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Trinath BiswalDept. of Chemistry, Veer Surendra Sai University of Technology, Burla, Sambalpur, Odisha, IndiaPart of the book: Advances in Chemistry Research. Volume 76Chapter DOI: https://doi.org/10.52305/SQOK3793AbstractDesign and development of scaffolds of biological active hydrogels with superior properties is one of the vital factors for tissue engineering and tissue implant application. Today, hydrogels are considered a promising material used as scaffolds for tissue engineering applications owing to their similarity in structure and composition to the natural extracellular matrix along with their required framework for survival and cellular proliferation. Due to some amazing properties and biocompatibility, hydrogels have been applied effectively in biomedical sectors such as tissue engineering and drug delivery owing to some amazing properties and biocompatibility. The higher water content fits these materials with the proteins and living tissues, and the rubbery nature of these materials injures the surrounding tissues. The capability of hydrogel to control and regulate the shape, size, surface morphology, and porosity provides opportunities to overcome the different challenges for tissue engineering applications such as tissue architecture, seeding of multiple cells, and vascularization. Hydrogels selected for tissue engineering are usually biodegradable, bioactive, and never require further surgery after functioning. The bio-functionality property of hydrogels is highly required to monitor cellular behaviours like proliferation, matrix production, and differentiation. Over the last two decades, hydrogels have been used as one of the effective materials used for tissue engineering owing to their capability to uphold a distinctive 3D structure, which offers good mechanical strength for the cells and activates the local extracellular matrix. In this chapter, special emphasis is placed on the use of hydrogels of various kinds in tissue engineering.Keywords: hydrogels, tissue engineering, extracellular matrix, biodegradable, biocompatibleReferences[1] Hoffman, A. S. (2012). Hydrogels for biomedical applications. Advanced DrugDelivery Reviews, 64, pp. 18–23.[2] Khademhosseini, A., and Langer, R. (2007). Micro-engineered hydrogels for tissueengineering Biomaterials, 28(34), pp. 5087–5092.[3] Qinyuan, C., Yang J., and Xinjun, Y. (2017). Hydrogels for BiomedicalApplications: Their Characteristics and the Mechanisms behind Them, Gels, 3(1),6–.20.[4] Lee, E. J., Kasper, F. K., and Mikos, A. G. (2014). Biomaterials for TissueEngineering. Annals of Biomedical Engineering, 42(2), 323–337.[5] Enrica, C., and Khutoryanskiy, V. V. (2015). Biomedical applications of hydrogels:A review of patents and commercial products, European Polymer Journal, 65(),252–267.[6] Mantha, S., Pillai, S., Khayambashi, P., Upadhyay, A., Zhang, Y., Tao, O., Pham,H. M., and Tran, S. D. (2019). Smart Hydrogels in Tissue Engineering andRegenerative Medicine, Materials, 12(20), 3323.[7] Biswal, T. (2021). Biopolymers for tissue engineering applications: A review.Materials Today: Proceedings, 41(2), 397-402.[8] Christopher, D. S. (2020). Hydrogel scaffolds for tissue engineering: the importanceof polymer choice, Polymer Chemistry, 11(2), 184-219.[9] Chaudhary, S., and Chakraborty, E. (2022). Hydrogel based tissue engineering andits future applications in personalized disease modelling and regenerative therapy,Beni-Suef University Journal of Basic and Applied Sciences, 11(3), 1-15.[10] Ahmed, E. M. (2015). Hydrogel: Preparation, characterization, and applications: Areview, Journal of Advanced Research, 6(2), 105–121.[11] Cai, M. H., Chen, X. Y., Fu, L. Q., Du, W. L., Yang, X., Mou, X. Z., and Hu, P. Y.(2021). Design and Development of Hybrid Hydrogels for Biomedical Applications:Recent Trends in Anticancer Drug Delivery and Tissue Engineering, Frontiers inBioengineering and Biotechnology, 9, 1-18.[12] Bashir, S., Hina, M., Iqbal, J., Rajpar, A. H., Mujtaba, M. A., Alghamdi, N. A.,Wageh, S., Ramesh, K., and Ramesh, S. (2020). Fundamental Concepts ofHydrogels: Synthesis, Properties, and Their Applications, Polymers, 12(11), 2702–.2761.[13] Bustamante-Torres, M., Romero-Fierro, D., Arcentales-Vera, B., Palomino, K.,Magaña, H., and Bucio, E. (2021). Hydrogels Classification According to thePhysical or Chemical Interactions and as Stimuli-Sensitive Materials, Gels, 7, 182-206.[14] Garg, S., and Garg, A. (2016). Hydrogel: Classification, Properties, Preparation andTechnical Features, Asian Journal of Biomaterial Research, 2(6), 163-170.[15] Ullah, F., Othman, M. B. H., Javed, F., Ahmad, Z., and Akil, H. Md. (2015).Classification, processing, and application of hydrogels: A review, MaterialsScience and Engineering: C, 57, 414-433.[16] Zhou, Y., Dong, X., Mi, Y., Fan, F. Xu, Q., Zhao, H., Wang, S., and Long, Y. (2020).Hydrogel Smart Windows. Journal of Materials Chemistry A, 8(20), 10007-10025.[17] White, E. M., Yatvin, J., Grubbs, J. B., Bilbrey, J. A., and Locklin, J. (2013).Advances in smart materials: Stimuli-responsive hydrogel thin films, Journal ofPolymer Science Part B: Polymer Physics, 51(14), 1084–1099.[18] Bayat, M. R., and Baghani, M. (2021). A review on swelling theories of pH-sensitivehydrogels. Journal of Intelligent Material Systems and Structures., 32(18-19), 2349-2365.[19] Rizwan, M., Yahya, R., Hassan, A., Yar, M., Azzahari, A., Selvanathan, V.,Sonsudin, F., and Abouloula, C. (2017). pH Sensitive Hydrogels in Drug Delivery:Brief History, Properties, Swelling, and Release Mechanism, Material Selection andApplications, Polymers, 9(12), 137–173.[20] Huang, H., Qi, X., Chen, Y., and Wu, Z. (2019). Thermo-sensitive hydrogels fordelivering biotherapeutic molecules: A review, Saudi Pharmaceutical Journal,27(7), 990-999.[21] Yibin, Y., Yi, C., Junye, T., Lei, Z., Yen, W., and Mei, T. (2021). Recent advancesin thermo-sensitive hydrogels for drug delivery, Journal of Materials Chemistry B,8(13), 2979-2992.[22] Berger, J., Reist, M., Mayer, J. M., Felt, O., and Gurny, R. (2004). Structure andinteractions in chitosan hydrogels formed by complexation or aggregation forbiomedical applications, European Journal of Pharmaceutics andBiopharmaceutics, 57(1), 35–52.[23] Janga, K. Y., Tatke, A., Balguri, S. P., Lamichanne, S. P., Ibrahim, M. M., Maria,D. N., Jablonski, M. M., and Majumdar, S. (2018). Ion-sensitive hydrogels ofnatamycin bilosomes for enhanced and prolonged ocular pharmacotherapy:permeability, cytotoxicity, and in vivo evaluation. Artificial Cells, Nanomedicine,and Biotechnology, 46(1), 1039-1050.[24] You, Y., Yang, J., and Zheng, Q. (2020). Ultra-stretchable hydrogels withhierarchical hydrogen bonds, Scientific Reports, 10, 11727-11735.[25] Gao, L., Luo, H., Wang, Q., Hu, G., and Xiong, Y. (2021). Synergistic Effect ofHydrogen Bonds and Chemical Bonds to Construct a Starch-Based Water-Absorbing/Retaining Hydrogel Composite Reinforced with Cellulose andPoly(ethylene glycol), ACS Omega, 6(50), 35039-35049.[26] Ziyuan, L., Yanzi, Z., Tianyue, L., Junji, Z., and He, T. (2021). Stimuli‐responsivehydrogels: Fabrication and biomedical applications, VIEW, 3(2), 1 –25.[27] Nagam, S. P., Jyothi, A. N., Poojitha, J., and Aruna, S. (2016). A Comprehensivereview on hydrogels, International Journal of Current Pharmaceutical Review andResearch, 8(1), 19-23.[28] Kytai, T. N., and Jennifer, L. W. (2002). Photopolymerizable hydrogels for tissueengineering applications, Biomaterials, 23(22), 4307–4314.[29] Hunt, J. A., Chen, R., van Veen, T., and Bryan, N. (2014). Hydrogels for tissueengineering and regenerative medicine, Journal of Materials Chemistry B, 2(33),5319-5338.[30] Lee, K. Y., and Mooney, D. J. (2001). Hydrogels for Tissue Engineering, ChemicalReviews, 101(7), 1869–1880.[31] El-Sherbiny, I. M., and Yacoub, M. H. (2013). Hydrogel scaffolds for tissueengineering: Progress and challenges, Global Cardiology Science and Practice,2013(3), 316–342.[32] Jeanie, L. D., and Mooney, D. J. (2003). Hydrogels for tissue engineering: scaffolddesign variables and applications, Biomaterials, 24(24), 4337–4351.[33] Zhao, H., Liu, M., Zhang, Y., Yin, J., and Pei, R. (2020). Nanocomposite Hydrogelsfor Tissue Engineering Applications, Nanoscale, 12(28), 14976-14995.\\[34] Mohan Kumar, B. S., Priyanka, G., and Rajalakshmi, S. (2021). Hydrogels: potentialaid in tissue engineering—a review. Polymer. Bulletin.https://doi.org/10.1007/s00289-021-03864-x.[35] Tavakoli, S., and Klar, A. S. (2020). Advanced Hydrogels as Wound Dressings,Biomolecules, 10(8), 1169–.1188.[36] Liang, Y., He, J., and Guo, B. (2021). Functional Hydrogels as Wound Dressing toEnhance Wound Healing, ACS Nano, 15 (8), 12687–12722.[37] Short, A. R., Koralla A., D. D. Stocker B., Wissel B., Calhoun M., D. Winter D. J.(2015). Hydrogels That Allow and Facilitate Bone Repair, Remodeling, andRegeneration, Journals of Material Chemistry B, 3 (40), 7818-7830.[38] Yue, S., He, H., Li, B., and Hou, T. (2020). Hydrogel as a Biomaterial for BoneTissue Engineering: A Review, Nanomaterials, 10(8), 1511–1534.[39] Nallusamy, J., and Das, R. K. (2021). Hydrogels and Their Role in Bone TissueEngineering: An Overview. J Pharm Bioallied Sci., 13(Suppl 2), S908-S912.[40] Bai, X., Gao, M., Syed, S., Zhuang, J., Xu, X., and Zhang, X. Q. (2018). Bioactivehydrogels for bone regeneration. Bioactive Materials, 3(4), 401–417.[41] Zhu, W., Liu, Y. W., Zhou, L. Z., and Weng, X. S. (2020). Strategy of injectablehydrogel and its application in tissue engineering. Chin Med J (Engl), 134(3), 275-277.[42] Liu, M., Zeng, X., Ma, C., Yi, H., Ali, Z., Mou, X., Li, S., Deng, Y., and He, N.(2017). Injectable hydrogels for cartilage and bone tissue engineering, BoneResearch, 5(), 17014–17034.[43] Saekhor, K., Udomsinprasert, W., Honsawek, S., and Tachaboonyakiat, W. (2018).Preparation of an injectable modified chitosan-based hydrogel approaching for bonetissue engineering. International Journal of Biological Macromolecules, 123, 167-173.[44] Shakya, A. K., and Kandalam, U. (2017). Three-dimensional macroporous materialsfor tissue engineering of craniofacial bone. British Journal of Oral andMaxillofacial Surgery, 55(9), 875-89.[45] Olov, N., Bagheri-Khoulenjani, S., and Mirzadeh, H. (2022). Injectable hydrogelsfor bone and cartilage tissue engineering: a review, Progress in Biomaterials, 11(2),113-135.[46] Yiwen, Z., Zhixiang, L., Jingjing, G., YingJi, M., and Pinghui, Z. (2021). Hydrogel:A potential therapeutic material for bone tissue engineering. AIP Advances, 11(1),1-16.[47] Fu, S., Ni, P. Y., Wang B. Y., Chu, B. Y., Zheng, L., Luo, F., Luo, J. C., and Qian,Z. Y. (2012). Injectable and thermo-sensitive PEG-PCL-PEG copolymer/collagen/n-HA hydrogel composite for guided bone regeneration, Biomaterials,33(19), 4801–4809.[48] Lin, G., Cosimbescu, L., Karin, N. J., and Tarasevich, B. J. (2012). Injectable andthermosensitive PLGA-g-PEG hydrogels containing hydroxyapatite: preparation,characterization and in vitro release behavior. Biomedical materials (Bristol,England), 7(2), 1-12.[49] Mei, Q., Rao, J., Bei, H. P., Liu, Y., and Zhao, X. (2021). 3D Bioprinting Photo CrosslinkableHydrogels for Bone and Cartilage Repair, Int J. of Bioprint, 7(3), 367-383.[50] Han, Y., Zeng, Q., Li, H., and Chang, J. (2013). The calcium silicate/alginatecomposite: Preparation and evaluation of its behaviour as bioactive injectablehydrogels, Acta Biomaterialia, 9(11), 9107–9117.[51] Tang, G., Tan, Z., Zeng, W., Wang, X., Shi, C., Liu, Y., He, H., Chen, R… and Ye,X. (2020) Recent Advances of Chitosan-Based Injectable Hydrogels for Bone andDental Tissue Regeneration. Front. Bioeng. Biotechnol, 8, 1-15.[52] Saravanan, S., Vimalraj, S., Thanikaivelan, P., Banudevi, S., and Manivasagam, G.(2019). A review on injectable chitosan/beta glycerophosphate hydrogels for bonetissue regeneration, International Journal of Biological Macromolecules, 121(), 38–54.[53] Li, J., Chen, G., Xu, X., Abdou, P., Jiang, Q., Shi, D., and Gu, Z. (2019). Advancesof injectable hydrogel-based scaffolds for cartilage regeneration, Regen Biomatter,6(3), 129-140.[54] Ngadimin, K, D., Stokes, A., Gentile, P., and Ferreira, A. M. (2021). Biomimetichydrogels designed for cartilage tissue engineering. Biomaterials Science, 9, 4246-4259.[55] Rey-Rico, A., Cucchiarini, M., and Madry, H. (2017). Hydrogels for precisionmeniscus tissue engineering: a comprehensive review, Connective Tissue Research,58 (3-4), 317-328.[56] Chen, M., Feng, Z., Guo, W., Yang, D., Gao, S., Li, Y., Shen, S., Yuan, Z., Huang,B., Zhang, Y., and Wang, M. (2019). PCL-MECM Based Hydrogel HybridScaffolds and Meniscal Fibrochondrocytes Promote Whole Meniscus Regenerationin a Rabbit Meniscectomy Model. ACS Applied Materials & Interfaces, 11 (44),41626–41639.[57] Vasiliadis, A. V., Koukoulias, N., and Katakalos, K. (2021). Three-Dimensional Printed Scaffolds for Meniscus Tissue Engineering: Opportunity for the Future inthe Orthopaedic World. J. Funct. Biomater, 12, 69-77.[58] Marrella, A., Lagazzo, A., Dellacasa, E., Pasquini, C., Finocchio, E., Barberis, F.,Pastorino, L., Giannoni, P., and Scaglione, S. (2018). 3D Porous Gelatin/PVAHydrogel as Meniscus Substitute Using Alginate Micro-Particles as Porogens,Polymers, 10(4), 380–395.[59] Zorzi, C., Rigotti, S., Screpis, D., Giordan, N., and Piovan, G. (2016). A newhydrogel for the conservative treatment of meniscal lesions: a randomized controlledstudy, Joints, 3(3), 136-45.[60] Mazlan, Z., and Mh Busra, F. (2021). Injectable Hydrogels for Chronic Skin WoundManagement: A Concise Review, Biomedicines, 9(5), 527-533.[61] Pereira, R. F., Sousa, A., and Barrias, C. C. (2017). Advances in bioprinted cell laden hydrogels for skin tissue engineering. Biomanufacturing Reviews, 2 (1), 1-26.[62] Han, Y., Li, Y., Zeng, Q., Li, H., Peng, J., Xu, Y., and Chang, J. (2017). Injectablebioactive akermanite/alginate composite hydrogels for in situ skin tissueengineering. Journal of Materials Chemistry B, 5(18), 3315-3326[63] Jeong, K. H., Park, D. and Lee, Y. C. (2017). Polymer-based hydrogel scaffolds forskin tissue engineering applications: a mini-review, Journal of Polymer Research,24(7), 112-121.[64] Weng, T., Zhang, W., Xia, Y., Wu, P., Yang, M., Jin, R., Xia, S., Wang, J., You, C.,Han, C., and Wang, X. (2021). 3D bioprinting for skin tissue engineering: Currentstatus and perspectives, Journal of Tissue Engineering, 12, 1-28.[65] Yang, G., Lin, H., Rothrauff, B, B., Yu, S., and Tuan, R. S. (2016). Multilayeredpolycaprolactone/gelatin fiber-hydrogel composite for tendon tissue engineering.Acta Biomater, 35, 68-76.[66] Liu, R., Zhang, S., and Chen, X. (2020). Injectable hydrogels for tendon andligament tissue engineering, Journal of Tissue Engineering and RegenerativeMedicine, 14(9), 1333-1348.[67] Bhattacharjee, P., and Ahearne, M. (2021). Significance of Crosslinking Approachesin the Development of Next Generation Hydrogels for Corneal Tissue Engineering,Pharmaceutics, 13, 319-341.[68] Ghezzi, C. E., Rnjak-Kovacina, J., and Kaplan, D. L. (2015). Corneal TissueEngineering: Recent Advances and Future Perspectives, Tissue Engineering Part B:Reviews, 21(3), 278–287.[69] Zhao, Y., Song, S., Ren, X., Zhang, J., Lin, Q., and Zhao, Y. (2022). SupramolecularAdhesive Hydrogels for Tissue Engineering Applications, Chemical Reviews, 122(6), 5604–5640[70] Li, Z., and Guan, J. (2011). Hydrogels for Cardiac Tissue Engineering, Polymers,3(4), 740–761.[71] Peña, B., Laughter, M., Jett, S., Rowland, T. J., Taylor Matthew, R. G., Mestroni,L., and Park, D. (2018). Injectable Hydrogels for Cardiac Tissue Engineering.Macromolecular Bioscience, 18(6), 1-22.[72] Aurand, E. R., Lampe, K. J., and Bjugstad, K. B. (2012). Defining and designingpolymers and hydrogels for neural tissue engineering, Neuroscience research, 72(3),199–213.[73] Peressotti, S., Koehl, G. E., Goding, J. A., and Green, R. A. (2021). Self-AssemblingHydrogel Structures for Neural Tissue Repair, ACS Biomaterials Science &Engineering, 7(9), 4136–4163.[74] Thomas, B., Mieke, V., Jorg, S., Sandra, Van V., and Peter, D. (2012). A review oftrends and limitations in hydrogel-rapid prototyping for tissue engineering,Biomaterials, 33(26), 6020 –6041.[75] Catoira, M. C., Fusaro, L., and Di Francesco, D. (2019). Overview of naturalhydrogels for regenerative medicine applications, Journal of Materials Science:Materials in Medicine, 30, 115-124.[76] Xu, F., Dawson, C., Lamb, M., Mueller, E., Stefanek, E., Akbari, M., and Hoare, T(2022). Hydrogels for Tissue Engineering: Addressing Key Design Needs TowardClinical Translation, Frontiers in Bioengineering and Biotechnology, 10, 1-37.[77] Yahia, L. H., Chirani, N., and Gritsch, L. (2015) History and Applications ofHydrogels, Journal of Biomedical Sciences, 4(2), 13-35.[78] Rogers, Z. J., Zeevi, M. P., Koppes, R., and Bencherif, S. A. (2020).Electroconductive Hydrogels for Tissue Engineering: Current Status and FuturePerspectives, Bioelectricity, DOI:10.1089/bioe.2020.0025.[79] Du, C., and Huang, W. (2022). Progress and prospects of nanocomposite hydrogelsin bone tissue engineering, Nanocomposites, 8(1), 102-124.