Comparison of Time-Zero Primary Stability Between a Biodegradable Magnesium Bone Staple and Metal Bone Staples for Knee Ligament Fixation: A Biomechanical Study in a Porcine Model

Adrian Deichsel; Johannes Glasbrenner; Michael J Raschke; Matthias Klimek; Christian Peez; Thorben Briese; Elmar Herbst; Christoph Kittl

doi:10.1177/23259671241236783

Comparison of Time-Zero Primary Stability Between a Biodegradable Magnesium Bone Staple and Metal Bone Staples for Knee Ligament Fixation: A Biomechanical Study in a Porcine Model

Orthop J Sports Med. 2024 Mar 25;12(3):23259671241236783. doi: 10.1177/23259671241236783. eCollection 2024 Mar.

Authors

Adrian Deichsel¹, Johannes Glasbrenner¹, Michael J Raschke¹, Matthias Klimek¹, Christian Peez¹, Thorben Briese¹, Elmar Herbst¹, Christoph Kittl¹

Affiliation

¹ Department of Trauma, Hand and Reconstructive Surgery, University Hospital Münster, Münster, Germany.

Abstract

Background: Bone staples have been shown previously to be a viable modality for cortical tendon graft fixation in ligament knee surgery. However, soft tissue reactions have been reported, making implant removal necessary. Magnesium alloys are a promising material for biodegradable orthopaedic implants, with mechanical properties closely resembling those of human bone.

Purpose: To compare the primary stability of a biodegradable bone staple prototype made from magnesium to bone staples made from metal in the cortical fixation of tendon grafts during knee surgery.

Study design: Controlled laboratory study.

Methods: Primary stability of peripheral tendon graft fixation was assessed in a porcine model of medial collateral ligament reconstruction. Two commercially available metal bone staples (Richards fixation staple with spikes [Me1] and spiked ligament staple [Me2]) were compared with a magnesium bone staple prototype for soft tissue fixation. Primary stability was assessed using a uniaxial materials testing machine. Cyclic loading at 50 and 100 N was applied for 500 cycles each, followed by load-to-failure testing.

Results: After 500 cycles at 50 N, elongation was 1.5 ± 0.5 mm in the Me1 group, 1.9 ± 0.5 mm in the Me2 group, and 1.8 ± 0.4 mm in the magnesium group. After 1000 cycles of loading (500 cycles at 50 N and 500 at 100 N), elongation was 3.6 ± 0.9 mm in the Me1 group, 3.5 ± 0.6 mm in the Me2 group, and 4.1 ± 1.0 mm in the magnesium group. No significant differences regarding elongation were found between the groups. Load to failure was 352 ± 115 N in the Me1 group, 373 ± 77 N in the Me2 group, and 449 ± 92 N in the magnesium group, with no significant difference between the groups.

Conclusion: In this study, the magnesium bone staples provided appropriate time-zero biomechanical primary stability in comparison with metal bone staples and may therefore be a feasible alternative for cortical fixation of tendon grafts in knee surgery.

Clinical relevance: The biodegradability of magnesium bone staples would eliminate the need for later implant removal.

Keywords: biomechanics; bone staples; cortical fixation; ligament reconstruction; magnesium.