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Biomechanical Comparison of Zone 1 5th Metatarsal Base Fracture Fixation
CATEGORY: Basic Sciences/Biologics; Midfoot/Forefoot INTRODUCTION/PURPOSE: Zone 1 5th metatarsal base fractures are more common than zone 2 or 3 fractures, but significant debate still exists as to their optimum management, particularly for large fragments. The objective of this study was to compare...
Autores principales: | , , , , |
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Formato: | Online Artículo Texto |
Lenguaje: | English |
Publicado: |
SAGE Publications
2020
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Materias: | |
Acceso en línea: | https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8705169/ http://dx.doi.org/10.1177/2473011420S00121 |
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author | Bean, Bryan Smyth, Niall A. Abbasi, Pooyan Parks, Brent Hembree, Walter C. |
author_facet | Bean, Bryan Smyth, Niall A. Abbasi, Pooyan Parks, Brent Hembree, Walter C. |
author_sort | Bean, Bryan |
collection | PubMed |
description | CATEGORY: Basic Sciences/Biologics; Midfoot/Forefoot INTRODUCTION/PURPOSE: Zone 1 5th metatarsal base fractures are more common than zone 2 or 3 fractures, but significant debate still exists as to their optimum management, particularly for large fragments. The objective of this study was to compare the biomechanical strength of two headless compression screws versus a hook plate for fixation of large zone 1 5th metatarsal fractures. We hypothesized that hook plates would be biomechanically superior. METHODS: Ten matched pairs of fresh-frozen 5th metatarsal cadaveric specimens were used. Large zone 1 avulsion fractures were simulated. Specimens were randomly assigned to fixation with two 2.5-mm headless compression screws or an anatomic 5th metatarsal hook plate. Specimens were mounted on a test frame and cyclically loaded through the plantar fascia, peroneus brevis tendon, and metatarsal base. Each specimen underwent 100 cycles at 50% physiological load (12 N on bone, 70 N on plantar fascia, 17.5 N on peroneus brevis), 100 cycles at 75% load (18 N on bone, 105 N on fascia, 26.25 N on peroneus brevis), and 100 cycles at 100% load (24 N on bone, 140 N on fascia, 35 N on peroneus brevis). Maximum cycles and maximum force were recorded. RESULTS: The hook plate group had significantly higher cycles to completion of loading or failure compared with the screw group (270.7 +- 66.0 [range 100-300] cycles versus 178.6 +- 95.7 [range 24-300] cycles, respectively; P=0.011). Seven of 10 hook plate specimens and 2 of 10 screw specimens were intact at the maximum 300 cycles. Mean maximum force on the plantar fascia did not differ between the plate and screw groups (133.0 +- 22.1 [range 70-140]) N versus 119.0 +- 4.5 (range 70-140) N, respectively; P=0.098). Nine of 10 plate specimens and 5 of 10 screw specimens were intact at maximum force of 140 N. CONCLUSION: To our knowledge, this is the first biomechanical study comparing fixation constructs for 5th metatarsal avulsion fractures while loading the plantar fascia, which is the primary deforming force in vivo. These data suggest an anatomic hook plate is biomechanically superior to headless compression screw fixation of large zone 1 5th metatarsal avulsion fractures, which may prove pertinent in the setting of morbid obesity, fracture comminution, and/or fracture nonunion. Limitations include the relatively small sample size and the use of cadaveric bone which imperfectly mimics living tissue. |
format | Online Article Text |
id | pubmed-8705169 |
institution | National Center for Biotechnology Information |
language | English |
publishDate | 2020 |
publisher | SAGE Publications |
record_format | MEDLINE/PubMed |
spelling | pubmed-87051692022-01-28 Biomechanical Comparison of Zone 1 5th Metatarsal Base Fracture Fixation Bean, Bryan Smyth, Niall A. Abbasi, Pooyan Parks, Brent Hembree, Walter C. Foot Ankle Orthop Article CATEGORY: Basic Sciences/Biologics; Midfoot/Forefoot INTRODUCTION/PURPOSE: Zone 1 5th metatarsal base fractures are more common than zone 2 or 3 fractures, but significant debate still exists as to their optimum management, particularly for large fragments. The objective of this study was to compare the biomechanical strength of two headless compression screws versus a hook plate for fixation of large zone 1 5th metatarsal fractures. We hypothesized that hook plates would be biomechanically superior. METHODS: Ten matched pairs of fresh-frozen 5th metatarsal cadaveric specimens were used. Large zone 1 avulsion fractures were simulated. Specimens were randomly assigned to fixation with two 2.5-mm headless compression screws or an anatomic 5th metatarsal hook plate. Specimens were mounted on a test frame and cyclically loaded through the plantar fascia, peroneus brevis tendon, and metatarsal base. Each specimen underwent 100 cycles at 50% physiological load (12 N on bone, 70 N on plantar fascia, 17.5 N on peroneus brevis), 100 cycles at 75% load (18 N on bone, 105 N on fascia, 26.25 N on peroneus brevis), and 100 cycles at 100% load (24 N on bone, 140 N on fascia, 35 N on peroneus brevis). Maximum cycles and maximum force were recorded. RESULTS: The hook plate group had significantly higher cycles to completion of loading or failure compared with the screw group (270.7 +- 66.0 [range 100-300] cycles versus 178.6 +- 95.7 [range 24-300] cycles, respectively; P=0.011). Seven of 10 hook plate specimens and 2 of 10 screw specimens were intact at the maximum 300 cycles. Mean maximum force on the plantar fascia did not differ between the plate and screw groups (133.0 +- 22.1 [range 70-140]) N versus 119.0 +- 4.5 (range 70-140) N, respectively; P=0.098). Nine of 10 plate specimens and 5 of 10 screw specimens were intact at maximum force of 140 N. CONCLUSION: To our knowledge, this is the first biomechanical study comparing fixation constructs for 5th metatarsal avulsion fractures while loading the plantar fascia, which is the primary deforming force in vivo. These data suggest an anatomic hook plate is biomechanically superior to headless compression screw fixation of large zone 1 5th metatarsal avulsion fractures, which may prove pertinent in the setting of morbid obesity, fracture comminution, and/or fracture nonunion. Limitations include the relatively small sample size and the use of cadaveric bone which imperfectly mimics living tissue. SAGE Publications 2020-11-06 /pmc/articles/PMC8705169/ http://dx.doi.org/10.1177/2473011420S00121 Text en © The Author(s) 2020 https://creativecommons.org/licenses/by-nc/4.0/This article is distributed under the terms of the Creative Commons Attribution-NonCommercial 4.0 License (https://creativecommons.org/licenses/by-nc/4.0/) which permits non-commercial use, reproduction and distribution of the work without further permission provided the original work is attributed as specified on the SAGE and Open Access pages (https://us.sagepub.com/en-us/nam/open-access-at-sage). |
spellingShingle | Article Bean, Bryan Smyth, Niall A. Abbasi, Pooyan Parks, Brent Hembree, Walter C. Biomechanical Comparison of Zone 1 5th Metatarsal Base Fracture Fixation |
title | Biomechanical Comparison of Zone 1 5th Metatarsal Base Fracture Fixation |
title_full | Biomechanical Comparison of Zone 1 5th Metatarsal Base Fracture Fixation |
title_fullStr | Biomechanical Comparison of Zone 1 5th Metatarsal Base Fracture Fixation |
title_full_unstemmed | Biomechanical Comparison of Zone 1 5th Metatarsal Base Fracture Fixation |
title_short | Biomechanical Comparison of Zone 1 5th Metatarsal Base Fracture Fixation |
title_sort | biomechanical comparison of zone 1 5th metatarsal base fracture fixation |
topic | Article |
url | https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8705169/ http://dx.doi.org/10.1177/2473011420S00121 |
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