In vitro grafting of hepatic spheroids and organoids on a microfluidic vascular bed

F. Bonanini; D. Kurek; S. Previdi; A. Nicolas; D. Hendriks; S. de Ruiter; M. Meyer; M.C. Cabrer; R. Dinkelberg; S.B. Garcia; B. Kramer; T. Olivier; H.L. Hu; C. Lopez-Iglesias; F. Schavemaker; E. Walinga; D. Dutta; K. Queiroz; K. Domansky; B. Ronden; J. Joore; H.L. Lanz; P.J. Peters; S.J. Trietsch; H. Clevers; P. Vulto

doi:10.1007/s10456-022-09842-9

In vitro grafting of hepatic spheroids and organoids on a microfluidic vascular bed

F. Bonanini, D. Kurek, S. Previdi, A. Nicolas, D. Hendriks, S. de Ruiter, M. Meyer, M.C. Cabrer, R. Dinkelberg, S.B. Garcia, B. Kramer, T. Olivier, H.L. Hu, C. Lopez-Iglesias, F. Schavemaker, E. Walinga, D. Dutta, K. Queiroz, K. Domansky, B. RondenJ. Joore, H.L. Lanz, P.J. Peters, S.J. Trietsch, H. Clevers, P. Vulto^*

^*Corresponding author for this work

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

Abstract

With recent progress in modeling liver organogenesis and regeneration, the lack of vasculature is becoming the bottleneck in progressing our ability to model human hepatic tissues in vitro. Here, we introduce a platform for routine grafting of liver and other tissues on an in vitro grown microvascular bed. The platform consists of 64 microfluidic chips patterned underneath a 384-well microtiter plate. Each chip allows the formation of a microvascular bed between two main lateral vessels by inducing angiogenesis. Chips consist of an open-top microfluidic chamber, which enables addition of a target tissue by manual or robotic pipetting. Upon grafting a liver microtissue, the microvascular bed undergoes anastomosis, resulting in a stable, perfusable vascular network. Interactions with vasculature were found in spheroids and organoids upon 7 days of co-culture with space of Disse-like architecture in between hepatocytes and endothelium. Veno-occlusive disease was induced by azathioprine exposure, leading to impeded perfusion of the vascularized spheroid. The platform holds the potential to replace animals with an in vitro alternative for routine grafting of spheroids, organoids, or (patient-derived) explants.

Original language	English
Pages (from-to)	455-470
Number of pages	16
Journal	Angiogenesis
Volume	25
Issue number	4
Early online date	15 Jun 2022
DOIs	https://doi.org/10.1007/s10456-022-09842-9
Publication status	Published - Nov 2022

Keywords

In vitro grafting
Vascularization
Liver organoids and spheroids
Microfluidics
SINUSOIDAL ENDOTHELIAL-CELLS
FUNCTIONAL HUMAN LIVER
VENOOCCLUSIVE DISEASE
HUMAN HEPATOCYTES
CULTURE
AZATHIOPRINE
TISSUE
ORGANOGENESIS
ANGIOGENESIS
PHENOTYPE

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Bonanini, F., Kurek, D., Previdi, S., Nicolas, A., Hendriks, D., de Ruiter, S., Meyer, M., Cabrer, M. C., Dinkelberg, R., Garcia, S. B., Kramer, B., Olivier, T., Hu, H. L., Lopez-Iglesias, C., Schavemaker, F., Walinga, E., Dutta, D., Queiroz, K., Domansky, K., ... Vulto, P. (2022). In vitro grafting of hepatic spheroids and organoids on a microfluidic vascular bed. Angiogenesis, 25(4), 455-470. https://doi.org/10.1007/s10456-022-09842-9

@article{38b09c8c3d8846e99d5de46119f60ee0,

title = "In vitro grafting of hepatic spheroids and organoids on a microfluidic vascular bed",

abstract = "With recent progress in modeling liver organogenesis and regeneration, the lack of vasculature is becoming the bottleneck in progressing our ability to model human hepatic tissues in vitro. Here, we introduce a platform for routine grafting of liver and other tissues on an in vitro grown microvascular bed. The platform consists of 64 microfluidic chips patterned underneath a 384-well microtiter plate. Each chip allows the formation of a microvascular bed between two main lateral vessels by inducing angiogenesis. Chips consist of an open-top microfluidic chamber, which enables addition of a target tissue by manual or robotic pipetting. Upon grafting a liver microtissue, the microvascular bed undergoes anastomosis, resulting in a stable, perfusable vascular network. Interactions with vasculature were found in spheroids and organoids upon 7 days of co-culture with space of Disse-like architecture in between hepatocytes and endothelium. Veno-occlusive disease was induced by azathioprine exposure, leading to impeded perfusion of the vascularized spheroid. The platform holds the potential to replace animals with an in vitro alternative for routine grafting of spheroids, organoids, or (patient-derived) explants.",

keywords = "In vitro grafting, Vascularization, Liver organoids and spheroids, Microfluidics, SINUSOIDAL ENDOTHELIAL-CELLS, FUNCTIONAL HUMAN LIVER, VENOOCCLUSIVE DISEASE, HUMAN HEPATOCYTES, CULTURE, AZATHIOPRINE, TISSUE, ORGANOGENESIS, ANGIOGENESIS, PHENOTYPE",

author = "F. Bonanini and D. Kurek and S. Previdi and A. Nicolas and D. Hendriks and {de Ruiter}, S. and M. Meyer and M.C. Cabrer and R. Dinkelberg and S.B. Garcia and B. Kramer and T. Olivier and H.L. Hu and C. Lopez-Iglesias and F. Schavemaker and E. Walinga and D. Dutta and K. Queiroz and K. Domansky and B. Ronden and J. Joore and H.L. Lanz and P.J. Peters and S.J. Trietsch and H. Clevers and P. Vulto",

note = "Funding Information: We would like to thank Rumaisha Annida and members of the Microscopy CORE Lab of M4I-FHML of Maastricht University for their technical support and Kristin Bircsak for valuable comments. We also would like to thank Mimetas Biocore team including Kristina Bishard, Arthur Stok, Manon Haarmans, and Julia Grasegger This project has received funding from the European Union{\textquoteright}s Horizon 2020 research and innovation program under grant agreement No 848429 and Interreg, project Biomat on microfluidic chip 433. AN and FB have received funding from the European Union{\textquoteright}s Horizon 2020 research and innovation program under the Marie Sk{\l}odowska-Curie grant agreement No 641639 and No 812616, respectively. This project was partly funded by an innovation loan (IK17088) from the Dutch Ministry of Economic Affairs and Climate. This work was supported by partners of Regenerative Medicine Crossing Borders (www.regmedxb.com), powered by Health-Holland, Top Sector Life Sciences & Health. Funding Information: We would like to thank Rumaisha Annida and members of the Microscopy CORE Lab of M4I-FHML of Maastricht University for their technical support and Kristin Bircsak for valuable comments. We also would like to thank Mimetas Biocore team including Kristina Bishard, Arthur Stok, Manon Haarmans, and Julia Grasegger This project has received funding from the European Union{\textquoteright}s Horizon 2020 research and innovation program under grant agreement No 848429 and Interreg, project Biomat on microfluidic chip 433. AN and FB have received funding from the European Union{\textquoteright}s Horizon 2020 research and innovation program under the Marie Sk{\l}odowska-Curie grant agreement No 641639 and No 812616, respectively. This project was partly funded by an innovation loan (IK17088) from the Dutch Ministry of Economic Affairs and Climate. This work was supported by partners of Regenerative Medicine Crossing Borders (www.regmedxb.com), powered by Health-Holland, Top Sector Life Sciences & Health. Publisher Copyright: {\textcopyright} 2022, The Author(s).",

year = "2022",

month = nov,

doi = "10.1007/s10456-022-09842-9",

language = "English",

volume = "25",

pages = "455--470",

journal = "Angiogenesis",

issn = "0969-6970",

publisher = "Springer Science and Business Media B.V.",

number = "4",

}

Bonanini, F, Kurek, D, Previdi, S, Nicolas, A, Hendriks, D, de Ruiter, S, Meyer, M, Cabrer, MC, Dinkelberg, R, Garcia, SB, Kramer, B, Olivier, T, Hu, HL, Lopez-Iglesias, C, Schavemaker, F, Walinga, E, Dutta, D, Queiroz, K, Domansky, K, Ronden, B, Joore, J, Lanz, HL, Peters, PJ, Trietsch, SJ, Clevers, H & Vulto, P 2022, 'In vitro grafting of hepatic spheroids and organoids on a microfluidic vascular bed', Angiogenesis, vol. 25, no. 4, pp. 455-470. https://doi.org/10.1007/s10456-022-09842-9

TY - JOUR

T1 - In vitro grafting of hepatic spheroids and organoids on a microfluidic vascular bed

AU - Bonanini, F.

AU - Kurek, D.

AU - Previdi, S.

AU - Nicolas, A.

AU - Hendriks, D.

AU - de Ruiter, S.

AU - Meyer, M.

AU - Cabrer, M.C.

AU - Dinkelberg, R.

AU - Garcia, S.B.

AU - Kramer, B.

AU - Olivier, T.

AU - Hu, H.L.

AU - Lopez-Iglesias, C.

AU - Schavemaker, F.

AU - Walinga, E.

AU - Dutta, D.

AU - Queiroz, K.

AU - Domansky, K.

AU - Ronden, B.

AU - Joore, J.

AU - Lanz, H.L.

AU - Peters, P.J.

AU - Trietsch, S.J.

AU - Clevers, H.

AU - Vulto, P.

N1 - Funding Information: We would like to thank Rumaisha Annida and members of the Microscopy CORE Lab of M4I-FHML of Maastricht University for their technical support and Kristin Bircsak for valuable comments. We also would like to thank Mimetas Biocore team including Kristina Bishard, Arthur Stok, Manon Haarmans, and Julia Grasegger This project has received funding from the European Union’s Horizon 2020 research and innovation program under grant agreement No 848429 and Interreg, project Biomat on microfluidic chip 433. AN and FB have received funding from the European Union’s Horizon 2020 research and innovation program under the Marie Skłodowska-Curie grant agreement No 641639 and No 812616, respectively. This project was partly funded by an innovation loan (IK17088) from the Dutch Ministry of Economic Affairs and Climate. This work was supported by partners of Regenerative Medicine Crossing Borders (www.regmedxb.com), powered by Health-Holland, Top Sector Life Sciences & Health. Funding Information: We would like to thank Rumaisha Annida and members of the Microscopy CORE Lab of M4I-FHML of Maastricht University for their technical support and Kristin Bircsak for valuable comments. We also would like to thank Mimetas Biocore team including Kristina Bishard, Arthur Stok, Manon Haarmans, and Julia Grasegger This project has received funding from the European Union’s Horizon 2020 research and innovation program under grant agreement No 848429 and Interreg, project Biomat on microfluidic chip 433. AN and FB have received funding from the European Union’s Horizon 2020 research and innovation program under the Marie Skłodowska-Curie grant agreement No 641639 and No 812616, respectively. This project was partly funded by an innovation loan (IK17088) from the Dutch Ministry of Economic Affairs and Climate. This work was supported by partners of Regenerative Medicine Crossing Borders (www.regmedxb.com), powered by Health-Holland, Top Sector Life Sciences & Health. Publisher Copyright: © 2022, The Author(s).

PY - 2022/11

Y1 - 2022/11

N2 - With recent progress in modeling liver organogenesis and regeneration, the lack of vasculature is becoming the bottleneck in progressing our ability to model human hepatic tissues in vitro. Here, we introduce a platform for routine grafting of liver and other tissues on an in vitro grown microvascular bed. The platform consists of 64 microfluidic chips patterned underneath a 384-well microtiter plate. Each chip allows the formation of a microvascular bed between two main lateral vessels by inducing angiogenesis. Chips consist of an open-top microfluidic chamber, which enables addition of a target tissue by manual or robotic pipetting. Upon grafting a liver microtissue, the microvascular bed undergoes anastomosis, resulting in a stable, perfusable vascular network. Interactions with vasculature were found in spheroids and organoids upon 7 days of co-culture with space of Disse-like architecture in between hepatocytes and endothelium. Veno-occlusive disease was induced by azathioprine exposure, leading to impeded perfusion of the vascularized spheroid. The platform holds the potential to replace animals with an in vitro alternative for routine grafting of spheroids, organoids, or (patient-derived) explants.

AB - With recent progress in modeling liver organogenesis and regeneration, the lack of vasculature is becoming the bottleneck in progressing our ability to model human hepatic tissues in vitro. Here, we introduce a platform for routine grafting of liver and other tissues on an in vitro grown microvascular bed. The platform consists of 64 microfluidic chips patterned underneath a 384-well microtiter plate. Each chip allows the formation of a microvascular bed between two main lateral vessels by inducing angiogenesis. Chips consist of an open-top microfluidic chamber, which enables addition of a target tissue by manual or robotic pipetting. Upon grafting a liver microtissue, the microvascular bed undergoes anastomosis, resulting in a stable, perfusable vascular network. Interactions with vasculature were found in spheroids and organoids upon 7 days of co-culture with space of Disse-like architecture in between hepatocytes and endothelium. Veno-occlusive disease was induced by azathioprine exposure, leading to impeded perfusion of the vascularized spheroid. The platform holds the potential to replace animals with an in vitro alternative for routine grafting of spheroids, organoids, or (patient-derived) explants.

KW - In vitro grafting

KW - Vascularization

KW - Liver organoids and spheroids

KW - Microfluidics

KW - SINUSOIDAL ENDOTHELIAL-CELLS

KW - FUNCTIONAL HUMAN LIVER

KW - VENOOCCLUSIVE DISEASE

KW - HUMAN HEPATOCYTES

KW - CULTURE

KW - AZATHIOPRINE

KW - TISSUE

KW - ORGANOGENESIS

KW - ANGIOGENESIS

KW - PHENOTYPE

U2 - 10.1007/s10456-022-09842-9

DO - 10.1007/s10456-022-09842-9

M3 - Article

C2 - 35704148

SN - 0969-6970

VL - 25

SP - 455

EP - 470

JO - Angiogenesis

JF - Angiogenesis

IS - 4

ER -

In vitro grafting of hepatic spheroids and organoids on a microfluidic vascular bed

Abstract

Keywords

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