Experimental Evidence of Mechanical Isotropy in Porcine Lung Parenchyma

Weed, Benjamin; Patnaik, Sourav; Rougeau-Browning, Mary; Brazile, Bryn; Liao, Jun; Prabhu, Raj; Williams, Lakiesha

doi:10.3390/ma8052454

Title: Experimental Evidence of Mechanical Isotropy in Porcine Lung Parenchyma

Journal Article · Fri May 01 00:00:00 EDT 2015 · Materials

DOI:https://doi.org/10.3390/ma8052454· OSTI ID:1628448

Weed, Benjamin ^[1]; Patnaik, Sourav ^[1]; Rougeau-Browning, Mary ^[2]; Brazile, Bryn ^[1]; Liao, Jun ^[1]; Prabhu, Raj ^[1]; Williams, Lakiesha ^[1]

Mississippi State Univ., Starkville, MS (United States). Department of Agricultural and Biological Engineering
University of Georgia, Athens, GA 30602, (United States). Department of Genetics

Pulmonary injuries are a major source of morbidity and mortality associated with trauma. Trauma includes injuries associated with accidents and falls as well as blast injuries caused by explosives. The prevalence and mortality of these injuries has made research of pulmonary injury a major priority. Lungs have a complex structure, with multiple types of tissues necessary to allow successful respiration. The soft, porous parenchyma is the component of the lung which contains the alveoli responsible for gas exchange. Parenchyma is also the portion which is most susceptible to traumatic injury. Finite element simulations are an important tool for studying traumatic injury to the human body. These simulations rely on material properties to accurately recreate real world mechanical behaviors. Previous studies have explored the mechanical properties of lung tissues, specifically parenchyma. These studies have assumed material isotropy but, to our knowledge, no study has thoroughly tested and quantified this assumption. This study presents a novel methodology for assessing isotropy in a tissue, and applies these methods to porcine lung parenchyma. Briefly, lung parenchyma samples were dissected so as to be aligned with one of the three anatomical planes, sagittal, frontal, and transverse, and then subjected to compressive mechanical testing. Stress-strain curves from these tests were statistically compared by a novel method for differences in stresses and strains at percentages of the curve. Histological samples aligned with the anatomical planes were also examined by qualitative and quantitative methods to determine any differences in the microstructural morphology. Our study showed significant evidence to support the hypothesis that lung parenchyma behaves isotropically.

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Research Organization:: Mississippi State Univ., Starkville, MS (United States)

Sponsoring Organization:: USDOE National Nuclear Security Administration (NNSA)

Grant/Contract Number:: FC26-06NT42755

OSTI ID:: 1628448

Journal Information:: Materials, Vol. 8, Issue 5; ISSN 1996-1944

Publisher:: MDPICopyright Statement

Country of Publication:: United States

Language:: English

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