Biocompatible silk fibroin scaffold prepared by reactive inkjet printing

Rider, Patrick; Tse, Christopher; Zhang, Yi; Jayawardane, Dharana; Stringer, Jonathan; Callaghan, Jill; Brook, Ian M.; Miller, Cheryl A.; Zhao, Xiubo; Smith, Patrick J.

doi:10.1007/s10853-016-0121-3

Cited by 21 publications

(16 citation statements)

References 22 publications

(29 reference statements)

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“…It is an emerging new interdisciplinary field that needs cooperation of many fields of science and technology, such as biomaterials, biology, physics, chemistry, computers, mechanics, bioinformatics, and medicine ( Figure 2). During the last 16 years, a large variety of 3D bioprinting technologies have been exploited, which has led to the emergence of fully automatic manufacturing of bioartificial organs for wide biomedical applications, such as high-throughput drug screening, controlled cell transplantation, customized organ repair/regeneration/replacement/restoration, pathological mechanism analysis, metabolism model establishment, and living tissue/organ cryopreservation [10][11][12][13][14][15][16][17][18][19][20]. Based on the working principles, these technologies can be classified into four major groups: inkjet-based, extrusion-based, laser-based, and their combinations ( Figure 3).…”

Section: Introductionmentioning

confidence: 99%

“…Each of the former three groups has advantages and disadvantages in bioartificial organ manufacturing. [10][11][12][13][14][15][16][17][18][19][20]. Images reproduced with permission from [10][11][12][13][14][15][16][17][18][19][20].…”

Section: Introductionmentioning

confidence: 99%

“…In this article, several advanced polymers with excellent biocompatibility, biodegradability, 3D printability, and structural stability are reviewed. The challenges and perspectives of polymers for rapid manufacturing of complex organs, such as the liver, heart, kidney, lung, breast, and brain, are outlined.2 of 25 computer-aided design (CAD) models [10][11][12][13]. Patient-specific organ image data, such as computerized tomography (CT) and magnetic resonance imaging (MRI), can be easily transferred into CAD models for customized organ manufacturing with predefined geometrical shapes, biomaterial constituents, and physiological functions [14][15][16][17].high-throughput drug screening [38][39][40], in vivo biocompatibilities of implanted biomaterials [41][42][43].…”

mentioning

confidence: 99%

“…2 of 25 computer-aided design (CAD) models [10][11][12][13]. Patient-specific organ image data, such as computerized tomography (CT) and magnetic resonance imaging (MRI), can be easily transferred into CAD models for customized organ manufacturing with predefined geometrical shapes, biomaterial constituents, and physiological functions [14][15][16][17].…”

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confidence: 99%

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Advanced Polymers for Three-Dimensional (3D) Organ Bioprinting

Wang

2019

Micromachines

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Three-dimensional (3D) organ bioprinting is an attractive scientific area with huge commercial profit, which could solve all the serious bottleneck problems for allograft transplantation, high-throughput drug screening, and pathological analysis. Integrating multiple heterogeneous adult cell types and/or stem cells along with other biomaterials (e.g., polymers, bioactive agents, or biomolecules) to make 3D constructs functional is one of the core issues for 3D bioprinting of bioartificial organs. Both natural and synthetic polymers play essential and ubiquitous roles for hierarchical vascular and neural network formation in 3D printed constructs based on their specific physical, chemical, biological, and physiological properties. In this article, several advanced polymers with excellent biocompatibility, biodegradability, 3D printability, and structural stability are reviewed. The challenges and perspectives of polymers for rapid manufacturing of complex organs, such as the liver, heart, kidney, lung, breast, and brain, are outlined.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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confidence: 99%

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confidence: 99%

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Advanced Polymers for Three-Dimensional (3D) Organ Bioprinting

Wang

2019

Micromachines

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“…Then, the mixing and the chemical reaction take place on the substrate's surface, forming the desired chemical structure. Silk micro‐rockets, as well as silk fibroin scaffolds, have successfully been created using the full RIJ approach . In both the cases, a silk ink is reacted with a methanol ink in order to transform the soluble random coil silk structure into the insoluble beta‐sheet structure.…”

Section: Introductionmentioning

confidence: 99%

Reactive inkjet printing of polyethylene glycol and isocyanate based inks to create porous polyurethane structures

Schuster

Hirth

Weber

2018

J of Applied Polymer Sci

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Reactive inkjet printing offers a direct way to create polymeric structures in situ on a substrate. Therefore, two component polyurethane formulations can be utilized to be used in multicomponent inkjet printing. In this contribution, the use of polyethylene glycol (M = 200 g mol −1 ), glycerol ethoxylate (M = 1,000 g mol −1 ), and water (blowing agent) in combination with aliphatic 1,6-hexamethylene diisocyanate or aromatic methylene diphenyl diisocyanate for reactive inkjet printing is evaluated. The inks are jettable on a Dimatix DMP-3000 inkjet printer using a 10 pL piezo driven drop-on-demand printhead showing stable droplet formation. Solid films on glass are formed using a drop-by-drop printing strategy. Layer-by-Layer strategy gives best results on polycarbonate substrates forming porous polyurethane structures.

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3D Inkjet Printing of Biomaterials with Solvent‐Free, Thiol‐Yne‐Based Photocurable Inks

Kainz,

Haudum,

Guillén

et al. 2024

Macro Materials & Eng

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Abstract3D inkjet printing is a fast, reliable, and non‐contact bottom–up approach to printing small and large models and is one of the fastest additive manufacturing technologies available. These attributes position inkjet printing as a promising tool for the additive manufacturing of biomaterials, for example, tissue engineering scaffolds. However, due to the stringent technical rheological requirements of current inkjet technologies, there is a lack of photopolymer resins suitable for the inkjet printing of biomaterials. Hence, a novel ink engineered for 3D piezoelectric inkjet printing of biomaterials is designed and developed. The novel resin leverages a biodegradable amino acid phosphorodiamidate matrix copolymerized with a dialkyne ether to modulate the viscosity. Copolymerization with commercially available thiols facilitates the photochemical thiol‐yne curing reaction. The ink exhibits optimal viscosity, eliminating the need for solvents, as well as reliable jetting and sufficiently swift curing kinetics. Furthermore, the formulation is successfully demonstrated in an industrial inkjet printhead. Notably, the resulting materials have low cytotoxicity and, hence, have significant promise in advancing the applications of 3D inkjet printing of biological scaffolds.

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Biocompatible silk fibroin scaffold prepared by reactive inkjet printing

Cited by 21 publications

References 22 publications

Advanced Polymers for Three-Dimensional (3D) Organ Bioprinting

Advanced Polymers for Three-Dimensional (3D) Organ Bioprinting

Reactive inkjet printing of polyethylene glycol and isocyanate based inks to create porous polyurethane structures

3D Inkjet Printing of Biomaterials with Solvent‐Free, Thiol‐Yne‐Based Photocurable Inks

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