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Physicochemical Effects of PEG Content in Alginate-based Double Network Hydrogels as Hybrid Scaffolds

Year 2024, Volume: 19 Issue: 1, 249 - 256, 28.03.2024
https://doi.org/10.55525/tjst.1410187

Abstract

This study aims to prepare a double-network hydrogel as hybrid networks bearing both natural and synthetic polymers to obtain scaffolds with increased swelling capacity and tunable mechanical and morphological properties. Physically cross-linked alginate hydrogel was reinforced with various ratios of Poly(ethylene glycol) (PEG) polymers which were chemically gellated via UV light exposure with a water soluble initiator. Physicochemical properties of the resulting hydrogels were systematically investigated via Fourier-transform infrared (FT-IR) spectroscopy for chemical composition and Scanning Electron Microscopy (SEM) for their morphological features like porosity. Furthermore, the effect of PEG amount in the final hydrogel (10, 20 and 40%) on swelling capacity was evaluated as well as the rheological properties. Prepared double-network hydrogels were demonstrated to be composed of both natural alginate polymer and synthetic PEG chains in FT-IR spectrum. Although 10%PEG containing hydrogel was not significantly different in terms of swelling capacity from the alginate hydrogel alone, increasing PEG amount seems to have improved the swelling ability. Comparative reological studies presented that introducing covalently cross-linked PEG network into alginate one increased crosspoint of storage and loss moduli almost 12 times more providing a stiffer scaffold. Increasing PEG content decreased the pore size on SEM images, indicating more crosslinking points in hydrogel structure.

References

  • Liaw C, Ji S, Guvendiren M. Engineering 3D Hydrogels for Personalized In Vitro Human Tissue Models. Adv Healthcare Mater 2018;1–16.
  • Dhandayuthapani B, Yoshida Y, Maekawa T, Kumar DS. Polymeric Scaffolds in Tissue Engineering Application: A Review. Int J Polym Sci 2011; 290602.
  • Nicodemus GD, Bryant SJ. Cell Encapsulation in Biodegradable Hydrogels for Tissue Engineering Applications. Tissue Eng Part B Rev 2008;14:149–165.
  • Liu M, Zeng X, Ma C, Yi H, Ali Z, Mou X, Li S, Deng Y, He N. Injectable Hydrogels for Cartilage and Bone Tissue Engineering. Bone Res 2017; 30:17014.
  • Saraiva SM, Miguel SP, Ribeiro MP, Coutinho P, Correia IJ. Synthesis and Characterization of a Photocrosslinkable Chitosan-Gelatin Hydrogel Aimed for Tissue Regeneration. RSC Adv 2015; 5: 63478-63488.
  • Edri R, Gal I, Noor N, Harel T, Fleischer S, Adadi N, Green O, Shabat D, Heller L, Shapira A. Personalized Hydrogels for Engineering Diverse Fully Autologous Tissue Implants. Adv Mater 2019; 31:1803895.
  • Thornton D, Mart RJ, WebbSJ, Ulijn RV. Enzyme-Responsive Hydrogel Particles for the Controlled Release of Proteins: Designing Peptide Actuators to Match Payload. Soft Matter 2008;4:821–827.
  • Chen Y, Tan Z, Wang W, Peng YY, Narain R. Injectable, Self-Healing, and Multi-Responsive Hydrogels via Dynamic Covalent Bond Formation between Benzoxaborole and Hydroxyl Groups. Biomacromolecules 2019;20:1028–1035.
  • Guaresti O, Basasoro S, González K, Eceiza A, Gabilondo N. In Situ Cross–Linked Chitosan Hydrogels via Michael Addition Reaction Based on Water–Soluble Thiol–Maleimide Precursors. Eur Polym J 2019; 119:376-384.
  • Koehler KC, Anseth KS, Bowman CN. Diels-Alder Mediated Controlled Release from a Poly(Ethylene Glycol) Based Hydrogel. Biomacromolecules 2013;14:538–547.
  • Yan S, Chai L, Li W, Xiao LP, Chen X, Sun RC. Tunning the Properties of PH-Responsive Lignin-Based Hydrogels by Regulating Hydroxyl Content. Colloids Surfaces A Physicochem Eng Asp 2022;643:128815.
  • Summonte S, Racaniello GF, Lopedota A, Denora N, Bernkop-Schnürch A. Thiolated Polymeric Hydrogels for Biomedical Application: Cross-Linking Mechanisms. J Control Release 2021, 330: 470– 482.
  • Cengiz N, Kabadayioglu H, Sanyal R. Orthogonally Functionalizable Copolymers Based on a Novel Reactive Carbonate Monomer. J Polym Sci Part A Polym Chem 2010;48:4737–4746.
  • Safakas K, Saravanou SF, Iatridi Z, Tsitsilianis C. Thermo-Responsive Injectable Hydrogels Formed by Self-Assembly of Alginate-Based Heterograft Copolymers. Gels 2023; 9(3):236.
  • Cai L, Dewi RE, Heilshorn SC. Injectable Hydrogels with in Situ Double Network Formation Enhance Retention of Transplanted Stem Cells. Adv Funct Mater 2015; 25(9):1344-1351.
  • Huang Y, Jayathilaka PB, Islam MS, Tanaka CB, Silberstein MN, Kilian KA, Kruzic JJ. Structural Aspects Controlling the Mechanical and Biological Properties of Tough, Double Network Hydrogels. Acta Biomater 2022; 138: 301–312.
  • Gong JP, Katsuyama Y, Kurokawa T, Osada Y. Double-Network Hydrogels with Extremely High Mechanical Strength. Adv Mater 2003; 15: 1155–1158.
  • Yasuda K, Gong JP, Katsuyama Y, Nakayama A, Tanabe Y, Kondo E, Ueno M, Osada Y. Biomechanical Properties of High-Toughness Double Network Hydrogels. Biomaterials 2005;26:4468– 4475.
  • Chen Q, Chen H, Zhu L, Zheng J. Fundamentals of Double Network Hydrogels. J Mater Chem B 2015;3:3654–3676.
  • Zhao J, Zhao X, Guo B. Multifunctional Interpenetrating Polymer Network Hydrogels Based on Methacrylated Alginate for the Delivery of Small Molecule Drugs and Sustained Release of Protein. Biomacromolecules 2014; 15(9): 3246–3252.
  • Polaske NW, McGrath DV, McElhanon JR. Thermally Reversible Dendronized Linear Ab StepPolymers via “Click” Chemistry. Macromolecules 2011;44:3203–3210.
  • Xu X, Jerca VV, Hoogenboom R. Bioinspired Double Network Hydrogels: From Covalent Double Network Hydrogels: Via Hybrid Double Network Hydrogels to Physical Double Network Hydrogels. Mater Horizons 2021;8:1173–1188.
  • Lee KY, Mooney DJ. Alginate: Properties and Biomedical Applications. Prog Polym Sci 2012;37:106–126.
  • Ma ZP, Song X, Yang BZ, Liu ST, Zheng RY, Xu XZ, Liu CH, Zhu YY. Fabrication of PEG-Anthracene/Alginate Double-Network Hydrogels and Their Application in Photolithography. J Appl Polym Sci 2023;140(48): 1–11.
  • BrackW, Altenburger R, Küster E, Meissner B, Wenzel KD, Schüürmann G. Identification of Toxic Products of Anthracene Photomodification in Simulated Sunlight. Environ. Toxicol Chem 2003; 22:2228–2237.
  • Hong S, Sycks D, Chan HF, Lin S, Lopez GP, Guilak F, Leong KW, Zhao X. 3D Printing: 3D Printing of Highly Stretchable and Tough Hydrogels into Complex, Cellularized Structures. Adv Mater 2015; 27:4034-4034.
  • Savić-Gajić IM, Savić IM, Svirčev Z. Preparation and Characterization of Alginate Hydrogels with High Water-Retaining Capacity. Polymers (Basel) 2023;15(12): 2592.
  • Wilems TS, Lu X, Kurosu YE, Khan Z, Lim HJ, Smith Callahan LA. Effects of Free Radical Initiators on Polyethylene Glycol Dimethacrylate Hydrogel Properties and Biocompatibility. J Biomed Mater Res - Part A 2017;105:3059–3068.
  • Tucker RM, Parcher BW, Jones EF, Desai TA. Single-Injection HPLC Method for Rapid Analysis of a Combination Drug Delivery System. AAPS PharmSciTech 2012; 13(2): 605–610.

Hibrit İskeleler Olarak Aljinat Bazlı Çift Ağ Hidrojellerindeki PEG İçeriğinin Fizikokimyasal Etkileri

Year 2024, Volume: 19 Issue: 1, 249 - 256, 28.03.2024
https://doi.org/10.55525/tjst.1410187

Abstract

This study aims to prepare a double-network hydrogel as hybrid networks bearing both natural and synthetic polymers to obtain scaffolds with increased swelling capacity and tunable mechanical and morphological properties. Physically cross-linked alginate hydrogel was reinforced with various ratios of Poly(ethylene glycol) (PEG) polymers which were chemically gellated via UV light exposure with a water soluble initiator. Physicochemical properties of the resulting hydrogels were systematically investigated via Fourier-transform infrared (FT-IR) spectroscopy for chemical composition and Scanning Electron Microscopy (SEM) for their morphological features like porosity. Furthermore, the effect of PEG amount in the final hydrogel (10, 20 and 40%) on swelling capacity was evaluated as well as the rheological properties. Prepared double-network hydrogels were demonstrated to be composed of both natural alginate polymer and synthetic PEG chains in FT-IR spectrum. Although 10%PEG containing hydrogel was not significantly different in terms of swelling capacity from the alginate hydrogel alone, increasing PEG amount seems to have improved the swelling ability. Comparative reological studies presented that introducing covalently cross-linked PEG network into alginate one increased crosspoint of storage and loss moduli almost 12 times more providing a stiffer scaffold. Increasing PEG content decreased the pore size on SEM images, indicating more crosslinking points in hydrogel structure.

References

  • Liaw C, Ji S, Guvendiren M. Engineering 3D Hydrogels for Personalized In Vitro Human Tissue Models. Adv Healthcare Mater 2018;1–16.
  • Dhandayuthapani B, Yoshida Y, Maekawa T, Kumar DS. Polymeric Scaffolds in Tissue Engineering Application: A Review. Int J Polym Sci 2011; 290602.
  • Nicodemus GD, Bryant SJ. Cell Encapsulation in Biodegradable Hydrogels for Tissue Engineering Applications. Tissue Eng Part B Rev 2008;14:149–165.
  • Liu M, Zeng X, Ma C, Yi H, Ali Z, Mou X, Li S, Deng Y, He N. Injectable Hydrogels for Cartilage and Bone Tissue Engineering. Bone Res 2017; 30:17014.
  • Saraiva SM, Miguel SP, Ribeiro MP, Coutinho P, Correia IJ. Synthesis and Characterization of a Photocrosslinkable Chitosan-Gelatin Hydrogel Aimed for Tissue Regeneration. RSC Adv 2015; 5: 63478-63488.
  • Edri R, Gal I, Noor N, Harel T, Fleischer S, Adadi N, Green O, Shabat D, Heller L, Shapira A. Personalized Hydrogels for Engineering Diverse Fully Autologous Tissue Implants. Adv Mater 2019; 31:1803895.
  • Thornton D, Mart RJ, WebbSJ, Ulijn RV. Enzyme-Responsive Hydrogel Particles for the Controlled Release of Proteins: Designing Peptide Actuators to Match Payload. Soft Matter 2008;4:821–827.
  • Chen Y, Tan Z, Wang W, Peng YY, Narain R. Injectable, Self-Healing, and Multi-Responsive Hydrogels via Dynamic Covalent Bond Formation between Benzoxaborole and Hydroxyl Groups. Biomacromolecules 2019;20:1028–1035.
  • Guaresti O, Basasoro S, González K, Eceiza A, Gabilondo N. In Situ Cross–Linked Chitosan Hydrogels via Michael Addition Reaction Based on Water–Soluble Thiol–Maleimide Precursors. Eur Polym J 2019; 119:376-384.
  • Koehler KC, Anseth KS, Bowman CN. Diels-Alder Mediated Controlled Release from a Poly(Ethylene Glycol) Based Hydrogel. Biomacromolecules 2013;14:538–547.
  • Yan S, Chai L, Li W, Xiao LP, Chen X, Sun RC. Tunning the Properties of PH-Responsive Lignin-Based Hydrogels by Regulating Hydroxyl Content. Colloids Surfaces A Physicochem Eng Asp 2022;643:128815.
  • Summonte S, Racaniello GF, Lopedota A, Denora N, Bernkop-Schnürch A. Thiolated Polymeric Hydrogels for Biomedical Application: Cross-Linking Mechanisms. J Control Release 2021, 330: 470– 482.
  • Cengiz N, Kabadayioglu H, Sanyal R. Orthogonally Functionalizable Copolymers Based on a Novel Reactive Carbonate Monomer. J Polym Sci Part A Polym Chem 2010;48:4737–4746.
  • Safakas K, Saravanou SF, Iatridi Z, Tsitsilianis C. Thermo-Responsive Injectable Hydrogels Formed by Self-Assembly of Alginate-Based Heterograft Copolymers. Gels 2023; 9(3):236.
  • Cai L, Dewi RE, Heilshorn SC. Injectable Hydrogels with in Situ Double Network Formation Enhance Retention of Transplanted Stem Cells. Adv Funct Mater 2015; 25(9):1344-1351.
  • Huang Y, Jayathilaka PB, Islam MS, Tanaka CB, Silberstein MN, Kilian KA, Kruzic JJ. Structural Aspects Controlling the Mechanical and Biological Properties of Tough, Double Network Hydrogels. Acta Biomater 2022; 138: 301–312.
  • Gong JP, Katsuyama Y, Kurokawa T, Osada Y. Double-Network Hydrogels with Extremely High Mechanical Strength. Adv Mater 2003; 15: 1155–1158.
  • Yasuda K, Gong JP, Katsuyama Y, Nakayama A, Tanabe Y, Kondo E, Ueno M, Osada Y. Biomechanical Properties of High-Toughness Double Network Hydrogels. Biomaterials 2005;26:4468– 4475.
  • Chen Q, Chen H, Zhu L, Zheng J. Fundamentals of Double Network Hydrogels. J Mater Chem B 2015;3:3654–3676.
  • Zhao J, Zhao X, Guo B. Multifunctional Interpenetrating Polymer Network Hydrogels Based on Methacrylated Alginate for the Delivery of Small Molecule Drugs and Sustained Release of Protein. Biomacromolecules 2014; 15(9): 3246–3252.
  • Polaske NW, McGrath DV, McElhanon JR. Thermally Reversible Dendronized Linear Ab StepPolymers via “Click” Chemistry. Macromolecules 2011;44:3203–3210.
  • Xu X, Jerca VV, Hoogenboom R. Bioinspired Double Network Hydrogels: From Covalent Double Network Hydrogels: Via Hybrid Double Network Hydrogels to Physical Double Network Hydrogels. Mater Horizons 2021;8:1173–1188.
  • Lee KY, Mooney DJ. Alginate: Properties and Biomedical Applications. Prog Polym Sci 2012;37:106–126.
  • Ma ZP, Song X, Yang BZ, Liu ST, Zheng RY, Xu XZ, Liu CH, Zhu YY. Fabrication of PEG-Anthracene/Alginate Double-Network Hydrogels and Their Application in Photolithography. J Appl Polym Sci 2023;140(48): 1–11.
  • BrackW, Altenburger R, Küster E, Meissner B, Wenzel KD, Schüürmann G. Identification of Toxic Products of Anthracene Photomodification in Simulated Sunlight. Environ. Toxicol Chem 2003; 22:2228–2237.
  • Hong S, Sycks D, Chan HF, Lin S, Lopez GP, Guilak F, Leong KW, Zhao X. 3D Printing: 3D Printing of Highly Stretchable and Tough Hydrogels into Complex, Cellularized Structures. Adv Mater 2015; 27:4034-4034.
  • Savić-Gajić IM, Savić IM, Svirčev Z. Preparation and Characterization of Alginate Hydrogels with High Water-Retaining Capacity. Polymers (Basel) 2023;15(12): 2592.
  • Wilems TS, Lu X, Kurosu YE, Khan Z, Lim HJ, Smith Callahan LA. Effects of Free Radical Initiators on Polyethylene Glycol Dimethacrylate Hydrogel Properties and Biocompatibility. J Biomed Mater Res - Part A 2017;105:3059–3068.
  • Tucker RM, Parcher BW, Jones EF, Desai TA. Single-Injection HPLC Method for Rapid Analysis of a Combination Drug Delivery System. AAPS PharmSciTech 2012; 13(2): 605–610.
There are 29 citations in total.

Details

Primary Language English
Subjects Biomaterial
Journal Section TJST
Authors

Ozgul Gok 0000-0001-5960-2397

Publication Date March 28, 2024
Submission Date December 26, 2023
Acceptance Date March 26, 2024
Published in Issue Year 2024 Volume: 19 Issue: 1

Cite

APA Gok, O. (2024). Physicochemical Effects of PEG Content in Alginate-based Double Network Hydrogels as Hybrid Scaffolds. Turkish Journal of Science and Technology, 19(1), 249-256. https://doi.org/10.55525/tjst.1410187
AMA Gok O. Physicochemical Effects of PEG Content in Alginate-based Double Network Hydrogels as Hybrid Scaffolds. TJST. March 2024;19(1):249-256. doi:10.55525/tjst.1410187
Chicago Gok, Ozgul. “Physicochemical Effects of PEG Content in Alginate-Based Double Network Hydrogels As Hybrid Scaffolds”. Turkish Journal of Science and Technology 19, no. 1 (March 2024): 249-56. https://doi.org/10.55525/tjst.1410187.
EndNote Gok O (March 1, 2024) Physicochemical Effects of PEG Content in Alginate-based Double Network Hydrogels as Hybrid Scaffolds. Turkish Journal of Science and Technology 19 1 249–256.
IEEE O. Gok, “Physicochemical Effects of PEG Content in Alginate-based Double Network Hydrogels as Hybrid Scaffolds”, TJST, vol. 19, no. 1, pp. 249–256, 2024, doi: 10.55525/tjst.1410187.
ISNAD Gok, Ozgul. “Physicochemical Effects of PEG Content in Alginate-Based Double Network Hydrogels As Hybrid Scaffolds”. Turkish Journal of Science and Technology 19/1 (March 2024), 249-256. https://doi.org/10.55525/tjst.1410187.
JAMA Gok O. Physicochemical Effects of PEG Content in Alginate-based Double Network Hydrogels as Hybrid Scaffolds. TJST. 2024;19:249–256.
MLA Gok, Ozgul. “Physicochemical Effects of PEG Content in Alginate-Based Double Network Hydrogels As Hybrid Scaffolds”. Turkish Journal of Science and Technology, vol. 19, no. 1, 2024, pp. 249-56, doi:10.55525/tjst.1410187.
Vancouver Gok O. Physicochemical Effects of PEG Content in Alginate-based Double Network Hydrogels as Hybrid Scaffolds. TJST. 2024;19(1):249-56.