Titanium oxide particles of various morphologies have been prepared for applications of scientific or industrial interest in recent decades. Besides development of novel synthetic routes and solid-state characterization of the obtained particles, colloidal stability of titanium oxide dispersions was the focus of numerous research groups due to the high importance of this topic in applications in heterogeneous systems. The influence of dissolved ionic compounds, including monovalent salts, multivalent ions and polyelectrolytes, on the charging and aggregation behaviour of titanium oxide materials of spherical and elongated structures will be discussed in the present review.
An antioxidant material composed of halloysite nanotubes
(HNTs), protamine sulfate polyelectrolyte (PSP), and superoxide dismutase
(SOD) enzyme was prepared by self-assembly of the PSP and SOD biomacromolecules
on the nanoparticulate support. The structural, colloidal and biocatalytic
features were assessed. Adsorption of PSP on the oppositely charged
HNT surface at appropriate loadings gave rise to charge neutralization
and overcharging, which resulted in unstable and stable dispersions,
respectively. The formation of a saturated PSP layer on the HNT led
to the development of positive surface charge and to remarkable resistance
against salt-induced aggregation making the obtained HNT-PSP hybrid
suitable for immobilization of negatively charged SOD. No enzyme leakage
was observed from the HNT-PSP-SOD composite indicating sufficient
structural stability of this material due to electrostatic, hydrophobic,
and hydrogen bonding interactions taking place between the particles
and the biomacromolecules. Enzymatic assays revealed that SOD kept
its functional integrity upon immobilization and showed high activity
in superoxide radical dismutation. In this way, stable antioxidant
bionanocomposite dispersions were obtained, which can be used as antioxidants
in heterogeneous samples.
Ellagic acid (EA), a polyphenolic antioxidant of poor water solubility, was intercalated into biocompatible layered double hydroxide (LDH) nanoparticles by the coprecipitation method. Structural investigation of the composite revealed that the lactone bonds split under the synthetic experimental conditions, and EA was transformed to 4,4′,5,5′,6,6′-hexahydroxydiphenic acid during intercalation. To improve the surface properties of the EA-LDH composite, the samples were treated with different organic solvents. The antioxidant activity of the LDH hybrids was assessed in test reactions. Most of the obtained hybrids showed antioxidant activity comparable to the one of the free EA indicating that the spontaneous structural transformation upon immobilization did not change the efficiency in radical scavenging. Treatments with organic solvents influenced the activities of the materials remarkably. The main advantage of the immobilization procedure is that the products can be applied in aqueous samples in high concentrations overcoming the problem related to the low solubility of EA in water. The developed composites of high antioxidant content can be applied as efficient reactive oxygen species scavenging materials during biomedical treatments or industrial manufacturing processes.
A broad-spectrum reactive oxygen species (ROS)-scavenging hybrid material (CASCADE) was developed by sequential adsorption of heparin (HEP) and poly(L-lysine) (PLL) polyelectrolytes together with superoxide dismutase (SOD) and horseradish peroxidase (HRP) antioxidant enzymes on layered double hydroxide (LDH) nanoclay support. The synthetic conditions were optimized so that CASCADE possessed remarkable structural (no enzyme leakage) and colloidal (excellent resistance against salt-induced aggregation) stability. The obtained composite was active in decomposition of both superoxide radical anions and hydrogen peroxide in biochemical assays revealing that the strong electrostatic interaction with the functionalized support led to high enzyme loadings, nevertheless, it did not interfere with the native enzyme conformation. In vitro tests demonstrated that ROS generated in human cervical adenocarcinoma cells were successfully consumed by the hybrid material. The cellular uptake was not accompanied with any toxicity effects, which makes the developed CASCADE a promising candidate for treatment of oxidative stress-related diseases.
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