Effect of glucose on the biomechanical function of arterial elastin

Wang, Yunjie; Zeinali‐Davarani, Shahrokh; Davis, Elaine C.; Zhang, Yanhang

doi:10.1016/j.jmbbm.2015.04.025

Cited by 39 publications

(26 citation statements)

References 49 publications

(55 reference statements)

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“…These observations suggest that glucose also reduces the piezoelectric response of elastin substantially, which could be related to crosslinking that stiffens elastic fibers and reduces their piezoelectricity. Indeed, we also found increase of tangent modulus in glucose treated elastin (Wang et al 2015; Zou and Zhang 2012). The structural and functional alterations of elastin with glucose exposure may have important physiological implications.…”

Section: Bio-chemo-electro-mechanical Behavior Revealed By Piezosupporting

confidence: 70%

“…In vitro studies have shown that glucose treatments stiffens arterial elastin (Winlove et al 1996), increases the storage and loss modulus (Lillie and Gosline 1996), and also changes the viscoelastic stress relaxation behavior of elastin (Zou and Zhang 2011). Elastin was found to become markedly stiffer and more viscoelastic with excessive glucose exposure (Wang et al 2015; Zou and Zhang 2012). Mechanical testing results (Figure 4) show that the stiffness of elastin increases gradually with glucose treatment.…”

Section: Contribution Of Elastin To Vascular Mechanicsmentioning

confidence: 99%

“…Moreover, the amount of hysteresis also increases with treatment times. Transmission electron microscopy (TEM) studies revealed no obvious structural changes in elastin due to glucose treatment, suggesting molecular level structural modifications due to the interactions between elastin and glucose (Wang et al 2015). …”

Section: Contribution Of Elastin To Vascular Mechanicsmentioning

confidence: 99%

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The coupled bio-chemo-electro-mechanical behavior of glucose exposed arterial elastin

Zhang¹,

Li²,

Boutis³

2017

J. Phys. D: Appl. Phys.

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Elastin, the principle protein component of the elastic fiber, is a critical extracellular matrix (ECM) component of the arterial wall providing structural resilience and biological signaling essential in vascular morphogenesis and maintenance of mechanical homeostasis. Pathogenesis of many cardiovascular diseases have been associated with alterations of elastin. As a long-lived ECM protein that is deposited and organized before adulthood, elastic fibers can suffer from cumulative effects of biochemical exposure encountered during aging and/or disease, which greatly compromise their mechanical function. This review article covers findings from recent studies of the mechanical and structural contribution of elastin to vascular function, and the effects of biochemical degradation. Results from diverse experimental methods including tissue-level mechanical characterization, fiber-level nonlinear optical imaging, piezoelectric force microscopy, and nuclear magnetic resonance are reviewed. The intriguing coupled bio-chemo-electro-mechanical behavior of elastin calls for a multi-scale and multi-physical understanding of ECM mechanics and mechanobiology in vascular remodeling.

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Section: Bio-chemo-electro-mechanical Behavior Revealed By Piezosupporting

confidence: 70%

Section: Contribution Of Elastin To Vascular Mechanicsmentioning

confidence: 99%

Section: Contribution Of Elastin To Vascular Mechanicsmentioning

confidence: 99%

See 1 more Smart Citation

The coupled bio-chemo-electro-mechanical behavior of glucose exposed arterial elastin

Zhang¹,

Li²,

Boutis³

2017

J. Phys. D: Appl. Phys.

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“…The experiments showed that under uniaxial strain the surrounding waters of hydration of elastin upon extension undergo more rapid tumbling, pointing to an increase in the entropy of water; this finding indicated that the entropic recoil of hydrated elastin does not arise from a change in water entropy 32 . In a separate study, we investigated the effects of glucose on the elastic recoil of elastin through a combined experimental and computational approach 24,64 . In glucose, elastin is found to exhibit stiffer characteristics as well as viscoelastic behavior.…”

Section: Resultsmentioning

confidence: 99%

Mechanical, structural, and dynamical modifications of cholesterol exposed porcine aortic elastin

Bilici

Morgan

Silverstein

et al. 2016

Biophysical Chemistry

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Elastin is a protein of the extracellular matrix that contributes significantly to the elasticity of connective tissues. In this study, we examine dynamical and structural modifications of aortic elastin exposed to cholesterol by NMR spectroscopic and relaxation methodologies. Macroscopic measurements are also presented and reveal that cholesterol treatment may cause a decrease in the stiffness of tissue. 2H NMR relaxation techniques revealed differences between the relative populations of water that correlate with the swelling of the tissue following cholesterol exposure. 13C magic-angle-spinning NMR spectroscopy and relaxation methods indicate that cholesterol treated aortic elastin appears more mobile than control samples. Molecular dynamics simulations on a short elastin repeat VPGVG in the presence of cholesterol are used to investigate the energetic and entropic contributions to the retractive force, in comparison to the same peptide in water. Peptide stiffness is observed to reduce following cholesterol exposure due to a decrease in the entropic force.

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“…Cytoskeletal mechanics figure courtesy P. Alford; cytoskeletal model figure courtesy W. Ronan; tissue model figure courtesy G. Holzapfel. For further reference, see 9, 19, 21, 49, 72, 160–162 .…”

Section: Figurementioning

confidence: 99%

Multi-scale Modeling of the Cardiovascular System: Disease Development, Progression, and Clinical Intervention

et al. 2016

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Cardiovascular diseases (CVDs) are the leading cause of death in the western world. With the current development of clinical diagnostics to more accurately measure the extent and specifics of CVDs, a laudable goal is a better understanding of the structure-function relation in the cardiovascular system. Much of this fundamental understanding comes from the development and study of models that integrate biology, medicine, imaging, and biomechanics. Information from these models provides guidance for developing diagnostics, and implementation of these diagnostics to the clinical setting, in turn, provides data for refining the models. In this review, we introduce multi-scale and multi-physical models for understanding disease development, progression, and designing clinical interventions. We begin with multi-scale models of cardiac electrophysiology and mechanics for diagnosis, clinical decision support, personalized and precision medicine in cardiology with examples in arrhythmia and heart failure. We then introduce computational models of vasculature mechanics and associated mechanical forces for understanding vascular disease progression, designing clinical interventions, and elucidating mechanisms that underlie diverse vascular conditions. We conclude with a discussion of barriers that must be overcome to provide enhanced insights, predictions, and decisions in pre-clinical and clinical applications.

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Effect of glucose on the biomechanical function of arterial elastin

Cited by 39 publications

References 49 publications

The coupled bio-chemo-electro-mechanical behavior of glucose exposed arterial elastin

The coupled bio-chemo-electro-mechanical behavior of glucose exposed arterial elastin

Mechanical, structural, and dynamical modifications of cholesterol exposed porcine aortic elastin

Multi-scale Modeling of the Cardiovascular System: Disease Development, Progression, and Clinical Intervention

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