Wearable devices
are now recognized as a powerful tool to collect
physiological and environmental information in a smart, noninvasive,
and real-time manner. Despite the rapid progress of wearable devices
especially wearable electronic devices, there are still several challenges
that limit their further development, for example, a complicated electrical
signal acquisition and processing process to eliminate the interference
from the surrounding signals, bulky power supply, inevitable e-waste,
and environmental pollution. Herein, we report a 3D-printed recyclable,
flexible, and wearable device for visualized UV, temperature, and
sweat pH sensing. Compared with wearable electronic devices, our visualized
wearable device senses environmental (UV light, ambient temperature),
biophysical (skin temperature), and biochemical (sweat pH) signals
via stimuli-responsive color change, which does not require complicated
electronic circuit design/assembly, time-consuming data processing
and additional power source. In addition, this visualized wearable
device is fabricated via a 3D support bath printing technology by
printing UV-, temperature-, and sweat pH-sensing inks containing photochromic,
thermochromic, and pH-chromic materials, respectively, into/onto sustainable
starch solution, resulting in a multi-functional, recyclable, and
flexible sensing device with high reproducibility. Our results reveal
that UV light intensities under sunlight (0–2500 μW/cm
2
), ambient, and skin temperatures (0–38 °C) as
well as sweat pH (4.0–7.0) can be successfully monitored.
