Printability, Durability, Contractility and Vascular Network Formation in 3D Bioprinted Cardiac Endothelial Cells Using Alginate–Gelatin Hydrogels

Printability, Durability, Contractility and Vascular Network Formation in 3D Bioprinted Cardiac Endothelial Cells Using Alginate–Gelatin Hydrogels

Background3D bioprinting cardiac patches for epicardial transplantation are a promising approach for myocardial regeneration. Challenges remain such as quantifying printability, determining the ideal moment to transplant, and promoting vascularisation within bioprinted patches. We aimed to evaluate...

Full description

Bibliographic Details
Main Authors: Christopher David Roche, Poonam Sharma, Anthony Wayne Ashton, Chris Jackson, Meilang Xue, Carmine Gentile
Format: Article
Language:English
Published: Frontiers Media S.A. 2021-02-01
Series:Frontiers in Bioengineering and Biotechnology
Subjects:
3D bioprinting
spheroids
hydrogel
bioink
durability
printability
Online Access:https://www.frontiersin.org/articles/10.3389/fbioe.2021.636257/full
id doaj-0a4063a799e945c59203d3263ef41d8e
record_format Article
collection DOAJ
language English
format Article
sources DOAJ
author Christopher David Roche
Christopher David Roche
Poonam Sharma
Poonam Sharma
Poonam Sharma
Anthony Wayne Ashton
Chris Jackson
Meilang Xue
Carmine Gentile
Carmine Gentile
spellingShingle Christopher David Roche
Christopher David Roche
Poonam Sharma
Poonam Sharma
Poonam Sharma
Anthony Wayne Ashton
Chris Jackson
Meilang Xue
Carmine Gentile
Carmine Gentile
Printability, Durability, Contractility and Vascular Network Formation in 3D Bioprinted Cardiac Endothelial Cells Using Alginate–Gelatin Hydrogels
Frontiers in Bioengineering and Biotechnology
3D bioprinting
spheroids
hydrogel
bioink
durability
printability
author_facet Christopher David Roche
Christopher David Roche
Poonam Sharma
Poonam Sharma
Poonam Sharma
Anthony Wayne Ashton
Chris Jackson
Meilang Xue
Carmine Gentile
Carmine Gentile
author_sort Christopher David Roche
title Printability, Durability, Contractility and Vascular Network Formation in 3D Bioprinted Cardiac Endothelial Cells Using Alginate–Gelatin Hydrogels
title_short Printability, Durability, Contractility and Vascular Network Formation in 3D Bioprinted Cardiac Endothelial Cells Using Alginate–Gelatin Hydrogels
title_full Printability, Durability, Contractility and Vascular Network Formation in 3D Bioprinted Cardiac Endothelial Cells Using Alginate–Gelatin Hydrogels
title_fullStr Printability, Durability, Contractility and Vascular Network Formation in 3D Bioprinted Cardiac Endothelial Cells Using Alginate–Gelatin Hydrogels
title_full_unstemmed Printability, Durability, Contractility and Vascular Network Formation in 3D Bioprinted Cardiac Endothelial Cells Using Alginate–Gelatin Hydrogels
title_sort printability, durability, contractility and vascular network formation in 3d bioprinted cardiac endothelial cells using alginate–gelatin hydrogels
publisher Frontiers Media S.A.
series Frontiers in Bioengineering and Biotechnology
issn 2296-4185
publishDate 2021-02-01
description Background3D bioprinting cardiac patches for epicardial transplantation are a promising approach for myocardial regeneration. Challenges remain such as quantifying printability, determining the ideal moment to transplant, and promoting vascularisation within bioprinted patches. We aimed to evaluate 3D bioprinted cardiac patches for printability, durability in culture, cell viability, and endothelial cell structural self-organisation into networks.MethodsWe evaluated 3D-bioprinted double-layer patches using alginate/gelatine (AlgGel) hydrogels and three extrusion bioprinters (REGEMAT3D, INVIVO, BIO X). Bioink contained either neonatal mouse cardiac cell spheroids or free (not-in-spheroid) human coronary artery endothelial cells with fibroblasts, mixed with AlgGel. To test the effects on durability, some patches were bioprinted as a single layer only, cultured under minimal movement conditions or had added fibroblast-derived extracellular matrix hydrogel (AlloECM). Controls included acellular AlgGel and gelatin methacryloyl (GELMA) patches.ResultsPrintability was similar across bioprinters. For AlgGel compared to GELMA: resolutions were similar (200–700 μm line diameters), printing accuracy was 45 and 25%, respectively (AlgGel was 1.7x more accurate; p < 0.05), and shape fidelity was 92% (AlgGel) and 96% (GELMA); p = 0.36. For durability, AlgGel patch median survival in culture was 14 days (IQR:10–27) overall which was not significantly affected by bioprinting system or cellular content in patches. We identified three factors which reduced durability in culture: (1) bioprinting one layer depth patches (instead of two layers); (2) movement disturbance to patches in media; and (3) the addition of AlloECM to AlgGel. Cells were viable after bioprinting followed by 28 days in culture, and all BIO X-bioprinted mouse cardiac cell spheroid patches presented contractile activity starting between day 7 and 13 after bioprinting. At day 28, endothelial cells in hydrogel displayed organisation into endothelial network-like structures.ConclusionAlgGel-based 3D bioprinted heart patches permit cardiomyocyte contractility and endothelial cell structural self-organisation. After bioprinting, a period of 2 weeks maturation in culture prior to transplantation may be optimal, allowing for a degree of tissue maturation but before many patches start to lose integrity. We quantify AlgGel printability and present novel factors which reduce AlgGel patch durability (layer number, movement, and the addition of AlloECM) and factors which had minimal effect on durability (bioprinting system and cellular patch content).
topic 3D bioprinting
spheroids
hydrogel
bioink
durability
printability
url https://www.frontiersin.org/articles/10.3389/fbioe.2021.636257/full
work_keys_str_mv AT christopherdavidroche printabilitydurabilitycontractilityandvascularnetworkformationin3dbioprintedcardiacendothelialcellsusingalginategelatinhydrogels
AT christopherdavidroche printabilitydurabilitycontractilityandvascularnetworkformationin3dbioprintedcardiacendothelialcellsusingalginategelatinhydrogels
AT poonamsharma printabilitydurabilitycontractilityandvascularnetworkformationin3dbioprintedcardiacendothelialcellsusingalginategelatinhydrogels
AT poonamsharma printabilitydurabilitycontractilityandvascularnetworkformationin3dbioprintedcardiacendothelialcellsusingalginategelatinhydrogels
AT poonamsharma printabilitydurabilitycontractilityandvascularnetworkformationin3dbioprintedcardiacendothelialcellsusingalginategelatinhydrogels
AT anthonywayneashton printabilitydurabilitycontractilityandvascularnetworkformationin3dbioprintedcardiacendothelialcellsusingalginategelatinhydrogels
AT chrisjackson printabilitydurabilitycontractilityandvascularnetworkformationin3dbioprintedcardiacendothelialcellsusingalginategelatinhydrogels
AT meilangxue printabilitydurabilitycontractilityandvascularnetworkformationin3dbioprintedcardiacendothelialcellsusingalginategelatinhydrogels
AT carminegentile printabilitydurabilitycontractilityandvascularnetworkformationin3dbioprintedcardiacendothelialcellsusingalginategelatinhydrogels
AT carminegentile printabilitydurabilitycontractilityandvascularnetworkformationin3dbioprintedcardiacendothelialcellsusingalginategelatinhydrogels
_version_ 1724232638275780608
spelling doaj-0a4063a799e945c59203d3263ef41d8e2021-03-03T15:54:45ZengFrontiers Media S.A.Frontiers in Bioengineering and Biotechnology2296-41852021-02-01910.3389/fbioe.2021.636257636257Printability, Durability, Contractility and Vascular Network Formation in 3D Bioprinted Cardiac Endothelial Cells Using Alginate–Gelatin HydrogelsChristopher David Roche0Christopher David Roche1Poonam Sharma2Poonam Sharma3Poonam Sharma4Anthony Wayne Ashton5Chris Jackson6Meilang Xue7Carmine Gentile8Carmine Gentile9Northern Clinical School, Faculty of Medicine and Health, The University of Sydney, Sydney, NSW, AustraliaSchool of Biomedical Engineering, Faculty of Engineering and IT, University of Technology Sydney, Sydney, NSW, AustraliaNorthern Clinical School, Faculty of Medicine and Health, The University of Sydney, Sydney, NSW, AustraliaSchool of Biomedical Engineering, Faculty of Engineering and IT, University of Technology Sydney, Sydney, NSW, AustraliaFaculty of Health and Medicine, The University of Newcastle, Callaghan, NSW, AustraliaNorthern Clinical School, Faculty of Medicine and Health, The University of Sydney, Sydney, NSW, AustraliaNorthern Clinical School, Faculty of Medicine and Health, The University of Sydney, Sydney, NSW, AustraliaNorthern Clinical School, Faculty of Medicine and Health, The University of Sydney, Sydney, NSW, AustraliaNorthern Clinical School, Faculty of Medicine and Health, The University of Sydney, Sydney, NSW, AustraliaSchool of Biomedical Engineering, Faculty of Engineering and IT, University of Technology Sydney, Sydney, NSW, AustraliaBackground3D bioprinting cardiac patches for epicardial transplantation are a promising approach for myocardial regeneration. Challenges remain such as quantifying printability, determining the ideal moment to transplant, and promoting vascularisation within bioprinted patches. We aimed to evaluate 3D bioprinted cardiac patches for printability, durability in culture, cell viability, and endothelial cell structural self-organisation into networks.MethodsWe evaluated 3D-bioprinted double-layer patches using alginate/gelatine (AlgGel) hydrogels and three extrusion bioprinters (REGEMAT3D, INVIVO, BIO X). Bioink contained either neonatal mouse cardiac cell spheroids or free (not-in-spheroid) human coronary artery endothelial cells with fibroblasts, mixed with AlgGel. To test the effects on durability, some patches were bioprinted as a single layer only, cultured under minimal movement conditions or had added fibroblast-derived extracellular matrix hydrogel (AlloECM). Controls included acellular AlgGel and gelatin methacryloyl (GELMA) patches.ResultsPrintability was similar across bioprinters. For AlgGel compared to GELMA: resolutions were similar (200–700 μm line diameters), printing accuracy was 45 and 25%, respectively (AlgGel was 1.7x more accurate; p < 0.05), and shape fidelity was 92% (AlgGel) and 96% (GELMA); p = 0.36. For durability, AlgGel patch median survival in culture was 14 days (IQR:10–27) overall which was not significantly affected by bioprinting system or cellular content in patches. We identified three factors which reduced durability in culture: (1) bioprinting one layer depth patches (instead of two layers); (2) movement disturbance to patches in media; and (3) the addition of AlloECM to AlgGel. Cells were viable after bioprinting followed by 28 days in culture, and all BIO X-bioprinted mouse cardiac cell spheroid patches presented contractile activity starting between day 7 and 13 after bioprinting. At day 28, endothelial cells in hydrogel displayed organisation into endothelial network-like structures.ConclusionAlgGel-based 3D bioprinted heart patches permit cardiomyocyte contractility and endothelial cell structural self-organisation. After bioprinting, a period of 2 weeks maturation in culture prior to transplantation may be optimal, allowing for a degree of tissue maturation but before many patches start to lose integrity. We quantify AlgGel printability and present novel factors which reduce AlgGel patch durability (layer number, movement, and the addition of AlloECM) and factors which had minimal effect on durability (bioprinting system and cellular patch content).https://www.frontiersin.org/articles/10.3389/fbioe.2021.636257/full3D bioprintingspheroidshydrogelbioinkdurabilityprintability

Similar Items