Antithrombotic Protein Filter Composed of Hybrid Tissue-Fabric Material has a Long Lifetime

Yusuke Inoue; Tomoyuki Yokota; Tsuyoshi Sekitani; Akiko Kaneko; Taeseong Woo; Shingo Kobayashi; Tomokazu Shibuya; Masaru Tanaka; Hiroyuki Kosukegawa; Itsuro Saito; Takashi Isoyama; Yusuke Abe; Tomoyuki Yambe; Takao Someya; Masaki Sekino

doi:10.1007/s10439-016-1781-5

Antithrombotic Protein Filter Composed of Hybrid Tissue-Fabric Material has a Long Lifetime

Yusuke Inoue, Tomoyuki Yokota, Tsuyoshi Sekitani, Akiko Kaneko, Taeseong Woo, Shingo Kobayashi, Tomokazu Shibuya, Masaru Tanaka, Hiroyuki Kosukegawa, Itsuro Saito, Takashi Isoyama, Yusuke Abe, Tomoyuki Yambe, Takao Someya, Masaki Sekino

Research output: Contribution to journal › Article › peer-review

3 Citations (Scopus)

Abstract

There are recent reports of hybrid tissue–fabric materials with good performance—high biocompatibility and high mechanical strength. In this study, we demonstrate the capability of a hybrid material as a long-term filter for blood proteins. Polyester fabrics were implanted into rats to fabricate hybrid tissue–fabric material sheets. The hybrid materials comprised biological tissue grown on the fabric. The materials were extracted from the rat’s body, approximately 100 days post-implantation. The tissues were decellularized to prevent immunological rejection. An antithrombogenicity test was performed by dropping blood onto the hybrid material surface. The hybrid material showed lesser blood coagulation than polysulfone and cellulose. Blood plasma was filtered using the hybrid material to evaluate the protein removal percentage and the lifetime of the hybrid material in vitro. The hybrid material showed a comparable performance to conventional filters for protein removal. Moreover, the hybrid material could work as a protein filter for 1 month, which is six times the lifetime of polysulfone.

Original language	English
Pages (from-to)	1352-1364
Number of pages	13
Journal	Annals of Biomedical Engineering
Volume	45
Issue number	5
DOIs	https://doi.org/10.1007/s10439-016-1781-5
Publication status	Published - 2017 May 1

Keywords

Blood coagulation
Decellularization
Glucose sensor
Protein filter
Scaffold

ASJC Scopus subject areas

Biomedical Engineering

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10.1007/s10439-016-1781-5

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Inoue, Y., Yokota, T., Sekitani, T., Kaneko, A., Woo, T., Kobayashi, S., Shibuya, T., Tanaka, M., Kosukegawa, H., Saito, I., Isoyama, T., Abe, Y., Yambe, T., Someya, T., & Sekino, M. (2017). Antithrombotic Protein Filter Composed of Hybrid Tissue-Fabric Material has a Long Lifetime. Annals of Biomedical Engineering, 45(5), 1352-1364. https://doi.org/10.1007/s10439-016-1781-5

Inoue, Y, Yokota, T, Sekitani, T, Kaneko, A, Woo, T, Kobayashi, S, Shibuya, T, Tanaka, M, Kosukegawa, H, Saito, I, Isoyama, T, Abe, Y, Yambe, T, Someya, T & Sekino, M 2017, 'Antithrombotic Protein Filter Composed of Hybrid Tissue-Fabric Material has a Long Lifetime', Annals of Biomedical Engineering, vol. 45, no. 5, pp. 1352-1364. https://doi.org/10.1007/s10439-016-1781-5

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abstract = "There are recent reports of hybrid tissue–fabric materials with good performance—high biocompatibility and high mechanical strength. In this study, we demonstrate the capability of a hybrid material as a long-term filter for blood proteins. Polyester fabrics were implanted into rats to fabricate hybrid tissue–fabric material sheets. The hybrid materials comprised biological tissue grown on the fabric. The materials were extracted from the rat{\textquoteright}s body, approximately 100 days post-implantation. The tissues were decellularized to prevent immunological rejection. An antithrombogenicity test was performed by dropping blood onto the hybrid material surface. The hybrid material showed lesser blood coagulation than polysulfone and cellulose. Blood plasma was filtered using the hybrid material to evaluate the protein removal percentage and the lifetime of the hybrid material in vitro. The hybrid material showed a comparable performance to conventional filters for protein removal. Moreover, the hybrid material could work as a protein filter for 1 month, which is six times the lifetime of polysulfone.",

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author = "Yusuke Inoue and Tomoyuki Yokota and Tsuyoshi Sekitani and Akiko Kaneko and Taeseong Woo and Shingo Kobayashi and Tomokazu Shibuya and Masaru Tanaka and Hiroyuki Kosukegawa and Itsuro Saito and Takashi Isoyama and Yusuke Abe and Tomoyuki Yambe and Takao Someya and Masaki Sekino",

note = "Funding Information: The authors gratefully acknowledge Dr. Yoshinori Mitamura and Hidemoto Nakagawa for their helpful in-depth discussions on this study. This study was supported by JST ERATO. The strength test of hybrid material was supported by the cooperation program of research institutes in Tohoku University. Publisher Copyright: {\textcopyright} 2017, Biomedical Engineering Society.",

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AU - Inoue, Yusuke

AU - Yokota, Tomoyuki

AU - Sekitani, Tsuyoshi

AU - Kaneko, Akiko

AU - Woo, Taeseong

AU - Kobayashi, Shingo

AU - Shibuya, Tomokazu

AU - Tanaka, Masaru

AU - Kosukegawa, Hiroyuki

AU - Saito, Itsuro

AU - Isoyama, Takashi

AU - Abe, Yusuke

AU - Yambe, Tomoyuki

AU - Someya, Takao

AU - Sekino, Masaki

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Y1 - 2017/5/1

N2 - There are recent reports of hybrid tissue–fabric materials with good performance—high biocompatibility and high mechanical strength. In this study, we demonstrate the capability of a hybrid material as a long-term filter for blood proteins. Polyester fabrics were implanted into rats to fabricate hybrid tissue–fabric material sheets. The hybrid materials comprised biological tissue grown on the fabric. The materials were extracted from the rat’s body, approximately 100 days post-implantation. The tissues were decellularized to prevent immunological rejection. An antithrombogenicity test was performed by dropping blood onto the hybrid material surface. The hybrid material showed lesser blood coagulation than polysulfone and cellulose. Blood plasma was filtered using the hybrid material to evaluate the protein removal percentage and the lifetime of the hybrid material in vitro. The hybrid material showed a comparable performance to conventional filters for protein removal. Moreover, the hybrid material could work as a protein filter for 1 month, which is six times the lifetime of polysulfone.

AB - There are recent reports of hybrid tissue–fabric materials with good performance—high biocompatibility and high mechanical strength. In this study, we demonstrate the capability of a hybrid material as a long-term filter for blood proteins. Polyester fabrics were implanted into rats to fabricate hybrid tissue–fabric material sheets. The hybrid materials comprised biological tissue grown on the fabric. The materials were extracted from the rat’s body, approximately 100 days post-implantation. The tissues were decellularized to prevent immunological rejection. An antithrombogenicity test was performed by dropping blood onto the hybrid material surface. The hybrid material showed lesser blood coagulation than polysulfone and cellulose. Blood plasma was filtered using the hybrid material to evaluate the protein removal percentage and the lifetime of the hybrid material in vitro. The hybrid material showed a comparable performance to conventional filters for protein removal. Moreover, the hybrid material could work as a protein filter for 1 month, which is six times the lifetime of polysulfone.

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Antithrombotic Protein Filter Composed of Hybrid Tissue-Fabric Material has a Long Lifetime

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