2021
DOI: 10.1002/adfm.202009574
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3D Patterning within Hydrogels for the Recreation of Functional Biological Environments

Abstract: Biological structures are inherently complex in nature. Structural hierarchy, chemical anisotropy, and compositional heterogeneity are ubiquitous in biological systems and play a key role in the functionality of living systems. For decades, methods such as soft lithography have enabled recreation of such arrangements through precise spatial control of molecular patterns in 2D. With technological advances and increasing understanding of molecular and structural biology, there has been an increasing interest in … Show more

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Cited by 51 publications
(42 citation statements)
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References 313 publications
(344 reference statements)
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“…They used single-photon lithography, discussing the possibility to implement a MPL fabrication. Other efforts in this direction, made with methods complementary to laser fabrication, including precise chemical design, microfluidics, 3D printing, and non-contact forces, have been recently reviewed by Primo and Mata [ 86 ]. Stiffness is always related to the degree of cross-linking that can occur via photo-activation, thermally or chemically.…”
Section: Laser-fabricated Active Microstructured Hydrogelsmentioning
confidence: 99%
“…They used single-photon lithography, discussing the possibility to implement a MPL fabrication. Other efforts in this direction, made with methods complementary to laser fabrication, including precise chemical design, microfluidics, 3D printing, and non-contact forces, have been recently reviewed by Primo and Mata [ 86 ]. Stiffness is always related to the degree of cross-linking that can occur via photo-activation, thermally or chemically.…”
Section: Laser-fabricated Active Microstructured Hydrogelsmentioning
confidence: 99%
“…Light-based approaches, such as two-photon polymerisation, allow better resolution on the micro to nanoscale; however often require transparent materials [105][106][107]. Photopatterning is also a well-established method of patterning biologically active growth factors, proteins and peptides into hydrogel scaffolds [99,108]. Microfluidics enable creation of devices with microchannels and segregated compartments [54,61]; as well as enabling tight control over microscale features via precise biochemical patterning of organoids and hydrogel scaffolds [48,99].…”
Section: Topographical Patterningmentioning
confidence: 99%
“…Fluid gels show particular promise as bioinks, protecting cells from shear forces during the printing process that would otherwise reduce viability [ 69 , 93 , 97 ]. 3D bioprinting of hydrogels allows reliable production of spatially defined macrostructures, including vascular components, with the use of sacrificial inks suggested as a means to create complex vascular networks [ 70 , 98 , 99 ]. Microfluidics present an alternative for creation of perfusable culture systems to mimic vasculature within 3D in vitro models of the CNS [ 52 ].…”
Section: Biomaterialsmentioning
confidence: 99%
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