Influence of nickel hydroxide nanoparkets in self-assemble structure of fibroin microparticles

Abstract

Among the strategies for structuring nanomaterials, self-assembly presents advantages such as efficiency and specificity in the organization of nanometric structures. In this field, the use of peptides and proteins has been drawing attention due to its inherent capacity to organize complex systems, in a following sequence and specific way, which can thus be used in the creation of inorganic nanostructures in a mimetic way to biological systems. Nickel hydroxide is a material known for a long time because of its electrocatalytic properties, but new routes for the synthesis of nanostructures of the material have been developed, potentializing its properties. Among the possible applications, its ability to electrocatalytically oxidize small molecules can be exploited in the construction of sensors and biosensors. The main challenges in these applications are the low electrical conductivity and low selectivity of nickel hydroxide, so several authors have investigated how the combination of nickel hydroxide with other materials can overcome these challenges. Fibroin is a protein extracted from silk, which has excellent mechanical properties, secure processing, and biocompatibility. Its features are directly related to its hierarchical structures, especially the formation of ²-sheet crystallites. Studies have shown that its mechanical and electrical properties can be modulated according to the manipulation of these structures by the introduction of external materials acting as nucleating agents of the crystals. In this way, the present work aims to study the influence that the introduction of nanoparticles of nickel hydroxide can have on the formation of the hierarchical structures of fibroin, as well as to explore the synergy between these materials in the construction of biosensors. Initially, glucose biosensors will be tested because they have a well-known and relatively inexpensive construction. However, it is expected that once the architecture is defined, it can be extrapolated to other types of modified electrodes. (AU)