We introduce a simple concept of a light induced pH change, followed by high amplitude manipulation of the mechanical properties of an adjacent polymer film. Irradiation of a titania surface is known to cause water splitting, and this can be used to reduce the environmental pH to pH 4. The mechanical modulus of an adjacent pH sensitive polymer film can thus be changed by more than an order of magnitude. The changes can be localized, maintained for hours and repeated without material destruction.
Polyelectrolyte block copolymer micelles assembled thin film is switched in response to local photocatalytic reactions on titanium dioxide, resulting in a layer of variable height, stiffness in response to visible light irradiation. Preosteoblasts migrate toward stiffer side of the substrates.
The adhesion of cells to surfaces, as well as their proliferation, migration, and differentiation, is guided not only by chemical functionalization but also by surface nanostructuring, nanotopography. [1] Nano-patterned titanium surfaces are one example in which the scale of patterning controls the size of focal adhesions. [2] Nanoscale disorder in surface structure can be used to stimulate cell differentiation [3] or can also be used to maintain stem cell phenotypes over long times. [4] Nanoroughness modulates cells interactions and function via mechanosensing. [5] These all suggest that the careful control of surface nanostructure of such important as titanium (Ti) biomaterial [6] could be a useful tool to achieve desired cellular responses.We first time highlight that ultrasonic treatment is able to produce surface porous sponge layer in Ti. We find it great technological advances that Ti can be also modified with highintensity ultrasonic treatment. We really think that presenting high-intensity ultrasonic technique for Ti nanostructuring increases interest of scientists to the technique. Great advantage of our methodology is a large number of synthetic parameters which can be optimized to tune surface nanostructuring in a controllable manner. Moreover, this methodology will be very interesting in future to provide single-step hybrids and effective loading of porous structures with active chemicals. We compare our methodology with more known for bio-application anodization for surface nanostructuring.Anodization leads to TiO 2 nanotube arrays covering the surface of titanium and is one of the most studied methods to develop porous surface nanotopographies with controlled pore sizes. [6] It has been demonstrated in cell culture experiments on TiO 2 nanotube arrays of different sizes that adhesion, proliferation, and migration of mesenchymal stem cells are optimal on ordered nano-pore arrays with spacings in the range of 15-30 nm; these length scales also lead to significantly less apoptosis than on 100 nm structures. [7,8] It should be taken into account that nanostructuring does affect cell function at many levels but in a cell specific manner, and smaller surface features (50 nm) tend to favor cell proliferation in comparison to larger features (300 nm). [9] Anodization requires a conductive substrate, is difficult to use over large surface areas, and uses aggressive media for synthesis. [6] Recently, we have shown that ultrasonic treatments in aqueous media can produce surface porosities in various size-ranges also below 100 nm in metals such as Al or Mg. [10] Here, we demonstrate that such nanostructuring can also be effectively induced in an important biomaterial, titanium, by investigating its influence on cell behavior in comparison to the well-established electrochemical method.To this end, we investigate the response in terms of morphology, adhesion, proliferation, and differentiation of C2C12 cells on a glass substrate and on three different titanium/TiO 2 surfaces: a titania mesoporous sponge layer (...
In
the present work, transparent holographic poly(diallyldimethylammonium
chloride) (PDADMAC)/heparin and PDADMAC/poly(styrenesulfonate) (PSS)
films were synthesized via polyelectrolyte coacervates. PDADMAC/heparin
films were obtained without temperature treatment. Thin holographic
free-standing films with a 1 μm grating period and uniform surface
of a polyelectrolyte complex were readily and quickly made by pressing
polyelectrolyte coacervate, the hydrated viscoelastic fluid-like form
of polyelectrolyte complex precursor, between a flat surface and holographic
mask. Heparin replaces PSS in film composition to prepare the sheer
film. Thus, the PDADMAC/heparin holographic film demonstrates transparency
and reversible response for humidity under diffraction detection.
In addition to diffraction humidity signal measurements, the cobalt(II)
chloride was impregnated in polyelectrolyte coacervate to make an
additional colorimetric signal response. In this case, the free-standing
film serves both as the substrate for the hygroscopic salt and as
a diffraction humidity sensor. The PDADMAC/heparin/Co(II) chloride
film demonstrates a linear humidity range from 50 to 90%. Additionally,
due to hydrated inorganic salt ion size, cobalt chloride prevents
film porosity, which initiates under film swelling. Based on the results
and calculations obtained, the study proposes the mechanism of water
incorporation, including the reptation model and polyelectrolyte complex
behavior. Results of density functional theory calculations prove
that binding of cobalt aqua complexes [Co(H2O)6]2+ with the dimeric associates heparin/PDADMAC via noncovalent
interactions (hydrogen bonds) additionally is much more energetically
favorable compared with the alternative association of heparin/PDADMAC
with water molecules.
We introduce asimple concept of alight induced pH change,f ollowed by high amplitude manipulation of the mechanical properties of an adjacent polymer film. Irradiation of at itania surface is knownt oc ause water splitting,a nd this can be used to reduce the environmental pH to pH 4. The mechanical modulus of an adjacent pH sensitive polymer film can thus be changed by more than an order of magnitude.The changes can be localized, maintained for hours and repeated without material destruction.
A porous hydroxyapatite (HA)-incorporated TiO 2 coating has been deposited on the titanium substrate using a plasma electrolytic oxidation coupled with electrophoretic deposition (PEO-EPD).Potassium titanium(IV) oxalate is decomposed by micro arcs gener-
The
development of stimuli-responsive nanocontainers is an issue
of utmost importance for many applications such as targeted drug delivery,
regulation of the cell and tissue behavior, making bacteria have useful
functions and here converting light. The present work shows a new
contribution to the design of polyelectrolyte (PE) containers based
on surface modified mesoporous titania particles with deposited Ag
nanoparticles to achieve chemical light upconversion via biofilms.
The PE shell allows slowing down the kinetics of a release of loaded l-arabinose and switching the bacteria luminescence in a certain
time. The hybrid TiO2/Ag/PE containers activated at 980
nm (IR) illumination demonstrate 10 times faster release of l-arabinose as opposed to non-activated containers. Fast IR-released l-arabinose switch bacteria fluorescence which we monitor at
510 nm. The approach described herein can be used in many applications
where the target and delayed switching and light upconversion are
required.
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