Titanium dioxide, first manufactured a century ago, is significant in industry due to its chemical inertness, low cost, and availability. The white mineral has a wide range of applications in photocatalysis, in the pharmaceutical industry, and in food processing sectors. Its practical uses stem from its dual feature to act as both a semiconductor and light scatterer. Optical performance is therefore of relevance in understanding how titanium dioxide impacts these industries. Recent breakthroughs are summarised herein, focusing on whether restructuring the surface properties of titanium dioxide either enhances or inhibits its reactivity, depending on the required application. Its recent exposure as a potential carcinogen to humans has been linked to controversies around titanium dioxides toxicity; this is discussed by illustrating discrepancies between experimental protocols of toxicity assays and their results. In all, it is important to review the latest achievements in fast-growing industries where titanium dioxide prevails, while keeping in mind insights into its disputed toxicity.
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Titanium dioxide (TiO2) is a white powder extensively used to decontaminate water and food, ensuring environmental and industrial safety, while also serving to protect the skin against harmful radiation [1,2,3,4,5]. To better understand how this metal oxide functions, it is relevant to describe its polymorphic crystal structure [1,2].
Titanium dioxide exists in three phases: as rutile [1], anatase [1], and brookite [2]. These crystal phases assemble as octahedra, where six oxygen anions are shared by three titanium (IV) cations [2], hence the formula TiO6/3, which equals TiO2. While expanding in a three-dimensional space, these octahedral units arrange and distort differently for each polymorph, which leads to distinct patterns of crystallinity [2]. As such, the three polymorphs differ in shape, structure [1,2,3], density [1], and refractive index [1]. Rutile has a comparatively higher structural stability [1,2,4,5,6], given that transitions of this phase during synthesis and use are rare [1]. The metastable anatase and brookite can be thermally restructured into the more thermodynamically stable rutile, depending on the minerals industrial purpose [4,5]. Brookite is a rarely encountered crystal phase and challenging to manufacture in industry [2].
Titanium dioxide nanoparticles are part of the top five nanoparticles used in industry [12], owing to their versatility in applicationsas photocatalysts [5], in pharmaceuticals [13,14], processed foods [15,16,17,18] and household products [13,17,19], cosmetic white pigments [17,18], fabrics [18], and paints, and sunscreens [19].
Compared to microparticles, titanium dioxide nanoparticles display enhanced catalytic activity [3,5]. This is because a decrease in size leads to an increased surface area available for catalysis [5,10,12,20,21]. Recent breakthroughs have been achieved in medicinal applications of photocatalysis, by testing nano-titania as an anticancer agent [14,20,21]. Balachandran et al. reported that irradiated TiO2 particles below 20 nm are an efficient photo-killer of pulmonary cancer cells [20]. Valence band holes, with their strong oxidant character, lead to the formation of reactive oxygen species; these will interact with defective cells, causing significant intracellular damage, to finally induce their necrosis [20,21].
Modern breakthroughs are also seen in nanobiotechnology. Although many synthetic routes have been designed for nano-TiO2, their cost is significant and often associated with environmental hazards [22,23,24,25]. In contrast, the "green" syntheses of nano-TiO2 from plants and seeds extracts have been extensively researched, as they prove to be safer, cost-effective, and less toxic [23,24,25]. In general, these methods require TiO2 precursors, such as titanium isopropoxide [24] or titanium trichloride [25], which are centrifuged with natural extracts in aqueous solutions [23,24,25]. Interestingly, nanoparticle formation is accelerated by stabilizing interactions with these natural biocomponents [24]. Lingaraju et al. recently tailored the synthesis of anatase titania nanoparticles from fungal biomass [13]. The publication highlights an improved activity of UV-irradiated nano-TiO2 against the proliferation of microbial pathogens [13]. Moreover, the metal oxides cytotoxic character was assessed, by monitoring the induction of apoptosis in lung and breast cancer cells [13]. Another medicinal attribute observed is the oxides role as an anticoagulant, by limiting the formation of blood clots and preventing heart and brain damage [13]. While the interaction mechanisms with cells have yet to be explored, the novel synthesis was facile, cost-effective, and environmentally benign [13].
Titanias nanoform is also valuable in preventing skin cancer caused by overexposure to ultraviolet radiation [26,27]. TiO2 nanoparticles scatter UV photons more efficiently than microparticles [26]. This ability enhances the sun protection factor (SPF) of sun creams, a measure of dermal shielding against photodamage [28,29,30]. Moreover, nano-titanias photoprotective behaviour [28], coupled with its ability to preserve aliments [31], have seen a multitude of applications in the food industry [15,16,31].
Given the complexity of titanias features, this review highlights the impact of the metal oxides optical properties on the environmental safety sector, and on the pharmaceutical and food industries. Further on, the focus will be on growing concerns in the scientific community regarding titanium dioxides nanotoxicity. Then, the discrepancies between toxicity assays will be elaborated on.
Titanium Dioxide (TiO2) is a white inorganic compound that sees significant use as a white pigment, especially in the manufacture of paints, coatings, printer ink and plastics, as well as in the production of papers, pharmaceuticals, food products and cosmetics, among others. Choosing the type of titanium dioxide that works for you will mostly depend on its ultimate use and the types and characteristics of the titanium dioxide.
What is titanium dioxide?
TiO2 is composed of one titanium atom and two oxygen atoms, and its CAS registry number is -67-7. It is quite good at scattering light, offering luminosity (what we call a high refractive index) without being toxic or reactive, allowing for intensifying the whiteness and shine of many materials in a safe manner. The shine, chromatic intensity, opacity and whiteness that it offers are unique.
TiO2is considered to be chemically inert, which means that it does not react with other chemicals.
Both its melting point(°C / °F) and its boiling point (°C / °F) are extremely high, which means that it is found in nature in a solid state and is insoluble in water even as a particle.
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TiO2 Varieties
Among the existing varieties of TiO2, the most conventional forms are RUTILE, which sees the most widespread use worldwide, and ANATASE, which sees more use in the pharmaceutical, cosmetics and food industry.
Titanium Dioxide production methods
There are two methods to produce TiO2: a sulfate process and a chloride process.
In the sulfate process, the mineral is dissolved in sulfuric acid and extracted as sulfate salts, and is then subjected to hydrolysis, calcination and a milling stage, where any remnant of sulfuric acid is broken down and crystals of the required size are formed. In the chloride process, chlorine is used instead of sulfuric acid, where Rutile is transformed into titanium chloride, and the titanium chloride oxidizes, thereby obtaining it through a more affordable process.
Main Characteristics of Titanium Dioxide
The various forms of TiO2 are characterized by usually being subjected to a surface treatment that improves their properties in regard to dispersibility, coating capabilities, surface compatibility and low oil absorption. These treatments are commonly inorganic, with the use of alumina, silica and zinc.
When choosing a variant of titanium dioxide you must analyze the following:
Whiteness it is important for the TiO2 not to turn yellow and to have an adequate shininess.
Dispersibility that it is easy to add into the system.
Opacity that it has excellent coating properties.
Oil absorption that it is as low as possible.
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