Browsing by Subject "nanotube"
Now showing 1 - 2 of 2
- Results Per Page
- Sort Options
Item Open Access Generation of phospholipid vesicle-nanotube networks and transport of molecules therein(2011) Jesorka, A.; Stepanyants, N.; Zhang H.; Ortmen, B.; Hakonen, B.; Orwar O.We describe micromanipulation and microinjection procedures for the fabrication of soft-matter networks consisting of lipid bilayer nanotubes and surface-immobilized vesicles. These biomimetic membrane systems feature unique structural flexibility and expandability and, unlike solid-state microfluidic and nanofluidic devices prepared by top-down fabrication, they allow network designs with dynamic control over individual containers and interconnecting conduits. The fabrication is founded on self-assembly of phospholipid molecules, followed by micromanipulation operations, such as membrane electroporation and microinjection, to effect shape transformations of the membrane and create a series of interconnected compartments. Size and geometry of the network can be chosen according to its desired function. Membrane composition is controlled mainly during the self-assembly step, whereas the interior contents of individual containers is defined through a sequence of microneedle injections. Networks cannot be fabricated with other currently available methods of giant unilamellar vesicle preparation (large unilamellar vesicle fusion or electroformation). Described in detail are also three transport modes, which are suitable for moving water-soluble or membrane-bound small molecules, polymers, DNA, proteins and nanoparticles within the networks. The fabrication protocol requires ∼90 min, provided all necessary preparations are made in advance. The transport studies require an additional 60-120 min, depending on the transport regime. © 2011 Nature America, Inc. All rights reserved.Item Open Access Supramolecular chiral self-assembled peptide nanostructures(2016-01) Hatip, MeryemSelf-assembly process is an easy and convenient bottom-up technique for designing novel functional materials. Self-assembled peptide amphiphile (PA) molecules are remarkable building blocks for a wide-range of applications due to their easy synthesis, biocompatibility, biodegradabability and dynamic nature in aqueous conditions. Controlling self-assembly behavior still remains complex, since it can be affected by multiple factors. Chirality is an important parameter for designing and controlling self-assembled supramolecular nanomaterials. In this thesis, self-assembly mechanism of chiral peptide molecules was studied with different driving forces in order to develop new methodsfor producing self-assembled nanomaterials. In addition to self-assembly mechanism, different morphologies and chiral behaviors of the self-assembled supramolecular chiral peptide amphiphile nanostructureswere monitored with variouscharacterization methods. pH is a significant contributor for the self-assembly process and this effect was studied in detail to elucidate pH dependency of supramolecular conformation. According to morphological characterizations, histidine containing PA molecules form nanosheet like structures under acidic pH.At the isoelectric point of imidazole, they have a tendency to form twisted fiber or ribbon structures. Athigh pH iv conditions, pH 10, they form nanotubes due to the neutralization of imidazole groups and π-π interactionsat theside chain of histidine moiety.When another aromatic ring is included in the sequence, in this case phenylalanine residue, different nanostructures were observed. In addition to histidine PA, lysine and glutamic acid containing peptide building blocks were also studied to understand the effect of electrostatic interactions. Phenylalanine containing PAs and valine containing PAs were compared in terms of their chiral self-assembly behaviors. As a result of self-assembly of the positively charged and negatively charged peptides, well defined nanostructures were obtained. While valine containing PA molecules form straight nanofibers, phenyl alanine containing PAs form well ordered rigid twisted fibers and twisted ribbon structures.