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Bioink Selection for 3D Bioprinting

What Is 3D Bioprinting?

3D bioprinting enables the generation of precisely controlled 3D cell models and tissue constructs, by engineering anatomically-shaped substrates with tissue-like complexity. Due to the high degree of control on structure and composition, 3D bioprinting has the potential to solve many critical unmet needs in medical research, including applications in cosmetics testing, drug discovery, regenerative medicine, and functional organ replacement.Personalized models of disease can be created using patient-derived stem cells, such as induced pluripotent stem cells (iPS cells) or mesenchymal stem cells. Depending on the application, a range of materials, methods, and cells can be used to yield the desired tissue construct (Figure 1). For more in-depth information, including expert review articles on 3D Bioprinting, protocols, and related products, please explore our 3D Bioprinting Handbook.

The process of 3D bioprinting of tissue and organs. The image is divided into three sections: “Extrusion-based bioprinting” with a syringe extruding bioink, “Inkjet-based bioprinting” with an inkjet printer head releasing polymer-based bioink, and “Laser-assisted bioprinting” using a laser pulse to deposit material. Below these sections, diagrams depict the composition of bioinks and their applications in tissue engineering, drug screening, and in vitro disease modeling.

Figure 1.3D Bioprinting of tissue and organs. Bioinks are created by combining cultured cells and various biocompatable materials. Bioinks can then be 3D bioprinted into functional tissue constructs for drug screening, disease modeling, and in vitro transplantation.

What Are Bioinks?

Bioinks contain living cells and biomaterials that mimic the extracellular matrix environment, supporting cell adhesion, proliferation, and differentiation after printing. In contrast to tradtional 3D printing materials, bioinks must have:

  • Print temperatures that do not exceed physiological temperatures
  • Mild cross-linking or gelation conditions
  • Bioative components that are non-toxic and able to be modified by the cells after printing

Bioinks for Extrusion-based Printing

Cell-encapsulating hydrogels are used in 3D bioprinting to create living tissue structures by forming multicellular bioprinting building blocks. Cell encapsulation allows for precise control over cell attachment and the spatial distribution of the cells and biomolecules within the scaffold, in comparison to other methods and materials.1 Combining multiple cell types and growth factors in a prescribed pattern allows for the generation of highly-complex tissue constructs.3 In addition to biocompatibility, bioprinting materials used  for cellular encapsulation must feaure high water content and porosity, allowing encapsulated cells to receive nutrients and remove waste.1 As water-swollen, porous networks, hydrogels are ideal materials for cell-encapsulation, tissue engineering, and 3D bioprinting applications. Hydrogels for 3D bioprinting must also feature tunable substrate stiffness and allow for network remodeling post-printing, so cells can spread, migrate, proliferate, and interact.9 While a wide variety of materials are used for bioinks, the most popular materials include gelatin methacrylol (GelMA), collagen, poly(ethylene glycol) (PEG), Pluronic®, alginate, and decellularized extracellular matrix (ECM)-based materials (Table 1).

Featured Bioink Material

Gelatin MethacryloylGelatin methacryloyl (GelMA) can be used to form crosslinked hydrogels for tissue engineering and 3D printing. GelMA-based bioinks feature excellent cytocompatibility, tunable substrate stiffness, improved printability, and rapid crosslinking with exposure to UV or visible light (depending on the identity of the photoinitiator)11. GelMA has been used in endothelial cell morphogenesis, cardiomyocytes, epidermal tissue, injectable tissue constructs, bone differentiation, and cartilage regeneration. Gelatin methacryloyl has also been used in microspheres and hydrogels for drug delivery applications.

A structural chemical formula of Gelatin Methacryloyl (GelMA), showing a complex arrangement of carbon rings, chains, nitrogen bases, oxygen, and hydrogen atoms. The structure includes repeating units indicated by “(N)” to denote polymerization, with various functional groups such as hydroxyls, ketones, and amides. GelMA is a modified gelatin used in biomedicine and tissue engineering for creating hydrogels.

Figure 2.Gelatin Methacryloyl

Acellular Materials

In addition to bioinks, acellular materials are also used in 3D bioprinted structures.2 Acellular materials typically provide structural support for tissue constructs and when utilized with bioinks, can generate functional, bioprinted tissues. Acellular materials are porous structures that recapitulate both mechanical and biochemical properties of the native extracellular matrix (ECM)4. Porosity enables cell migration, tissue growth, vascular formation, and cell viability within these structural constructs.6  In addition, acellular materials must also have the necessary surface chemistry for cell attachment, proliferation, and differentiation.5 Popular acellular materials include: collagen, fibrin, chitosan, nanocellulose, poly(lactic acid) (PLA), polycaprolactone (PCL), hydroxyapatite (HA), and β-tricalcium phosphate (β-TCP) (Table 1).

Bioink Material Building Blocks

Table 1Biomaterials commonly used in 3D bioprinting.

What 3D Bioprinting Method Should Be Used?

Depending on the type of ink (bioink or acellular materials) selected and complexity of the final tissue construct, different 3D printing methods can be used (Figure 1). Advantages and disadvantages of common methods can be found in the table below (Table 2).

Table 2.Summary of 3D bioprinting methods.

In addition to ink type, the bioprinting method can also be dictated by the end application of the printed construct (Table 3).

Tissue Engineering Applications

Table 3.3D Bioprinting of tissue constructs.

Conclusion

3D bioprinting allows for the spatially-controlled placement of cells in a defined 3D microenvironment. Bioinks are formed by combining cells and various biocompatible materials, which are subsequently printed in specific shapes to generate tissue-like, 3D structures. Combing our expertise in materials science and cell biology, we offer a variety of solutions to simplify the 3D bioprinting workflow.

References

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Pan C, Bruyas A, Yang Y. 2016. Material Matters.. 11(2):49-55.
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Sears NA, Seshadri DR, Dhavalikar PS, Cosgriff-Hernandez E. 2016. A Review of Three-Dimensional Printing in Tissue Engineering. Tissue Engineering Part B: Reviews. 22(4):298-310. https://doi.org/10.1089/ten.teb.2015.0464
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Langer R, Vacanti J. 1993. Tissue engineering. Science. 260(5110):920-926. https://doi.org/10.1126/science.8493529
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Bose S, Vahabzadeh S, Bandyopadhyay A. 2013. Bone tissue engineering using 3D printing. Materials Today. 16(12):496-504. https://doi.org/10.1016/j.mattod.2013.11.017
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Hutmacher DW. 2000. Scaffolds in tissue engineering bone and cartilage. Biomaterials. 21(24):2529-2543. https://doi.org/10.1016/s0142-9612(00)00121-6
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Bose S, Roy M, Bandyopadhyay A. 2012. Recent advances in bone tissue engineering scaffolds. Trends in Biotechnology. 30(10):546-554. https://doi.org/10.1016/j.tibtech.2012.07.005
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Lichte P, Pape H, Pufe T, Kobbe P, Fischer H. 2011. Scaffolds for bone healing: Concepts, materials and evidence. Injury. 42(6):569-573. https://doi.org/10.1016/j.injury.2011.03.033
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Lu L, Zhang Q, Wootton D, Chiou R, Li D, Lu B, Lelkes P, Zhou J. 2012. Biocompatibility and biodegradation studies of PCL/?-TCP bone tissue scaffold fabricated by structural porogen method. J Mater Sci: Mater Med. 23(9):2217-2226. https://doi.org/10.1007/s10856-012-4695-2
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Elomaa L, Kang Y, Seppälä JV, Yang Y. 2014. Biodegradable photocrosslinkable poly(depsipeptide-co-?-caprolactone) for tissue engineering: Synthesis, characterization, and In vitro evaluation. J. Polym. Sci. Part A: Polym. Chem.. 52(23):3307-3315. https://doi.org/10.1002/pola.27400
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Elomaa L, Pan C, Shanjani Y, Malkovskiy A, Seppälä JV, Yang Y. Three-dimensional fabrication of cell-laden biodegradable poly(ethylene glycol-co-depsipeptide) hydrogels by visible light stereolithography. J. Mater. Chem. B. 3(42):8348-8358. https://doi.org/10.1039/c5tb01468a
11.
Yue K, Trujillo-de Santiago G, Alvarez MM, Tamayol A, Annabi N, Khademhosseini A. 2015. Synthesis, properties, and biomedical applications of gelatin methacryloyl (GelMA) hydrogels. Biomaterials. 73254-271. https://doi.org/10.1016/j.biomaterials.2015.08.045
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