Literature DB >> 12628831

Collapse pressures of biodegradable stents.

Subbu Venkatraman1, Tan Lay Poh, Tjong Vinalia, Koon Hou Mak, Freddy Boey.   

Abstract

Biodegradable stent prototypes were produced from poly L-lactic acid polymers with different molecular weights. The effects of molecular weight, drug incorporation and stent design on the collapse pressure of the stents were evaluated. While molecular weights did not show a significant effect on the collapse pressure of the stents, drug incorporation at high percentage decreased the collapse pressure of the stents substantially. Cryogenic fracture surfaces showed significant drug agglomeration as the concentration increased. The design of the stent was also found to a have significant effect on the collapse pressure. The stent produced from the same material has a higher collapse pressure when the load bearing surface area is increased.

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Year:  2003        PMID: 12628831     DOI: 10.1016/s0142-9612(02)00640-3

Source DB:  PubMed          Journal:  Biomaterials        ISSN: 0142-9612            Impact factor:   12.479


  12 in total

Review 1.  Enhancing Stent Effectiveness with Nanofeatures.

Authors:  Nicole Bassous; John P Cooke; Thomas J Webster
Journal:  Methodist Debakey Cardiovasc J       Date:  2016-09

2.  A shape memory stent of poly(ε-caprolactone-co-DL-lactide) copolymer for potential treatment of esophageal stenosis.

Authors:  Xiongjun Yu; Lin Wang; Maotao Huang; Tao Gong; Wenbing Li; Yaling Cao; Daijin Ji; Ping Wang; Jing Wang; Shaobing Zhou
Journal:  J Mater Sci Mater Med       Date:  2011-11-05       Impact factor: 3.896

3.  Endovascular treatment of the vertebral artery origin stenosis by using the closed-cell, self-expandable Carotid Wallstent.

Authors:  Jun-Kyeung Ko; Chang-Hwa Choi; Lee Hwangbo; Hie-Bum Suh; Tae-Hong Lee; Han-Jin Cho; Sang-Min Sung
Journal:  Interv Neuroradiol       Date:  2020-06-20       Impact factor: 1.610

4.  In vivo degradation of copolymers prepared from L-lactide, 1,3-trimethylene carbonate and glycolide as coronary stent materials.

Authors:  Yuan Yuan; Xiaoyun Jin; Zhongyong Fan; Suming Li; Zhiqian Lu
Journal:  J Mater Sci Mater Med       Date:  2015-02-26       Impact factor: 3.896

5.  Ductile electroactive biodegradable hyperbranched polylactide copolymers enhancing myoblast differentiation.

Authors:  Meihua Xie; Ling Wang; Baolin Guo; Zhong Wang; Y Eugene Chen; Peter X Ma
Journal:  Biomaterials       Date:  2015-08-20       Impact factor: 12.479

6.  Thermomechanical properties, collapse pressure, and expansion of shape memory polymer neurovascular stent prototypes.

Authors:  Géraldine M Baer; Thomas S Wilson; Ward Small; Jonathan Hartman; William J Benett; Dennis L Matthews; Duncan J Maitland
Journal:  J Biomed Mater Res B Appl Biomater       Date:  2009-07       Impact factor: 3.368

Review 7.  Translation in cardiovascular stents and occluders: From biostable to fully degradable.

Authors:  Yingying Huang; Yee Shan Wong; Herr Cheun Anthony Ng; Freddy Y C Boey; Subbu Venkatraman
Journal:  Bioeng Transl Med       Date:  2017-07-19

8.  Next generation drug-eluting stents: focus on bioabsorbable platforms and polymers.

Authors:  Brendan Doyle; David R Holmes
Journal:  Med Devices (Auckl)       Date:  2009-11-10

9.  Fabrication and in vitro deployment of a laser-activated shape memory polymer vascular stent.

Authors:  Géraldine M Baer; Ward Small; Thomas S Wilson; William J Benett; Dennis L Matthews; Jonathan Hartman; Duncan J Maitland
Journal:  Biomed Eng Online       Date:  2007-11-27       Impact factor: 2.819

10.  Promoting endothelial recovery and reducing neointimal hyperplasia using sequential-like release of acetylsalicylic acid and paclitaxel-loaded biodegradable stents.

Authors:  Cheng-Hung Lee; Chia-Ying Yu; Shang-Hung Chang; Kuo-Chun Hung; Shih-Jung Liu; Chao-Jan Wang; Ming-Yi Hsu; I-Chang Hsieh; Wei-Jan Chen; Yu-Shien Ko; Ming-Shien Wen
Journal:  Int J Nanomedicine       Date:  2014-08-27
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