End-block length dependence of the hydrogel relaxation dynamics was investigated using PEO-based ABA triblock copolymer solutions in an aqueous solvent. Both ends of PEO were capped with hydrophobic poly(isopropyl glycidyl ether-co-ethyl glycidyl ether) exhibiting a lower critical solution temperature (LCST) behavior, resulting in the transition between sol and gel with temperature. Despite the nearly identical hydrophobicity of the end-blocks, the sol-to-gel transition temperature is found to be significantly dependent on the end-block length. Particularly, a small increment of the end-block length leads to significantly slower relaxation dynamics which is attributed to the thermodynamic barrier of end-block extraction. Hydrogels with an appropriate relaxation time show excellent injectability and self-healing ability, yet extremely slow relaxation dynamics result in brittle hydrogels. These results are discussed in terms of current understanding of the hydrogel relaxation dynamics and particular attention is paid to the issue of the chain dynamics between aggregated cores.

1 Lauber, L., "pH-and thermoresponsive selfassembly of cationic triblock copolymers with controlled dynamics" 50 : 416-423, 2017

2 Tanaka, F., "Viscoelastic properties of physically crosslinked networks. 1. Transient network theory" 25 : 1516-1523, 1992

3 Fellin, C. R., "Tunable temperature-and shear-responsive hydrogels based on poly(alkyl glycidyl ether)s" 68 : 1238-1246, 2019

4 Tsitsilianis, C., "Thermoresponsive hydrogels based on telechelic polyelectrolytes : From dynamic to"Frozen"networks" 51 : 2169-2179, 2018

5 Angelopoulos, S. A., "Thermo-reversible hydrogels based on poly(N,N-diethylacrylamide)-blockpoly(acrylic acid)-block-poly(N,N-diethylacrylamide) double hydrophilic triblock copolymer" 207 : 2188-2194, 2006

6 Annable, T., "The rheology of solutions of associating polymers : comparison of experimental behavior with transient network theory" 37 : 695-726, 1993

7 Zinn, T., "Telechelic polymer hydrogels : Relation between the microscopic dynamics and macroscopic viscoelastic response" 5 : 1353-1356, 2016

8 Murakami, T., "Synthesis of PEO-based physical gels with tunable viscoelastic properties" 56 : 1033-1038, 2018

9 Kadam, V. S., "Synthesis and self-assembling properties of α, ω-hydroxy-poly(ethylene oxide)end-capped with 1-isocyanato-3-pentadecylcyclohexane" 49 : 4635-4646, 2008

10 Kim, J., "Structure and relaxation dynamics for complex coacervate hydrogels formed by ABA triblock copolymers" 53 : 9234-9243, 2020

11 Lettow, J. S., "Small-angle neutron scattering and theoretical investigation of poly(ethylene oxide)-poly(propylene oxide)-poly(ethylene oxide)stabilized oil-in-water microemulsions" 21 : 5738-5746, 2005

12 Seitz, M. E., "Self-assembly and stress relaxation in acrylic triblock copolymer gels" 40 : 1218-1226, 2007

13 Dyakonova, M. A., "Salt-induced changes in triblock polyampholyte hydrogels : Computer simulations and rheological, structural, and dynamic characterization" 48 : 8177-8189, 2015

14 Ye, Y. N., "Relaxation dynamics and underlying mechanism of a thermally reversible gel from symmetric triblock copolymer" 52 : 8651-8661, 2019

15 Jung, H., "Regulating dynamics of polyether-based triblock copolymer hydrogels by end-block hydrophobicity" 53 : 10339-10348, 2020

16 Ogura, M., "Preparation and solution behavior of a thermoresponsive diblock copolymer of poly(ethyl glycidyl ether)and poly(ethylene oxide)" 23 : 9429-9434, 2007

17 Onoda, M., "Precisely tunable sol–gel transition temperature by blending thermoresponsive ABC triblock terpolymers" 7 : 950-955, 2018

18 Aoki, S., "Novel thermosensitive polyethers prepared by anionic ringopening polymerization of glycidyl ether derivatives" 31 : 1128-1129, 2002

19 Choi, S., "Molecular exchange in ordered diblock copolymer micelles" 44 : 3594-3604, 2011

20 Choi, S., "Mechanism of molecular exchange in diblock copolymer micelles : Hypersensitivity to core chain length" 104 : 047802-, 2010

21 Yu, L., "Injectable hydrogels as unique biomedical materials" 37 : 1473-1481, 2008

22 Huynh, C. T., "Injectable block copolymer hydrogels : Achievements and future challenges for biomedical applications" 44 : 6629-6636, 2011

23 Peppas, N., "Hydrogels in biology and medicine : From molecular principles to bionanotechnology" 18 : 1345-1360, 2006

24 Winter, H. H., "Glass transition as the rheological inverse of gelation" 46 : 2425-2432, 2013

25 Hong, Y., "Facile synthesis of poly(ethylene oxide)-based selfhealable dynamic triblock copolymer hydrogels" 21 : 4913-4922, 2020

26 Liu, C., "Evaluation of different methods for the determination of the plateau modulus and the entanglement molecular weight" 47 : 4461-4479, 2006

27 Krogstad, D. V., "Effects of polymer and salt concentration on the structure and properties of triblock copolymer coacervate hydrogels" 46 : 1512-1518, 2013

28 Zhang, M., "Dual-responsive hydrogels for directwrite 3D printing" 48 : 6482-6488, 2015

29 Isono, T., "Design and synthesis of thermoresponsive aliphatic polyethers with a tunable phase transition temperature" 8 : 5698-5707, 2017

30 Karis, D. G., "Cross-linkable multi-stimuli responsive hydrogel inks for direct-write 3D printing" 8 : 4199-4206, 2017

31 Charbonneau, C., "Controlling the dynamics of self-assembled triblock copolymer networks via the pH" 44 : 4487-4495, 2011

32 Nagarajan, R., "Comparison of solubilization of hydrocarbons in(PEO–PPO)diblock versus(PEO–PPO–PEO)triblock copolymer micelles" 184 : 489-499, 1996

33 Peters, A. J., "Comparison of gel relaxation times and end-block pullout times in ABA triblock copolymer networks" 49 : 7340-7349, 2016

34 Madsen, J., "Biocompatible wound dressings based on chemically degradable triblock copolymer hydrogels" 9 : 2265-2275, 2008

35 Inomata, K., "Association and physical gelation of ABA triblock copolymer in selective solvent" 44 : 5303-5310, 2003

36 Lu, J., "Addition of corona block homopolymer retards chain exchange in solutions of block copolymer micelles" 49 : 1405-1413, 2016