A bench-top molding method for the production of cell-laden fibrin micro-fibers with longitudinal topography

Hans Keijdener; Jens Konrad; Bernd Hoffmann; José Gerardo-Nava; Stephan Rütten; Rudolf Merkel; Jaime Vázquez-Jiménez; Gary A Brook; Stefan Jockenhoevel; Petra Mela

doi:10.1002/jbm.b.34469

A bench-top molding method for the production of cell-laden fibrin micro-fibers with longitudinal topography

Hans Keijdener, Jens Konrad, Bernd Hoffmann, José Gerardo-Nava, Stephan Rütten, Rudolf Merkel, Jaime Vázquez-Jiménez, Gary A Brook, Stefan Jockenhoevel^*, Petra Mela^*

^*Corresponding author for this work

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

Abstract

Tissue-engineered constructs have great potential in many intervention strategies. In order for these constructs to function optimally, they should ideally mimic the cellular alignment and orientation found in the tissues to be treated. Here we present a simple and reproducible method for the production of cell-laden pure fibrin micro-fibers with longitudinal topography. The micro-fibers were produced using a molding technique and longitudinal topography was induced by a single initial stretch. Using this method, fibers up to 1 m in length and with diameters of 0.2-3 mm could be produced. The micro-fibers were generated with embedded endothelial cells, smooth muscle cell/fibroblasts or Schwann cells. Polarized light and scanning electron microscopy imaging showed that the initial stretch was sufficient to induce longitudinal topography in the fibrin gel. Cells in the unstretched control micro-fibers elongated randomly in both the floating and encapsulated environments, whereas the cells in the stretched micro-fibers responded to the introduced topography by adopting a similar orientation. Proof of concept bottom-up tissue engineering (TE) constructs are shown, all displaying various anisotropic organization of cells within. This simple, economical, versatile and scalable approach for the production of highly orientated and cell-laden micro-fibers is easily transferrable to any TE laboratory.

Original language	English
Pages (from-to)	1198-1212
Number of pages	15
Journal	Journal of Biomedical Materials Research Part B-applied Biomaterials
Volume	108
Issue number	4
Early online date	13 Aug 2019
DOIs	https://doi.org/10.1002/jbm.b.34469
Publication status	Published - May 2020

Keywords

ALIGNMENT
ARCHITECTURE
CONDUITS
HEART-VALVE
MECHANICAL-PROPERTIES
MICROFIBERS
ORIENTATION
PERIPHERAL-NERVE REPAIR
SCAFFOLDS
TISSUE
biotextiles
bottom-up tissue engineering
cellular orientation
fibers
fibrin gel

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10.1002/jbm.b.34469

Cite this

Keijdener, H., Konrad, J., Hoffmann, B., Gerardo-Nava, J., Rütten, S., Merkel, R., Vázquez-Jiménez, J., Brook, G. A., Jockenhoevel, S., & Mela, P. (2020). A bench-top molding method for the production of cell-laden fibrin micro-fibers with longitudinal topography. Journal of Biomedical Materials Research Part B-applied Biomaterials, 108(4), 1198-1212. https://doi.org/10.1002/jbm.b.34469

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title = "A bench-top molding method for the production of cell-laden fibrin micro-fibers with longitudinal topography",

abstract = "Tissue-engineered constructs have great potential in many intervention strategies. In order for these constructs to function optimally, they should ideally mimic the cellular alignment and orientation found in the tissues to be treated. Here we present a simple and reproducible method for the production of cell-laden pure fibrin micro-fibers with longitudinal topography. The micro-fibers were produced using a molding technique and longitudinal topography was induced by a single initial stretch. Using this method, fibers up to 1 m in length and with diameters of 0.2-3 mm could be produced. The micro-fibers were generated with embedded endothelial cells, smooth muscle cell/fibroblasts or Schwann cells. Polarized light and scanning electron microscopy imaging showed that the initial stretch was sufficient to induce longitudinal topography in the fibrin gel. Cells in the unstretched control micro-fibers elongated randomly in both the floating and encapsulated environments, whereas the cells in the stretched micro-fibers responded to the introduced topography by adopting a similar orientation. Proof of concept bottom-up tissue engineering (TE) constructs are shown, all displaying various anisotropic organization of cells within. This simple, economical, versatile and scalable approach for the production of highly orientated and cell-laden micro-fibers is easily transferrable to any TE laboratory.",

keywords = "ALIGNMENT, ARCHITECTURE, CONDUITS, HEART-VALVE, MECHANICAL-PROPERTIES, MICROFIBERS, ORIENTATION, PERIPHERAL-NERVE REPAIR, SCAFFOLDS, TISSUE, biotextiles, bottom-up tissue engineering, cellular orientation, fibers, fibrin gel",

author = "Hans Keijdener and Jens Konrad and Bernd Hoffmann and Jos{\'e} Gerardo-Nava and Stephan R{\"u}tten and Rudolf Merkel and Jaime V{\'a}zquez-Jim{\'e}nez and Brook, {Gary A} and Stefan Jockenhoevel and Petra Mela",

note = "{\textcopyright} 2019 Wiley Periodicals, Inc.",

year = "2020",

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doi = "10.1002/jbm.b.34469",

language = "English",

volume = "108",

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Keijdener, H, Konrad, J, Hoffmann, B, Gerardo-Nava, J, Rütten, S, Merkel, R, Vázquez-Jiménez, J, Brook, GA, Jockenhoevel, S & Mela, P 2020, 'A bench-top molding method for the production of cell-laden fibrin micro-fibers with longitudinal topography', Journal of Biomedical Materials Research Part B-applied Biomaterials, vol. 108, no. 4, pp. 1198-1212. https://doi.org/10.1002/jbm.b.34469

TY - JOUR

T1 - A bench-top molding method for the production of cell-laden fibrin micro-fibers with longitudinal topography

AU - Keijdener, Hans

AU - Konrad, Jens

AU - Hoffmann, Bernd

AU - Gerardo-Nava, José

AU - Rütten, Stephan

AU - Merkel, Rudolf

AU - Vázquez-Jiménez, Jaime

AU - Brook, Gary A

AU - Jockenhoevel, Stefan

AU - Mela, Petra

PY - 2020/5

Y1 - 2020/5

N2 - Tissue-engineered constructs have great potential in many intervention strategies. In order for these constructs to function optimally, they should ideally mimic the cellular alignment and orientation found in the tissues to be treated. Here we present a simple and reproducible method for the production of cell-laden pure fibrin micro-fibers with longitudinal topography. The micro-fibers were produced using a molding technique and longitudinal topography was induced by a single initial stretch. Using this method, fibers up to 1 m in length and with diameters of 0.2-3 mm could be produced. The micro-fibers were generated with embedded endothelial cells, smooth muscle cell/fibroblasts or Schwann cells. Polarized light and scanning electron microscopy imaging showed that the initial stretch was sufficient to induce longitudinal topography in the fibrin gel. Cells in the unstretched control micro-fibers elongated randomly in both the floating and encapsulated environments, whereas the cells in the stretched micro-fibers responded to the introduced topography by adopting a similar orientation. Proof of concept bottom-up tissue engineering (TE) constructs are shown, all displaying various anisotropic organization of cells within. This simple, economical, versatile and scalable approach for the production of highly orientated and cell-laden micro-fibers is easily transferrable to any TE laboratory.

AB - Tissue-engineered constructs have great potential in many intervention strategies. In order for these constructs to function optimally, they should ideally mimic the cellular alignment and orientation found in the tissues to be treated. Here we present a simple and reproducible method for the production of cell-laden pure fibrin micro-fibers with longitudinal topography. The micro-fibers were produced using a molding technique and longitudinal topography was induced by a single initial stretch. Using this method, fibers up to 1 m in length and with diameters of 0.2-3 mm could be produced. The micro-fibers were generated with embedded endothelial cells, smooth muscle cell/fibroblasts or Schwann cells. Polarized light and scanning electron microscopy imaging showed that the initial stretch was sufficient to induce longitudinal topography in the fibrin gel. Cells in the unstretched control micro-fibers elongated randomly in both the floating and encapsulated environments, whereas the cells in the stretched micro-fibers responded to the introduced topography by adopting a similar orientation. Proof of concept bottom-up tissue engineering (TE) constructs are shown, all displaying various anisotropic organization of cells within. This simple, economical, versatile and scalable approach for the production of highly orientated and cell-laden micro-fibers is easily transferrable to any TE laboratory.

KW - ALIGNMENT

KW - ARCHITECTURE

KW - CONDUITS

KW - HEART-VALVE

KW - MECHANICAL-PROPERTIES

KW - MICROFIBERS

KW - ORIENTATION

KW - PERIPHERAL-NERVE REPAIR

KW - SCAFFOLDS

KW - TISSUE

KW - biotextiles

KW - bottom-up tissue engineering

KW - cellular orientation

KW - fibers

KW - fibrin gel

U2 - 10.1002/jbm.b.34469

DO - 10.1002/jbm.b.34469

M3 - Article

C2 - 31408584

SN - 1552-4973

VL - 108

SP - 1198

EP - 1212

JO - Journal of Biomedical Materials Research Part B-applied Biomaterials

JF - Journal of Biomedical Materials Research Part B-applied Biomaterials

IS - 4

ER -