Lateral cortical notching facilitates dynamization of proximal femoral nailing - A finite element analysis

Nico Hinz; Katrin Stacenko; Christian Lutz; Arndt-Peter Schulz; Robert Wendlandt

doi:10.1016/j.injury.2023.111009

Lateral cortical notching facilitates dynamization of proximal femoral nailing - A finite element analysis

Injury. 2023 Nov;54(11):111009. doi: 10.1016/j.injury.2023.111009. Epub 2023 Aug 23.

Authors

Nico Hinz¹, Katrin Stacenko², Christian Lutz², Arndt-Peter Schulz³, Robert Wendlandt⁴

Affiliations

¹ Department of Trauma Surgery, Orthopaedics and Sports Traumatology, BG Trauma Hospital Hamburg, Bergedorfer Strasse 10, Hamburg 21033, Germany. Electronic address: n.hinz@bgk-hamburg.de.
² Swemac Innovation (Germany) GmbH, Faulmannweg 5, Kiel 24148, Germany.
³ Department of Trauma Surgery, Orthopaedics and Sports Traumatology, BG Trauma Hospital Hamburg, Bergedorfer Strasse 10, Hamburg 21033, Germany; Medical Faculty, Universität zu Lübeck, Ratzeburger Allee 160, Lübeck 23562, Germany.
⁴ Medical Faculty, Universität zu Lübeck, Ratzeburger Allee 160, Lübeck 23562, Germany; Clinic for Orthopedics and Trauma Surgery, Laboratory for Biomechanics, University Medical Center Schleswig-Holstein, Ratzeburger Allee 160, Lübeck 23538, Germany.

PMID: 37643944
DOI: 10.1016/j.injury.2023.111009

Abstract

Introduction: Dynamization of proximal femoral nailing by removal of distal interlocking is one of the recommended treatment options for nonunions of femur fractures. However, in certain inter-/subtrochanteric fractures, gliding of the nail along the femoral shaft is blocked by lateral femoral cortical support of the lag screw. For these cases, Biber et al. proposed lateral cortical notching (LCN), in which the supporting lateral bone is removed. This study investigates the biomechanical effect of LCN on gliding of proximal femoral nailing and stress distribution at the bone/implant interface.

Materials and methods: In this finite element analysis a three-dimensional model of an unstable intertrochanteric fracture with proximal femoral nailing without distal interlocking was simulated using the FebioStudio software suite. To simulate LCN, the lag screw hole was lengthened to 15.34 mm at the lateral cortex. Displacement of the nail along the femoral shaft axis and von Mises stress distribution were compared between LCN model and standard implantation model.

Results: Displacement of the nail along the femoral shaft axis was higher in the LCN model than in the standard implantation model (0.48 mm vs. 0.07 mm). Highest von Mises stresses of 176-178 MPa at the implant and of 52-81 MPa at the proximal femur were detected. Maximum von Mises stresses of the implant were comparable at all sides, except for a reduced von Mises stress at the lateral inferior side in the LCN model (80 vs. 102 MPa). At the inferior lateral screw hole and the anterior/posterior lateral screw hole maximum von Mises stress was reduced in the LCN model (2 vs. 49 MPa and 52 vs. 81 MPa), whereas the maximum von Mises stress at the inferior medial screw hole was higher in the LCN model than in the standard implantation model (53 vs. 27 MPa).

Conclusions: Lateral cortical notching facilitates gliding of a distally dynamized proximal femoral nail along the femoral shaft axis in intertrochanteric fractures. Additionally, the lack of lateral cortical bone support at the lag screw reduces von Mises stress at the bone/implant interface and thus could lower the risk for implant breakage and peri‑implant fractures.

Keywords: Dynamization; Intertrochanteric fracture; Lateral cortical notching; Nonunion; Proximal femoral nailing.

MeSH terms

Biomechanical Phenomena
Bone Nails
Bone Screws
Femur / surgery
Finite Element Analysis
Fracture Fixation, Intramedullary* / methods
Hip Fractures* / surgery
Humans