Mussel-inspired hydrogels as tough, self-adhesive and conductive bioelectronics: a review.
Qin YuZirong ZhengXinhao DongRui CaoShuheng ZhangXiaolin WuXinya ZhangPublished in: Soft matter (2021)
To overcome the wearable sensor's defects and achieve the goal of robust mechanical properties, long-term adhesion, sensitive electrical conductivity, the multifunctional hydrogels were inspired by various mussels on the base of catechol and its analogues. In this review, we review the strategies for improving the mechanical strength, adhesion, conductivity and antibacterial properties of mussel-inspired hydrogels as bioelectronics. Double network structures, nanocomposites, supramolecular block polymers and other strategies were utilized for achieving tough hydrogels to prevent tensile fractures under high deformation. Many mussel-inspired chemistries were incorporated for constructing skin-attachable hydrogel strain sensors and some strategies for controlling the oxidation of catechol were employed to achieve long-term adhesion. In addition, electrolytes, conductive fillers, conductive polymers and their relevant hydrophilic modifications were introduced for fabricating the conductive hydrogel bioelectronics to enhance the conductivity properties. Finally, the challenges and outlooks in this promising field are featured from the perspective of materials chemistry.
Keyphrases
- tissue engineering
- hyaluronic acid
- drug delivery
- wound healing
- reduced graphene oxide
- biofilm formation
- drug release
- cancer therapy
- extracellular matrix
- cell adhesion
- liquid chromatography
- molecular docking
- ionic liquid
- staphylococcus aureus
- pseudomonas aeruginosa
- nitric oxide
- candida albicans
- quantum dots
- carbon nanotubes