Innovations in Bioink Materials and 3D Bioprinting for Precision Tissue Engineering
DOI:
https://doi.org/10.37329/metta.v4i3.3520Keywords:
Bioink, 3D Bioprinting, Tissue EngineeringAbstract
The progress in bioink materials and 3D bioprinting techniques has created new opportunities in tissue engineering. The goal is to develop cellular implants that closely resemble native tissues in structure, function, and microenvironment, addressing challenges such as nutrient transport and mechanical support for tissue regeneration. This literature review evaluates current trends in bioink development and 3D bioprinting methodologies, assessing their effectiveness for enhancing tissue-engineered constructs for clinical applications. Recent studies were comprehensively analyzed, focusing on novel bioink formulations, optimization of 3D bioprinting processes, and evaluate on of printed constructs' mechanical and biological properties. Various fabrication techniques and their implications for tissue integration were examined. The review shows significant progress in bioink compositions that enhance cell viability and nutrient diffusion within printed scaffolds. Constructs demonstrated improved mechanical properties and biological functionality, enabling better integration with host tissues. In vivo studies highlighted the potential of these bioprinted tissues to support cellular activity and regeneration, signifying significant advancements in clinical viability. The findings emphasize the crucial role of bioink materials and bioprinting technology in advancing tissue engineering. Continual innovation in bioink formulation and printing techniques is essential to overcome current limitations and achieve widespread clinical application. Future research should focus on personalized bioink development and expanding the range of tissues that can be effectively engineered, ultimately improving patient outcomes in regenerative medicine.
References
Alonzo, M., Dominguez, E., Alvarez-Primo, F., Quinonez, A., Munoz, E., Puebla, J., ... & Joddar, B. (2020). A Comparative Study In The Printability Of A Bioink And 3d Models Across Two Bioprinting Platforms. Materials Letters, 264, 127382.
Ananth, K. P., & Jayram, N. D. (2023). A comprehensive review of 3D Printing Techniques For Biomaterial-Based Scaffold Fabrication In Bone Tissue Engineering. Annals of 3D Printed Medicine, 100141.
Angelopoulos, I., Allenby, M. C., Lim, M., & Zamorano, M. (2020). Engineering Inkjet Bioprinting Processes Toward Translational Therapies. Biotechnology And Bioengineering, 117(1), 272-284.
Cavallo, A., Al Kayal, T., Mero, A., Mezzetta, A., Guazzelli, L., Soldani, G., & Losi, P. (2023). Fibrinogen-Based Bioink for Application in Skin Equivalent 3D Bioprinting. Journal of Functional Biomaterials, 14(9), 459.
Di Marzio, N., Eglin, D., Serra, T., & Moroni, L. (2020). Bio-fabrication: Convergence Of 3d Bioprinting And Nano-Biomaterials In Tissue Engineering And Regenerative Medicine. Frontiers In Bioengineering And Biotechnology, 8, 326.
Ding, Y. W., Zhang, X. W., Mi, C. H., Qi, X. Y., Zhou, J., & Wei, D. X. (2023). Recent Advances In Hyaluronic Acid-Based Hydrogels For 3d Bioprinting In Tissue Engineering Applications. Smart Materials in Medicine, 4, 59-68.
Fatimi, A., Okoro, O. V., Podstawczyk, D., Siminska-Stanny, J., & Shavandi, A. (2022). Natural Hydrogel-Based Bio-Inks For 3D Bioprinting In Tissue Engineering: A Review. Gels, 8(3), 179.
Fritschen, A., Acedo Mestre, M., Scholpp, S., & Blaeser, A. (2023). Influence Of The Physico-Chemical Bioink Composition On The Printability And Cell Biological Properties In 3d-Bioprinting Of A Liver Tumor Cell Line. Frontiers in Bioengineering and Biotechnology, 11, 1093101.
Gang, F., Ye, W., Ma, C., Wang, W., Xiao, Y., Liu, C., & Sun, X. (2022). 3D Printing of Plla/Biomineral Composite Bone Tissue Engineering Scaffolds. Materials, 15(12), 4280.
García-Villén, F., Ruiz-Alonso, S., Lafuente-Merchan, M., Gallego, I., Sainz-Ramos, M., Saenz-del-Burgo, L., & Pedraz, J. L. (2021). Clay Minerals As Bioink Ingredients For 3d Printing And 3d Bioprinting: Application In Tissue Engineering And Regenerative Medicine. Pharmaceutics, 13(11), 1806.
Gungor-Ozkerim, P. S., Inci, I., Zhang, Y. S., Khademhosseini, A., & Dokmeci, M. R. (2018). Bioinks for 3D Bioprinting: An Overview. Biomaterials Science, 6(5), 915-946.
Gupta, S., & Bit, A. (2022). 3D Bioprinting In Tissue Engineering And Regenerative Medicine. Cell and Tissue Banking, 23(2), 199-212.
Hölzl, K., Lin, S., Tytgat, L., Van Vlierberghe, S., Gu, L., & Ovsianikov, A. (2016). Bioink Properties Before, During And After 3d Bioprinting. Biofabrication, 8(3), 032002.
Hospodiuk, M., Dey, M., Sosnoski, D., & Ozbolat, I. T. (2017). The bioink: A Comprehensive Review On Bioprintable Materials. Biotechnology advances, 35(2), 217-239.
Huang, Y., Zhang, X. F., Gao, G., Yonezawa, T., & Cui, X. (2017). 3D Bioprinting And The Current Applications In Tissue Engineering. Biotechnology Journal, 12(8), 1600734.
Isaeva, E. V., Beketov, E. E., Yuzhakov, V. V., Arguchinskaya, N. V., Kisel, A. A., Malakhov, E. P., ... & Kaprin, A. D. (2021). The Use Of Collagen With High Concentration In Cartilage Tissue Engineering By Means Of 3d-Bioprinting. Cell and Tissue Biology, 15, 493-502.
Ji, S., & Guvendiren, M. (2017). Recent advances In Bioink Design For 3d Bioprinting Of Tissues And Organs. Frontiers in Bioengineering And Biotechnology, 5, 23.
Jian, Z., Zhuang, T., Qinyu, T., Liqing, P., Kun, L., Xujiang, L., ... & Quanyi, G. (2021). 3D Bioprinting Of A Biomimetic Meniscal Scaffold For Application In Tissue Engineering. Bioactive materials, 6(6), 1711-1726.
Kakarla, A. B., Kong, I., Kong, C., Irving, H., & Thomas, C. J. (2022). Extrusion Of Cell Encapsulated In Boron Nitride Nanotubes Reinforced Gelatin—Alginate Bioink For 3d Bioprinting. Gels, 8(10), 603.
Khiari, Z. (2024). Recent Developments in Bio-Ink Formulations Using Marine-Derived Biomaterials for Three-Dimensional (3D) Bioprinting. Marine Drugs, 22(3), 134.
Khoeini, R., Nosrati, H., Akbarzadeh, A., Eftekhari, A., Kavetskyy, T., Khalilov, R., ... & Ozbolat, I. T. (2021). Natural And Synthetic Bioinks For 3d Bioprinting. Advanced NanoBiomed Research, 1(8), 2000097.
Kozaniti, F. K., Metsiou, D. N., Manara, A. E., Athanassiou, G., & Deligianni, D. D. (2021). Recent Advancements In 3d Printing And Bioprinting Methods For Cardiovascular Tissue Engineering. Bioengineering, 8(10), 133.
Lazaridou, M., Bikiaris, D. N., & Lamprou, D. A. (2022). 3D Bioprinted Chitosan-Based Hydrogel Scaffolds In Tissue Engineering And Localised Drug Delivery. Pharmaceutics, 14(9), 1978.
Lee, S. J., Esworthy, T., Stake, S., Miao, S., Zuo, Y. Y., Harris, B. T., & Zhang, L. G. (2018). Advances In 3d Bioprinting For Neural Tissue Engineering. Advanced Biosystems, 2(4), 1700213.
Liu, H., Gong, Y., Zhang, K., Ke, S., Wang, Y., Wang, J., & Wang, H. (2023). Recent Advances In Decellularized Matrix-Derived Materials For Bioink And 3d Bioprinting. Gels, 9(3), 195.
Liu, N., Ye, X., Yao, B., Zhao, M., Wu, P., Liu, G., ... & Zhu, P. (2021). Advances in 3D Bioprinting Technology For Cardiac Tissue Engineering And Regeneration. Bioactive Materials, 6(5), 1388-1401.
MacDonald, A. F., Harley-Troxell, M. E., Newby, S. D., & Dhar, M. S. (2022). 3D-Printing Graphene Scaffolds For Bone Tissue Engineering. Pharmaceutics, 14(9), 1834.
Mallakpour, S., Tukhani, M., & Hussain, C. M. (2021). Recent Advancements In 3d Bioprinting Technology Of Carboxymethyl Cellulose-Based Hydrogels: Utilization In Tissue Engineering. Advances in Colloid and Interface Science, 292, 102415.
Mandrycky, C., Wang, Z., Kim, K., & Kim, D. H. (2016). 3D Bioprinting For Engineering Complex Tissues. Biotechnology Advances, 34(4), 422-434.
Mani, M. P., Sadia, M., Jaganathan, S. K., Khudzari, A. Z., Supriyanto, E., Saidin, S., ... & Faudzi, A. A. M. (2022). A Review On 3d Printing In Tissue Engineering Applications. Journal of Polymer Engineering, 42(3), 243-265.
Masri, S., Fauzi, F. A. M., Hasnizam, S. B., Azhari, A. S., Lim, J. E. A., Hao, L. Q., ... & Fauzi, M. B. (2022). Engineered-skin Of Single Dermal Layer Containing Printed Hybrid Gelatin-Polyvinyl Alcohol Bioink Via 3d-Bioprinting: In Vitro Assessment Under Submerged Vs. Air-lifting models. Pharmaceuticals, 15(11).
Mobaraki, M., Ghaffari, M., Yazdanpanah, A., Luo, Y., & Mills, D. K. (2020). Bioinks And Bioprinting: A Focused Review. Bioprinting, 18, e00080.
O’Connell, G., Garcia, J., & Amir, J. (2017). 3D bioprinting: New Directions In Articular Cartilage Tissue Engineering. ACS Biomaterials Science & Engineering, 3(11).
Ostrovidov, S., Salehi, S., Costantini, M., Suthiwanich, K., Ebrahimi, M., Sadeghian, R. B., ... & Khademhosseini, A. (2019). 3D Bioprinting In Skeletal Muscle Tissue Engineering. Small, 15(24), 1805530.
Ozbolat, I. T., & Hospodiuk, M. (2016). Current Advances And Future Perspectives In Extrusion-Based Bioprinting. Biomaterials, 76, 321-343.
Panwar, A., & Tan, L. P. (2016). Current status Of Bioinks For Micro-Extrusion-Based 3d Bioprinting. Molecules, 21(6), 685.
Saini, G., Segaran, N., Mayer, J. L., Saini, A., Albadawi, H., & Oklu, R. (2021). Applications of 3D Bioprinting In Tissue Engineering And Regenerative Medicine. Journal of Clinical Medicine, 10(21), 4966.
Sodupe-Ortega, E., Sanz-Garcia, A., Pernia-Espinoza, A., & Escobedo-Lucea, C. (2018). Accurate Calibration In Multi-Material 3d Bioprinting For Tissue Engineering. Materials, 11(8), 1402.
Tiwari, A. P., Thorat, N. D., Pricl, S., Patil, R. M., Rohiwal, S., & Townley, H. (2021). Bioink: a 3D-bioprinting Tool For Anticancer Drug Discovery And Cancer Management. Drug Discovery Today, 26(7), 1574-1590.
Wang, Z., Wang, L., Li, T., Liu, S., Guo, B., Huang, W., & Wu, Y. (2021). 3D Bioprinting In Cardiac Tissue Engineering. Theranostics, 11(16), 7948.
Wu, C. A., Zhu, Y., & Woo, Y. J. (2023). Advances in 3D bioprinting: Techniques, Applications, And Future Directions For Cardiac Tissue Engineering. Bioengineering, 10(7), 842.
Xie, Z., Gao, M., Lobo, A. O., & Webster, T. J. (2020). 3D Bioprinting In Tissue Engineering For Medical Applications: The Classic And The Hybrid. Polymers, 12(8), 1717.
Yu, J., Park, S. A., Kim, W. D., Ha, T., Xin, Y. Z., Lee, J., & Lee, D. (2020). Current Advances In 3d Bioprinting Technology And Its Applications For Tissue Engineering. Polymers, 12(12), 2958.
Zennifer, A., Senthilvelan, P., Sethuraman, S., & Sundaramurthi, D. (2021). Key Advances Of Carboxymethyl Cellulose In Tissue Engineering & 3d Bioprinting Applications. Carbohydrate polymers, 256, 117561.
Zhang, Q., Zhou, J., Zhi, P., Liu, L., Liu, C., Fang, A., & Zhang, Q. (2023). 3D Printing Method For Bone Tissue Engineering Scaffold. Medicine in Novel Technology and Devices, 17, 100205.
Zhe, M., Wu, X., Yu, P., Xu, J., Liu, M., Yang, G., ... & Ritz, U. (2023). Recent Advances In Decellularized Extracellular Matrix-Based Bioinks For 3d Bioprinting In Tissue Engineering. Materials, 16(8), 3197.
Züger, F., Berner, N., & Gullo, M. R. (2023). Towards A Novel Cost-Effective And Versatile Bioink For 3d-Bioprinting In Tissue Engineering. Biomimetics, 8(1), 27.
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