveric bones

End caps are intended to prevent nail migration (push-out) in elastic stable intramedullary nailing. The aim of this study was to investigate the force at failure with and without end caps, and whether different insertion angles of nails and end caps would alter that force at failure. Simulated oblique fractures of the diaphysis were created in 15 artificial paediatric femurs. Titanium Elastic Nails with end caps were inserted at angles of 45°, 55° and 65° in five specimens for each angle to create three study groups. Biomechanical testing was performed with axial compression until failure. An identical fracture was created in four small adult cadaveric femurs harvested from two donors (both female, aged 81 and 85 years, height 149 cm and 156 cm, respectively). All femurs were tested without and subsequently with end caps inserted at 45°. In the artificial femurs, maximum force was not significantly different between the three groups (p = 0.613). Push-out force was significantly higher in the cadaveric specimens with the use of end caps by an up to sixfold load increase (830 N, standard deviation (SD) 280 vs 150 N, SD 120, respectively; p = 0.007). These results indicate that the nail and end cap insertion angle can be varied within 20° without altering construct stability and that the risk of elastic stable intramedullary nailing push-out can be effectively reduced by the use of end caps.

Biomechanical comparison of semi-rigid pediatric locking nail versus titanium elastic nails in a femur fracture model

BACKGROUND

The treatment for length-unstable diaphyseal femur fractures among school-age children is commonly intramedullary elastic nails, with or without end caps. Another possible treatment is the semi-rigid pediatric locking nail (PLN). The purpose of this biomechanical study was to assess the stability of a length-unstable oblique midshaft fracture in a synthetic femur model stabilized with different combinations of intramedullary elastic nails and with a PLN.

METHODS

Twenty-four femur models with an intramedullary canal diameter of 10.0 mm were used. Three groups with various combinations of titanium elastic nails (TEN) with end caps and one group with a PLN were tested. An oblique midshaft fracture was created, and the models underwent compression, rotation, flexion/extension, and a varus/valgus test, with 50 and 100 % of the forces generated during walking in corresponding planes.

RESULTS

We present the results [median (range)] from 100 % loading during walking. In axial compression, the PLN was less shortened than the combination with two 4.0-mm TEN [by 4.4 (3.4-5.4) mm vs. 5.2 (4.8-6.6) mm, respectively; p = 0.030]. No difference was found in shortening between the PLN and the four 3.0-mm TEN [by 7.0 (3.3-8.4) mm; p = 0.065]. The two 3.0-mm TEN did not withstand the maximum shortening of 10.0 mm. In external rotation, the PLN rotated 12.0° (7.0-16.4°) while the TEN models displaced more than the maximum of 20.0°. No model withstood a maximal rotation of 20.0° internal rotation. In the four-point bending test, in the coronal and the sagittal plane, all combinations except the two 3.0-mm TEN in extension withstood the maximum angulation of 20.0°.

CONCLUSIONS

PLN provides the greatest stability in all planes compared to TEN models with end caps, even though the difference from the two 4.0-mm or four 3.0-mm TEN models was small.