There is tremendous current interest in using nanoparticles to deliver biomolecules and macromolecules (e.g., drugs and DNA) to specific sites in living systems. Release of the biomedical payload from the nanoparticle can be accomplished by chemical or enzymatic degradation of the nanoparticle or of the link between the payload and the nanoparticle. We are exploring an alternative payload-release strategy that builds on our work on template-synthesized nano test tubes. These are hollow nanotubes that are closed on one end and open on the other, and the dimensions can be controlled at will. If these nano test tubes could be filled with a payload and then the open end corked with a chemically labile cap, they might function as a universal delivery vehicle. We show here that silica nano test tubes can be covalently corked by chemical self-assembly of nanoparticles to the tubes. We also show that the nanoparticle corks remain attached to the mouths of the nano test tubes after liberation from the alumina template. For this proof-of-principle study, we used simple imine linkages to attach the corks to the test tubes. Schiff's bases are thermodynamically unstable in the presence of water; however, the multiple points of contact between the nano test tubes and nanoparticles allow the assembled structure to be metastable under our experimental conditions. Other chemical linkages-either more or less stable-may be more appropriate for other applications, and these are currently under development.
In this review we consider recent results from our group that are directed towards developing "smart" synthetic nanopores that can mimic the functions of biological nanopores (transmembrane proteins). We first discuss the preparation and characterization of conical nanopores synthesized using the track-etch process. We then consider the design and function of conical nanopores that can rectify the ionic current that flows through these pores under an applied transmembrane potential. Finally, two types of sensors that we have developed with these conical nanopores are described. The first sensor makes use of molecular recognition elements that are bound to the nanopore mouth to selectively block the nanopore tip, thus detecting the presence of the analyte. The second sensor makes use of conical nanopores in a resistive-pulse type experiment, detecting the analyte via transient blockages in ionic current.
This review details the advances made in alumina template-synthesized nanotubes and nano test tubes as delivery vehicles for biomedical applications. Most current research has focused on spherical nanoparticles because they are easier to make; however, cylindrical particles or nanotubes offer many advantages over spherical particles. One advantage is that the template is tunable, which means the pore diameter and template thickness can be controlled, resulting in larger payload capacities for nanotubes. Another advantage is that template synthesized nanotubes can be differentially functionalized on their inner and outer surfaces. Inner and outer surface nanotube modification for use in drug extraction, antibody-antigen interactions and magnetization is discussed. Recent advances made in covalent capping ('corking') nanotubes to prevent premature payload leakage are also covered. Although many applications for nanotubes have already been discovered, many new and exciting paths await exploration.
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