Bacterial cellulose (BC) has interesting properties including high crystallinity, tensile strength, degree of polymerisation, water holding capacity (98%) and an overall attractive 3D nanofibrillar structure. The mechanical and electrochemical properties can be tailored upon incomplete BC dehydration. Under different water contents (100, 80 and 50%), the rheology and electrochemistry of BC were evaluated, showing a progressive stiffening and increasing resistance with lower capacitance after partial dehydration. BC water loss was mathematically modelled for predicting its water content and for understanding the structural changes of post-dried BC. The dehydration of the samples was determined via water evaporation at 37 °C for different diameters and thicknesses. The gradual water evaporation observed was well-described by the model proposed (R
2 up to 0.99). The mathematical model for BC water loss may allow the optimisation of these properties for an intended application and may be extendable for other conditions and purposes.
Bacterial cellulose (BC) nanofibril network is modified with an electrically conductive polyvinylaniline/polyaniline (PVAN/PANI) bilayer for construction of potential electrochemical biosensors. This is accomplished through surface-initiated atom transfer radical polymerization of 4-vinylaniline, followed by in situ chemical oxidative polymerization of aniline. A uniform coverage of BC nanofiber with 1D supramolecular PANI nanostructures is confirmed by FTIR, XRD and CHN elemental analysis. Cyclic voltammograms evince the switching in the electrochemical behavior of 2 BC/PVAN/PANI nanocomposites from the redox peaks at 0.74 V, in the positive scan and at-0.70 V, in the reverse scan, (at 100 mV.s-1 scan rate). From these redox peaks, PANI is the emeraldine form with the maximal electrical performance recorded, showing charge-transfer resistance as low as 21 Ω and capacitance as high as 39 μF. The voltage-sensible nanocomposites can interact with neural stem cells (NSCs) isolated from subventricular zone (SVZ) of the brain, through stimulation and characterization of differentiated SVZ cells into specialized and mature neurons with long neurites measuring up to 115±24 μm length after 7 days of culture without visible signs of cytotoxic effects. The findings pave the path to the new effective nanobiosensor technologies for nerve regenerative medicine, which demands both electroactivity and biocompatibility.
Microbial
cellulose paper treated with polyaniline and carbon nanotubes
(PANI/CNTs) can be attractive as potential flexible capacitors in
terms of further improvements to the conductivity and thermal resistance.
The interactions between PANI and CNTs exhibit new electrochemical
features with increased electrical conductivity and enhanced capacity.
In this study, PANI/CNTs was incorporated into a flexible poly(4-vinylaniline)-grafted
bacterial cellulose (BC/PVAN) nanocomposite substrate for further
functionalization and processability. PANI/CNTs coatings with a nanorod-like
structure can promote an efficient ion diffusion and charge transfer,
with a significant enhancement of the electrical conductivity after
CNTs reinforcement of 1 order of magnitude up to (1.0 ± 0.3)
× 10–1 S·cm–1. An escalating
improvement of the double charge capacity (∼54 mF) of the grafted
BC nanocomposites was also detected through electrochemical analysis.
The multilayered electrical coatings also reinforce the thermal resistance,
preventing anticipated thermal degradation of the BC substrate. The
cell viability and differentiation assays using neural stem cells
(SVZ cells) testified to the cytocompatibility of the grafted BC nanocomposites,
while inducing neuronal differentiation over 7 days of culture with
a neurite that was 77 ± 24.7 μm long. This is promising
for meeting the requirements in the construction of high-performance
bioelectronic devices that can actively interface biologically, providing
a friendly environment for cells while tuning the device performance.
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