Refixation of a Large Osteochondral Fragment with Magnesium Compression Screws-A Case Report

Overview

Journal Life (Basel)

Specialty Biology

Date 2023 May 27

PMID 37240824

Authors

Adrian Deichsel

Lucas Klaus Palma Kries

Michael J Raschke

Christian Peez

Thorben Briese

Johannes Glasbrenner

Elmar Herbst

Christoph Kittl

Affiliations

Soon will be listed here.

Abstract

Introduction: Osteochondrosis dissecans (OCD) is a disease affecting the subchondral bone and the overlying articular cartilage. The etiology is most likely a combination of biological and mechanical factors. The incidence is highest in children >12 years old and it predominantly affects the knee. In high-grade OCD lesions, free osteochondral fragments usually are refixed via titanium screws or biodegradable screws or pins. In this case, headless compression screws made from magnesium were used for refixation.

Case Report: A thirteen-year-old female patient with a two-year history of knee pain was diagnosed with an OCD lesion of the medial femoral condyle. After initial conservative treatment, displacement of the osteochondral fragment occurred. Refixation was performed using two headless magnesium compression screws. At the 6 months follow up, the patient was pain free, and the fragment showed progressive healing while the implants were biodegrading.

Discussion: Existing implants for refixation of OCD lesions either require subsequent removal or show less stability and possible inflammatory reactions. The new generation of magnesium screws used in this case did not lead to a gas release, as described for previous magnesium implants, while maintaining stability during continuous biodegradation.

Conclusions: The data available to date on magnesium implants for the treatment of OCD are promising. However, the evidence on the magnesium implants in refixation surgery of OCD lesions is still limited. Further research needs to be conducted to provide data on outcomes and possible complications.

Citing Articles

The Biological Effects of Magnesium-Based Implants on the Skeleton and Their Clinical Implications in Orthopedic Trauma Surgery.

Muller E, Schoberwalter T, Mader K, Seitz J, Kopp A, Baranowsky A Biomater Res. 2024; 28:0122.

PMID: 39717475 PMC: 11665827. DOI: 10.34133/bmr.0122.

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