Estudo experimental comparativo de remendos arteriais de polidimetilsiloxano com reforço de tecido de poliéster (PDMSr) versus politetrafluoretileno expandido (PTFEe) em aorta de coelhos / Patch of polydimethylsiloxane reinforced with polyester fabric for aortic angioplasty in rabbits

Sassaki Neto, Paulo Isao

15 October 2014

Introdução: Apesar de bons resultados descritos na literatura, o substituto ideal para a utilização como remendo no fechamento arterial ainda não existe. Por este motivo, ainda há espaço para a busca por remendo que seja biocompatível, e que apresente facilidade de manuseio e resultados satisfatórios. Avaliamos remendos arteriais de silicone (polidimetilsiloxano com reforço em poliéster - PDMSr) em comparação com remendos arteriais de PTFEe. Objetivo: O objetivo deste trabalho é comparar, em modelo experimental, em coelhos, os resultados de remendos arteriais feitos em PDMSr com remendos de PTFEe. Materiais e Método: A amostra foi definida em 10 animais que completassem todas as etapas da pesquisa em cada grupo. Os animais foram submetidos à laparotomia mediana e abertura longitudinal da aorta de aproximadamente 8mm, realizando-se o seu fechamento com remendo do grupo selecionado, seguido do fechamento por planos. Os animais foram mantidos em biotério até o 60º PO, quando, então, realizou-se arteriografia de controle, e análise macro e microscópica de peça. Resultados: Para se atingir a amostra desejada, foram necessários 12 procedimentos no grupo PDMSr e 16 no grupo PTFEe. Ocorreram 2 óbitos no grupo PDMSr e 6 no grupo PTFEe. Apesar do número maior de óbitos no grupo PTFEe não houve diferença estatística na sobrevida entre os grupos. Um animal do grupo PDMSr apresentou monoparesia em pata posterior direita e um animal do grupo PTFEe apresentou hérnia incisional. Não houve diferença estatística nas complicações entre os grupos. O tempo operatório foi estatisticamente maior no grupo PTFEe quando comparamos todos os animais, fato que não se repetiu quando excluímos os animais que faleceram. O peso e o tempo operatório foram estatisticamente maiores nos animais que morreram. Todos os animais que chegaram ao final do tempo de estudo apresentavam aorta patente. Na análise macroscópica da peça, houve, estatisticamente, maior reação tecidual periprótese no grupo PTFEe. A microscopia eletrônica de varredura evidenciou cobertura de todo o remendo de PDMSr por tecido similar ao endotélio, enquanto, nos remendos de PTFEe, o crescimento limitou-se às bordas da linha de sutura e ilhas isoladas no seu centro. Conclusão: O material estudado apresentou resultados comparáveis ao do PTFEe, porém com menor reação tecidual local e maior proliferação celular para a luz do vaso. Apesar de novos estudos serem necessários, inclusive para avaliação de uso em humanos, o presente estudo apresenta resultados promissores que encorajam a continuidade de sua pesquisa / Introduction: Although good results are reported for various materials for use as patches for arterial closure, as yet none of these is ideal. Therefore, research is continuing into development of a patch that is biocompatible and provides ease of handling, while having satisfactory outcomes. A new silicone arterial patch (polydimethylsiloxane reinforced with polyester fabric, PDMSr) was compared with patches made of expanded polytetrafluoroethylene (ePTFE). Objective: To compare the outcomes between arterial patches made of PDMSr with those made of ePTFE, in an experimental rabbit model. Materials and Method: Rabbits were placed in two groups, and received either PDMSr or ePTFE arterial patches (PDMSr group and ePTFE group, respectively). The animals underwent laparotomy and longitudinal opening of the aorta, which was then closed with the selected patch, followed by suture of all layers. The animals were kept in their cages until the 60th postoperative day, when arteriography, removal of the aorta, and macroscopic and optic and scanning electron microscopic analyzes of the aorta were performed. Ten rabbits from each group that had completed all stages of the research were included in analyses. Results: Twelve procedures were performed in the PDMSr group and 16 in the ePTFE group. There were 2 deaths in the PDMSr group and 6 in the ePTFE group. Despite the higher number of deaths in the ePTFE group, there was no statistical difference in survival rate between the groups. One animal in the PDMSr group developed monoparesis in its right hind paw and 1 animal in the ePTFE group had an incisional hernia. There was no statistical difference in complications between the groups. The operative time was significantly longer in the ePTFE group when all animals were included in analysis, but not when animals that died were excluded. Body weight was significantly greater and operative time was significantly longer in animals that died. Postsurgical aortic patency in the survival animals was 100% in both groups by arteriography. Macroscopically, tissue reaction around the prosthesis was greater in the ePTFE group (statistically significant). Microscopically, the PDMSr patches were entirely covered with a cellular endothelium-like tissue, while tissue growth on the ePTFE patches was limited to the edges of the suture line and to isolated central islands. Conclusion: The two materials showed comparable outcomes; however, PDMSr showed cellular proliferation to the entire graft, and less local inflammatory reaction compared with ePTFE. Although further studies are required, including assessment in humans, the results of the present study indicate that PDMSr shows promise as an arterial patch material

Abdominal/surgery

Aorta abdominal/cirurgia

Coelhos

Comparative study

Degree of vascular patency

Dimethylpolysiloxanes

Dimetilpolisiloxanos

Endotélio vascular

Enxerto vascular

Estudo comparativo

Experimental implants

Grau de desobstrução vascular

Implante de prótese vascular

Implantes experimentais

Poliésteres

Politetrafluoretileno

Polyesters

Polytetrafluoroethylene

Prótese vascular

Rabbits

Silicones

Silicones

Vascular endothelium

Vascular graft

Vascular prosthesis

Vascular prosthesis implantation

Mechanical optimization of vascular bypass grafts

Felden, Luc

14 April 2005

Synthetic vascular grafts are useful to bypass diseased arteries. The long-term failure of synthetic grafts is primarily due to intimal hyperplasia at the anastomotic sites. The accelerated intimal hyperplasia may stem from a compliance mismatch between the host artery and the graft since commercially available synthetic conduits are much stiffer than an artery. The objective of this thesis is to design a method for fabricating a vascular graft that mechanically matches the patients native artery over the expected physiologic range of pressures. The creation of an optimized mechanical graft will hopefully lead to an improvement in patency rates. The mechanical equivalency between the graft and the host artery is defined locally by several criteria including the diameter upon inflation, the elasticity at mean pressure, and axial force. A single parameter mathematical for a thin-walled tube is used to describe of the final mechanical behavior of a synthetic graft. For the general problem, the objective would be to fabricate a mechanics-matching vascular graft for each host artery. Typically, fabrication parameters are set initially and the properties of the fabricated graft are measured. However, by modeling the entire fabrication process and final mechanical properties, it is possible to invert the situation and let the typical output mechanical values be used to define the fabrication parameters. The resultant fabricated graft will then be mechanically matching. As a proof-of-concept, several prototype synthetic grafts were manufactured and characterized by a single Invariant to match a canine artery. The resultant graft equaled the diameter upon inflation, the elasticity at mean pressure, and axial force of the native canine artery within 6%. An alternative to making an individual graft for each artery is also presented. A surgeon may choose the best graft from a set of pre-manufactured grafts, using a computer program algorithm for best fit using two parameters in a neighborhood. The design optimization problem was solved for both canine carotid and human coronary arteries. In conclusion, the overall process of design, fabrication and selection of a mechanics matching synthetic vascular graft is shown to be reliable and robust.

Biomechanics

Burst pressure of grafts

Bypass graft anastomosis

CABG

Compliance mismatch

Constitutive laws

Coronary arteries

Elastic modulus

Finite deformations

Graft prototypes

Mechanics matching

Nonlinear elasticity

Optimal graft selection

Patient's specific graft

Small vascular prosthesis

Soft tissue mechanics

Strain energy density function

Synthetic vascular graft

Estudo experimental comparativo de remendos arteriais de polidimetilsiloxano com reforço de tecido de poliéster (PDMSr) versus politetrafluoretileno expandido (PTFEe) em aorta de coelhos / Patch of polydimethylsiloxane reinforced with polyester fabric for aortic angioplasty in rabbits

Paulo Isao Sassaki Neto

15 October 2014

Introdução: Apesar de bons resultados descritos na literatura, o substituto ideal para a utilização como remendo no fechamento arterial ainda não existe. Por este motivo, ainda há espaço para a busca por remendo que seja biocompatível, e que apresente facilidade de manuseio e resultados satisfatórios. Avaliamos remendos arteriais de silicone (polidimetilsiloxano com reforço em poliéster - PDMSr) em comparação com remendos arteriais de PTFEe. Objetivo: O objetivo deste trabalho é comparar, em modelo experimental, em coelhos, os resultados de remendos arteriais feitos em PDMSr com remendos de PTFEe. Materiais e Método: A amostra foi definida em 10 animais que completassem todas as etapas da pesquisa em cada grupo. Os animais foram submetidos à laparotomia mediana e abertura longitudinal da aorta de aproximadamente 8mm, realizando-se o seu fechamento com remendo do grupo selecionado, seguido do fechamento por planos. Os animais foram mantidos em biotério até o 60º PO, quando, então, realizou-se arteriografia de controle, e análise macro e microscópica de peça. Resultados: Para se atingir a amostra desejada, foram necessários 12 procedimentos no grupo PDMSr e 16 no grupo PTFEe. Ocorreram 2 óbitos no grupo PDMSr e 6 no grupo PTFEe. Apesar do número maior de óbitos no grupo PTFEe não houve diferença estatística na sobrevida entre os grupos. Um animal do grupo PDMSr apresentou monoparesia em pata posterior direita e um animal do grupo PTFEe apresentou hérnia incisional. Não houve diferença estatística nas complicações entre os grupos. O tempo operatório foi estatisticamente maior no grupo PTFEe quando comparamos todos os animais, fato que não se repetiu quando excluímos os animais que faleceram. O peso e o tempo operatório foram estatisticamente maiores nos animais que morreram. Todos os animais que chegaram ao final do tempo de estudo apresentavam aorta patente. Na análise macroscópica da peça, houve, estatisticamente, maior reação tecidual periprótese no grupo PTFEe. A microscopia eletrônica de varredura evidenciou cobertura de todo o remendo de PDMSr por tecido similar ao endotélio, enquanto, nos remendos de PTFEe, o crescimento limitou-se às bordas da linha de sutura e ilhas isoladas no seu centro. Conclusão: O material estudado apresentou resultados comparáveis ao do PTFEe, porém com menor reação tecidual local e maior proliferação celular para a luz do vaso. Apesar de novos estudos serem necessários, inclusive para avaliação de uso em humanos, o presente estudo apresenta resultados promissores que encorajam a continuidade de sua pesquisa / Introduction: Although good results are reported for various materials for use as patches for arterial closure, as yet none of these is ideal. Therefore, research is continuing into development of a patch that is biocompatible and provides ease of handling, while having satisfactory outcomes. A new silicone arterial patch (polydimethylsiloxane reinforced with polyester fabric, PDMSr) was compared with patches made of expanded polytetrafluoroethylene (ePTFE). Objective: To compare the outcomes between arterial patches made of PDMSr with those made of ePTFE, in an experimental rabbit model. Materials and Method: Rabbits were placed in two groups, and received either PDMSr or ePTFE arterial patches (PDMSr group and ePTFE group, respectively). The animals underwent laparotomy and longitudinal opening of the aorta, which was then closed with the selected patch, followed by suture of all layers. The animals were kept in their cages until the 60th postoperative day, when arteriography, removal of the aorta, and macroscopic and optic and scanning electron microscopic analyzes of the aorta were performed. Ten rabbits from each group that had completed all stages of the research were included in analyses. Results: Twelve procedures were performed in the PDMSr group and 16 in the ePTFE group. There were 2 deaths in the PDMSr group and 6 in the ePTFE group. Despite the higher number of deaths in the ePTFE group, there was no statistical difference in survival rate between the groups. One animal in the PDMSr group developed monoparesis in its right hind paw and 1 animal in the ePTFE group had an incisional hernia. There was no statistical difference in complications between the groups. The operative time was significantly longer in the ePTFE group when all animals were included in analysis, but not when animals that died were excluded. Body weight was significantly greater and operative time was significantly longer in animals that died. Postsurgical aortic patency in the survival animals was 100% in both groups by arteriography. Macroscopically, tissue reaction around the prosthesis was greater in the ePTFE group (statistically significant). Microscopically, the PDMSr patches were entirely covered with a cellular endothelium-like tissue, while tissue growth on the ePTFE patches was limited to the edges of the suture line and to isolated central islands. Conclusion: The two materials showed comparable outcomes; however, PDMSr showed cellular proliferation to the entire graft, and less local inflammatory reaction compared with ePTFE. Although further studies are required, including assessment in humans, the results of the present study indicate that PDMSr shows promise as an arterial patch material

Aorta abdominal/cirurgia

Coelhos

Dimetilpolisiloxanos

Endotélio vascular

Enxerto vascular

Estudo comparativo

Grau de desobstrução vascular

Implante de prótese vascular

Implantes experimentais

Poliésteres

Politetrafluoretileno

Prótese vascular

Silicones

Abdominal/surgery

Comparative study

Degree of vascular patency

Dimethylpolysiloxanes

Experimental implants

Polyesters

Polytetrafluoroethylene

Rabbits

Silicones

Vascular endothelium

Vascular graft

Vascular prosthesis

Vascular prosthesis implantation

Fluid dynamic assessments of spiral flow induced by vascular grafts

Kokkalis, Efstratios

January 2014

Peripheral vascular grafts are used for the treatment of peripheral arterial disease and arteriovenous grafts for vascular access in end stage renal disease. The development of neo-intimal hyperplasia and thrombosis in the distal anastomosis remains the main reason for occlusion in that region. The local haemodynamics produced by a graft in the host vessel is believed to significantly affect endothelial function. Single spiral flow is a normal feature in medium and large sized vessels and it is induced by the anatomical structure and physiological function of the cardiovascular system. Grafts designed to generate a single spiral flow in the distal anastomosis have been introduced in clinical practice and are known as spiral grafts. In this work, spiral peripheral vascular and arteriovenous grafts were compared with conventional grafts using ultrasound and computational methods to identify their haemodynamic differences. Vascular-graft flow phantoms were developed to house the grafts in different surgical configurations. Mimicking components, with appropriate acoustic properties, were chosen to minimise ultrasound beam refraction and distortion. A dual-beam two-dimensional vector Doppler technique was developed to visualise and quantify vortical structures downstream of each graft outflow in the cross-flow direction. Vorticity mapping and measurements of circulation were acquired based on the vector Doppler data. The flow within the vascular-graft models was simulated with computed tomography based image-guided modelling for further understanding of secondary flow motions and comparison with the experimental results. The computational assessments provided a three-dimensional velocity field in the lumen of the models allowing a range of fluid dynamic parameters to be predicted. Single- or double-spiral flow patterns consisting of a dominant and a smaller vortex were detected in the outflow of the spiral grafts. A double- triple- or tetra-spiral flow pattern was found in the outflow of the conventional graft, depending on model configuration and Reynolds number. These multiple-spiral patterns were associated with increased flow stagnation, separation and instability, which are known to be detrimental for endothelial behaviour. Increased in-plane mixing and wall shear stress, which are considered atheroprotective in normal vessels, were found in the outflow of the spiral devices. The results from the experimental approach were in agreement with those from the computational approach. This study applied ultrasound and computational methods to vascular-graft phantoms in order to characterise the flow field induced by spiral and conventional peripheral vascular and arteriovenous grafts. The results suggest that spiral grafts are associated with advanced local haemodynamics that may protect endothelial function and thereby may prevent their outflow anastomosis from neo-intimal hyperplasia and thrombosis. Consequently this work supports the hypothesis that spiral grafts may decrease outflow stenosis and hence improve patency rates in patients.

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