Efficient Use of Bio-Inspired Nanofabrication in Soft Electronics

Abstract

Self-assembly plays an important role in the formation of different nanostructures either organic or inorganic. Controlled assembly of molecules into higher ordered hierarchical structures on the other hand require a thorough insight into the interactive forces that lie behind such an assembly. The interface between organic and inorganic materials is thus of primary significance when it comes to the tasks of selective deposition and assembly of inorganic molecules through organic agents. One of the bacterial species that belong to the class α-proteobacteria called Magnetospirillum magneticum (classified as AMB-1) is investigated in this study and it is found that this species is able to fulfill the requirements that are imposed by the complexity of the selective deposition and controlled assembly tasks. AMB-1 contain single-domain crystals of magnetite (Fe3O4) called magnetosomes that sense the external magnetic field that is further utilized for cellular displacement (magnetotaxis) through lash-like cellular appendages called flagella. The two flagella located at the proximal and distal ends of the cell consists of a protein monomer flagellin. Individual flagellin in turn that are located on the periphery of each of the flagellum's central channel consists of four sub-domains, two inner domains (D0, D1) made up of alpha helices and two outer domains (D2, D3) made up of beta sheets. However, it is the domain D3 that is exposed to the surrounding micro-environment, thereby interacting with the components to be selectively deposited, in this case, carbon nanotubes (CNT). Based on the electromagnetic and molecular dynamics simulations and the real-time experimental analysis involving optical microscopy utilizing 50 micron diameter conductor (44AWG) magnetic coils as directional magnetic field generation centers to visualize the motion of free as well as loaded AMB-1 as well as electron microscopy (TEM & SEM) to analyze the interactive forces between CNT and AMB-1 flagellum, it is found that once the domain D3 is functionalized with either metallic (m-) or semiconducting (s-) carbon nanotubes (CNT), the AMB-1 cell can be used as an efficient carrier for selective deposition tasks. Two aspects that are of particular interest are the phenomenal control of direction exhibited by AMB-1 using locally generated magnetic field and the efficient interactive forces in the form of short range forces (van der Waals, hydrophobic interactions and hydrogen bonds) and long range forces (electrostatic interactions) between m-CNT or s-CNT and D3. Thus, it is recognized that a compound semiconductor manufacturing technology involving bacterial carriers and carbon-based materials such as carbon nanotubes would be a desirable choice in the future.