A musculoskeletal model of the equine forelimb for determining surface stresses and strains in the humerus–part I. Mathematical modeling.
Abstract: Knowledge of the forces that act upon the equine humerus while the horse is standing and the resulting strains experienced by the bone is useful for the prevention and treatment of fractures and for assessing the proximolateral aspect of the bone as a site for obtaining autogenous bone graft material. The first objective was to develop a mathematical model to predict the loads on the proximal half of the humerus created by the surrounding musculature and ground reaction forces while the horse is standing. The second objective was to calculate surface bone stresses and strains at three cross sections on the humerus corresponding to the donor site for bone grafts, a site predisposed to stress fracture, and the middle of the diaphysis. A three-dimensional mathematical model employing optimization techniques and asymmetrical beam analysis was used to calculate shoulder muscle forces and surface strains on the proximal and mid-diaphyseal aspects of the humerus. The active shoulder muscles, which included the supraspinatus, infraspinatus, subscapularis, and short head of the deltoid, produced small forces while the horse is standing; all of which were limited to 4.3% of their corresponding maximum voluntary contraction. As a result, the strains calculated at the proximal cross sections of the humerus were small, with maximum compressive strains of -104microepsilon at the cranial aspect of the bone graft donor cross section. The middle of the diaphysis experienced larger strain magnitudes with compressive strains at the lateral and the caudal aspects and tensile strains at the medial and cranial aspects (-377microepsilon and 258microepsilon maximum values, respectively) while the horse is standing. Small strains at the donor bone graft site do not rule out using this location to harvest bone graft tissue, although strains while rising to a standing position during recovery from anesthesia are unknown. At the site common to stress fractures, small strains imply that the stresses seen by this region while the horse is standing, although applied for long periods of time, are not a cause of fracture in this location. Knowing the specific regions of the middle of the diaphysis of the humerus that experience tensile and compressive strains is valuable in determining optimum placement of internal fixation devices for the treatment of complete fractures.
Publication Date: 2008-07-08 PubMed ID: 18601448DOI: 10.1115/1.2898726Google Scholar: Lookup
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- Journal Article
- Research Support
- Non-U.S. Gov't
Summary
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This research paper focuses on creating a mathematical model to understand the forces acting on the skeleton of a horse’s forelimb (specifically the humerus), particularly when the horse is standing. The study helps predict muscle loads and stress points that inform hospital treatment, like proper placement of graft materials and fracture fixation devices.
Objectives of the Research
- The primary aim was to create a mathematical model that would predict the loads on the proximal half of a horse’s humerus, taking into account muscle and ground reaction forces when a horse is standing.
- The secondary aim was to determine the surface bone stresses and strains at three particular cross-sections of the humerus.
Research Method and Approach
- The researchers employed a three-dimensional mathematical model which used optimization techniques and asymmetrical beam analysis to calculate shoulder muscle forces and surface strains on the top and mid-diaphyseal aspects of the humerus.
- The study concentrated on the active shoulder muscles while the horse is standing. They included the supraspinatus, infraspinatus, subscapularis, and short head of the deltoid.
Research Findings
- The research found that the forces produced by active shoulder muscles while a horse is standing are small and limited to 4.3% of their maximum voluntary contraction.
- The study observed diminutive strains at the proximal cross sections of the humerus with maximum compressive strains at the cranial aspect of the bone graft donor cross-section.
- The mid-diaphysis region of the humerus experienced larger stress magnitudes with compressive strains and lateral and caudal aspects and tensile strains at the medial and cranial aspects.
Implications of the Research
- The research suggests that small strains at the bone graft donor site do not negate this location as a potential bone graft tissue harvest site.
- The observed small strains at the common stress fracture site indicate that the stresses this region experiences while a horse is standing do not cause fractures at this location.
- The study findings are valuable in determining the optimal placement of internal fixation devices for treating complete fractures by understanding the specific regions that experience tensile and compressive strains.
Cite This Article
APA
Pollock S, Hull ML, Stover SM, Galuppo LD.
(2008).
A musculoskeletal model of the equine forelimb for determining surface stresses and strains in the humerus–part I. Mathematical modeling.
J Biomech Eng, 130(4), 041006.
https://doi.org/10.1115/1.2898726 Publication
Researcher Affiliations
- Biomedical Engineering Program, University of California, One Shields Avenue, Davis, CA 95616, USA.
MeSH Terms
- Animals
- Computer Simulation
- Elasticity
- Forelimb / physiology
- Horses / physiology
- Humerus / physiology
- Models, Biological
- Muscle Contraction / physiology
- Muscle, Skeletal / physiology
- Postural Balance / physiology
- Posture / physiology
- Stress, Mechanical
- Surface Properties
Citations
This article has been cited 3 times.- Gozalo-Marcilla M, Ringer SK. Recovery after General Anaesthesia in Adult Horses: A Structured Summary of the Literature. Animals (Basel) 2021 Jun 14;11(6).
- Trumbull A, Subramanian G, Yildirim-Ayan E. Mechanoresponsive musculoskeletal tissue differentiation of adipose-derived stem cells. Biomed Eng Online 2016 Apr 22;15:43.
- Lang JJ, Li X, Micheler CM, Wilhelm NJ, Seidl F, Schwaiger BJ, Barnewitz D, von Eisenhart-Rothe R, Grosse CU, Burgkart R. Numerical evaluation of internal femur osteosynthesis based on a biomechanical model of the loading in the proximal equine hindlimb. BMC Vet Res 2024 May 10;20(1):188.
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