Hybrid external fixation of distal tibial fractures

New strategy to place pins and wires without penetrating the anterior compartment

Jong-Keon Oh, Jeong Joon Lee, Duk Young Jung, Bong Ju Kim, Chang Wug Oh

Research output: Contribution to journalArticle

8 Citations (Scopus)

Abstract

Introduction: Impalement of the anterior compartment musculature remains a problem in the hybrid external fixation of distal tibial fractures. The purposes of this study were to develop a tensioned wire configuration which does not violate the anterior compartment and to analyze the biomechanical implications of new wire configuration. Mater ials and methods: Thirty-seven adult volunteers without known pathology around either tibia were recruited. Axial computed tomography of the distal tibia was performed at 5-mm slices from the plafond to the upper margin of the syndesmosis. The wire convergence angle was measured at the 1-, 2-, and 2.5-cm levels using the following landmarks: tibialis anterior tendon (TA), tibialis posterior tendon (TP), peroneus brevis tendon (PB), anterolateral border of the lateral malleolus (LM). Two straight lines were drawn by connecting TA and PB and connecting TP and LM. The wire convergence angle was defined as an acute angle between these two lines. Then the orientation of the bisector axis of the wires was measured. As a second part of this study, a validated three-dimensional hybrid external fixator model was developed using finite elements modeling to analyze the stiffness of the frames constructed according to the measured wire convergence angle and orientation. Five simulated configurations were tested. The stiffness of each frame was analyzed under four load conditions: torsion, axial compression, side bending, and anteroposterior bending. Results: The me an convergence angle was 30° irrespective of the level. The bisector axis was oriented towards the anterolateral direction about 20° from the coronal plane. The stiffness of the frame constructed with a wire convergence angle of 30° and an anterolateral wire orientation of 20° was 20-30% less than that of the frame constructed with 60° wires oriented in a coronal plane. The addition of an anteromedial half-pin increased the stiffness significantly. Conclusions: Two tensio ned wires may be placed without violating the anterior compartment by using the above four clinically identifiable landmarks. Addition of a half-pin on the anteromedial surface of the distal articular fragment makes the frame markedly stiffer than is possible using the standard wire configuration.

Original languageEnglish
Pages (from-to)542-546
Number of pages5
JournalArchives of Orthopaedic and Trauma Surgery
Volume124
Issue number8
DOIs
Publication statusPublished - 2004 Oct 1
Externally publishedYes

Fingerprint

Tibial Fractures
Tendons
Tibia
External Fixators
Volunteers
Joints
Tomography
Mothers
Pathology

Keywords

  • Distal tibial fractures
  • Finite elements modeling
  • Hybrid external fixation
  • Impalement
  • Wire convergence angle

ASJC Scopus subject areas

  • Surgery
  • Orthopedics and Sports Medicine

Cite this

Hybrid external fixation of distal tibial fractures : New strategy to place pins and wires without penetrating the anterior compartment. / Oh, Jong-Keon; Lee, Jeong Joon; Jung, Duk Young; Kim, Bong Ju; Oh, Chang Wug.

In: Archives of Orthopaedic and Trauma Surgery, Vol. 124, No. 8, 01.10.2004, p. 542-546.

Research output: Contribution to journalArticle

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title = "Hybrid external fixation of distal tibial fractures: New strategy to place pins and wires without penetrating the anterior compartment",
abstract = "Introduction: Impalement of the anterior compartment musculature remains a problem in the hybrid external fixation of distal tibial fractures. The purposes of this study were to develop a tensioned wire configuration which does not violate the anterior compartment and to analyze the biomechanical implications of new wire configuration. Mater ials and methods: Thirty-seven adult volunteers without known pathology around either tibia were recruited. Axial computed tomography of the distal tibia was performed at 5-mm slices from the plafond to the upper margin of the syndesmosis. The wire convergence angle was measured at the 1-, 2-, and 2.5-cm levels using the following landmarks: tibialis anterior tendon (TA), tibialis posterior tendon (TP), peroneus brevis tendon (PB), anterolateral border of the lateral malleolus (LM). Two straight lines were drawn by connecting TA and PB and connecting TP and LM. The wire convergence angle was defined as an acute angle between these two lines. Then the orientation of the bisector axis of the wires was measured. As a second part of this study, a validated three-dimensional hybrid external fixator model was developed using finite elements modeling to analyze the stiffness of the frames constructed according to the measured wire convergence angle and orientation. Five simulated configurations were tested. The stiffness of each frame was analyzed under four load conditions: torsion, axial compression, side bending, and anteroposterior bending. Results: The me an convergence angle was 30° irrespective of the level. The bisector axis was oriented towards the anterolateral direction about 20° from the coronal plane. The stiffness of the frame constructed with a wire convergence angle of 30° and an anterolateral wire orientation of 20° was 20-30{\%} less than that of the frame constructed with 60° wires oriented in a coronal plane. The addition of an anteromedial half-pin increased the stiffness significantly. Conclusions: Two tensio ned wires may be placed without violating the anterior compartment by using the above four clinically identifiable landmarks. Addition of a half-pin on the anteromedial surface of the distal articular fragment makes the frame markedly stiffer than is possible using the standard wire configuration.",
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AU - Oh, Chang Wug

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N2 - Introduction: Impalement of the anterior compartment musculature remains a problem in the hybrid external fixation of distal tibial fractures. The purposes of this study were to develop a tensioned wire configuration which does not violate the anterior compartment and to analyze the biomechanical implications of new wire configuration. Mater ials and methods: Thirty-seven adult volunteers without known pathology around either tibia were recruited. Axial computed tomography of the distal tibia was performed at 5-mm slices from the plafond to the upper margin of the syndesmosis. The wire convergence angle was measured at the 1-, 2-, and 2.5-cm levels using the following landmarks: tibialis anterior tendon (TA), tibialis posterior tendon (TP), peroneus brevis tendon (PB), anterolateral border of the lateral malleolus (LM). Two straight lines were drawn by connecting TA and PB and connecting TP and LM. The wire convergence angle was defined as an acute angle between these two lines. Then the orientation of the bisector axis of the wires was measured. As a second part of this study, a validated three-dimensional hybrid external fixator model was developed using finite elements modeling to analyze the stiffness of the frames constructed according to the measured wire convergence angle and orientation. Five simulated configurations were tested. The stiffness of each frame was analyzed under four load conditions: torsion, axial compression, side bending, and anteroposterior bending. Results: The me an convergence angle was 30° irrespective of the level. The bisector axis was oriented towards the anterolateral direction about 20° from the coronal plane. The stiffness of the frame constructed with a wire convergence angle of 30° and an anterolateral wire orientation of 20° was 20-30% less than that of the frame constructed with 60° wires oriented in a coronal plane. The addition of an anteromedial half-pin increased the stiffness significantly. Conclusions: Two tensio ned wires may be placed without violating the anterior compartment by using the above four clinically identifiable landmarks. Addition of a half-pin on the anteromedial surface of the distal articular fragment makes the frame markedly stiffer than is possible using the standard wire configuration.

AB - Introduction: Impalement of the anterior compartment musculature remains a problem in the hybrid external fixation of distal tibial fractures. The purposes of this study were to develop a tensioned wire configuration which does not violate the anterior compartment and to analyze the biomechanical implications of new wire configuration. Mater ials and methods: Thirty-seven adult volunteers without known pathology around either tibia were recruited. Axial computed tomography of the distal tibia was performed at 5-mm slices from the plafond to the upper margin of the syndesmosis. The wire convergence angle was measured at the 1-, 2-, and 2.5-cm levels using the following landmarks: tibialis anterior tendon (TA), tibialis posterior tendon (TP), peroneus brevis tendon (PB), anterolateral border of the lateral malleolus (LM). Two straight lines were drawn by connecting TA and PB and connecting TP and LM. The wire convergence angle was defined as an acute angle between these two lines. Then the orientation of the bisector axis of the wires was measured. As a second part of this study, a validated three-dimensional hybrid external fixator model was developed using finite elements modeling to analyze the stiffness of the frames constructed according to the measured wire convergence angle and orientation. Five simulated configurations were tested. The stiffness of each frame was analyzed under four load conditions: torsion, axial compression, side bending, and anteroposterior bending. Results: The me an convergence angle was 30° irrespective of the level. The bisector axis was oriented towards the anterolateral direction about 20° from the coronal plane. The stiffness of the frame constructed with a wire convergence angle of 30° and an anterolateral wire orientation of 20° was 20-30% less than that of the frame constructed with 60° wires oriented in a coronal plane. The addition of an anteromedial half-pin increased the stiffness significantly. Conclusions: Two tensio ned wires may be placed without violating the anterior compartment by using the above four clinically identifiable landmarks. Addition of a half-pin on the anteromedial surface of the distal articular fragment makes the frame markedly stiffer than is possible using the standard wire configuration.

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