Skip to main page content
U.S. flag

An official website of the United States government

Dot gov

The .gov means it’s official.
Federal government websites often end in .gov or .mil. Before sharing sensitive information, make sure you’re on a federal government site.

Https

The site is secure.
The https:// ensures that you are connecting to the official website and that any information you provide is encrypted and transmitted securely.

Access keys NCBI Homepage MyNCBI Homepage Main Content Main Navigation
Comparative Study
. 2018 Apr 1;162(2):655-666.
doi: 10.1093/toxsci/kfx289.

Comparison of Hepatic 2D Sandwich Cultures and 3D Spheroids for Long-term Toxicity Applications: A Multicenter Study

Catherine C Bell  1   2 Anita C A Dankers  3 Volker M Lauschke  1 Rowena Sison-Young  4 Roz Jenkins  4 Cliff Rowe  4 Chris E Goldring  4 Kevin Park  4 Sophie L Regan  5 Tracy Walker  6 Chris Schofield  7 Audrey Baze  8   9 Alison J Foster  5 Dominic P Williams  5 Amy W M van de Ven  3 Frank Jacobs  3 Jos van Houdt  3 Tuula Lähteenmäki  10 Jan Snoeys  3 Satu Juhila  10 Lysiane Richert  8   11 Magnus Ingelman-Sundberg  1
Affiliations
Comparative Study

Comparison of Hepatic 2D Sandwich Cultures and 3D Spheroids for Long-term Toxicity Applications: A Multicenter Study

Catherine C Bell et al. Toxicol Sci. .

Abstract

Primary human hepatocytes (PHHs) are commonly used for in vitro studies of drug-induced liver injury. However, when cultured as 2D monolayers, PHH lose crucial hepatic functions within hours. This dedifferentiation can be ameliorated when PHHs are cultured in sandwich configuration (2Dsw), particularly when cultures are regularly re-overlaid with extracellular matrix, or as 3D spheroids. In this study, the 6 participating laboratories evaluated the robustness of these 2 model systems made from cryopreserved PHH from the same donors considering both inter-donor and inter-laboratory variability and compared their suitability for use in repeated-dose toxicity studies using 5 different hepatotoxins with different toxicity mechanisms. We found that expression levels of proteins involved in drug absorption, distribution, metabolism, and excretion, as well as catalytic activities of 5 different CYPs, were significantly higher in 3D spheroid cultures, potentially affecting the exposure of the cells to drugs and their metabolites. Furthermore, global proteomic analyses revealed that PHH in 3D spheroid configuration were temporally stable whereas proteomes from the same donors in 2Dsw cultures showed substantial alterations in protein expression patterns over the 14 days in culture. Overall, spheroid cultures were more sensitive to the hepatotoxic compounds investigated, particularly upon long-term exposures, across testing sites with little inter-laboratory or inter-donor variability. The data presented here suggest that repeated-dosing regimens improve the predictivity of in vitro toxicity assays, and that PHH spheroids provide a sensitive and robust system for long-term mechanistic studies of drug-induced hepatotoxicity, whereas the 2Dsw system has a more dedifferentiated phenotype and lower sensitivity to detect hepatotoxicity.

PubMed Disclaimer

Figures

Figure 1.
Figure 1.
Scheme of experimental procedure. Primary human hepatocytes (PHHs) were seeded in either 2Dsw or 3D spheroid configuration. Due to the time taken for spheroids to form (7–10 days) day 0 for 3D experiments is 7–10 days after seeding. Medium changes (± test compound) were performed every 2–3 days (grey boxes) and for 2Dsw cultures matrigel was re-overlaid as shown (black boxes). Sampling points for proteomics (triangles) and ATP measurements (circles) are indicated. Toxicity assays were done with cells from 3 different donors. The morphologies of cells from donor 1 in each of the systems at days 3, 7, and 14 are illustrated. These images were generated at Janssen.
Figure 2.
Figure 2.
Proteomic signatures of primary human hepatocytes are strongly influenced by the choice of in vitro culture paradigm. Heatmap visualization of mean-centered, sigma-normalized hierarchically clustered whole proteome data from freshly thawed PHH as well as from cultures from the same 3 donors in 2Dsw and 3D spheroid culture is shown (FDR = 5%). Enrichment analyses of the identified gene clusters revealed significantly affected pathways. In addition, ADME genes within each cluster are shown separately.
Figure 3.
Figure 3.
PHH undergo distinct molecular changes in 2Dsw and 3D spheroid culture that substantially influence their phenotype and functionality. Semi-log volcano plots showing the distribution of up- and downregulated proteins in 2D sandwich or 3D spheroid culture at day 0 (A) and after 14 days in culture (B). The dashed lines indicate the significance threshold of p = .05. C, Venn diagram visualizing the overlap of dysregulated proteins at day 0 and day 14 in 2Dsw and 3D spheroid cultures compared with freshly thawed cells. Note that the vast majority of proteins are either affected in 2Dsw or in 3D culture but only few in both. 2Dsw = 2D sandwich culture. D, Principal component analysis of differentially expressed genes reveals that samples cluster by in vitro culture paradigm. Furthermore, the plot indicates that the molecular phenotypes of PHH in 3D spheroid cultures remain stable over time, whereas substantial changes occur in 2Dsw configuration. Thawed cells are also depicted. E, Targeted analysis of ADME proteins and other factors with importance for hepatic functionality indicates that their levels are overall increased in 3D spheroids compared with 2Dsw cultures from the same donor (ie, positive fold-change) throughout the culture time. Values on the ordinate indicate the fold change (FC), defined as protein abundance in 3D spheroids divided by protein abundance in 2Dsw cultures if FC > 1 and the negative inverse if FC < 1. All samples for proteomic analysis were generated at KaLyCell (2Dsw) and Karolinska Institutet (3D) and processed and analyzed at the University of Liverpool.
Figure 4.
Figure 4.
CYP catalyzed drug metabolism in 3D spheroids and 2Dsw cultures from the same donor. PHHs from donor 1 were cultured as either 3D spheroids or 2Dsw cultures and the activities of CYP1A2, CYP2C8, CYP2C9, CYP2D6, and CYP3A4 were quantified by LC-MS/MS using phenacetin, amodiaquine, tolbutamide, dextromethorphan, and midazolam as probe substrates, respectively. As cells were incubated with probe substrates for different times (2h for spheroids and 30min for 2Dsw), activity data are shown as normalized per time and number of cells. Data represent the average of three 2Dsw incubations or 6 spheroids. Error bars indicate SD.
Figure 5.
Figure 5.
The choice of culture format influences the sensitivity to selected hepatotoxins in a compound-specific manner. Hepatocytes from 3 different donors were cultured in 2Dsw and 3D spheroid configuration at 6 different laboratories. A, Hepatocyte viability remains stable in both culture methods for up to 2 weeks in culture as quantified by ATP measurements in untreated cells. Viability is represented as normalized to ATP levels from the same donor at day 3. For 2Dsw incubations, n = 6, for 3D spheroids n = 10–12. PHH from 3 donors cultured in either 3D spheroid or 2Dsw configuration were exposed to the hepatotoxic compounds acetaminophen (APAP, B), bosentan (C), diclofenac (D), fialuridine (E), or troglitazone (F) for up to 14 days. Furthermore, we determined the toxicity of troglitazone’s less-toxic structural analog pioglitazone (G). EC50 values were determined by quantification of intracellular ATP levels. Dashed lines indicate 10× therapeutic Cmax concentrations for the respective compound (human Cmax values: APAP = 139 µM [Sevilla-Tirado et al., 2003], bosentan = 7.4 µM [Gutierrez et al., 2013], diclofenac = 8 µM [G.D. Searle LLC Division of Pfizer Inc., FDA professional drug information—Arthrotec (2015) available at: http://www.drugs.com/pro/arthrotec.html (accessed: 4 September 2017)], fialuridine = 1 µM [Bowsher et al., 1994], pioglitazone = 2.9 µM [Wong et al., 2004], troglitazone = 3.6 µM corresponding to 400 mg recommended daily dose [Loi et al., 1999]). Dotted line indicates EC50 values above the highest tested concentration. All 3D spheroid experiments were performed at a minimum of 3 different laboratories (as indicated in Table 1), whereas for 2Dsw experiments, donor 1 was compared across 3 sites, while incubations for donors 2 and 3 were performed only at a single site. Error bars indicate SEM.
See this image and copyright information in PMC

Similar articles

See all similar articles

Cited by

See all "Cited by" articles

References

    1. Bell C. C., Hendriks D. F. G., Moro S. M. L., Ellis E., Walsh J., Renblom A., Fredriksson Puigvert L., Dankers A. C. A., Jacobs F., Snoeys J. et al. , (2016). Characterization of primary human hepatocyte spheroids as a model system for drug-induced liver injury, liver function and disease. Scientific Reports 6, 25187.. - PMC - PubMed
    1. Bell C. C., Lauschke V. M., Vorrink S. U., Palmgren H., Duffin R., Andersson T. B., Ingelman-Sundberg M. (2017). Transcriptional, functional, and mechanistic comparisons of stem cell-derived hepatocytes, HepaRG cells, and three-dimensional human hepatocyte spheroids as predictive in vitro systems for drug-induced liver injury. Drug Metabolism and Disposition 45, 419–429. - PMC - PubMed
    1. Bellwon P., Truisi G. L., Bois F. Y., Wilmes A., Schmidt T., Savary C. C., Parmentier C., Hewitt P. G., Schmal O., Josse R. et al. , (2015). Kinetics and dynamics of cyclosporine A in three hepatic cell culture systems. Toxicology in Vitro 30, 62–78. - PubMed
    1. Bort R., Macé K., Boobis A., Gómez-Lechón M. J., Pfeifer A., Castell J. (1999). Hepatic metabolism of diclofenac: Role of human CYP in the minor oxidative pathways. Biochemical Pharmacology 58, 787–796. - PubMed
    1. Bowsher R. R., Compton J. A., Kirkwood J. A., Place G. D., Jones C. D., Mabry T. E., Hyslop D. L., Hatcher B. L., DeSante K. A. (1994). Sensitive and specific radioimmunoassay for fialuridine: Initial assessment of pharmacokinetics after single oral doses to healthy volunteers. Antimicrobial Agents and Chemotherapy 38, 2134–2142. - PMC - PubMed

Publication types

MeSH terms

Substances