In situ development of self-healing, injectable, glucose- and pH-responsive electroconductive composite hydrogels

Ali A, Govindharaj M, et al.

Advanced Composites and Hybrid Materials

Khalifa University

RESEARCH SUMMARY

This study presents an in situ gelation strategy for creating multifunctional PEGDA-based composite hydrogels that combine self-healing, injectability, electrical conductivity, and glucose- and pH-responsive behavior. The hydrogel network is formed through borax-catalyzed thiol–acrylate Michael addition and dynamic boronate ester crosslinking, enabling reversible bonding and stimulus responsiveness. Conductive fillers including gold nanoparticles, PEDOT:PSS, and MXene were incorporated during gelation to create electroactive hydrogel systems with enhanced stretchability, adhesiveness, and conductivity. Mechanical characterization demonstrated that the hydrogels could sustain large tensile deformations while maintaining structural integrity and recovering mechanical performance after self-healing. In vitro studies further showed glucose- and pH-triggered drug release, antibacterial activity, and enhanced wound closure, highlighting the potential of these materials for smart wound dressings and wearable biomedical devices.

Uniaxial tensile testing of hydrogel specimens was performed using a CellScale UniVert mechanical testing system equipped with a 5 N load limit. Nearly rectangular hydrogel samples were secured in clamp holders with protective duct tape to prevent gripping damage and stretched to failure while recording stress–strain curves. This setup enabled accurate low-force mechanical characterization of the soft, self-healing hydrogel formulations, providing quantitative measures of tensile strength, elongation at break, and mechanical robustness relevant to injectable and wearable biomedical applications.

AUTHORS

Akbar Ali; Mano Govindharaj; Bushara Fatma; Khulood H. Alshehhi; Deema Islayem; Nazmi B. Alsaafeen; Anna Maria Pappa; Charalampos Pitsalidis.

PUBLICATION DETAILS

JOURNAL

Advanced Composites and Hybrid Materials

YEAR

2025

INSTITUTIONS

Khalifa University

COUNTRIES

United Arab Emirates

INSTRUMENT USED

UniVert

TESTING METHODS

Tensile Testing

RESEARCH APPLICATIONS

Drug Screening & Drug Delivery MechanicsHydrogel Mechanical TestingInjectable & Regenerative BiomaterialsSkin and Wound Healing BiomechanicsStimuli Responsive Hydrogels CharacterizationWearable Bioelectronics

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