A review of techniques for visualising soft tissue microstructure deformation and quantifying strain <i>Ex Vivo</i>

Disney, Catherine; Lee, Peter; Hoyland, Judith A.; Sherratt, Michael J.; Bay, Brian K.

doi:10.1111/jmi.12701

Cited by 38 publications

(32 citation statements)

References 120 publications

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“…A first possible solution to overcome this problem consists in selectively digesting a target protein from the vocal-fold tissue, as previously done in the case of arterial walls 44 . Another solution could be to use chemical markers able to track one specific fibrous protein 29 , 45 . Last, we were not able to properly analyse the morphology of individual ECM fibres: this challenging task could be achieved by further increasing the spatial resolution of the images 46 .…”

Section: Discussion and Concluding Remarksmentioning

confidence: 99%

3D multiscale imaging of human vocal folds using synchrotron X-ray microtomography in phase retrieval mode

Bailly¹,

Cochereau²,

Orgéas³

et al. 2018

Sci Rep

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Human vocal folds possess outstanding abilities to endure large, reversible deformations and to vibrate up to more than thousand cycles per second. This unique performance mainly results from their complex specific 3D and multiscale structure, which is very difficult to investigate experimentally and still presents challenges using either confocal microscopy, MRI or X-ray microtomography in absorption mode. To circumvent these difficulties, we used high-resolution synchrotron X-ray microtomography with phase retrieval and report the first ex vivo 3D images of human vocal-fold tissues at multiple scales. Various relevant descriptors of structure were extracted from the images: geometry of vocal folds at rest or in a stretched phonatory-like position, shape and size of their layered fibrous architectures, orientation, shape and size of the muscle fibres as well as the set of collagen and elastin fibre bundles constituting these layers. The developed methodology opens a promising insight into voice biomechanics, which will allow further assessment of the micromechanics of the vocal folds and their vibratory properties. This will then provide valuable guidelines for the design of new mimetic biomaterials for the next generation of artificial larynges.

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Section: Discussion and Concluding Remarksmentioning

confidence: 99%

3D multiscale imaging of human vocal folds using synchrotron X-ray microtomography in phase retrieval mode

Bailly¹,

Cochereau²,

Orgéas³

et al. 2018

Sci Rep

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“…Measurement of skin micromechanical properties currently requires the use of ex vivo techniques such as atomic force microscopy indentation. In the future, it may be possible to apply digital volume correlation approaches in combination with micro CT imaging to map 3D strain in skin biopsies . The 3D micro CT images of skin are reproduced with permission from the publishers of Newton et al…”

Section: Current State Of Knowledgementioning

confidence: 99%

How stiff is skin?

Graham

McConnell

Limbert

et al. 2019

Experimental Dermatology

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The measurement of the mechanical properties of skin (such as stiffness, extensibility and strength) is a key step in characterisation of both dermal ageing and disease mechanisms and in the assessment of tissue‐engineered skin replacements. However, the biomechanical terminology and plethora of mathematical analysis approaches can be daunting to those outside the field. As a consequence, mechanical studies are often inaccessible to a significant proportion of the intended audience. Furthermore, devices for the measurement of skin function in vivo generate relative values rather than formal mechanical measures, therefore limiting the ability to compare studies. In this viewpoint essay, we discuss key biomechanical concepts and the influence of technical and biological factors (including the nature of the testing apparatus, length scale, donor age and anatomical site) on measured mechanical properties such as stiffness. Having discussed the current state‐of‐the‐art in macro‐mechanical and micromechanical measuring techniques and in mathematical and computational modelling methods, we then make suggestions as to how these approaches, in combination with 3D X‐ray imaging and mechanics methods, may be adopted into a single strategy to characterise the mechanical behaviour of skin.

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“…Tools such as linear variable differential transformers (LVDTs) and strain gauges are widely used during materials testing but lack sufficient spatial resolution for this application [ 5 ]. Digital image correlation (DIC) improves on resolution, has been applied to biomechanical analysis [ 6 ] and is an established technique to measure deformation and quantify strain [ 7 ], yet it is still inherently limited to surface measurements.…”

Section: Introductionmentioning

confidence: 99%

Quantifying 3D Strain in Scaffold Implants for Regenerative Medicine

et al. 2020

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Regenerative medicine solutions require thoughtful design to elicit the intended biological response. This includes the biomechanical stimulus to generate an appropriate strain in the scaffold and surrounding tissue to drive cell lineage to the desired tissue. To provide appropriate strain on a local level, new generations of scaffolds often involve anisotropic spatially graded mechanical properties that cannot be characterised with traditional materials testing equipment. Volumetric examination is possible with three-dimensional (3D) imaging, in situ loading and digital volume correlation (DVC). Micro-CT and DVC were utilised in this study on two sizes of 3D-printed inorganic/organic hybrid scaffolds (n = 2 and n = 4) with a repeating homogenous structure intended for cartilage regeneration. Deformation was observed with a spatial resolution of under 200 µm whilst maintaining displacement random errors of 0.97 µm, strain systematic errors of 0.17% and strain random errors of 0.031%. Digital image correlation (DIC) provided an analysis of the external surfaces whilst DVC enabled localised strain concentrations to be examined throughout the full 3D volume. Strain values derived using DVC correlated well against manually calculated ground-truth measurements (R2 = 0.98, n = 8). The technique ensures the full 3D micro-mechanical environment experienced by cells is intimately considered, enabling future studies to further examine scaffold designs for regenerative medicine.

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A review of techniques for visualising soft tissue microstructure deformation and quantifying strain Ex Vivo

Cited by 38 publications

References 120 publications

3D multiscale imaging of human vocal folds using synchrotron X-ray microtomography in phase retrieval mode

3D multiscale imaging of human vocal folds using synchrotron X-ray microtomography in phase retrieval mode

How stiff is skin?

Quantifying 3D Strain in Scaffold Implants for Regenerative Medicine

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