Self‐Assembly of Polyaniline—From Nanotubes to Hollow Microspheres

Zhang, L.; Wan, Meixiang

doi:10.1002/adfm.200304458

Cited by 410 publications

(278 citation statements)

References 46 publications

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“…This technique has been referred to as a ''template-free'' or ''self-assembly'' approach because the synthesis does not entail the use of an insoluble hard-template. [63][64][65][66][67][68][69][70][71] As noted previously, we classify this approach in this particular section based on the author's own proposed mechanism, which involves the self-assembly of dopant molecules (molecules that are not inherent to the polymer chain) in order to produce anisotropic conducting polymer nanostructures. The unique aspect of this approach, compared to other soft-template techniques, is that the functional dopant does not necessarily need to be removed from the polymer.…”

Section: Soft Templates -Templating Against External Self-assembled Mmentioning

confidence: 99%

One‐Dimensional Conducting Polymer Nanostructures: Bulk Synthesis and Applications

2009

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This Progress Report provides a brief overview of current research activities in the field of one‐dimensional (1D) conducting polymer nanostructures. The synthesis, properties, and applications of these materials are outlined with a strong emphasis on recent literature examples. Chemical methods that can produce 1D nanostructures in bulk quantities are discussed in the context of two different strategies: 1) procedures that rely on a nanoscale template or additive not inherent to the polymer and 2) those that do not. The different sub‐classifications of these two strategies are delineated and the virtues and vices of each area are discussed. Following this discussion is an outline of the properties and applications of 1D conducting polymer nanostructures. This section focuses on applications in which nanostructured conducting polymers are clearly advantageous over their conventional counterparts. We conclude with our perspective on the main challenges and future research directions for this new class of nanomaterials. This Progress Report is not intended as a comprehensive review of the field, but rather a summary of select contributions that we feel will provide the reader with a strong basis for further investigation into this fast emerging field.

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Section: Soft Templates -Templating Against External Self-assembled Mmentioning

confidence: 99%

One‐Dimensional Conducting Polymer Nanostructures: Bulk Synthesis and Applications

2009

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“…Studies involving PANi have been extensively centered around the seeding of cells on pre-fabricated PANi films, as synthesis of 2D thin films can be processed quite easily with current manufacturing methods such as inkjet printing, casting, self-assembly, and electrospinning. [21][22][23][24][25] The use of PANi in engineering cell-laden three-dimensional biomimetic constructs has been limited due to its difficult and non-biocompatible processing steps and its insolubility in common solvents. [17,[26][27][28] Previously, we have reported that PANi can be integrated with synthetic PEGDA and naturally derived gelatin methacrylate (GelMA) hydrogels in situ in order to develop 3D conductive-hydrogels that are sufficiently biocompatible with seeded cells.…”

Section: Introductionmentioning

confidence: 99%

Conductive gelatin methacrylate-poly(aniline) hydrogel for cell encapsulation

Sawyer

Dong

Venn

et al. 2017

Biomed. Phys. Eng. Express

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New conductive hydrogels with superior biocompatibility continue to be developed in order to serve as bioactive scaffolds capable of modulating cellular functionality for tissue engineering applications. We developed an electrically conductive gelatin methacrylate-poly(aniline) (GelMA-PANi) hydrogel that is permissive of matrix mineralization by encapsulated osteoblast-like cells. Incorporation of PANi clusters within the GelMA matrix increases the electro-conductivity of the composite gel, while maintaining the osteoid-like soft mechanical properties that allows three-dimensional encapsulation of living cells. Viability of human osteogenic cells encapsulated within GelMA-PANi hydrogels was similar to that of GelMA. Cells within GelMA-PANi also demonstrated the capability of depositing mineral within the hydrogel matrix after being chemically induced for two weeks, although the total mineral content was lower as compared to GelMA. Additionally, we demonstrated that the GelMA-PANi-composite hydrogel could be printed in complex, user-defined geometries using digital projection stereolithography.

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“…Zeolite, 5 porous alumina, 11 and polymer fibers 12 have been used as hard templates to synthesize PANI nanotubes and nanofibers. Organized molecular assemblies of micelles, [13][14][15][16][17][18] inverse micelles, [19][20][21] and lamellar liquid crystals 22,23 have been applied as soft templates to obtain various morphologies of PANI, such as nanotubes, nanorods, nanofibers, and hollow microspheres. Wan and Li 24 also proposed a template-free method for fabricating microtubes of PANI in the presence of b-naphthalene sulfonic acid as a dopant.…”

Section: Introductionmentioning

confidence: 99%

Synthesis of rectangular tubes of polyaniline/NiO composites

Han

Gao

Guo

2006

J. Polym. Sci. A Polym. Chem.

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Polyaniline nanorods and nanotubes can be synthesized in the presence of sodium dodecylbenzenesulfonate as a micellar template and dopant, whereas polyaniline/NiO composite rectangular tubes can be obtained through a self‐assembly process with the addition of NiO nanoparticles. With an increasing number of NiO nanoparticles, the size of polyaniline/NiO composite rectangular tubes changes from a nanometer to a micrometer, and the conductivity and thermal stability also increase. The coordination bond between NiO and polyaniline is the key factor in the formation of the right angle of polyaniline/NiO composite rectangular tubes.

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Self‐Assembly of Polyaniline—From Nanotubes to Hollow Microspheres

Cited by 410 publications

References 46 publications

One‐Dimensional Conducting Polymer Nanostructures: Bulk Synthesis and Applications

One‐Dimensional Conducting Polymer Nanostructures: Bulk Synthesis and Applications

Conductive gelatin methacrylate-poly(aniline) hydrogel for cell encapsulation

Synthesis of rectangular tubes of polyaniline/NiO composites

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