Twist buckling of veins under torsional loading

Garcia, Justin R.; Sanyal, Arnav; Fatemifar, Fatemeh; Mottahedi, Mohammad; Han, Hugang

doi:10.1016/j.jbiomech.2017.04.018

Cited by 15 publications

(7 citation statements)

References 51 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…One limitation is that the vessel wall as an isotropic hyperelastic material whose constitutive relationship is present as a six-parameter Odgen hyperelastic constitutive equation, although the constitutive equation of the vessel varies according to the vessel type [27, 28]. Fetamifar et al [27] developed the lumen buckling equation for nonlinear anisotropic thick-walled arteries to determine the effect of axial tension based on exponential Fung strain function.…”

Section: Discussionmentioning

confidence: 99%

“…Fetamifar et al [27] developed the lumen buckling equation for nonlinear anisotropic thick-walled arteries to determine the effect of axial tension based on exponential Fung strain function. Garcia et al [28] used a two-fiber strain energy density function to characterize the mechanical behavior of veins under torsion. In future research, scaffold effects of the patented stent when it is deployed into stenotic vessels with different types and materials will be investigated.…”

Section: Discussionmentioning

confidence: 99%

See 1 more Smart Citation

Mechanical analysis of a novel biodegradable zinc alloy stent based on a degradation model

et al. 2019

View full text Add to dashboard Cite

Background Biodegradable stents display insufficient scaffold performance due to their poor Young’s Modulus. In addition, the corresponding biodegradable materials harbor weakened structures during degradation processes. Consequently, such stents have not been extensively applied in clinical therapy. In this study, the scaffold performance of a patented stent and its ability to reshape damaged vessels during degradation process were evaluated. Methods A common stent was chosen as a control to assess the mechanical behavior of the patented stent. Finite element analysis was used to simulate stent deployment into a 40% stenotic vessel. A material corrosion model involving uniform and stress corrosion was implemented within the finite element framework to update the stress state following degradation. Results The results showed that radial recoiling ratio and mass loss ratio of the patented stent is 7.19% and 3.1%, respectively, which are definitely lower than those of the common stent with the corresponding values of 22.6% and 14.1%, respectively. Moreover, the patented stent displayed stronger scaffold performance in a corrosive environment and the plaque treated with patented stents had a larger and flatter lumen. Conclusion Owing to its improved mechanical performance, the novel biodegradable zinc alloy stent reported here has high potential as an alternative choice in surgery.

show abstract

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Mechanical analysis of a novel biodegradable zinc alloy stent based on a degradation model

et al. 2019

View full text Add to dashboard Cite

show abstract

“…The shear strain and principal strain direction were determined using the methods as previously described (Wang et al 2015; Garcia et al 2017). Briefly, arteries were modeled as circular cylinders under an axial force (N), lumen pressure (P i ), and torque (T).…”

Section: Methodsmentioning

confidence: 99%

“…Severe twisting of arteries and veins can affect their patency, impair endothelium function and delay wound healing in the anastomosis area, and lead to distal ischemia (Barton and Margolis 1975; Endean et al 1989; Izquierdo et al 1998; Topalan et al 2003; Selvaggi et al 2004; Garcia et al 2017). These changes can cause increased risks for thrombosis and organ dysfunction (Endean et al 1989; Bilgin et al 2003; Selvaggi et al 2004; Chesnutt and Han 2011).…”

Section: Introductionmentioning

confidence: 99%

Arterial wall remodeling under sustained axial twisting in rats

Wang

Yang

et al. 2017

Journal of Biomechanics

Self Cite

View full text Add to dashboard Cite

Blood vessels often experience torsion along their axes and it is essential to understand their biological responses and wall remodeling under torsion. To this end, a rat model was developed to investigate the arterial wall remodeling under sustained axial twisting in vivo. Rat carotid arteries were twisted at 180 degrees along the longitudinal axis through a surgical procedure and maintained for different durations up to 4 weeks. The wall remodeling in these twisted arteries was examined using histology, immunohistochemistry and fluorescent microscopy. Our data showed that arteries remodeled under twisting in a time-dependent manner during the 4 weeks post-surgery. Cell proliferation, MMP-2 and MMP-9 expressions, medial wall thickness and lumen diameter increased while collagen to elastin ratio decreased. While the size and number of internal elastic lamina fenestrae increased with elongated shapes, the endothelial cells elongated and aligned towards the blood flow direction gradually. These results demonstrated that sustained axial twisting results in artery remodeling in vivo. The rat carotid artery twisting model is an effective in vivo model for studying arterial wall remodeling under long-term torsion. These results enrich our understanding of vascular biology and arterial wall remodeling under mechanical stresses.

show abstract

“…Torsional buckling is a common configuration that is generated due to the relative twist of vessel ends 8 . Likewise, a topologically C-shaped buckling is also likely when the internal pressure of vessel segments exceeds a mechanical limit 9 .…”

Section: Introductionmentioning

confidence: 99%

Haemodynamic Recovery Properties of the Torsioned Testicular Artery Lumen

Goktas

Yalçın

Ermek

et al. 2017

Sci Rep

View full text Add to dashboard Cite

Testicular artery torsion (twisting) is one such severe vascular condition that leads spermatic cord injury. In this study, we investigate the recovery response of a torsioned ram testicular artery in an isolated organ-culture flow loop with clinically relevant twisting modes (90°, 180°, 270° and 360° angles). Quantitative optical coherence tomography technique was employed to track changes in the lumen diameter, wall thickness and the three-dimensional shape of the vessel in the physiological pressure range (10–50 mmHg). As a control, pressure-flow characteristics of the untwisted arteries were studied when subjected to augmented blood flow conditions with physiological flow rates up to 36 ml/min. Both twist and C-shaped buckling modes were observed. Acute increase in pressure levels opened the narrowed lumen of the twisted arteries noninvasively at all twist angles (at ∼22 mmHg and ∼35 mmHg for 360°-twisted vessels during static and dynamic flow experiments, respectively). The association between the twist-opening flow rate and the vessel diameter was greatly influenced by the initial twist angle. The biomechanical characteristics of the normal (untwisted) and torsioned testicular arteries supported the utilization of blood flow augmentation as an effective therapeutic approach to modulate the vessel lumen and recover organ reperfusion.

show abstract

Twist buckling of veins under torsional loading

Cited by 15 publications

References 51 publications

Mechanical analysis of a novel biodegradable zinc alloy stent based on a degradation model

Mechanical analysis of a novel biodegradable zinc alloy stent based on a degradation model

Arterial wall remodeling under sustained axial twisting in rats

Haemodynamic Recovery Properties of the Torsioned Testicular Artery Lumen

Contact Info

Product

Resources

About