External rib structure can be predicted using mathematical models: An anatomical study with application to understanding fractures and intercostal muscle function

As ribs adapt to stress like all bones, and the chest behaves as a pressure vessel, the effect of stress on the ribs can be determined by measuring rib height and thickness. Rib height and thickness (depth) were measured using CT scans of seven rib cages from anonymized cadavers. A Finite Element An...

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Bibliographic Details
Published in:Clinical anatomy (New York, N.Y.) N.Y.), 2015-05, Vol.28 (4), p.512-519
Main Authors: Casha, Aaron R, Camilleri, Liberato, Manché, Alexander, Gatt, Ruben, Attard, Daphne, Gauci, Marilyn, Camilleri-Podesta, Marie-Therese, Grima, Joseph N.
Format: Article
Language:English
Subjects:
Anatomy
biomechanics
Bones
Cadavers
Cages
Chest
Children
Computed tomography
Environmental factors
Equator
Finite Element Analysis
Finite element method
Fractures
Humans
Imaging, Three-Dimensional
Intercostal Muscles - physiology
Laplace law
Mathematical analysis
Mathematical models
Mathematical morphology
Medical imaging
Models, Biological
Morphology
pressure vessel
Radiography
Rib
Rib Fractures - etiology
Ribs
Ribs (structural)
Ribs - anatomy & histology
Ribs - diagnostic imaging
Ribs - physiology
Statistical analysis
Statistical significance
Stress, Mechanical
Stresses
Vectors (mathematics)
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Summary:As ribs adapt to stress like all bones, and the chest behaves as a pressure vessel, the effect of stress on the ribs can be determined by measuring rib height and thickness. Rib height and thickness (depth) were measured using CT scans of seven rib cages from anonymized cadavers. A Finite Element Analysis (FEA) model of a rib cage was constructed using a validated approach and used to calculate intramuscular forces as the vectors of both circumferential and axial chest wall forces at right angles to the ribs. Nonlinear quadratic models were used to relate rib height and rib thickness to rib level, and intercostal muscle force to vector stress. Intercostal muscle force was also related to vector stress using Pearson correlation. For comparison, rib height and thickness were measured on CT scans of children. Rib height increased with rib level, increasing by 13% between the 3rd and 7th rib levels, where the 7th/8th rib was the widest part or “equator” of the rib cage, P 
ISSN:0897-3806
1098-2353
DOI:10.1002/ca.22513