Hydrogels derived from decellularized liver tissue support the growth and differentiation of cholangiocyte organoids

Jorke Willemse; Gilles van Tienderen; Eline van Hengel; Ivo Schurink; Diana van der Ven; Yik Kan; Petra de Ruiter; Oskar Rosmark; Gunilla Westergren-Thorsson G; Kerstin Schneeberger; Bram van der Eerden; Henk Roest; Bart Spee; Luc van der Laan; Jeroen de Jonge; Monique Verstegen

doi:10.1016/j.biomaterials.2022.121473

Hydrogels derived from decellularized liver tissue support the growth and differentiation of cholangiocyte organoids

Jorke Willemse, Gilles van Tienderen, Eline van Hengel, Ivo Schurink, Diana van der Ven, Yik Kan, Petra de Ruiter, Oskar Rosmark, Gunilla Westergren-Thorsson G, Kerstin Schneeberger, Bram van der Eerden, Henk Roest, Bart Spee, Luc van der Laan, Jeroen de Jonge, Monique Verstegen^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

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Abstract

Human cholangiocyte organoids are promising for regenerative medicine applications, such as repair of damaged bile ducts. However, organoids are typically cultured in mouse tumor-derived basement membrane extracts (BME), which is poorly defined, highly variable and limits the direct clinical applications of organoids in patients. Extracellular matrix (ECM)-derived hydrogels prepared from decellularized human or porcine livers are attractive alternative culture substrates. Here, the culture and expansion of human cholangiocyte organoids in liver ECM(LECM)-derived hydrogels is described. These hydrogels support proliferation of cholangiocyte organoids and maintain the cholangiocyte-like phenotype. The use of LECM hydrogels does not significantly alter the expression of selected genes or proteins, such as the cholangiocyte marker cytokeratin-7, and no species-specific effect is found between human or porcine LECM hydrogels. Proliferation rates of organoids cultured in LECM hydrogels are lower, but the differentiation capacity of the cholangiocyte organoids towards hepatocyte-like cells is not altered by the presence of tissue-specific ECM components. Moreover, human LECM extracts support the expansion of ICO in a dynamic culture set up without the need for laborious static culture of organoids in hydrogel domes. Liver ECM hydrogels can successfully replace tumor-derived BME and can potentially unlock the full clinical potential of human cholangiocyte organoids.

Original language	English
Article number	121473
Journal	Biomaterials
Volume	284
Early online date	24 May 2022
DOIs	https://doi.org/10.1016/j.biomaterials.2022.121473
Publication status	Published - May 2022

Bibliographical note

Funding Information:
We would like to thank Dr. Bram Zoetebier from the University of Twente for assistance on performing shear rheology experiment. This project was funded by a ‘Medical Delta Regenerative Medicine 4D: Generating complex tissues with stem cells and printing technology’ grant, a TKI-LSH grant (EMC-LSH19002) and a Gastrostart grant from the Dutch Society for GastroEnterology (NVGE).

Funding Information:
We would like to thank Dr. Bram Zoetebier from the University of Twente for assistance on performing shear rheology experiment. This project was funded by a ‘ Medical Delta Regenerative Medicine 4D: Generating complex tissues with stem cells and printing technology ’ grant, a TKI-LSH grant ( EMC-LSH19002 ) and a Gastrostart grant from the Dutch Society for GastroEnterology (NVGE).

Publisher Copyright:
© 2022

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Cite this

Willemse, J., van Tienderen, G., van Hengel, E., Schurink, I., van der Ven, D., Kan, Y., de Ruiter, P., Rosmark, O., Westergren-Thorsson G, G., Schneeberger, K., van der Eerden, B., Roest, H., Spee, B., van der Laan, L., de Jonge, J., & Verstegen, M. (2022). Hydrogels derived from decellularized liver tissue support the growth and differentiation of cholangiocyte organoids. Biomaterials, 284, Article 121473. https://doi.org/10.1016/j.biomaterials.2022.121473

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title = "Hydrogels derived from decellularized liver tissue support the growth and differentiation of cholangiocyte organoids",

abstract = "Human cholangiocyte organoids are promising for regenerative medicine applications, such as repair of damaged bile ducts. However, organoids are typically cultured in mouse tumor-derived basement membrane extracts (BME), which is poorly defined, highly variable and limits the direct clinical applications of organoids in patients. Extracellular matrix (ECM)-derived hydrogels prepared from decellularized human or porcine livers are attractive alternative culture substrates. Here, the culture and expansion of human cholangiocyte organoids in liver ECM(LECM)-derived hydrogels is described. These hydrogels support proliferation of cholangiocyte organoids and maintain the cholangiocyte-like phenotype. The use of LECM hydrogels does not significantly alter the expression of selected genes or proteins, such as the cholangiocyte marker cytokeratin-7, and no species-specific effect is found between human or porcine LECM hydrogels. Proliferation rates of organoids cultured in LECM hydrogels are lower, but the differentiation capacity of the cholangiocyte organoids towards hepatocyte-like cells is not altered by the presence of tissue-specific ECM components. Moreover, human LECM extracts support the expansion of ICO in a dynamic culture set up without the need for laborious static culture of organoids in hydrogel domes. Liver ECM hydrogels can successfully replace tumor-derived BME and can potentially unlock the full clinical potential of human cholangiocyte organoids.",

author = "Jorke Willemse and {van Tienderen}, Gilles and {van Hengel}, Eline and Ivo Schurink and {van der Ven}, Diana and Yik Kan and {de Ruiter}, Petra and Oskar Rosmark and {Westergren-Thorsson G}, Gunilla and Kerstin Schneeberger and {van der Eerden}, Bram and Henk Roest and Bart Spee and {van der Laan}, Luc and {de Jonge}, Jeroen and Monique Verstegen",

note = "Funding Information: We would like to thank Dr. Bram Zoetebier from the University of Twente for assistance on performing shear rheology experiment. This project was funded by a {\textquoteleft}Medical Delta Regenerative Medicine 4D: Generating complex tissues with stem cells and printing technology{\textquoteright} grant, a TKI-LSH grant (EMC-LSH19002) and a Gastrostart grant from the Dutch Society for GastroEnterology (NVGE). Funding Information: We would like to thank Dr. Bram Zoetebier from the University of Twente for assistance on performing shear rheology experiment. This project was funded by a {\textquoteleft} Medical Delta Regenerative Medicine 4D: Generating complex tissues with stem cells and printing technology {\textquoteright} grant, a TKI-LSH grant ( EMC-LSH19002 ) and a Gastrostart grant from the Dutch Society for GastroEnterology (NVGE). Publisher Copyright: {\textcopyright} 2022",

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doi = "10.1016/j.biomaterials.2022.121473",

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Willemse, J, van Tienderen, G, van Hengel, E , Schurink, I, van der Ven, D, Kan, Y, de Ruiter, P, Rosmark, O, Westergren-Thorsson G, G, Schneeberger, K, van der Eerden, B , Roest, H, Spee, B, van der Laan, L , de Jonge, J & Verstegen, M 2022, 'Hydrogels derived from decellularized liver tissue support the growth and differentiation of cholangiocyte organoids', Biomaterials, vol. 284, 121473. https://doi.org/10.1016/j.biomaterials.2022.121473

TY - JOUR

T1 - Hydrogels derived from decellularized liver tissue support the growth and differentiation of cholangiocyte organoids

AU - Willemse, Jorke

AU - van Tienderen, Gilles

AU - van Hengel, Eline

AU - Schurink, Ivo

AU - van der Ven, Diana

AU - Kan, Yik

AU - de Ruiter, Petra

AU - Rosmark, Oskar

AU - Westergren-Thorsson G, Gunilla

AU - Schneeberger, Kerstin

AU - van der Eerden, Bram

AU - Roest, Henk

AU - Spee, Bart

AU - van der Laan, Luc

AU - de Jonge, Jeroen

AU - Verstegen, Monique

N1 - Funding Information: We would like to thank Dr. Bram Zoetebier from the University of Twente for assistance on performing shear rheology experiment. This project was funded by a ‘Medical Delta Regenerative Medicine 4D: Generating complex tissues with stem cells and printing technology’ grant, a TKI-LSH grant (EMC-LSH19002) and a Gastrostart grant from the Dutch Society for GastroEnterology (NVGE). Funding Information: We would like to thank Dr. Bram Zoetebier from the University of Twente for assistance on performing shear rheology experiment. This project was funded by a ‘ Medical Delta Regenerative Medicine 4D: Generating complex tissues with stem cells and printing technology ’ grant, a TKI-LSH grant ( EMC-LSH19002 ) and a Gastrostart grant from the Dutch Society for GastroEnterology (NVGE). Publisher Copyright: © 2022

PY - 2022/5

Y1 - 2022/5

N2 - Human cholangiocyte organoids are promising for regenerative medicine applications, such as repair of damaged bile ducts. However, organoids are typically cultured in mouse tumor-derived basement membrane extracts (BME), which is poorly defined, highly variable and limits the direct clinical applications of organoids in patients. Extracellular matrix (ECM)-derived hydrogels prepared from decellularized human or porcine livers are attractive alternative culture substrates. Here, the culture and expansion of human cholangiocyte organoids in liver ECM(LECM)-derived hydrogels is described. These hydrogels support proliferation of cholangiocyte organoids and maintain the cholangiocyte-like phenotype. The use of LECM hydrogels does not significantly alter the expression of selected genes or proteins, such as the cholangiocyte marker cytokeratin-7, and no species-specific effect is found between human or porcine LECM hydrogels. Proliferation rates of organoids cultured in LECM hydrogels are lower, but the differentiation capacity of the cholangiocyte organoids towards hepatocyte-like cells is not altered by the presence of tissue-specific ECM components. Moreover, human LECM extracts support the expansion of ICO in a dynamic culture set up without the need for laborious static culture of organoids in hydrogel domes. Liver ECM hydrogels can successfully replace tumor-derived BME and can potentially unlock the full clinical potential of human cholangiocyte organoids.

AB - Human cholangiocyte organoids are promising for regenerative medicine applications, such as repair of damaged bile ducts. However, organoids are typically cultured in mouse tumor-derived basement membrane extracts (BME), which is poorly defined, highly variable and limits the direct clinical applications of organoids in patients. Extracellular matrix (ECM)-derived hydrogels prepared from decellularized human or porcine livers are attractive alternative culture substrates. Here, the culture and expansion of human cholangiocyte organoids in liver ECM(LECM)-derived hydrogels is described. These hydrogels support proliferation of cholangiocyte organoids and maintain the cholangiocyte-like phenotype. The use of LECM hydrogels does not significantly alter the expression of selected genes or proteins, such as the cholangiocyte marker cytokeratin-7, and no species-specific effect is found between human or porcine LECM hydrogels. Proliferation rates of organoids cultured in LECM hydrogels are lower, but the differentiation capacity of the cholangiocyte organoids towards hepatocyte-like cells is not altered by the presence of tissue-specific ECM components. Moreover, human LECM extracts support the expansion of ICO in a dynamic culture set up without the need for laborious static culture of organoids in hydrogel domes. Liver ECM hydrogels can successfully replace tumor-derived BME and can potentially unlock the full clinical potential of human cholangiocyte organoids.

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Hydrogels derived from decellularized liver tissue support the growth and differentiation of cholangiocyte organoids

Abstract

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