Measurements of Dynamic Viscoelasticity of Poly (vinyl alcohol) Hydrogel for the Development of Blood Vessel Biomodeling

Kosukegawa, Hiroyuki; Mamada, Keisuke; Kuroki, Kanju; Liu, Lei; Inoue, Kosuke; Hayase, Toshiyuki; Ohta, Makoto

doi:10.1299/jfst.3.533

Cited by 63 publications

(42 citation statements)

References 16 publications

(17 reference statements)

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“…It is apparent from previous research into biomechanical modelling and the development of synthetic blood vessels for clinicians' training devices that PVA hydrogel can be used to simulate the interior of blood vessels [32][33][34]. In addition to having similar mechanical properties, PVA hydrogels have a high water content resulting in a low surface friction resistance and low interfacial energy with water or biological fluids [35], thus these materials canmimic human soft tissues.…”

Section: Blood Vessel Analogue (Pva Hydrogel)mentioning

confidence: 99%

Friction behaviour of hydrophilic lubricious coatings for medical device applications

Niemczyk

Fray

Franklin

2015

Tribology International

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The friction behaviour of new chitosan derivative coatings obtained by chemical modification of chitosan with fatty acids (linoleic and dilinoleic acid) has been investigated in order to explore their potential as endovascular catheter coatings and to benchmark them against commercially available coatings used in endovascular catheter applications. An in vitro tribological system was developed that was intended to represent to a limited extent the in vivo tribological conditions of a typical endovascular catheterization procedure. Continuous reciprocating sliding tests were carried out with uncoated and coated polymer specimens. The results showed that all of the coatings tested decreased the coefficient of friction compared to the uncoated polymer. Compared to a neat chitosan coating, the chitosan derivative coatings showed a clear reduction in the coefficient of friction to levels similar to those of the commercially-available coatings. A comparison between the friction results and contact angle measurements carried out on the coatings indicated that a range of contact angle values exists for which the friction coefficient is at a minimum. The reason for this is unclear and further studies are required in order to confirm and investigate the trend, especially within the context of hydrophilic lubricious coating development.

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Section: Blood Vessel Analogue (Pva Hydrogel)mentioning

confidence: 99%

Friction behaviour of hydrophilic lubricious coatings for medical device applications

Niemczyk

Fray

Franklin

2015

Tribology International

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“…Lawton et al (2000) employed a finite element discretization to model the catheter and to compute its deformed configurations. On the other hand, several simulators using blood vessel biomodels made of silicone rubber (Ikeda et al, 2005;Wetzel et al, 2005) or poly (vinyl alcohol) hydrogel (PVA-H) (Kosukegawa et al, 2008;Ohta et al, 2004), mimicking a living tissue, have also been developed. Many catheter simulators are developed for training, and include a haptic interface, with which medical students or physicians operate the virtual guidewire, to provide feedback to the operator yielding a sensation similar to that encountered in actual catheter insertion.…”

Section: Introductionmentioning

confidence: 99%

Evaluation of the effect of catheter on the guidewire motion in a blood vessel model by physical and numerical simulations

Takashima

Oike

Yoshinaka

et al. 2017

JBSE

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Various catheter simulators using a computer or blood vessel biomodels have been developed for training of medical students and young physicians. Moreover, we have developed a system to simulate a guidewire in blood vessels that uses both numerical analysis and experimental observation for the quantitative analysis of treatment technique, surgical planning, intra-operative assistance, and to facilitate the design of new guidewires. However, not limited to our group, there is a lack of studies evaluating the motions of both the guidewire and catheter and their interaction in a blood vessel. Therefore, in the present study, we modified our computer-based system and experimental apparatus to evaluate the catheter motion and compared both results. First, we added a mechanism to the experimental apparatus to move and evaluate the catheter in a poly (vinyl alcohol) hydrogel blood vessel model. Second, we added a new catheter model to the calculation. We subsequently evaluated the behaviors of the medical devices (the guidewire and the catheter) by measuring the three-dimensional position and the contact force between the medical devices and the vessel wall. Comparison of the calculation and experimental results showed that the trajectories and the contact forces of both the experimental and numerically analyzed medical devices had the same tendencies. By considering the flexibility of the catheter in both the experimental and numerical analysis methods, we could reproduce the phenomena seen in clinical situations, such as movement of the catheter during the insertion or removal of the guidewire, and movement of the guidewire during the insertion of the catheter.

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“…The crystalline regions are formed mainly by hydrogen bonds on the hydrophilic groups, while the amorphous regions include flexible chains without hydrogen bonds. Therefore, its thermal and mechanical properties can be flexibly controlled by changing the PVA factors such as concentration, polymerization, and saponification [4][5][6][7][8][9][10][11].…”

Section: Introductionmentioning

confidence: 99%

“…Higher DP of PVA induces increased entanglement of the polymer chains, and higher SV induces decreased amorphous regions. The amorphous regions may act as a damper, and consequently the variation of the inner crystalline structure appears as the different thermal and mechanical properties[4][5][6][7][8][9]. As shown inFig.…”

mentioning

confidence: 99%

Friction Properties of Poly(vinyl alcohol) Hydrogel: Effects of Degree of Polymerization and Saponification Value

et al. 2011

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In this study, the friction of eight kinds of poly(vinyl alcohol) hydrogel (PVA-H) samples has been studied under various load and velocity conditions to elucidate the effects of PVA factors such as the degree of polymerization (DP) and the saponification value (SV) on the tribological behavior of PVA-H. Results showed the variations of the friction properties due to the PVA factors in the two friction conditions found for the hydrogels: elastic friction and hydrodynamic lubrication. In the elastic friction, the larger frictions were induced by the higher values of DP and SV. In the hydrodynamic lubrication, on the other hand, PVA-Hs with lower SV showed larger friction. The results can then be used to adjust the parameters of PVA-H in order to get given friction properties, for instance for the friction between catheter or scalpel and PVA-H, which can be used as a biomodel material of artery or oral mucosa, for the training of surgeons.

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Measurements of Dynamic Viscoelasticity of Poly (vinyl alcohol) Hydrogel for the Development of Blood Vessel Biomodeling

Cited by 63 publications

References 16 publications

Friction behaviour of hydrophilic lubricious coatings for medical device applications

Friction behaviour of hydrophilic lubricious coatings for medical device applications

Evaluation of the effect of catheter on the guidewire motion in a blood vessel model by physical and numerical simulations

Friction Properties of Poly(vinyl alcohol) Hydrogel: Effects of Degree of Polymerization and Saponification Value

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