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Publications
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Data for 2020-2025 from SciVal
Selected Publications
2020
1.
Figueiredo, Lara; Visage, Catherine Le; Weiss, Pierre; Yang, Jing
Quantifying oxygen levels in 3D bioprinted cell-laden thick constructs with perfusable microchannel networks Journal Article
In: Polymers (Basel), vol. 12, no. 6, pp. 1260, 2020.
Abstract | Tags: 3D bioprinting, hydrogel, microchannels, microfluidics, oxygen, silated-HPMC
@article{Figueiredo2020-bz,
title = {Quantifying oxygen levels in 3D bioprinted cell-laden thick
constructs with perfusable microchannel networks},
author = {Lara Figueiredo and Catherine Le Visage and Pierre Weiss and Jing Yang},
year = {2020},
date = {2020-05-01},
journal = {Polymers (Basel)},
volume = {12},
number = {6},
pages = {1260},
publisher = {MDPI AG},
abstract = {The survival and function of thick tissue engineered implanted
constructs depends on pre-existing, embedded, functional,
vascular-like structures that are able to integrate with the
host vasculature. Bioprinting was employed to build perfusable
vascular-like networks within thick constructs. However, the
improvement of oxygen transportation facilitated by these
vascular-like networks was directly quantified. Using an optical
fiber oxygen sensor, we measured the oxygen content at different
positions within 3D bioprinted constructs with and without
perfusable microchannel networks. Perfusion was found to play an
essential role in maintaining relatively high oxygen content in
cell-laden constructs and, consequently, high cell viability.
The concentration of oxygen changes following switching on and
off the perfusion. Oxygen concentration depletes quickly after
pausing perfusion but recovers rapidly after resuming the
perfusion. The quantification of oxygen levels within cell-laden
hydrogel constructs could provide insight into channel network
design and cellular responses.},
keywords = {3D bioprinting, hydrogel, microchannels, microfluidics, oxygen, silated-HPMC},
pubstate = {published},
tppubtype = {article}
}
The survival and function of thick tissue engineered implanted
constructs depends on pre-existing, embedded, functional,
vascular-like structures that are able to integrate with the
host vasculature. Bioprinting was employed to build perfusable
vascular-like networks within thick constructs. However, the
improvement of oxygen transportation facilitated by these
vascular-like networks was directly quantified. Using an optical
fiber oxygen sensor, we measured the oxygen content at different
positions within 3D bioprinted constructs with and without
perfusable microchannel networks. Perfusion was found to play an
essential role in maintaining relatively high oxygen content in
cell-laden constructs and, consequently, high cell viability.
The concentration of oxygen changes following switching on and
off the perfusion. Oxygen concentration depletes quickly after
pausing perfusion but recovers rapidly after resuming the
perfusion. The quantification of oxygen levels within cell-laden
hydrogel constructs could provide insight into channel network
design and cellular responses.
constructs depends on pre-existing, embedded, functional,
vascular-like structures that are able to integrate with the
host vasculature. Bioprinting was employed to build perfusable
vascular-like networks within thick constructs. However, the
improvement of oxygen transportation facilitated by these
vascular-like networks was directly quantified. Using an optical
fiber oxygen sensor, we measured the oxygen content at different
positions within 3D bioprinted constructs with and without
perfusable microchannel networks. Perfusion was found to play an
essential role in maintaining relatively high oxygen content in
cell-laden constructs and, consequently, high cell viability.
The concentration of oxygen changes following switching on and
off the perfusion. Oxygen concentration depletes quickly after
pausing perfusion but recovers rapidly after resuming the
perfusion. The quantification of oxygen levels within cell-laden
hydrogel constructs could provide insight into channel network
design and cellular responses.
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