Fluorescent nanocarbons are well-proficient nanomaterials
because
of their optical properties and surface engineering. Herein, Apium graveolens-derived carbon dots (ACDs) have
been synthesized by a one-step hydrothermal process without using
any surplus vigorous chemicals or ligands. ACDs were captured via
an in situ gelation reaction to form a semi-interpenetrating polymer
network system showing mechanical robustness, fluorescent behavior,
and natural adhesivity. ACDs-reinforced hydrogels were tested against
robust uniaxial stress, repeated mechanical stretching, thixotropy,
low creep, and fast strain recovery, confirming their elastomeric
sustainability. Moreover, the room-temperature self-healing behavior
was observed for the ACDs-reinforced hydrogels, with a healing efficacy
of more than 45%. Water imbibition through hydrogel surfaces was digitally
monitored via “breathing” and “accelerated breathing”
behaviors. The phytomedicine release from the hydrogels was tuned
by the ACDs’ microstructure regulatory activity, resulting
in better control of the diffusion rate compared to conventional chemical
hydrogels. Finally, the phytomedicine-loaded hydrogels were found
to be excellent bactericidal materials eradicating more than 85% of
Gram-positive and -negative bacteria. The delayed network rupturing,
superstretchability, fluorescent self-healing, controlled release,
and antibacterial behavior could make this material an excellent alternative
to soft biomaterials and soft robotics.