Shear wave elastography can assess the in-vivo nonlinear mechanical behavior of heel-pad

Chatzistergos, Panagiotis; Behforootan, Sara; Allan, David B.; Naemi, Roozbeh; Chockalingam, Nachiappan

doi:10.1016/j.jbiomech.2018.09.003

Cited by 22 publications

(24 citation statements)

References 31 publications

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“…In a study about spatial dependent mechanical properties of the heel pad using SWE, Young's modulus was not used considering the heterogeneity of the tissue (Lin et al, 2017). Thus, SWE should be used to assess the changes in stiffness of the tissue but not to quantify stiffness itself (Chatzistergos et al, 2018).…”

Section: Feasibility and Reproducibility Of 2d Swe In Canine Soft Tismentioning

confidence: 99%

Two-Dimensional Shear Wave Elastography of Normal Soft Tissue Organs in Adult Beagle Dogs; Interobserver Agreement and Sources of Variability

Jung

Lee

et al. 2020

Front. Bioeng. Biotechnol.

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Shear wave elastography (SWE) induces lateral shear wave through acoustic pulses of the transducer and evaluates tissue stiffness quantitatively. This study was performed to evaluate feasibility and reproducibility of two-dimensional shear wave elastography (2D SWE) for evaluation of tissue stiffness and to examine technical factors that affect shear wave speed (SWS) measurements in adult dogs. Nine healthy, 2 yearold, adult beagles with the median weight of 9.8 kg were included. In this prospective, experimental, exploratory study, 2D SWE (Aplio 600) from the liver, spleen, kidneys, pancreas, prostate, lymph nodes (submandibular, retropharyngeal, axillary, medial iliac, and inguinal), submandibular salivary gland, and thyroid was performed in anesthetized beagles. Color map was drawn and SWS of each SWE were measured as Young's modulus (kPa) and shear wave velocity (m/s). The effect of measuring site, scan approach, depth, and anesthesia on SWE was assessed in abdominal organs by two observers independently. A total of 27 SWE examinations were performed in 12 organs by each observer. All SWS measurements were preformed successfully; however, SWE in the renal medulla could not be successfully conducted, and it was excluded from further analysis. Interobserver agreement of SWE was moderate to excellent in all organs, except for the left liver lobe at 10-15 mm depth with the intercostal scan. In the liver, there was no significant effect of the measuring site and scan approach on SWE. SWS of the liver and spleen tended to be higher with increasing the depth, but no significant difference. However, anesthesia significantly increased tissue stiffness in the spleen compared to awake dog regardless of the depth (P < 0.05). There was a significant difference in SWS according to the measuring site in the kidneys and pancreas (P < 0.001). 2D SWE was feasible and highly reproducible for the estimation of tissue stiffness in dogs. Measuring site and anesthesia are sources of variability affecting SWE in abdominal organs. Therefore, these factors should be considered during SWS measurement in 2D SWE. This study provides basic data for further studies on 2D SWE on pathological conditions that may increase tissue stiffness in dogs.

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Section: Feasibility and Reproducibility Of 2d Swe In Canine Soft Tismentioning

confidence: 99%

Two-Dimensional Shear Wave Elastography of Normal Soft Tissue Organs in Adult Beagle Dogs; Interobserver Agreement and Sources of Variability

Jung

Lee

et al. 2020

Front. Bioeng. Biotechnol.

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“…Localised stiffening was assessed by measuring changes in the distribution of SW propagation speed in an axial imaging plane at the centre of the heel (Figure 1a). Previous research from the authors of this study had shown that increased or decreased SW speed in the plantar soft tissue is a reliable indicator for tissue stiffening or softening respectively 4 . To precondition the plantar soft tissue and eliminate the effect of loading history, the participants were asked to walk barefoot the length of the lab twice before imaging (≈80 steps).…”

Section: Resultsmentioning

confidence: 73%

“…In this study, changes in tissue biomechanics were assessed in 5mm wide circular areas close to the skin surface (Figure 1c-e). The effect of overloading in deeper tissues was not assessed because SW elastography cannot produce reliable measurements close to bony surfaces 4,5 . The use of alternative elastography techniques could enable the investigation of the effect of overloading on different plantar soft tissue layers 19 .…”

Section: Discussionmentioning

confidence: 99%

“…To ensure no compression was applied to the tissue during imaging, special care was taken to always maintain a visible layer of ultrasound gel between the probe and skin. This was necessary to avoid any misleading increase in SW speed due to externally applied compression 4 . The probe was kept in the same position for at least 10 seconds or until a stable SW map was achieved before capturing a frame for analysis.…”

Section: Sw Imagingmentioning

confidence: 99%

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An In-Vivo Model For Overloading-Induced Soft Tissue Injury

Chatzistergos

Chockalingam

2021

Preprint

Self Cite

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This proof-of-concept study demonstrates that repetitive loading to the pain threshold can safely recreate overloading-induced soft tissue damage and that localised tissue stiffening can be used as a marker for injury. This concept was demonstrated here for the soft tissue of the sole of the foot where it was found that repeated loading to the pain threshold led to long-lasting statistically significant stiffening in the areas where pressure was most intense. Loading at lower magnitudes did not have the same effect. This method can shed new light on the aetiology of overloading injury in the foot to improve the management of conditions such as diabetic foot ulceration and heel pain syndrome. At the same time, the presented concept can also enable the direct assessment of subject-specific thresholds for overloading in other soft tissues which are sensitive to pain, accessible for imaging and can be loaded in a clinically relevant manner.

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“…The nonlinear behaviour of tissue causes errors in the measurements made since, in most clinical settings, the pressure from ultrasound probes is unregulated. This phenomenon, known as “tissue stiffening” or “strain stiffening”, is present in most soft tissues, for example, breast tissue [ 11 ], heel pad [ 12 , 13 ], calf muscle [ 14 ] and thyroid gland [ 15 ]. The occurrence of tissue stiffening is especially detrimental for cervical elastography as the probe is in direct contact with the tissue, and the shape of the probe causes non-uniform deformation [ 16 ].…”

Section: Introductionmentioning

confidence: 99%

Measured Hyperelastic Properties of Cervical Tissue with Shear-Wave Elastography

Brooker

Mogra

et al. 2021

Sensors

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The nonlinear mechanical behaviour of cervical tissue causes unpredictable changes in measured elastograms when pressure is applied. These uncontrolled variables prevent the reliable measurement of tissue elasticity in a clinical setting. Measuring the nonlinear properties of tissue is difficult due to the need for both shear modulus and strain to be taken simultaneously. A simulation-based method is proposed in this paper to resolve this. This study describes the nonlinear behaviour of cervical tissue using the hyperelastic material models of Demiray–Fung and Veronda–Westmann. Elastograms from 33 low-risk patients between 18 and 22 weeks gestation were obtained. The average measured properties of the hyperelastic material models are: Demiray–Fung—A1α = 2.07 (1.65–2.58) kPa, α = 6.74 (4.07–19.55); Veronda–Westmann—C1C2 = 4.12 (3.24–5.04) kPa, C2 = 4.86 (2.86–14.28). The Demiray–Fung and Veronda–Westmann models performed similarly in fitting to the elastograms with an average root mean square deviation of 0.41 and 0.47 ms−1, respectively. The use of hyperelastic material models to calibrate shear-wave speed measurements improved the consistency of measurements. This method could be applied in a large-scale clinical setting but requires updated models and higher data resolution.

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Shear wave elastography can assess the in-vivo nonlinear mechanical behavior of heel-pad

Cited by 22 publications

References 31 publications

Two-Dimensional Shear Wave Elastography of Normal Soft Tissue Organs in Adult Beagle Dogs; Interobserver Agreement and Sources of Variability

Two-Dimensional Shear Wave Elastography of Normal Soft Tissue Organs in Adult Beagle Dogs; Interobserver Agreement and Sources of Variability

An In-Vivo Model For Overloading-Induced Soft Tissue Injury

Measured Hyperelastic Properties of Cervical Tissue with Shear-Wave Elastography

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