3D Bioprinting of Architected Hydrogels from Entangled Microstrands

Kessel, Benjamin; Lee, M.; Bonato, Angela; Tinguely, Yann; Tosoratti, Enrico; Zenobi‐Wong, Marcy

doi:10.1101/2019.12.13.870220

Cited by 12 publications

(16 citation statements)

References 29 publications

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“…[311][312] Kessel et al showed that elongated gel microstands were also applicable to extrusion bioprinting (Figure 19). 313 High-aspect ratio HA-MA microstrands entangled, producing a printed construct with greater stability compared to spherical granular gels. The microstrand constructs did not need to be secondarily crosslinked and the properties of the printed bioink could be adjusted by the time of exposure of the bulk gel to UV light.…”

Section: Figure 19 Common Strategies To Achieve Good Extrusion Printabilitymentioning

confidence: 99%

“…An added advantage is the alignment of the microstrands along the printing direction which contributed to the formation of anisotropic structures and alignment of cells. 313 The mechanism of shear thinning in the nozzle of extrusion printers using entangled inks is illustrated in Figure 21, along with our current understanding of how molecules, nanoparticles, and microgels align and/or deform during flow. In each of these examples, stabilization of the structures by photo-activated materials can be advantageous.…”

Section: Figure 19 Common Strategies To Achieve Good Extrusion Printabilitymentioning

confidence: 99%

“…Despite these limitations, extrusion bioprinting has unique advantages compared to its competitors. It is the only biofabrication technique which can create truly anisotropic properties 313 , as the flow of the material can be used to effectively align fibrils, microgels, and by implication, cells. To benefit from this phenomenon, non-planar slicing software 335 and curvilinear printing 336 could be harnessed to exploit the natural anisotropy of tissues or organs, replacing arbitrary layer-by-layer slicing.…”

Section: Limitations and Outlookmentioning

confidence: 99%

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Guiding Lights: Tissue Bioprinting Using Photoactivated Materials

et al. 2020

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Photo-activated materials have found widespread use in biological and medical applications and are playing an increasingly important role in the nascent field of three-dimensional (3D) bioprinting. Light can be used as a trigger to drive the formation or the degradation of chemical bonds, leading to unprecedented spatiotemporal control over a material's chemical, physical, and biological properties. With resolution and construct size ranging from nanometres to centimeters, light-mediated biofabrication allows multicellular and multimaterial approaches. It promises to be a powerful tool to mimic the complex multiscale organization of living tissues including skin, bone, cartilage, muscle, vessels, heart, and liver, among others, with increasing organotypic functionality. With this review, we comprehensively discuss photochemical reactions, photo-activated materials, and their use in state-of-the-art deposition-based (extrusion and droplet) and vat polymerization-based (one-and two-photon) bioprinting. By offering an up-to-date view on these techniques, we identify emerging trends, focusing on both the chemistry and instrument aspects, thereby allowing the readers to select the best-suited approach. Starting with photochemical reactions and photo-activated materials, we then discuss principles, applications, and limitations of each technique. With a critical eye to the most recent achievements, the reader is guided through this exciting, emerging field with special emphasis on cell-laden hydrogel constructs.

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Section: Figure 19 Common Strategies To Achieve Good Extrusion Printabilitymentioning

confidence: 99%

Section: Figure 19 Common Strategies To Achieve Good Extrusion Printabilitymentioning

confidence: 99%

Section: Limitations and Outlookmentioning

confidence: 99%

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Guiding Lights: Tissue Bioprinting Using Photoactivated Materials

et al. 2020

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“…Among these forms, hydrogels are the most applicable and injectable forms of scaffolds in 3D bioprinting owing to their cell‐encapsulating capability and good biocompatibility. [ 95 ] Cells and morphogens can be loaded within the hydrogel solution prior to the gelling via curing agents and through alternations in pH, ionic concentration, and temperature. [ 73 ] As previously discussed, there are two types of hydrogels: natural and synthetic based on their origins.…”

Section: Materials and Biomaterials For 3d‐printable Hydrogels For Bomentioning

confidence: 99%

Hydrogel‐Based 3D Bioprinting for Bone and Cartilage Tissue Engineering

Abdollahiyan

Oroojalian

Mokhtarzadeh

et al. 2020

Biotechnology Journal

100

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As a milestone in soft and hard tissue engineering, a precise control over the micropatterns of scaffolds has lightened new opportunities for the recapitulation of native body organs through three dimentional (3D) bioprinting approaches. Well-printable bioinks are prerequisites for the bioprinting of tissues/organs where hydrogels play a critical role. Despite the outstanding developments in 3D engineered microstructures, current printer devices suffer from the risk of exposing loaded living agents to mechanical (nozzle-based) and thermal (nozzle-free) stresses. Thus, tuning the rheological, physical, and mechanical properties of hydrogels is a promising solution to address these issues. The relationship between the mechanical characteristics of hydrogels and their printability is important to control printing quality and fidelity. Recent developments in defining this relationship have highlighted the decisive role of main additive manufacturing strategies. These strategies are applied to enhance the printing quality of scaffolds and determine the nurture of cellular morphology. In this regard, it is beneficial to use external and internal stabilization, photocurable biopolymers, and cooling substrates containing the printed scaffolds. The objective of this study is to review cutting-edge developments in hydrogel-type bioinks and discuss the optimum simulation of the zonal stratification in osteochondral and cartilage units.

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“…Such hydrogels have been developed in previous studies using either porogen, [ 14,15 ] leachable particles, [ 16 ] nanoclay, [ 17 ] granular particles, [ 18 ] self‐assembly, [ 19,20 ] or polymer degradation. [ 21 ] Bioprintable pore‐forming formulas, such as aqueous two‐phase emulsion system [ 12,22,23 ] and hydrogel microstrands, [ 24 ] could be used for injection as well. These hydrogels, however, suffer from limited pore size and low interconnectivity, which impair permeability and performance.…”

Section: Introductionmentioning

confidence: 99%

Injectable, Pore‐Forming, Perfusable Double‐Network Hydrogels Resilient to Extreme Biomechanical Stimulations

Taheri

Bao

et al. 2021

Advanced Science

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Biological tissues hinge on blood perfusion and mechanical toughness to function. Injectable hydrogels that possess both high permeability and toughness have profound impacts on regenerative medicine but remain a long‐standing challenge. To address this issue, injectable, pore‐forming double‐network hydrogels are fabricated by orchestrating stepwise gelation and phase separation processes. The interconnected pores of the resulting hydrogels enable direct medium perfusion through organ‐sized matrices. The hydrogels are amenable to cell encapsulation and delivery while promoting cell proliferation and spreading. They are also pore insensitive, tough, and fatigue resistant. When tested in biomimetic perfusion bioreactors, the hydrogels maintain physical integrity under prolonged, high‐frequency biomechanical stimulations (>6000 000 cycles at 120 Hz). The excellent biomechanical performance suggests the great potential of the new injectable hydrogel technology for repairing mechanically dynamic tissues, such as vocal folds, and other applications, such as tissue engineering, biofabrication, organs‐on‐chips, drug delivery, and disease modeling.

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3D Bioprinting of Architected Hydrogels from Entangled Microstrands

Cited by 12 publications

References 29 publications

Guiding Lights: Tissue Bioprinting Using Photoactivated Materials

Guiding Lights: Tissue Bioprinting Using Photoactivated Materials

Hydrogel‐Based 3D Bioprinting for Bone and Cartilage Tissue Engineering

Injectable, Pore‐Forming, Perfusable Double‐Network Hydrogels Resilient to Extreme Biomechanical Stimulations

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