3D Printing of Microgel-Loaded Modular Microcages as Instructive Scaffolds for Tissue Engineering

Ramesh Subbiah; Christina Hipfinger; Anthony Tahayeri; Avathamsa Athirasala; Sivaporn Horsophonphong; Greeshma Thrivikraman; Cristiane Miranda França; Diana Araujo Cunha; Amin Mansoorifar; Albena Zahariev; James M. Jones; Paulo G. Coelho; Lukasz Witek; Hua Xie; Robert E. Guldberg; Luiz E. Bertassoni

doi:10.1002/adma.202001736

3D Printing of Microgel-Loaded Modular Microcages as Instructive Scaffolds for Tissue Engineering

Ramesh Subbiah, Christina Hipfinger, Anthony Tahayeri, Avathamsa Athirasala, Sivaporn Horsophonphong, Greeshma Thrivikraman, Cristiane Miranda França, Diana Araujo Cunha, Amin Mansoorifar, Albena Zahariev, James M. Jones, Paulo G. Coelho, Lukasz Witek, Hua Xie, Robert E. Guldberg, Luiz E. Bertassoni

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

29 Scopus citations

Abstract

Biomaterial scaffolds have served as the foundation of tissue engineering and regenerative medicine. However, scaffold systems are often difficult to scale in size or shape in order to fit defect-specific dimensions, and thus provide only limited spatiotemporal control of therapeutic delivery and host tissue responses. Here, a lithography-based 3D printing strategy is used to fabricate a novel miniaturized modular microcage scaffold system, which can be assembled and scaled manually with ease. Scalability is based on an intuitive concept of stacking modules, like conventional toy interlocking plastic blocks, allowing for literally thousands of potential geometric configurations, and without the need for specialized equipment. Moreover, the modular hollow-microcage design allows each unit to be loaded with biologic cargo of different compositions, thus enabling controllable and easy patterning of therapeutics within the material in 3D. In summary, the concept of miniaturized microcage designs with such straight-forward assembly and scalability, as well as controllable loading properties, is a flexible platform that can be extended to a wide range of materials for improved biological performance.

Original language	English (US)
Article number	2001736
Journal	Advanced Materials
Volume	32
Issue number	36
DOIs	https://doi.org/10.1002/adma.202001736
State	Published - Sep 1 2020

Keywords

cell migration
growth factor delivery
instructive scaffolds
microgels
vascularization

ASJC Scopus subject areas

Materials Science(all)
Mechanics of Materials
Mechanical Engineering

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10.1002/adma.202001736

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Subbiah, R., Hipfinger, C., Tahayeri, A., Athirasala, A., Horsophonphong, S., Thrivikraman, G., França, C. M., Cunha, D. A., Mansoorifar, A., Zahariev, A., Jones, J. M., Coelho, P. G., Witek, L., Xie, H., Guldberg, R. E., & Bertassoni, L. E. (2020). 3D Printing of Microgel-Loaded Modular Microcages as Instructive Scaffolds for Tissue Engineering. Advanced Materials, 32(36), [2001736]. https://doi.org/10.1002/adma.202001736

Subbiah, R, Hipfinger, C, Tahayeri, A, Athirasala, A, Horsophonphong, S, Thrivikraman, G, França, CM, Cunha, DA, Mansoorifar, A, Zahariev, A, Jones, JM, Coelho, PG, Witek, L, Xie, H, Guldberg, RE & Bertassoni, LE 2020, '3D Printing of Microgel-Loaded Modular Microcages as Instructive Scaffolds for Tissue Engineering', Advanced Materials, vol. 32, no. 36, 2001736. https://doi.org/10.1002/adma.202001736

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title = "3D Printing of Microgel-Loaded Modular Microcages as Instructive Scaffolds for Tissue Engineering",

abstract = "Biomaterial scaffolds have served as the foundation of tissue engineering and regenerative medicine. However, scaffold systems are often difficult to scale in size or shape in order to fit defect-specific dimensions, and thus provide only limited spatiotemporal control of therapeutic delivery and host tissue responses. Here, a lithography-based 3D printing strategy is used to fabricate a novel miniaturized modular microcage scaffold system, which can be assembled and scaled manually with ease. Scalability is based on an intuitive concept of stacking modules, like conventional toy interlocking plastic blocks, allowing for literally thousands of potential geometric configurations, and without the need for specialized equipment. Moreover, the modular hollow-microcage design allows each unit to be loaded with biologic cargo of different compositions, thus enabling controllable and easy patterning of therapeutics within the material in 3D. In summary, the concept of miniaturized microcage designs with such straight-forward assembly and scalability, as well as controllable loading properties, is a flexible platform that can be extended to a wide range of materials for improved biological performance.",

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author = "Ramesh Subbiah and Christina Hipfinger and Anthony Tahayeri and Avathamsa Athirasala and Sivaporn Horsophonphong and Greeshma Thrivikraman and Fran{\c c}a, {Cristiane Miranda} and Cunha, {Diana Araujo} and Amin Mansoorifar and Albena Zahariev and Jones, {James M.} and Coelho, {Paulo G.} and Lukasz Witek and Hua Xie and Guldberg, {Robert E.} and Bertassoni, {Luiz E.}",

note = "Funding Information: R.S. and C.H. contributed equally to this work. This project was partly supported by funding from the National Institute of Dental and Craniofacial Research (R01DE026170 and 3R01DE026170‐03S1 to L.E.B.), the Oregon Clinical & Translational Research Institute (OCTRI)—Biomedical Innovation Program (BIP), the Michigan‐Pittsburgh‐Wyss Resource Center—Regenerative Medicine Resource Center (MPWRM), OHSU‐UO Collaborative Seed Projects, and the OHSU Fellowship for Diversity and Inclusion in Research (OHSU‐OFDIR to C.M.F.). The authors would like to thank Dr. S. Prakash Parthiban for his kind assistance with data demonstrating hydrogel injectability. Publisher Copyright: {\textcopyright} 2020 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim",

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doi = "10.1002/adma.202001736",

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AU - Subbiah, Ramesh

AU - Hipfinger, Christina

AU - Tahayeri, Anthony

AU - Athirasala, Avathamsa

AU - Horsophonphong, Sivaporn

AU - Thrivikraman, Greeshma

AU - França, Cristiane Miranda

AU - Cunha, Diana Araujo

AU - Mansoorifar, Amin

AU - Zahariev, Albena

AU - Jones, James M.

AU - Coelho, Paulo G.

AU - Witek, Lukasz

AU - Xie, Hua

AU - Guldberg, Robert E.

AU - Bertassoni, Luiz E.

N1 - Funding Information: R.S. and C.H. contributed equally to this work. This project was partly supported by funding from the National Institute of Dental and Craniofacial Research (R01DE026170 and 3R01DE026170‐03S1 to L.E.B.), the Oregon Clinical & Translational Research Institute (OCTRI)—Biomedical Innovation Program (BIP), the Michigan‐Pittsburgh‐Wyss Resource Center—Regenerative Medicine Resource Center (MPWRM), OHSU‐UO Collaborative Seed Projects, and the OHSU Fellowship for Diversity and Inclusion in Research (OHSU‐OFDIR to C.M.F.). The authors would like to thank Dr. S. Prakash Parthiban for his kind assistance with data demonstrating hydrogel injectability. Publisher Copyright: © 2020 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim

PY - 2020/9/1

Y1 - 2020/9/1

N2 - Biomaterial scaffolds have served as the foundation of tissue engineering and regenerative medicine. However, scaffold systems are often difficult to scale in size or shape in order to fit defect-specific dimensions, and thus provide only limited spatiotemporal control of therapeutic delivery and host tissue responses. Here, a lithography-based 3D printing strategy is used to fabricate a novel miniaturized modular microcage scaffold system, which can be assembled and scaled manually with ease. Scalability is based on an intuitive concept of stacking modules, like conventional toy interlocking plastic blocks, allowing for literally thousands of potential geometric configurations, and without the need for specialized equipment. Moreover, the modular hollow-microcage design allows each unit to be loaded with biologic cargo of different compositions, thus enabling controllable and easy patterning of therapeutics within the material in 3D. In summary, the concept of miniaturized microcage designs with such straight-forward assembly and scalability, as well as controllable loading properties, is a flexible platform that can be extended to a wide range of materials for improved biological performance.

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KW - vascularization

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3D Printing of Microgel-Loaded Modular Microcages as Instructive Scaffolds for Tissue Engineering

Abstract

Keywords

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