The Effect of High Voltage, High Frequency Pulsed Electric Field on Slain Ovine Cortical Bone

Asgarifar, Hajarossadat; Oloyede, Adekunle; Zare, Firuz

doi:10.4103/2228-7477.130470

Cited by 6 publications

(4 citation statements)

References 31 publications

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“…For the purpose of the equivalent circuit modeling, the cortical bones can be assumed to exhibit mostly a resistive behavior and that the bone/electrode phase boundaries result in the appearance of an interfacial capacitance, uncharacteristic of bulk bone tissue ( Bauerle, 1969 ; Mercanzini et al, 2009 ; Jiang et al, 2016 ). Furthermore, since the cortical bone samples under study are mostly composed of an inorganic phase, which exhibits low relative permittivity <10, the capacitive behavior of the samples can be neglected for simplicity ( Asgarifar, 2012 ). Apart from the capacitive behavior at the bone-electrode interface, which is typically seen at lower frequencies (<100 kHz), another capacitive contribution to the impedance spectra could result from the stray capacitance of the measurement system at higher frequencies (>100 kHz).…”

Section: Discussionmentioning

confidence: 99%

Non-destructive characterization of bone mineral content by machine learning-assisted electrochemical impedance spectroscopy

Banerjee

Tai

Myung

et al. 2022

Front. Bioeng. Biotechnol.

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Continuous quantitative monitoring of the change in mineral content during the bone healing process is crucial for efficient clinical treatment. Current radiography-based modalities, however, pose various technological, medical, and economical challenges such as low sensitivity, radiation exposure risk, and high cost/instrument accessibility. In this regard, an analytical approach utilizing electrochemical impedance spectroscopy (EIS) assisted by machine learning algorithms is developed to quantitatively characterize the physico-electrochemical properties of the bone, in response to the changes in the bone mineral contents. The system is designed and validated following the process of impedance data measurement, equivalent circuit model designing, machine learning algorithm optimization, and data training and testing. Overall, the systematic machine learning-based classification utilizing the combination of EIS measurements and electrical circuit modeling offers a means to accurately monitor the status of the bone healing process.

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Section: Discussionmentioning

confidence: 99%

Non-destructive characterization of bone mineral content by machine learning-assisted electrochemical impedance spectroscopy

Banerjee

Tai

Myung

et al. 2022

Front. Bioeng. Biotechnol.

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“…This pathway would apply a transient electrical field [ 28 ] to the bone matrix resulting in inducing stress on the surrounding collagen matrix of the bone [ 42 ] leading to micro-fracturing of the bone matrix. Bone exposed to prolonged lower voltage and high-frequency pulsed currents (500 V; 10 kHz; over 66 h) appeared to result in an increase in bone strength and toughness, attributed to a change in collagen fibril arrangement [ 59 ]. A stronger impulse current, as was employed in the present study, could similarly result in stronger electric forces acting at high speeds on the collagen fibrils to possibly move them through the mineral matrix, damaging it visibly.…”

Section: Discussionmentioning

confidence: 99%

Harnessing Thor's Hammer: Experimentally induced lightning trauma to human bone by high impulse current

Bacci

Augustine

Hunt

et al. 2021

Forensic Science International: Synergy

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Lightning fatality identification relies primarily on soft tissue traumatic pattern recognition, prohibiting cause of death identification in cases of full skeletonisation. This study explores the effects of high impulse currents on human bone, simulating lightning-level intensities and characterising electrically induced micro-trauma through conventional thin-section histology and micro-focus X-ray computed tomography (μXCT). An experimental system for high impulse current application was applied to bone extracted from donated cadaveric lower limbs (n = 22). μXCT was undertaken prior to and after current application. Histological sections were subsequently undertaken. μXCT poorly resolved micro-trauma compared to conventional histology which allowed for identification and classification of lightning-specific patterns of micro-trauma. Statistical analyses demonstrated correlation between current intensity, extent and damage typology suggesting a multifaceted mechanism of trauma propagation - a combination of electrically, thermally and pressure induced alterations. This study gives an overview of high impulse current trauma to human bone, providing expanded definitions of associated micro-trauma.

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“…The biomechanics of subject left tibias was examined at room temperature on an Instron testing machine, equipped with a 2 kN load cell (5944, Single Column, Tabletop Model; ITW, Illinois, IL, USA). The movement speed was 2 mm s −1 for 2 s, with a tube diameter of 10 mm.…”

Section: Methodsmentioning

confidence: 99%

Prevention of retinoic acid‐induced osteoporosis in mice by isoflavone‐enriched soy protein

Yang

Peng

et al. 2015

J Sci Food Agric

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The SPA-IS exhibited obvious oestrogenic activities on retinoic acid-induced osteoporosis in Kunming mice compared to Mix, IS, and soy protein. The results suggest that there is a potential use for SPA-IS in the treatment of osteoporosis induced by intake of retinoic acid. The improvement of bone indicators might be attributed to the formation of aggregate particles and the improvement of IS solubility.

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The Effect of High Voltage, High Frequency Pulsed Electric Field on Slain Ovine Cortical Bone

Cited by 6 publications

References 31 publications

Non-destructive characterization of bone mineral content by machine learning-assisted electrochemical impedance spectroscopy

Non-destructive characterization of bone mineral content by machine learning-assisted electrochemical impedance spectroscopy

Harnessing Thor's Hammer: Experimentally induced lightning trauma to human bone by high impulse current

Prevention of retinoic acid‐induced osteoporosis in mice by isoflavone‐enriched soy protein

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