3D culture of HepaRG cells in GelMa and its application to bioprinting of a multicellular hepatic model

Cuvellier, Marie; Ezan, Frédéric; Oliveira, Hugo; Rose, Sophie; Fricain, Jean-Christophe; Langouët, Sophie; Legagneux, Vincent; Baffet, Georges

doi:10.1016/j.biomaterials.2020.120611

Cited by 86 publications

(99 citation statements)

References 62 publications

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“…Albumin synthesis was elevated at day 6 of spheroid culture, and mRNA levels of CYP1A2 , CYP2B6 and CYP3A4 first dropped, then slightly increased at day 4 and were elevated 1.2–3 -fold at day 7 when compared to day 0 [ 77 ]. Additionally, others have shown that HepaRG spheroids (self-aggregated or bioprinted) could be cultured over several weeks and that those cultures maintained several hepatic properties: HepaRG spheroids were capable of (a) albumin [ 87 , 88 , 89 , 90 , 91 ] and urea [ 87 , 90 ] production, (b) displayed expression and activity of CYP1A2 [ 88 , 89 ], CYP2B6 [ 89 ] and CYP3A4 [ 86 , 88 , 89 , 90 , 92 ], (c) showed phase II enzyme activity [ 89 , 91 ], and (d) displayed cellular polarization shown by MRP2 [ 87 , 88 , 90 ] and Pgp [ 91 ] expression, and by F-actin bands, indicative of bile canalicular structures [ 89 , 91 , 92 ]. Regarding expression and activity of phase I enzymes, however, several studies have shown that basal levels in spheroids were unaffected, in part even slightly lower than in monolayer cultures.…”

Section: Three-dimensional Culture Models For Human Hepatocytesmentioning

confidence: 99%

“…This might be explained by the relatively high basal expression of several CYP enzymes in HepaRG cells. However, the authors of those studies have deemed it necessary to elevate expression and activity of CYPs by induction using β-naphthoflavone (for CYP1A2), phenobarbital (for CYP2B6) or rifampicin (for CYP2C9 and CYP3A4) to reach more relevant levels [ 87 , 89 , 91 , 93 ].…”

Section: Three-dimensional Culture Models For Human Hepatocytesmentioning

confidence: 99%

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Three-Dimensional Liver Culture Systems to Maintain Primary Hepatic Properties for Toxicological Analysis In Vitro

Kammerer

2021

IJMS

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Drug-induced liver injury (DILI) is the major reason for failures in drug development and withdrawal of approved drugs from the market. Two-dimensional cultures of hepatocytes often fail to reliably predict DILI: hepatoma cell lines such as HepG2 do not reflect important primary-like hepatic properties and primary human hepatocytes (pHHs) dedifferentiate quickly in vitro and are, therefore, not suitable for long-term toxicity studies. More predictive liver in vitro models are urgently required in drug development and compound safety evaluation. This review discusses available human hepatic cell types for in vitro toxicology analysis and their usage in established and emerging three-dimensional (3D) culture systems. Generally, 3D cultures maintain or improve primary hepatic functions (including expression of drug-metabolizing enzymes) of different liver cells for several weeks of culture, thus allowing long-term and repeated-dose toxicity studies. Spheroid cultures of pHHs have been comprehensively tested, but also other cell types such as HepaRG benefit from 3D culture systems. Emerging 3D culture techniques include usage of induced pluripotent stem-cell-derived hepatocytes and primary-like upcyte cells, as well as advanced culture techniques such as microfluidic liver-on-a-chip models. In-depth characterization of existing and emerging 3D hepatocyte technologies is indispensable for successful implementation of such systems in toxicological analysis.

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Section: Three-dimensional Culture Models For Human Hepatocytesmentioning

confidence: 99%

Section: Three-dimensional Culture Models For Human Hepatocytesmentioning

confidence: 99%

Three-Dimensional Liver Culture Systems to Maintain Primary Hepatic Properties for Toxicological Analysis In Vitro

Kammerer

2021

IJMS

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“…Drug hepatotoxicity testing showed increased sensitivity to APAP compared to 2D adhesion controls. In addition, 3D extrusion bioprinting was used to fabricate a complex liver model [106]. The bioprinted structure showed 28-day cell viability and liver function.…”

Section: D-printed Liversmentioning

confidence: 99%

Recent advances in the development of in vitro liver models for hepatotoxicity testing

Zhang

Lin

et al. 2021

Bio-des. Manuf.

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Liver injury is a common cause of drug approval withdrawal during drug development, pre-clinical research, and clinical treatment. If not properly treated, patients with severe liver injury can suffer from acute liver failure or even death. Thus, utilization of the convenient in vitro hepatotoxicity assessment model for early detection of drug-induced hepatotoxicity is vital for drug development and safe personalized medication. Biomaterials (e.g., hydrogels, nanofibers, decellularized liver matrix) and bioengineering technologies (e.g., microarrays, micropatterns, 3D printing, and microfluidics) have been applied for in vitro hepatotoxicity assessment models. This review summarizes the structure and functions of the liver as well as the components of in vitro hepatotoxicity assessment models. In addition, it highlights the latest advances in developing hepatotoxicity models with the ultimate goal of further clinical translation.

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“…GelMA maintains high cellular viability with high shape integrity post-printing making it an excellent bioink for larger tissue constructs ( Figure 2 H) [ 69 ]. It has been extensively used in the bioprinting community to create a multitude of constructs, including skin, cartilage, tumors, cornea, blood vessels, and liver and cardiac tissues, capitalizing on the strong bioink–cell interactions and resulting in a bioink that can be used for a wide number of tissues [ 43 , 76 , 106 , 107 , 108 , 109 , 110 , 111 , 112 , 113 , 114 , 115 ].…”

Section: Biological Bioinksmentioning

confidence: 99%

Bioprinting Au Natural: The Biologics of Bioinks

2021

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The development of appropriate bioinks is a complex task, dependent on the mechanical and biochemical requirements of the final construct and the type of printer used for fabrication. The two most common tissue printers are micro-extrusion and digital light projection printers. Here we briefly discuss the required characteristics of a bioink for each of these printing processes. However, physical printing is only a short window in the lifespan of a printed construct—the system must support and facilitate cellular development after it is printed. To that end, we provide a broad overview of some of the biological molecules currently used as bioinks. Each molecule has advantages for specific tissues/cells, and potential disadvantages are discussed, along with examples of their current use in the field. Notably, it is stressed that active researchers are trending towards the use of composite bioinks. Utilizing the strengths from multiple materials is highlighted as a key component of bioink development.

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3D culture of HepaRG cells in GelMa and its application to bioprinting of a multicellular hepatic model

Cited by 86 publications

References 62 publications

Three-Dimensional Liver Culture Systems to Maintain Primary Hepatic Properties for Toxicological Analysis In Vitro

Three-Dimensional Liver Culture Systems to Maintain Primary Hepatic Properties for Toxicological Analysis In Vitro

Recent advances in the development of in vitro liver models for hepatotoxicity testing

Bioprinting Au Natural: The Biologics of Bioinks

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