Helical Rosette Nanotubes with Tunable Stability and Hierarchy

Journal of the American Chemical Society2005Vol. 127(23), pp. 8307–8309

Citations Over TimeTop 10% of 2005 papers

Jesus G. Moralez, Jose Raez, Takeshi Yamazaki, Radha Kishan Motkuri, Andriy Kovalenko, Hicham Fenniri

Abstract

The design of nanostructured materials with tunable dimensions and properties that maintain their structural integrity under physiological conditions is a major challenge in biomedical engineering and nanomedicine. Helical rosette nanotubes (HRN) are a new class of materials produced through a hierarchical self-assembly process of low molecular weight synthetic organic modules in water. Here, we describe a synthetic strategy to tune their stability and hierarchy by preorganization of the self-assembling units, control of net charge per unit of nanotube surface area, amphiphilicity, and number of H-bonds per self-assembling module, and through peripheral steric (de)compression. Using these criteria, HRNs with tunable stability and hierarchical architecture were produced from self-assembling modules that (a) persist as individual molecules in solution, (b) self-assemble into HRN but denature at high temperature (95 degrees C), and (d) self-assemble into well-dispersed short nanotubes, long nanotubes, ribbons, or superhelices. Given the biocompatibility, synthetic accessibility, and chemical and physical tunability of these materials, numerous applications in biomedical engineering, materials science, and nanoscience and technology are envisioned.

Citations Over TimeTop 10% of 2005 papers

Abstract

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