Abstract

dyna

DYNA

Dyna rev.fac.nac.minas

0012-7353

Universidad Nacional de Colombia

10.15446/dyna.v86n211.80730

Artículos

Fluid-structure study of a polymeric coating reinforced with carbon nanotubes (CNT) for potential application in stents

Estudio fluido-estructura de un recubrimiento polimérico reforzado con nanotubos de carbono (NTC) y su potencial aplicación en stents

Pérez-Arrieta

Jairo

^a Hernández-Marulanda

Andrés Felipe

^b Hoyos-Palacio

Lina

^a Valencia-Cardona

Raúl

a Facultad de Ingenierías, Universidad Pontificia Bolivariana, Medellín, Colombia. jparrieta29@gmail.com, lina.hoyos@upb.edu.co, raul.valencia@upb.edu.co Universidad Pontificia Bolivariana Facultad de Ingenierías Universidad Pontificia Bolivariana

Medellín

Colombia lina.hoyos@upb.edu.co raul.valencia@upb.edu.co b Facultad de Ingenierías, Universidad de San Buenaventura, Medellín, Colombia. andres.hernandez@usbmed.edu.co Universidad de San Buenaventura Facultad de Ingenierías Universidad de San Buenaventura

Medellín

Colombia andres.hernandez@usbmed.edu.co

Oct-Dec 2019

86 211 300 307 27 06 2019 24 10 2019 15 11 2019

The author; licensee Universidad Nacional de Colombia.

Abstract

The therapeutic approach of the atherosclerotic plaque has been visualized from multiple perspectives, which include from the handling of drugs until the implantation of medical devices like stents. A current alternative to restenosis appearance, is the use of stents with drug-releasing coatings.

The present work seeks to analyze the structural and hemodynamic behavior and to understand the effects between the interaction of a stent coating manufactured in PVOH with and without the presence of carbon nanotubes with concentrations of CNT varying from 0.1 to 0.3% (Wt), through a computational study. The computational study is based on a Fluid-Structure (FSI) model in one way and with a scheme partitioned using the finite element method.

In conclusion, predicting the mechanical behavior and local flow patterns of these devices may provide criteria elements that allow the improvement of the design of a stent coating.

Resumen

El abordaje terapéutico de la placa ateroesclerótica ha sido visualizado desde múltiples ángulos, que incluyen desde el manejo con fármacos hasta la implantación de dispositivos médicos como stents. Una alternativa actual a la aparición de reestenosis son stents con recubrimientos liberadores de fármacos.

El presente trabajo busca analizar el comportamiento y entender los efectos entre la interacción de un recubrimiento para stent fabricado en PVOH sin la presencia y con la presencia de nanotubos de carbono con porcentajes de NTC del 0.1, al 0.3% (WT) y la hemodinámica local, mediante un estudio computacional. El estudio computacional es basado en un modelo Fluido-Estructura (FSI) en una vía y con un esquema de solución particionado utilizando el método de elementos finitos.

En conclusión, predecir el comportamiento mecánico y los patrones de flujo locales de estos dispositivos, pueden proporcionar elementos de criterio que permitan el mejoramiento del diseño de un recubrimiento para stent.

<bold> <italic>Keywords</italic>:</bold> fluid-structure coating computational study Stent carbon nanotubes

<bold> <italic>Palabras clave</italic>:</bold> fluido-estructura recubrimiento estudio computacional Stent nanotubos de carbono

1. Introduction

Stents are vascular prostheses implanted through an angioplasty surgical procedure that helps to restore blood flow in areas with a narrowing of the lumen (stenosis) due to pathologies such as arteriosclerotic plaque. However, several studies in the literature have reported that in 30%-40% cases, lumen narrowing is observed due to plaque formation on the device about six months after the implantation [1]. One of the possible causes reported in the literature [4] is due to the geometric design and the surface finish of the prosthesis.

Cardiovascular stents to date are mainly made of nitinol, but there is a worldwide trend that these are coated. The coatings have been studied with synthetic and FDA-approved biodegradable polymers, most of which are lactic acid (PLLA),) and poly-lactic-co-glycolic acid (PLGA), which have been used even as a stent body, but PLA and the PLGA have shown that they are bioabsorbable materials but have no expandable capacity to be implanted together with the stent and that they do not suffer fractures and / or adequate mechanical support.

Recently, several medical case reports have shown that stent implants can lead to restenosis [2], myocardial infarction [3], thrombosis [4], and angina instability [5]. It is also frequently reported that stent failure can happen at any time, which can cause thrombosis, restenosis, pain, and other clinical complications in patients [6,8]. If a vascular endoprosthesis failure is diagnosed, patients will need to undergo another surgery to remove the failed stent and implant a new one to resolve the problem. To reduce the risk of complications associated with the stent, it is important to implant the most appropriate stent for the patient, for which it is necessary to have a complete understanding of the biomechanical behavior of stents with different designs, materials, and coatings. Also, stent deployment may be affected by plaque composition, such as calcified and hypocellular plaques, due to its very different mechanical behavior [9].

Most commercially available stents can generally be divided into two groups: closed cell and open cell design, with different types of connection (struts), such as peak to peak or valley to valley. In addition to the scaffold structure, modern stents tend to have drug-releasing coatings that are used to reduce and control the formation of arteriosclerotic plaque [10]. Although drug-eluting stents have mostly been used in the current clinical treatment of stenosis, very limited research has been conducted to study the mechanical behavior of drug-eluting coatings and existing work mainly focuses on drug releases. In fact, in the literature review of this study, it came across only two documents that studied coating. For example, Gu et al. [11] modeled the influence of the silicone coating during the deployment of a microstent in an artery with fusiform aneurysm. Therein, it was demonstrated that the coated stent appreciably required 30% higher pressure to expand the artery to the same extent as its bare metal version, where the coating and the strut had the same thickness (0.1 mm). Hopkins et al. [12] studied the bidimensional delamination of the stent coating during deployment, which occurred mainly in hinge regions with high plastic strain. Here, the coating started to separate depending on its thickness, material, and curvature of the hinge.

Table 1 Mechanical properties of NiTi (nitinol).

Source: [15]

The purpose of this research is to analyze the mechanical behavior of a PVOH-based stent coating with and without the presence of carbon nanotubes and to assess the effects of this membrane interacting with local hemodynamics through a fluid-structure computational study (FSI).

2. Material and methods <italic>2.1. Geometry</italic>

The study scope includes a stent and a coating located in a section of the arterial vessel (Fig. 1a). Since its technical information was available, the stent used was the nickel-titanium (nitinol) Cypher® stent by Xience. The length, internal diameter, and thickness of the stent were 8 mm, 3 mm, and 150 μm, respectively. The CAD model was created using the CAD Solidworks® software. The coating is a thin 10 μm layer attached to the surface of the stent. The blood vessel with a length of 20 mm and a wall thickness of 1 mm was simplified to a cylinder with an axi-symmetric stenotic plaque with a length and maximum thickness of 6 mm and 0.4 mm, respectively.

Figure 1a Geometry of the control system. Coated stent, plaque, and stenotic artery. <xref ref-type="fig" rid="f1">Figure 1</xref>b. Description of the fluid volume, input length, (development), interaction length (stent coating zone), and output length (inertia). Source: The Authors.

The internal diameter in the healthy section and in the stenotic plaque is 4 mm and 3.35 mm, respectively. For the wall, the three tissue layers were included, i.e., intima, media, and adventitia, with a thickness of 0.27 mm, 0.35 mm, and 0.38 mm, respectively [13].

<italic>2.2. Materials</italic>

The Cypher® test stent is made of nickel-titanium (nitinol); the mechanical properties of which is shown in Table 1 [14,15,16,17].

<italic>2.3. Governing equations and border conditions</italic> 2.3.1 Fluid

The fluid was assumed as incompressible, with a density ρ = 1060 kg/m³ and a dynamic viscosity of 0.0035 Pa s, under the domain of the mass and momentum conservation equations [20].

where u is the flow rate, p is the static pressure and t is time.

The fluid model is assumed as homogeneous and incompressible and it was based on the power law considering blood as non-Newtonian [21]. In this model, the shear stress 𝜏(𝑁/𝑚²) is calculated as:

where k = consistency index (𝑘g𝑠^𝑛−2/𝑚), n = power law index, T₀ = reference temperature (K), µ0 = minimum viscosity limit (kg/m s), and µ∞ = limit of maximum viscosity (kg/m s).

The assumed values are [21] µ0 = 0.0001 Pa s, µ∞ = 0.1 Pa s, n = 0.7, T0 = 310 K y k = 0.01691 (𝑘g𝑠^𝑛−2/𝑚)

For the input speed and the output pressure, a pulsatile flow was considered, which was programmed in two functions (UDF) [22] as follows:

where Vi = Initial speed, Ps = Output pressure, t = time

2.3.2 Structural

The governing equation for the solid domain is the momentum conservation equation.

where ρs is the density of the coating wall, t _s is the stress tensor of the solid, 𝑓_𝑆 ^𝐵 is the forces of the body per volume unit, and is the local acceleration of the solid.

The stent coating is polyvinyl alcohol (PVOH) reinforced with carbon nanotubes at 0.1%, 0.2%, and 0.3% by CNT weight. The material was modeled with a hyperelastic behavior according to the Yeoh model. Therefore, this model has been chosen to describe the hyperelastic properties of the polymer [18,19]:

The Yeoh model is applicable for a much wider range of strain.

This model is able to predict the stress-strain behavior in different strain modes from data obtained in a simple strain mode such as the uniaxial extension

where W = strain energy potential, first invariant of the Cauchy-Green strain tensor : main elongations, J = Jacobian determinant of the elastic deformation gradient F defined as material constants and d ₁,d ₂,d ₃ = incompressibility parameters.

The constant values are shown in Table 2. The constants of the material were calculated in Ansys® after entering the experimental data of the tests conducted in this work (see Section 4).

Table 2 Material constants of PVOH without reinforcement and PVOH reinforced with CNT for the Yeoh hyperelastic model.

Source: The Authors.

The FDA has some evaluation criteria that regulate the structural analysis of a vascular prosthesis. Some parameters considered in this study are as follows.

2.3.2.1. Longitudinal contraction

This criterion is used to calculate the shortening of the prosthesis at the axial level during a cycle and is expressed by equation 11:

where CL (longitudinal contraction), L _looad (coating length with working pressure), and L _unlooad (coating length without working pressure).

2.3.2.2. Radial contraction

This criterion is used to calculate prosthesis reduction at the radial level. This criterion depends on the type of material and its behavior, due to its elastic recoveries, as well as on the loads to which the prosthesis is subjected. Its calculation is expressed by the following equation:

where CR (radial contraction), R_load (radius of the coating with the working pressure) y R _unload (radius of the coating without the working pressure).

<italic>2.4. Mesh</italic> 2.4.1. Solid domain

The mesh of the coating’s solid domain was meshed with a shell-like element known as SHELL 181, which is suitable for analyzing structures with thin-to-moderately-thick layers. It is a four-node element with six degrees of freedom in each node: with movement in the x, y, and z directions and rotations around the x, y, and z axes. It adapts very well for nonlinear high strain applications and for modeling of composed materials [23]. The final mesh comprised approximately 70000 elements. The stent was meshed with SHELL 281 type elements, with similar characteristics as SHELL 181. Similar to SHELL 181, SHELL 281 is suitable for nonlinear high strain applications, but the SHELL 281 element has eight nodes with six degrees of freedom in each node: with movement and rotations in the x, y, and z axes [23]. Approximately 50000 elements were used; the vessel wall and the plaque were entangled with MAPPED elements, which is the default element used by the software to mesh thick-layered geometries. A total of 20,000 elements were used to generate this mesh. The balloon was meshed using hexahedral SHELL 181 elements, with an approximate number of 4500 elements [23].

2.4.2. Fluid Domain

The fluid domain was meshed with approximately 900000 tetrahedral PRISMA elements of four nodes, adequate for the preparation of complex geometries. In fact, using these triangular or tetrahedral elements to generate unstructured meshes saves times since this mesh allows the grouping of elements in selected regions of the flow domain. The quality of the mesh was evaluated based on the aspect ratio for the structural domain and the Skewness for the dynamic fluid domain. The values obtained were of 1.1 and 0.25, respectively, which indicate a very good behavior in the generation of the elements in order not to cause convergence errors or changes that interfere with the results [23,24]. The mesh was refined taking into account that they were compliant (the elements must be equal in size to obtain better transfer of information from one element to another) between the different subdomains of both the solid (stent coating) and the fluid (blood-coating) domain, with the sole purpose of reducing simulation resolution times [23].

<italic>2.5. Loads and Restrictions</italic>

Initially, a linear load that emulates the inflation and deflation processes of the balloon on the coated stent was applied to the model. The applied displacement was 35 microns, equivalent to a pressure of 0.9 MPa [25]. The inflation and deflation times were 0.5 s and coated stent ends were fixed emulating their fixation on the catheter. The contact between the stent and the coating was modeled as a frictionless surface, with contact adjustment and a stiffness factor of 0.01 that the software includes by default [26].

Additionally, a pulsatile profile is considered for the fluid with a sinusoidal pattern, with a maximum velocity at the inlet of 50 cm/s during the systolic phase and a minimum velocity of 10 cm/s during the diastolic phase. For the output, also a pulsatile pressure with a maximum of 120 mmHg and 80 mmHg was applied as a minimum point. Therefore, considering the mean pressure of the two phases, around 100 mmHg is used as the static manometric pressure at the outlet point [22]. If the heart rate is 120 beats per minute, the duration of each period is 0.5 s.

3. Results

Figs. 2, 3, and 4 denote the behavior of the PVOH coating with and without carbon nanotubes (displacement, stress, and strain) during the unfolding process within an artery with plaque obstruction. The results obtained show that as the CNT percentage increases, a small percentage variation is registered in its mechanical properties.

Figure 2 Total displacement of the PVOH coating [Microns] with and without nanoreinforcement: a) Displacements when the pressure balloon is maximum P = 0.9 MPa; b) Displacements when the pressure balloon is minimum P = 0 MPa. Source: The Authors

Figure 3 Normal von Mises stress of the PVOH coating [Pa] with and without nanoreinforcement: a) Stress when the pressure balloon is maximum P = 0.9 MPa; b) Stress when the pressure balloon is minimal P = 0 MPa. Source: The Authors.

Figure 4 Strain of the PVOH coating [Pa] with and without nanoreinforcement: a) Strain when the pressure balloon is maximum P = 0.9 MPa; b ) Strain when the pressure balloon is minimal P = 0 MPa. Source: The Authors.

Fig. 5 displays the stress-strain diagram of the coatings with and without nanoreinforcement.

Figure 5 Stress-deformation curve of the coating: a) PVOH without reinforcement; b) PVOH reinforced with 0.1% of CNT, c) PVOH reinforced with 0.2% of CNT and d) PVOH reinforced with 0.3% of CNT. Source: The Authors.

Table 4 shows the results of longitudinal and radial contraction and the percentage difference that exists between the PVOH coating with and without CNT.

Table 4 Results of the longitudinal contraction and radial contraction of the coating: a) PVOH without reinforcement; b) PVOH reinforced with 0.1% of CNT, c) PVOH reinforced with 0.2% of CNT, and d) PVOH reinforced with 0.3% of CNT.

Source: The Authors.

<italic>3.1. Fluid-structure analysis</italic>

In the case of fluid-structure interaction, there is a pulsatile flow and a covering structure with hyperelastic characteristics, which present a speed and shear stress solution for each instant of time.

3.1.1. Development of speed in the coating area

As seen in Fig. 6, the speed does not vary significantly, because the difference that exists in the radial contraction of the nanoreinforced coatings with respect to the coating of only PVOH is very small (Table 4).

Figure 6 Differences in velocity profiles of the zone-coating at time instant t = 0.1 s. Source: The Authors.

In Table 5, it is observed that the Reynolds number generated throughout the stent coating system for the four cases narrowly surpasses the critical Reynolds Re = 2200 [27].

Table 5 Reynolds number values and Womersley number for each instant time of the pulse in the zone-coating and zone-downstream.

Source: The Authors.

3.1.2. Mapping of the shear stress profiles on the surface of the coating with and without nanoreinforcement

Fig. 7 shows the profiles of the shear stresses that are generated in an exposed section of the coating in different time instants. In Fig. 8, a comparison is made in the mapping of the shear stresses generated in the surfaces of the coatings with and without CNT, as it can be observed is practically imperceptible the change in the results of these efforts, because the speeds also recorded a very small change as a result of the few difference that there was in the radial contraction of each material.

Figure 7 Mapping the shear stress on a section of the surface of the coating. a) section of the stent coating system chosen to perform the mapping of the shear forces. b) profile of the shear stress in the Z axis - t = 0.1 s (systole), 0.2 s (diastole), and 0.5 s (end of the pulse), PVOH c) profile of the shear stress in the Z axis - t = 0.1 s ( systole), 0.2 s (diastole), and 0.5 s (end of pulse), PVOH + CNT 0.1%. d) profile of the shear stress in the Z axis - t = 0.1 s (systole), 0.2 s (diastole), and 0.5 s (end of the pulse), PVOH + CNT 0.2%. e) profile of the shear stress in the Z axis - t = 0.1 s (systole), 0.2 s (diastole), and 0.5 s (end of the pulse), PVOH + CNT 0.3%. Source: The Authors.

Figure 8 Comparison of the shear stress profiles in the Z axis (longitudinal) of the coatings with and without nanoreinforcement. Profile of the shear stress on the Z axis - t = 0.1 s (systole) Source: The Authors.

4. Discussion

As shown in the results presented in Figs. 2, 3, and 4, corresponding to the case of implanting the coated stent, it is observed that as the CNT percentage increases, a percentage variation of 0.05%, 0.08%, and 0.1% is registered in the total displacements, 4.7%, 8.1%, and 9.05% in the von Mises stress, and a decrease in percentage variation of 1.55%, 2.67%, and 2.98% in total strain. All these variations occurred in coatings reinforced with carbon nanotubes (0.1%, 0.2%, and 0.3% (wt)) with respect to the coating without CNT and at the maximum pressure point.

As seen in Fig. 5, the system begins a stage of recoil or deflection. During deflation, there is a recovery in elastic deformation and radial pressure. As a result, the stent coating system has a stronger tendency to recover its hyperelastic deformation. This forced the stent coating system to retreat in the four simulation cases 0.01724 mm or 19.31% (PVOH), 0.017308 mm or 19.38% (PVOH + 0.1% CNT), 0.017361 mm or 19.43% (PVOH + 0.2% CNT), and 0.017377 mm or 19.45% (PVOH + 0.3% CNT). All values are taken from the point of maximum pressure until pressure reaches zero.

Table 4 denotes that there is an imperceptible difference in the longitudinal contraction as in the radial contraction, causing only a small variation in the speed and shear stress results, as shown in Figs. 6 and 7.

For the fluid-structure case, Fig. 6 denotes that the velocity does not vary significantly because the difference in the radial contraction of the nanoreinforced coatings with respect to only PVOH coating is very small in the range of 0.105%-0.315%.

As observed in Table 5, the critical laminar regime only just exceeded, which means that the regime is slightly turbulent since the flow comes into contact with the stent structure, causing small turbulences in the system wall. As time progresses, speed as well as the Reynolds number decrease, causing a laminar regime throughout most of the pulse. The Womersley number determines the shape of the velocity profile. As α in the zone of reduction presents a value less than 3, the profiles are completely parabolic that indicates that the flow is fully developed.

As can be observed in Figs. 7 and 8, the difference is almost imperceptible in the mapping of the shear stress profiles since the percentage in the radial contraction of the coatings with nanoreinforcements is not greater than 0.3%. Therefore, the PVOH velocity 0.93671 [m/s] - PVOH + CNT 0.3% 0.93966 [m/s] (Fig. 6) and the shear stresses PVOH 24,7405 [Pa] - PVOH + CNT 0.3% 24,8184 [Pa] increases.

Stagnation and re-circulation points were considered in the simulation, which can start thrombus formation Fig. 9.

Figure 9 <italic>Velocity streamlines, with 0,256 m/s as maximum velocity and 0,128 m/s medium velocity</italic>. Source: The Authors.

5. Conclusions

In this study, the effects of the selection of the coating material and its expansion behavior on a stent have been studied based on an FSI simulation with local hemodynamics and the membrane implanted inside a stenotic artery. The results of this study showed that at a given deployment pressure and as the CNT percentage increases, a percentage variation of no more than 0.1% in total displacements, 9% in the von Mises stress, and a decrease in the variation in the percentage of total deformation of less than 3% is reported. All these variations occurred in coatings reinforced with carbon nanotubes (0.1%, 0.2%, and 0.3% (wt)) with respect to the coating without CNT.

Therefore, the addition of carbon nanotubes as reinforcement is not significant since the mechanical properties of the material are not considerably modified. It is worth mentioning that the carbon nanotubes used to create the coating applied in the macroproject from which this study is derived had the purpose of transporting anti-adherent molecules of oxidized low density lipoproteins, which are the cause of the formation of the atherosclerotic plaque.

As it can be observed, the reduction speed developed at the selected instant of time (maximum speed point: systole), causing a slightly turbulent regime, due to the fact that the blood flow collides with the structure of the stent. Recirculation zones in which there would be an accumulation of blood fluid, which would lead to a possible thrombus, were not present. In the same way, as the flow moves away from the stent coating system and pulse time progresses, the fluid recovers the laminar regime and its initial velocity magnitude.

Another aspect to take into account is the percentage variation in the results of the recoil effect, the longitudinal and radial contraction that occurred at implantation time are very low in cases where they only exceed 0.3%, causing an insignificant speed variation in the reduction zone and therefore, an imperceptible variation in the shear stress zones where the coating is exposed.

Acknowledgments

The present study has been developed under the collaboration agreement between COLCIENCIAS and the Bioengineering Research Group of the Universidad Pontificia Bolivariana under the "Simulation through DFT, DM, and CFD techniques of the interaction of an endovascular nanocoating with lipoproteins at the atherosclerotic plaque level as a therapeutic management proposal” micro-project.

References [1]

[1] Duprat, G., Wright, K.C., Charnsangavej, C., Wallace, S. and Gianturco, C., Self-expanding metallic stents for small vessels: an experimental evaluation. Radiology, 162, pp. 469-472, 1987. DOI: 10.1148/radiology.162.2.3797661

Duprat

Wright

K.C

Charnsangavej, C., Wallace, S. and Gianturco, C., Self-expanding metallic stents for small vessels: an experimental evaluation

Radiology 162 469 472 1987

10.1148/radiology.162.2.3797661

[2]

[2] Okamura,T., Hiro, T, Fujii, T., Yamada, J., Fukumoto, Y., Hashimoto, G., Fujimura, T., Yasumoto, K., and Matsuzaki, M., Late giant coronary aneurysm associated with a fracture of sirolimus eluting stent: a case report, J. Cardiol., 51(1), pp. 74-79, 2008. DOI: 10.1016/j.jjcc.2007.11.002

Okamura

Hiro

Fujii

Yamada

Fukumoto

Hashimoto

Fujimura

Yasumoto

Matsuzaki

Late giant coronary aneurysm associated with a fracture of sirolimus eluting stent: a case report

J. Cardiol 51 1 74 79 2008

10.1016/j.jjcc.2007.11.002

[3]

[3] Park, J.S., Shin, D.G., Kim, Y.J., Hong, G.R. and Cho, I.H., Acute myocardial infarction as a consequence of stent fracture and plaque rupture after sirolimus-eluting stent implantation, Int. J. Cardiol., 134(2), pp. e79-e81, 2009. DOI: 10.1016/j.ijcard.2007.12.095

Park

J.S.

Shin

D.G.

Kim

Y.J.

Hong

G.R.

Cho

I.H

Acute myocardial infarction as a consequence of stent fracture and plaque rupture after sirolimus-eluting stent implantation

Int. J. Cardiol 134 2 e79 e81 2009

10.1016/j.ijcard.2007.12.095

[4]

[4] Choe, H., Hur, G., Doh, J.H., Namgung, J., Lee, S.Y., Park, K.T., Chang, W.I. and Lee,W.R., A case of very late stent thrombosis facilitated by drug eluting stent fracture: comparative images before and after stent fracture detected by 64-multidetector computed tomography, Int. J. Cardiol., 133(3), pp. e125-e128, 2009. DOI: 10.1016/j.ijcard.2008.11.040

Choe

Hur

Doh

J.H.

Namgung

Lee

S.Y.

Park

K.T.

Chang

W.I.

Lee

W.R

A case of very late stent thrombosis facilitated by drug eluting stent fracture: comparative images before and after stent fracture detected by 64-multidetector computed tomography

Int. J. Cardiol 133 3 e125 e128 2009

10.1016/j.ijcard.2008.11.040

[5]

[5] Adlakha, S., Sheikh, M., Bruhl, S., Eltahawy, E., Pandya, U., Colyer, W. and Cooper, C., Coronary stent fracture: a cause of cardiac chest pain?, Int. J. Cardiol., 141(2), pp. e23-e25, 2010. DOI: 10.1016/j.ijcard.2008.11.135

Adlakha

Sheikh

Bruhl

Eltahawy

Pandya

Colyer

Cooper

Coronary stent fracture: a cause of cardiac chest pain?

Int. J. Cardiol 141 2 e23 e25 2010

10.1016/j.ijcard.2008.11.135

[6]

[6] Celik, T., Iyisoy, A., Dogru, M.T., and Isik, E., Coronary stent strut fracture after drug-eluting stent implantation: a newly recognized complication, Int. J. Cardiol., 132(1), pp. 121-122, 2009. DOI: 10.1016/j.ijcard.2007.07.011

Celik

Iyisoy

Dogru

M.T.

Isik

Coronary stent strut fracture after drug-eluting stent implantation: a newly recognized complication

Int. J. Cardiol 132 1 121 122 2009

10.1016/j.ijcard.2007.07.011

[7]

[7] Kim, H.S., Kim, Y.H., Lee, S.W. , Park, D.W., Lee, C.W., Hong, M. K., Park, S.W., Ko, J.K., Park, J.H., Lee, J.H., Choi, S.W., Seong, I.W., Cho,Y.H., Lee, N.H., Kim, J.H., Chun, K.J. and Park, S.J., Incidence and predictors of drug-eluting stent fractures in long coronary disease, Int. J. Cardiol., 133(3), pp. 354-358, 2009. DOI: 10.1016/j.ijcard.2008.01.005

Kim

H.S.

Kim

Y.H.

Lee

S.W.

Park

D.W.

Lee

C.W.

Hong

M. K.

Park

S.W.

J.K.

Park

J.H.

Lee

J.H.

Choi

S.W.

Seong

I.W.

Cho

Y.H.

Lee

N.H.

Kim

J.H.

Chun

K.J.

Park

S.J

Incidence and predictors of drug-eluting stent fractures in long coronary disease

Int. J. Cardiol 133 3 354 358 2009

10.1016/j.ijcard.2008.01.005

[8]

[8] Umeda, H., Gochi,T., Iwase, M., Izawa, H., Shimizu, T., Ishiki, R., Inagaki, H., Toyama, J., Yokota, M. and Murohara, T., Frequency, predictors and outcome of stent fracture after sirolimus-eluting stent implantation, Int. J. Cardiol., 133(3), pp. 321-326, 2009. DOI: 10.1016/j.ijcard.2007.12.067

Umeda

Gochi

Iwase

Izawa

Shimizu

Ishiki

Inagaki

Toyama

Yokota

Murohara

Frequency, predictors and outcome of stent fracture after sirolimus-eluting stent implantation

Int. J. Cardiol 133 3 321 326 2009

10.1016/j.ijcard.2007.12.067

[9]

[9] Loree, H., Grodzinsky, A., Park, S., Gibson, L. and Lee, R., Static circumferential tangential modulus tissue, 27(2), pp.195-204,1994. DOI: 10.1016/0021-9290(94)90209-7

Loree

Grodzinsky

Park

Gibson

Lee

Static circumferential tangential modulus tissue 27 2 195 204 1994

10.1016/0021-9290(94)90209-7

[10]

[10] Khan, W., Farah, S. and Domb, A.J., Drug eluting stents: developments and current status, J. Control. Release, 161(2), pp. 703-712, 2012. DOI: 10.1016/j.jconrel.2012.02.010

Khan

Farah

Domb

A.J

Drug eluting stents: developments and current status

J. Control. Release 161 2 703 712 2012

10.1016/j.jconrel.2012.02.010

[11]

[11] Gu, L., Santra, S., Mericle, R.A. and Kumar, A.V., Finite element analysis of covered microstents, J. Biomech., 38(6), pp. 1221-1227, 2005. DOI: 10.1016/j.jbiomech.2004.06.008

Santra

Mericle

R.A.

Kumar

A.V

Finite element analysis of covered microstents

J. Biomech 38 6 1221 1227 2005

10.1016/j.jbiomech.2004.06.008

[12]

[12] Hopkins, C.G., McHugh, P.E. and McGarry, J.P., Computational investigation of the delamination of polymer coatings during stent deployment, Ann. Biomed. Eng., 38(7), pp. 2263-2273, 2010. DOI: 10.1007/s10439-010-9972-y

Hopkins

C.G.

McHugh

P.E.

McGarry

J.P

Computational investigation of the delamination of polymer coatings during stent deployment,

Ann. Biomed. Eng 38 7 2263 2273 2010

10.1007/s10439-010-9972-y

[13]

[13] Schiavone, A., Zhao, L.G. and Abdel-Wahab, A.A., Effects of material, coating, design and plaque composition on stent deployment inside a stenotic artery - Finite element simulation, Mater. Sci. Eng. C, 42, pp. 479-488, 2014. DOI: 10.1016/j.msec.2014.05.057

Schiavone

Zhao

L.G.

Abdel-Wahab

A.A

Effects of material, coating, design and plaque composition on stent deployment inside a stenotic artery - Finite element simulation

Mater. Sci. Eng. C 42 479 488 2014

10.1016/j.msec.2014.05.057

[14]

[14] Barrett, P. and Fridline, D., User implemented nitinol material model in ANSYS. In: International ANSYS Conference, May 24-26, Pittsburgh, PA, United States, 2004.

Barrett

Fridline

User implemented nitinol material model in ANSYS International ANSYS Conference

Pittsburgh, PA, United States

2004

[15]

[15] Barrett, P. and Cunningham P., Super Elastic alloy eyeglass frame design using the ANSYS workbench environment. In: International ANSYS Conference, May 24-26, Pittsburgh, PA, United States. 2004.

Barrett

Cunningham

Super Elastic alloy eyeglass frame design using the ANSYS workbench environment International ANSYS Conference

Pittsburgh, PA, United States

2004

[16]

[16] Nitinol Devices and Components., Material data sheet shape memory nitinol alloys. [online]. [cited March, 2016]. Available at: Available at: https://confluentmedical.com/wp-content/uploads/2016/01/Material-Data-Sheet-Shape-Memory.pdf

Nitinol Devices and Components

Material data sheet shape memory nitinol alloys March, 2016 Available at: https://confluentmedical.com/wp-content/uploads/2016/01/Material-Data-Sheet-Shape-Memory.pdf

[17]

[17] Divringi, K. and Ozcan, C., Advanced shape memory alloy material models for ansys. Ozen Engineering Inc, 2009.

Divringi

Ozcan

Advanced shape memory alloy material models for ansys Ozen Engineering Inc 2009

[18]

[18] Ali, A., Fouladi, M.H. and Sahari, B., A review of constitutive models for rubber-like materials, Am. J. Eng. Appl. Sci., 3(1), pp. 232-239, 2010. DOI: 10.3844/ajeassp.2010.232.239

Ali

Fouladi

M.H.

Sahari

A review of constitutive models for rubber-like materials

Am. J. Eng. Appl. Sci 3 1 232 239 2010

10.3844/ajeassp.2010.232.239

[19]

[19] Karimi, A., Navidbakhsh, M. and Haghpanahi, M., Constitutive model for numerical analysis of polyvinyl alcohol sponge under different strain rates. J. Thermoplast. Compos. Mater., 20, pp. 1601-1604, 2014. DOI: 10.1177/0892705713520176.

Karimi

Navidbakhsh

Haghpanahi

Constitutive model for numerical analysis of polyvinyl alcohol sponge under different strain rates

J. Thermoplast. Compos. Mater 20 1601 1604 2014

10.1177/0892705713520176

[20]

[20] Hsiao, H.M., Lee, K.H., Liao, Y.C. and Cheng, Y.C., Hemodynamic simulation of intra-stent blood flow. Procedia Eng., 36, pp. 128-136, 2012. DOI: 10.1016/j.proeng.2012.03.020.

Hsiao

H.M.

Lee

K.H.

Liao

Y.C.

Cheng

Y.C

Hemodynamic simulation of intra-stent blood flow

Procedia Eng 36 128 136 2012

10.1016/j.proeng.2012.03.020

[21]

[21] Soulis, J.V., Giannoglou, G.D., Chatzizisis, Y.S., Seralidou, K.V., Parcharidis, G.E. and Louridas, G.E., Non-Newtonian models for molecular viscosity and wall shear stress in a 3D reconstructed human left coronary artery. Med. Eng. Phys., 30(1), pp. 9-19, 2008. DOI: 10.1016/j.medengphy.2007.02.001

Soulis

J.V.

Giannoglou

G.D.

Chatzizisis

Y.S.

Seralidou

K.V.

Parcharidis

G.E.

Louridas

G.E

Non-Newtonian models for molecular viscosity and wall shear stress in a 3D reconstructed human left coronary artery

Med. Eng. Phys 30 1 9 19 2008

10.1016/j.medengphy.2007.02.001

[22]

[22] Sinnott, M., Cleary, P.W. and Prakash, M., An investigation of pulsatile blood flow in a bifurcation artery using a grid-free method. In: Proc. Fifth Int. Conf. CFD Process Ind., December 13-15, Melbourne, Australia. 2006

Sinnott

Cleary

P.W.

Prakash

An investigation of pulsatile blood flow in a bifurcation artery using a grid-free method Proc. Fifth Int. Conf. CFD Process Ind

Melbourne, Australia

2006

[23]

[23] ANSYS, Meshing User’s Guide, ANSYS Inc., Technology Drive Canonsburg, PA, 2013.

ANSYS

Meshing User’s Guide ANSYS Inc.

Technology Drive Canonsburg, PA

2013

[24]

[24] ANSYS, Fluent User’s Guide, ANSYS Inc., 2013, 2498 P.

ANSYS

Fluent User’s Guide ANSYS Inc 2013 2498 2498

[25]

[25] Catalog Teleflex. Catéter de dilatación con balón arrow GPSCATHTM.

Catalog Teleflex

Catéter de dilatación con balón arrow GPSCATHTM

[26]

[26] ANSYS, Mechanical User’s Guide, ANSYS Inc., 2014, pp. 724-746.

ANSYS

Mechanical User’s Guide ANSYS Inc 2014 724 746

[27]

[27] Lage, M., Simulación del flujo sanguíneo en una anastomosis arterial. Tesis, Universidad Pontificia Comillas, Madrid, España, 2011.

Lage

Simulación del flujo sanguíneo en una anastomosis arterial Tesis

Universidad Pontificia Comillas

Madrid, España

2011

J. Perez-Arrieta,

received the BSc. Eng in Mechanical Engineering in 2007, from the Universidad Pontificia Bolivariana, Colombia, the MSc. in Bioengineering in 2017, His research interests include: computational biomedicine and bioengineering, computational mechanics, porous media. ORCID: 0000-0003-3867-4986

A. Hernandez-Marulanda,

received the Bs. Eng in Electronic Engineering in 2005, and the PhD in Bioengineering - Computational Mechanics in 2018, all of them from the Universidad Pontificia Bolivariana. From 2016 to present, he is professor in the Biomedical Engineering, in the Instituto Tecnológico Metropolitano, Medellín, Colombia. Currently, he is full time professor in engineering, in the Universidad San Buenaventura, Colombia. His research interests include: boundary element methods, computational biomedicine and bioengineering, computational mechanics. ORCID: 0000-0001-8098-2427

R. Valencia-Cardona,

received the BSc. Eng in Textile Engineering in 1996, from the Universidad Pontificia Bolivariana, Colombia. The BSc in Mechanical Design Advanced in 2007, the MSc. in Mechanical Engineering - Computational Mechanics in 2008, and the PhD degree in Engineering - Computational Mechanics in 2015, all of them from the Universidad Eafit, Medellin, Colombia. From 2000 to present, he is full professor in the School of Mechanical and Nanotechnology Engineering, Universidad Pontificia Bolivariana. Currently, he is the director of Automatics and Design research group A+D (https://goo.gl/pNuyoA). His research interests include: multiscale methods, computational biomedicine and bioengineering, computational mechanics, porous media. ORCID: 0000-0002-3763-3034

L. Hoyos-Palacio

is a BSc. in Chemical Engineer in 2005, from the Universidad Nacional de Colombia, Medellín. In 2006, she began her PhD and became a researcher of the New Materials Research Group at the Universidad Pontificia Bolivariana, Medellín Colombia. In 2011 he completed his Dr. in Engineering, Energy and Thermodynamics. She is coordinator of the nanosystems research line of the Systems Biology research group of the Universidad Pontificia Bolivariana, Colombia. He has published several articles in indexed journals and has participated in international symposia. He participates as an evaluator of projects for Colciencias and as an article reviewer. ORCID: 0000-0003-2430-8504

How to cite:

Pérez-Arrieta, J, Hernández-Marulanda, A.F, Hoyos-Palacio, L. and Valencia-Cardona, R, Fluid-structure study of a polymeric coating reinforced with carbon nanotubes (CNT) for potential application in stents. DYNA, 86(211), pp. 300-307, October - December, 2019.