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Ultra-high molecular weight tanglemer hydrogels

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Rahaman, Md Saifur
Pollard, Brett Leslie
Connal, Luke A.

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Developing hydrogels that combine excellent mechanical strength with biocompatibility remains a challenge, particularly for designing materials for biomedical applications. We report the synthesis of ultra-high molecular weight poly(2-hydroxyethyl acrylate) hydrogels via xanthate-mediated photoiniferter reversible-deactivation radical polymerization. We systematically investigated the effects of changing the targeted degree of polymerization (500 to 50 000), crosslinker amount (0.001–2 mol%), and monomer concentration (0.5–5 M) on the mechanical properties and swelling behavior of the hydrogels. For our system, we found that the transition between crosslink-dominated gelation to entanglement-dominated gelation occurred at a degree of polymerization exceeding 5 000. The hydrogel prepared from a 5 M reaction mixture with 0.005 mol% crosslinker gave optimal mechanical properties, with a compressive strength approaching 1 MPa and toughness of 168.6 kJ m−3. These findings establish that minimal chemical crosslinking combined with dense polymer entanglements provides superior mechanical properties compared to conventional crosslinking strategies, offering design principles for next-generation tough hydrogels.

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Polymer Chemistry

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