Compressive and tensile mechanical properties of the porcine nasal septum

Dayeh, Ayman Al; Herring, Susan W.

doi:10.1016/j.jbiomech.2013.09.026

Cited by 12 publications

(17 citation statements)

References 37 publications

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“…Thus, a large range of values can be found in the literature for Young's modulus (0.5–564 MPa) of cartilage (e.g. [ 18 , 73 , 75 , 76 , 78 – 80 ]). Many values are derived from measurements under slow loading of unmineralized hyaline cartilage, but reported Young's modulus values are typically below 10 MPa (e.g.…”

Section: Methodsmentioning

confidence: 99%

The biomechanical role of the chondrocranium and sutures in a lizard cranium

Jones

Gröning

Dutel

et al. 2017

J. R. Soc. Interface.

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The role of soft tissues in skull biomechanics remains poorly understood. Not least, the chondrocranium, the portion of the braincase which persists as cartilage with varying degrees of mineralization. It also remains commonplace to overlook the biomechanical role of sutures despite evidence that they alter strain distribution. Here, we examine the role of both the sutures and the chondrocranium in the South American tegu lizard Salvator merianae. We use multi-body dynamics analysis (MDA) to provide realistic loading conditions for anterior and posterior unilateral biting and a detailed finite element model to examine strain magnitude and distribution. We find that strains within the chondrocranium are greatest during anterior biting and are primarily tensile; also that strain within the cranium is not greatly reduced by the presence of the chondrocranium unless it is given the same material properties as bone. This result contradicts previous suggestions that the anterior portion (the nasal septum) acts as a supporting structure. Inclusion of sutures to the cranium model not only increases overall strain magnitudes but also leads to a more complex distribution of tension and compression rather than that of a beam under sagittal bending.

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Section: Methodsmentioning

confidence: 99%

The biomechanical role of the chondrocranium and sutures in a lizard cranium

Jones

Gröning

Dutel

et al. 2017

J. R. Soc. Interface.

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“…To our knowledge, YS has never been tested in human nasal septal cartilage. 10 However, we believe that it is an important aspect of the nasal mechanics to understand. Most septal literature focuses on tensile strength, which is determined using the elastic modulus by Young, an intrinsic property of a material, although tensile strength does not provide any information on the limits of stress that the CNS can endure.…”

Section: Discussionmentioning

confidence: 99%

Yield Strength Testing in Human Cadaver Nasal Septal Cartilage and L-Strut Constructs

Liu

Messinger

Inman

2017

JAMA Facial Plast Surg

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IMPORTANCE To our knowledge, yield strength testing in human nasal septal cartilage has not been reported to date. An understanding of the basic mechanics of the nasal septum may help surgeons decide how much of an L-strut to preserve and how much grafting is needed. OBJECTIVES To determine the factors correlated with yield strength of the cartilaginous nasal septum and to explore the association between L-strut width and thickness in determining yield strength. DESIGN, SETTING, AND PARTICIPANTS In an anatomy laboratory, yield strength of rectangular pieces of fresh cadaver nasal septal cartilage was measured, and regression was performed to identify the factors correlated with yield strength. To measure yield strength in L-shaped models, 4 bonded paper L-struts models were constructed for every possible combination of the width and thickness, for a total of 240 models. Mathematical modeling using the resultant data with trend lines and surface fitting was performed to quantify the associations among L-strut width, thickness, and yield strength. The study dates were November 1, 2015, to April 1, 2016. MAIN OUTCOMES AND MEASURES The factors correlated with nasal cartilage yield strength and the associations among L-strut width, thickness, and yield strength in L-shaped models. RESULTS Among 95 cartilage pieces from 12 human cadavers (mean [SD] age, 67.7 [12.6] years) and 240 constructed L-strut models, L-strut thickness was the only factor correlated with nasal septal cartilage yield strength (coefficient for thickness, 5.54; 95% CI, 4.08-7.00; P < .001), with an adjusted R 2 correlation coefficient of 0.37. The mean (SD) yield strength R 2 varied with L-strut thickness exponentially (0.93 [0.06]) for set widths, and it varied with L-strut width linearly (0.82 [0.11]) or logarithmically (0.85 [0.17]) for set thicknesses. A 3-dimensional surface model of yield strength with L-strut width and thickness as variables was created using a 2-dimensional gaussian function (adjusted R 2 = 0.94). Estimated yield strengths were generated from the model to allow determination of the desired yield strength with different permutations of L-strut width and thickness. CONCLUSIONS AND RELEVANCE In this study of human cadaver nasal septal cartilage, L-strut thickness was significantly associated with yield strength. In a bonded paper L-strut model, L-strut thickness had a more important role in determining yield strength than L-strut width. Surgeons should consider the thickness of potential L-struts when determining the amount of cartilaginous septum to harvest and graft. LEVEL OF EVIDENCE NA.

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“…This behaviour can be correlated to the hydration degree of cartilages, which was observed to be frequency independent. It seems that the cartilage viscoelastic properties in unconfined compression are only triggered by the fluid mobility and structural interactions between reinforcing collagen and surrounding matrix gel [8,48,[67][68][69][70].…”

Section: Multi-frequency Tensile and Compressive Loading Of Nsmentioning

confidence: 99%

“…Tendons and ligaments, blood vessels, aortic valves, intervertebral discs, skin, and cartilage have been widely described in the literature from very early [1][2][3][4][5][6][7]. Cartilage is a resilient and viscoelastic tissue composed of specialized cells (chondrocytes) that is found in nose, ears, intervertebral discs, larynx, trachea, and thorax, as well as covering and protecting bones at the articular joints [8,9]. Due to its natural anisotropic organization, cartilage behaves differently in a variety of tensile and compressive modes [9][10][11][12].…”

Section: Introductionmentioning

confidence: 99%

Thermo-Mechanical Behaviour of Human Nasal Cartilage

et al. 2020

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The aim of this study was to undergo a comprehensive analysis of the thermo-mechanical properties of nasal cartilages for the future design of a composite polymeric material to be used in human nose reconstruction surgery. A thermal and dynamic mechanical analysis (DMA) in tension and compression modes within the ranges 1 to 20 Hz and 30 °C to 250 °C was performed on human nasal cartilage. Differential scanning calorimetry (DSC), as well as characterization of the nasal septum (NS), upper lateral cartilages (ULC), and lower lateral cartilages (LLC) reveals the different nature of the binding water inside the studied specimens. Three peaks at 60–80 °C, 100–130 °C, and 200 °C were attributed to melting of the crystalline region of collagen matrix, water evaporation, and the strongly bound non-interstitial water in the cartilage and composite specimens, respectively. Thermogravimetric analysis (TGA) showed that the degradation of cartilage, composite, and subcutaneous tissue of the NS, ULC, and LLC take place in three thermal events (~37 °C, ~189 °C, and ~290 °C) showing that cartilage releases more water and more rapidly than the subcutaneous tissue. The water content of nasal cartilage was estimated to be 42 wt %. The results of the DMA analyses demonstrated that tensile mode is ruled by flow-independent behaviour produced by the time-dependent deformability of the solid cartilage matrix that is strongly frequency-dependent, showing an unstable crystalline region between 80–180 °C, an amorphous region at around 120 °C, and a clear glass transition point at 200 °C (780 kJ/mol). Instead, the unconfined compressive mode is clearly ruled by a flow-dependent process caused by the frictional force of the interstitial fluid that flows within the cartilage matrix resulting in higher stiffness (from 12 MPa at 1 Hz to 16 MPa at 20 Hz in storage modulus). The outcomes of this study will support the development of an artificial material to mimic the thermo-mechanical behaviour of the natural cartilage of the human nose.

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Compressive and tensile mechanical properties of the porcine nasal septum

Cited by 12 publications

References 37 publications

The biomechanical role of the chondrocranium and sutures in a lizard cranium

The biomechanical role of the chondrocranium and sutures in a lizard cranium

Yield Strength Testing in Human Cadaver Nasal Septal Cartilage and L-Strut Constructs

Thermo-Mechanical Behaviour of Human Nasal Cartilage

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