INORGANIC NANOMATERIALS PATH FROM DESIGN TO COMMERCIALIZATION
INORGANIC NANOMATERIALS PATH FROM DESIGN TO COMMERCIALIZATION
AviXéla invests in the capability to fabricate nanomaterials with specific functional groups, including polymers, biomolecules, and inorganic components, as well as working on various types of surface coating by inorganic nanomaterials. We focus on development of steady systems and design, scale-up, and manufacturing methods to modify nanoparticles with a variety of anionic, cationic, neutral, and hydrophobic capping ligands. When you need a specific surface change for in vivo and in vitro applications, our team will collaborate with you to reach your specific goals.
AviXéla focuses on the development of different plasmonic biosensing materials with improved performance based on their unique properties, such as high surface area-to-volume ratio, that facilitate the biochemical analyte capturing and signal amplification, necessary for localized surface plasmon resonance, fluorescence enhancement, plasmon and colorimetry quenching. Using our alternate plasma scale treatment, we can achieve the reduction, deposition, and decomposition of active components, different types of nucleation, and crystal growth of catalytic materials. Compared to the conventional thermal methods, this plasma process produces smaller particle sizes over enhanced activity and stability.
Due to their unique properties, such as the size, optical, biodegradable, low-toxicity, biocompatibility, and highly catalytic features, our steadily developed spherical nanoparticles applicable for various bio-functionalization and represent a rapidly growing part of our internal research and development. In order to prevent rapid aggregation, oxidation, and other problems, we evaluate their subsequent utilization and adequate surface modification with organic and inorganic compounds.
We are in the process to utilize spherical gold nanoparticles, specifically conjugated for in vitro applications via a proprietary covalent polymer bridge to the PEG, alkyne, amine, azide, biotin, carboxyl, hydroxyl, methyl, maleimide, neutravidin, heparin, streptavidin, GSH, Protein A and G, galactose, thiol, and secondary antibodies. These nanoproducts are resistant to spontaneous aggregation, temperature, salt, pH, and possess exceptional loading capability that are critical for diagnostics and imaging in adverse environments.
Inorganic nanomaterials coating on the polymer separators and metallic surfaces drastically enhances their structural and mechanical stability along with the surface wettability for better electrolyte uptake and interaction with other components at the interfaces. The inorganic-based surface modifiers are mostly studied materials that are synthesized prior to loading on the surface of separators. Thus, the application of inorganic nanomaterials is opportunistic for the anticorrosive and multifunctional modification of protective surface coatings over different metals, that is critical for electroless plating, electroplating, silane and chemical conversion coatings.
Our plasma excitation method of controlled production and addition of inorganic nanoparticles without chemical contamination can become one of the advanced dispersion methods, as well as the alternative formation mechanism of nanocomposite coatings. Avixela aims to deliver the contolled surface coatings by titanium, aluminum, zinc, silicium, and molybdenum, as well as to improve already observed a spontaneous coating by gold, silver, platinum, palladium, and copper nanomaterials.
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