Longitudinal Stretching for Maturation of Vascular Tissues Using Magnetic Forces

Overview

Journal Bioengineering (Basel)

Date 2017 Sep 28

PMID 28952591

Citations 3

Authors

Timothy R Olsen

Megan Casco

Austin Herbst

Grace Evans

Taylor Rothermel

Lauren Pruett

Jared Reid

Kelly Barry

Michael P Jaeggli

Dan T Simionescu

Richard P Visconti

Frank Alexis

Affiliations

Soon will be listed here.

Abstract

Cellular spheroids were studied to determine their use as "bioinks" in the biofabrication of tissue engineered constructs. Specifically, magnetic forces were used to mediate the cyclic longitudinal stretching of tissues composed of Janus magnetic cellular spheroids (JMCSs), as part of a post-processing method for enhancing the deposition and mechanical properties of an extracellular matrix (ECM). The purpose was to accelerate the conventional tissue maturation process via novel post-processing techniques that accelerate the functional, structural, and mechanical mimicking of native tissues. The results of a forty-day study of JMCSs indicated an expression of collagen I, collagen IV, elastin, and fibronectin, which are important vascular ECM proteins. Most notably, the subsequent exposure of fused tissue sheets composed of JMCSs to magnetic forces did not hinder the production of these key proteins. Quantitative results demonstrate that cyclic longitudinal stretching of the tissue sheets mediated by these magnetic forces increased the Young's modulus and induced collagen fiber alignment over a seven day period, when compared to statically conditioned controls. Specifically, the elastin and collagen content of these dynamically-conditioned sheets were 35- and three-fold greater, respectively, at seven days compared to the statically-conditioned controls at three days. These findings indicate the potential of using magnetic forces in tissue maturation, specifically through the cyclic longitudinal stretching of tissues.

Citing Articles

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Bioinks for 3D Bioprinting: A Scientometric Analysis of Two Decades of Progress.

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Progress in scaffold-free bioprinting for cardiovascular medicine.

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