Biocompatibility Studies of the Anaconda Stent-Graft and Observations of Nitinol Corrosion Resistance

Purpose: To validate the deployment, in vivo performance, biostability, and healing capacity of the Anaconda self-expanding endoprosthesis in a canine aortic aneurysm model. Methods: Aneurysms were surgically created in 12 dogs by sewing a woven polyester patch onto the anterior side of the thoracic...

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Published in:Journal of endovascular therapy 2004-08, Vol.11 (4), p.385-403
Main Authors: Guidoin, Robert, Douville, Yvan, Baslé, Michel F., King, Martin, Marinov, Georgi R., Traoré, Amidou, Zhang, Ze, Guillemot, Fabien, Dionne, Guy, Sumanasinghe, Ruwan, Legrand, André-Pierre, Guidoin, Marie-France, Porté-Durrieu, Marie-Christine, Baquey, Charles
Format: Article
Language:English
Subjects:
Alloys - chemistry
Alloys - therapeutic use
Angioplasty
Animals
Aortic Aneurysm, Abdominal - pathology
Aortic Aneurysm, Abdominal - surgery
Bioengineering
Blood Vessel Prosthesis
Blood Vessel Prosthesis Implantation
Corrosion
Disease Models, Animal
Dogs
Female
Life Sciences
Male
Materials Testing
Polyesters - therapeutic use
Prosthesis Design
Stents
Wound Healing
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cited_by cdi_FETCH-LOGICAL-c315t-f94dd00728a77cdc29316bdf2903fc2efd253dbaed5bc98c30a12e35c91feb5b3
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container_issue 4
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container_title Journal of endovascular therapy
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creator Guidoin, Robert
Douville, Yvan
Baslé, Michel F.
King, Martin
Marinov, Georgi R.
Traoré, Amidou
Zhang, Ze
Guillemot, Fabien
Dionne, Guy
Sumanasinghe, Ruwan
Legrand, André-Pierre
Guidoin, Marie-France
Porté-Durrieu, Marie-Christine
Baquey, Charles
description Purpose: To validate the deployment, in vivo performance, biostability, and healing capacity of the Anaconda self-expanding endoprosthesis in a canine aortic aneurysm model. Methods: Aneurysms were surgically created in 12 dogs by sewing a woven polyester patch onto the anterior side of the thoracic or abdominal aorta. Anaconda prostheses were implanted transfemorally for prescheduled periods (1 or 3 months). Aneurysm exclusion and stent-graft patency were monitored angiographically. Healing was assessed with histological analysis and scanning electron microscopy (SEM). Textile analysis determined the physical and chemical stability of the woven polyester material, while the biostability of the nitinol wires was evaluated with SEM and spectroscopy. Results: All prostheses were intact at explantation. After 1 month, endothelial-like cells were migrating in a discontinuous manner both proximally and distally over the internal collagenous pannus at the device-host boundary. After 3 months, endothelialization had reached the midsections of the devices, with a thicker collagenous internal capsule. Patches of endothelial-like cells were sharing the luminal surface with thrombotic deposits. However, the wall of the device at the level of the aneurysm was generally poorly healed, with multiple thrombi scattered irregularly over the luminal surface. The polyester fabric was intact except for some filaments that were ruptured adjacent to the sutures and some abrasion caused by the nitinol wires. No evidence of corrosion was found on the nitinol stents. Conclusions: This Anaconda stent-graft has demonstrated its ability to exclude arterial aneurysms. The device used in this study was an experimental prototype, and the manufacturer has incorporated new immobilization features into the model for clinical use. The constituent materials appear to be suitable in terms of biocompatibility, biofunctionality, and short-term durability.
doi_str_mv 10.1583/03-1143.1
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Methods: Aneurysms were surgically created in 12 dogs by sewing a woven polyester patch onto the anterior side of the thoracic or abdominal aorta. Anaconda prostheses were implanted transfemorally for prescheduled periods (1 or 3 months). Aneurysm exclusion and stent-graft patency were monitored angiographically. Healing was assessed with histological analysis and scanning electron microscopy (SEM). Textile analysis determined the physical and chemical stability of the woven polyester material, while the biostability of the nitinol wires was evaluated with SEM and spectroscopy. Results: All prostheses were intact at explantation. After 1 month, endothelial-like cells were migrating in a discontinuous manner both proximally and distally over the internal collagenous pannus at the device-host boundary. After 3 months, endothelialization had reached the midsections of the devices, with a thicker collagenous internal capsule. Patches of endothelial-like cells were sharing the luminal surface with thrombotic deposits. However, the wall of the device at the level of the aneurysm was generally poorly healed, with multiple thrombi scattered irregularly over the luminal surface. The polyester fabric was intact except for some filaments that were ruptured adjacent to the sutures and some abrasion caused by the nitinol wires. No evidence of corrosion was found on the nitinol stents. Conclusions: This Anaconda stent-graft has demonstrated its ability to exclude arterial aneurysms. The device used in this study was an experimental prototype, and the manufacturer has incorporated new immobilization features into the model for clinical use. 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Patches of endothelial-like cells were sharing the luminal surface with thrombotic deposits. However, the wall of the device at the level of the aneurysm was generally poorly healed, with multiple thrombi scattered irregularly over the luminal surface. The polyester fabric was intact except for some filaments that were ruptured adjacent to the sutures and some abrasion caused by the nitinol wires. No evidence of corrosion was found on the nitinol stents. Conclusions: This Anaconda stent-graft has demonstrated its ability to exclude arterial aneurysms. The device used in this study was an experimental prototype, and the manufacturer has incorporated new immobilization features into the model for clinical use. 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subjects Alloys - chemistry
Alloys - therapeutic use
Angioplasty
Animals
Aortic Aneurysm, Abdominal - pathology
Aortic Aneurysm, Abdominal - surgery
Bioengineering
Blood Vessel Prosthesis
Blood Vessel Prosthesis Implantation
Corrosion
Disease Models, Animal
Dogs
Female
Life Sciences
Male
Materials Testing
Polyesters - therapeutic use
Prosthesis Design
Stents
Wound Healing
title Biocompatibility Studies of the Anaconda Stent-Graft and Observations of Nitinol Corrosion Resistance
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