Literature DB >> 28445803

JetValve: Rapid manufacturing of biohybrid scaffolds for biomimetic heart valve replacement.

Andrew K Capulli1, Maximillian Y Emmert2, Francesco S Pasqualini3, Debora Kehl4, Etem Caliskan5, Johan U Lind1, Sean P Sheehy1, Sung Jin Park1, Seungkuk Ahn1, Benedikt Weber3, Josue A Goss1, Simon P Hoerstrup3, Kevin Kit Parker6.   

Abstract

Tissue engineered scaffolds have emerged as a promising solution for heart valve replacement because of their potential for regeneration. However, traditional heart valve tissue engineering has relied on resource-intensive, cell-based manufacturing, which increases cost and hinders clinical translation. To overcome these limitations, in situ tissue engineering approaches aim to develop scaffold materials and manufacturing processes that elicit endogenous tissue remodeling and repair. Yet despite recent advances in synthetic materials manufacturing, there remains a lack of cell-free, automated approaches for rapidly producing biomimetic heart valve scaffolds. Here, we designed a jet spinning process for the rapid and automated fabrication of fibrous heart valve scaffolds. The composition, multiscale architecture, and mechanical properties of the scaffolds were tailored to mimic that of the native leaflet fibrosa and assembled into three dimensional, semilunar valve structures. We demonstrated controlled modulation of these scaffold parameters and show initial biocompatibility and functionality in vitro. Valves were minimally-invasively deployed via transapical access to the pulmonary valve position in an ovine model and shown to be functional for 15 h.
Copyright © 2017 Elsevier Ltd. All rights reserved.

Entities:  

Keywords:  Biohybrid; Heart valve; Nanofiber; Rapid manufacture; Rotary Jet Spinning; Tissue engineering

Mesh:

Substances:

Year:  2017        PMID: 28445803      PMCID: PMC5526340          DOI: 10.1016/j.biomaterials.2017.04.033

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


  65 in total

1.  Functional living trileaflet heart valves grown in vitro.

Authors:  S P Hoerstrup; R Sodian; S Daebritz; J Wang; E A Bacha; D P Martin; A M Moran; K J Guleserian; J S Sperling; S Kaushal; J P Vacanti; F J Schoen; J E Mayer
Journal:  Circulation       Date:  2000-11-07       Impact factor: 29.690

2.  Decellularized homologous tissue-engineered heart valves as off-the-shelf alternatives to xeno- and homografts.

Authors:  Petra E Dijkman; Anita Driessen-Mol; Laura Frese; Simon P Hoerstrup; Frank P T Baaijens
Journal:  Biomaterials       Date:  2012-03-31       Impact factor: 12.479

Review 3.  EMT-inducing biomaterials for heart valve engineering: taking cues from developmental biology.

Authors:  M K Sewell-Loftin; Young Wook Chun; Ali Khademhosseini; W David Merryman
Journal:  J Cardiovasc Transl Res       Date:  2011-07-13       Impact factor: 4.132

Review 4.  A review of rapid prototyping techniques for tissue engineering purposes.

Authors:  Sanna M Peltola; Ferry P W Melchels; Dirk W Grijpma; Minna Kellomäki
Journal:  Ann Med       Date:  2008       Impact factor: 4.709

Review 5.  Rapid manufacturing techniques for the tissue engineering of human heart valves.

Authors:  Cora Lueders; Ben Jastram; Roland Hetzer; Hartmut Schwandt
Journal:  Eur J Cardiothorac Surg       Date:  2014-07-25       Impact factor: 4.191

Review 6.  Substrates for cardiovascular tissue engineering.

Authors:  C V C Bouten; P Y W Dankers; A Driessen-Mol; S Pedron; A M A Brizard; F P T Baaijens
Journal:  Adv Drug Deliv Rev       Date:  2011-01-25       Impact factor: 15.470

Review 7.  Heart Valve Replacements with Regenerative Capacity.

Authors:  Petra E Dijkman; Emanuela S Fioretta; Laura Frese; Francesco S Pasqualini; Simon P Hoerstrup
Journal:  Transfus Med Hemother       Date:  2016-07-26       Impact factor: 3.747

Review 8.  Micro and nanotechnologies in heart valve tissue engineering.

Authors:  Anwarul Hasan; John Saliba; Hassan Pezeshgi Modarres; Ahmed Bakhaty; Amir Nasajpour; Mohammad R K Mofrad; Amir Sanati-Nezhad
Journal:  Biomaterials       Date:  2016-07-02       Impact factor: 12.479

9.  Rapid 3D printing of anatomically accurate and mechanically heterogeneous aortic valve hydrogel scaffolds.

Authors:  L A Hockaday; K H Kang; N W Colangelo; P Y C Cheung; B Duan; E Malone; J Wu; L N Girardi; L J Bonassar; H Lipson; C C Chu; J T Butcher
Journal:  Biofabrication       Date:  2012-08-23       Impact factor: 9.954

10.  Decellularized tissue-engineered heart valve leaflets with recellularization potential.

Authors:  Zeeshan H Syedain; Allison R Bradee; Stefan Kren; Doris A Taylor; Robert T Tranquillo
Journal:  Tissue Eng Part A       Date:  2012-12-10       Impact factor: 3.845
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  21 in total

Review 1.  Next-generation tissue-engineered heart valves with repair, remodelling and regeneration capacity.

Authors:  Emanuela S Fioretta; Sarah E Motta; Valentina Lintas; Sandra Loerakker; Kevin K Parker; Frank P T Baaijens; Volkmar Falk; Simon P Hoerstrup; Maximilian Y Emmert
Journal:  Nat Rev Cardiol       Date:  2020-09-09       Impact factor: 32.419

2.  Heart valve scaffold fabrication: Bioinspired control of macro-scale morphology, mechanics and micro-structure.

Authors:  Antonio D'Amore; Samuel K Luketich; Giuseppe M Raffa; Salim Olia; Giorgio Menallo; Antonino Mazzola; Flavio D'Accardi; Tamir Grunberg; Xinzhu Gu; Michele Pilato; Marina V Kameneva; Vinay Badhwar; William R Wagner
Journal:  Biomaterials       Date:  2017-10-06       Impact factor: 12.479

3.  Soy Protein/Cellulose Nanofiber Scaffolds Mimicking Skin Extracellular Matrix for Enhanced Wound Healing.

Authors:  Seungkuk Ahn; Christophe O Chantre; Alanna R Gannon; Johan U Lind; Patrick H Campbell; Thomas Grevesse; Blakely B O'Connor; Kevin Kit Parker
Journal:  Adv Healthc Mater       Date:  2018-01-23       Impact factor: 9.933

Review 4.  Natural Polymers in Heart Valve Tissue Engineering: Strategies, Advances and Challenges.

Authors:  Diana Elena Ciolacu; Raluca Nicu; Florin Ciolacu
Journal:  Biomedicines       Date:  2022-05-08

Review 5.  Biomaterials for recruiting and activating endogenous stem cells in situ tissue regeneration.

Authors:  Ingrid Safina; Mildred C Embree
Journal:  Acta Biomater       Date:  2022-03-12       Impact factor: 10.633

6.  Production-scale fibronectin nanofibers promote wound closure and tissue repair in a dermal mouse model.

Authors:  Christophe O Chantre; Patrick H Campbell; Holly M Golecki; Adrian T Buganza; Andrew K Capulli; Leila F Deravi; Stephanie Dauth; Sean P Sheehy; Jeffrey A Paten; Karl Gledhill; Yanne S Doucet; Hasan E Abaci; Seungkuk Ahn; Benjamin D Pope; Jeffrey W Ruberti; Simon P Hoerstrup; Angela M Christiano; Kevin Kit Parker
Journal:  Biomaterials       Date:  2018-03-05       Impact factor: 12.479

Review 7.  Current Trends in Biomaterial Utilization for Cardiopulmonary System Regeneration.

Authors:  Adegbenro Omotuyi John Fakoya; David Adeiza Otohinoyi; Joshua Yusuf
Journal:  Stem Cells Int       Date:  2018-04-29       Impact factor: 5.443

8.  Incorporating nanocrystalline cellulose into a multifunctional hydrogel for heart valve tissue engineering applications.

Authors:  Nianfang Ma; Daniel Y Cheung; Jonathan T Butcher
Journal:  J Biomed Mater Res A       Date:  2021-07-13       Impact factor: 4.854

9.  Tissue response, macrophage phenotype, and intrinsic calcification induced by cardiovascular biomaterials: Can clinical regenerative potential be predicted in a rat subcutaneous implant model?

Authors:  Madeline Cramer; Jordan Chang; Hongshuai Li; Aurelie Serrero; Mohammed El-Kurdi; Martijn Cox; Frederick J Schoen; Stephen F Badylak
Journal:  J Biomed Mater Res A       Date:  2021-07-29       Impact factor: 4.854

10.  Can We Grow Valves Inside the Heart? Perspective on Material-based In Situ Heart Valve Tissue Engineering.

Authors:  Carlijn V C Bouten; Anthal I P M Smits; Frank P T Baaijens
Journal:  Front Cardiovasc Med       Date:  2018-05-29
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