AI Article Synopsis
- Researchers developed a multifunctional hydrogel using resilin (a natural rubber-like protein), which combines stretchability, adhesiveness, and electroconductivity for diverse uses.
- They engineered resilin-like proteins to adjust the mechanical properties, added glycerol for adhesion, and created a graphene-RLP conjugate for enhanced network strength.
- The resulting hybrid hydrogel is highly stretchy (up to four times its original length), adheres strongly to surfaces, and can monitor human activities, making it a promising candidate for wearable sensors and innovative material applications.
Article Abstract
Integrating multifunctionality such as stretchability, adhesiveness, and electroconductivity on a single protein hydrogel is highly desirable for various applications, and remains a challenge. Here we present the development of such multifunctional hydrogels based on resilin, a natural rubber-like material with remarkable extensibility and resilience. First, genetically engineered reslin-like proteins (RLPs) with varying molecular weight were biosynthesized to tune mechanical strength and stiffness of the cross-linked RLP hydrogels. Second, glycerol was incorporated into the hydrogels to endow adhesive properties. Next, a graphene-RLP conjugate was synthesized for cross-linking with the unmodified, pristine RLP to form an integrated network. The obtained hybrid hydrogel could be stretched to over four times of its original length, and self-adhered to diverse substrate surfaces due to its high adhesion strength of ∼24 kPa. Furthermore, the hybrid hydrogel showed high sensitivity, with a gauge factor of 3.4 at 200% strain, and was capable of real-time monitoring human activities such as finger bending, swallowing, and phonating. Due to these favorable attributes, the graphene/resilin hybrid hydrogel was a promising material for use in wearable sensors. In addition, the above material design and functionalization strategy may provide intriguing opportunities to generate innovative materials for broad applications.
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| http://dx.doi.org/10.1021/acs.biomac.9b00389 | DOI Listing |
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