“…In particular, GO has different oxygen-rich functional groups, such as carboxyl, hydroxyl, carbonyl, and epoxy groups, which are easily soluble in water and have electronegativity, so GO is easily adsorbed to the positively charged amino group of silk and reduced to RGO in acidic aqueous solution. , As a conductive polymer with good prospects, PANI has advantages of easy synthesis, good conductivity, and stable performance, , but its poor solubility, biodegradability, and processability also limit its use in the biological field. , Because of the good film-forming properties of PANI, in situ polymerization of aniline (ANI) on fabric surfaces is commonly used to prepare PANI conductive textiles. , This method can not only give fabrics good electrical conductivity but also overcome the shortcomings of PANI, such as brittleness, to obtain good mechanical properties . In addition, because ANI is a good electron donor while GO is a good electron acceptor, a weak charge formed by an ANI monomer and GO structure on a surface will result in electrostatic attraction; therefore, GO can be used as a chemical dopant for PANI. , In recent years, electrostatic assembly of GO/PANI on fabrics surface has become a new research topic, mainly for its use as an electrode material for capacitors and smart wearable textiles. Here, we will explore its potential application in peripheral nerve regeneration.…”