Gestational
diabetes mellitus (GDM) is one of the most common metabolic
disorders during pregnancy, leading to serious complications for pregnant
women and a threat to life safety of infants. Therefore, it is particularly
important to establish a multipurpose monitoring pathway to important
physiological indicators of pregnant women. In this work, three kinds
of double network hydrogels are prepared with poly(vinyl alcohol)
(PVA), borax, and cellulose ethers with varying substituents of methyl
(methyl cellulose, MC), hydroxypropyl (hydroxypropyl cellulose, HPC),
or both (hydroxypropyl methyl cellulose, HPMC), respectively. The
corresponding toughness (143.9, 102.3, and 135.9 kJ cm–3) and conductivity (0.69, 0.45, and 0.51 S m–1)
of the hydrogels demonstrate that PB-MC was endowed with the prominent
performance. Molecular dynamics simulations further revealed the essence
that hydrogen bond interactions between PVA and cellulose ethers play
a critical role in regulating the structure and properties of hydrogels.
Thermochromic capsule powders (TCPs) were subsequently doped in to
achieve a composite hydrogel (TCPs@PB-MC) to indicate the change in
human body temperature. Furthermore, the process of the TCPs@PB-MC
response to glucose, pH, and temperature was tracked in-depth through
the electrochemical window. This work provides a novel strategy for
all-in-one health management of GDM.