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= Nanotechnology in Cosmetics and Skincare =

Introduction
Nanomaterials are defined as a material with a size ranging from 1 to 100 nm in at least one dimension. Nanomaterials are interesting material due to the difference in material properties at the nanoscale compared to bulk scale. These unique properties can be exploited for a variety of applications, including the use of nanoparticles in skincare and cosmetics products. Cosmeceuticals is one of the fastest growing industries in terms of personal care, accompanied by an increase in nanocosmeceuticals research and applications.

Titanium Dioxide and Zinc Oxide Nanoparticles in Sunscreen
Sunscreens are utilized to secure the skin from the destructive impacts of ultraviolet radiation from the sun. UVB (290-320 nm) together with UVA-2 (320–340 nm) and UVA-1 (340–400 nm) cause organic and metabolic reactions in the skin. Titanium dioxide (TiO2) and zinc oxide (ZnO) minerals are often utilized in sunscreens as inorganic physical sun blockers owing to their absorption of light in the UV range. As TiO2 is proven to be more effective for blocking UVB and ZnO in the UVA range, the mix of these particles guarantees abroad-band UV shield.

To solve the cosmetic disadvantage of these opaque sunscreens, TiO2 and ZnO nanoparticles have been used as a replacement for TiO2 and ZnO microparticles. Since the surface area to volume proportion of particles increases as the particle measurement diminishes, nanoparticles (NPs), ie, nano objects with all dimensions in the nanoscale, might be increasingly (bio)reactive than typical mass materials. When particles become smaller than 100 nm, novel optical attributes develop, owing to discrete nature of nanoparticle optical energy levels. Pat et al, for instance, measured a 0.15 eV blue shift for 4.7 nm TiO2 nanoparticles relative to the bulk material counterpart. When particles become smaller than the ideal light dispersing size (roughly half of the wavelength) visible light is transmitted and the particles appear transparent. This phenomenon explains the cosmetically undesired opaqueness of inorganic sunscreens and makes the utilization of NPs monetarily appealing. ZnO particles of 200 nm or smaller are transparent to the human eye. TiO2 NPs become more effective sunblocking materials due to their larger surface area to volume ratio. The purpose behind this is in direct-illegal gap semiconductors, for example, TiO2, direct electron transmissions are not allowed due to crystal symmetry. Absorption is subsequently small. However, it might be significantly upgraded when it happens at the precious crystal surface. This absorption upgrade gets significant for particles of 20 nm or smaller. Similarly, TiO2 becomes visibly transmissive when particle sizes are reduces to 10-20 nm in size.

Safety
The International Agency for Research on Cancer (IARC) has categorized TiO2 as an IARC group 2B carcinogen. The IARC made these decisions based on studies where rats are exposed to high concentrations of pigment-grade and ultrafine TiO2 dust. The lung cancers in rats appear similar pathology to those seen in people who are working in a dusty environment, thus the IARC concluded that the same impacts from high concentrations of pigment-grade and ultrafine TiO2 dust are relevant to human health. However, ZnO is generally considered as safe a substance by the FDA when utilized as an UV filter as indicated by beauty care products directives. Although both the US Environmental Protection Agency and the European Community (inside the Registration, Evaluation, Authorization and Restriction of Chemical Substances law) have taken preventative steps to reduce nanoparticle risk, there are still no standardized rule for nanoparticles specifically.

Liposomes Structure
Liposomes are sphere-shaped vesicular structures self-assembled in a solvent comprised of a broad type of lipids or other amphiphilic molecules. The vesicle structure of liposomes improves the effects on drug penetration through biological membrances, which enhance transdermal drug delivery.

Advantages

 * 1) Increase efficacy and therapeutic index of drug and stability via encapsulation
 * 2) Non-toxic, flexible, biocompatible, completely biodegradable, and non-immunogenic for systemic and non-systemic administrations
 * 3) Reduce toxicity of the encapsulated agent (amphotericin B, Taxol)
 * 4) Reduce the exposure of sensitive tissues to toxic drugs, site avoidance effect and flexibility to couple with site-specific ligands to achieve active targeting

Disadvantages

 * 1) Low solubility
 * 2) Short half-life
 * 3) Sometimes phospholipid undergoes oxidation and hydrolysis-like reaction
 * 4) Leakage and fusion of encapsulated drug/molecules
 * 5) Production cost is high
 * 6) Fewer stables

=== Topical Drug Delivery Using Ethosomes === Skin is the largest organ of human body that restricts the movement of drug to the systemic circulation. Topical drug delivery system is a system where the drug reaches the systemic circulation through the protective skin layer. The main disadvantage of this route is the low diffusion rate of the drugs across the layer of skin which is the stratum corneum. To overcome this problem to a certain extent, ethosomes are used to enhance transdermal drug delivery systems.

Gold Nanoparticles in Skin Care and Cosmetics
The utilization of gold in skin care and cosmetics dates back to 1st century B.C in Egypt, where Queen Cleopatra is said to have used masks made from gold to maintain her skin complexion. It was said that she used it every night to enhance her complexion and improve the suppleness of her skin. Nowadays, gold has made its way into various skincare products such as lotion and cream, as well as skincare treatments such as facial masks. Gold in skincare products are usually in the form of colloidal gold, or more commonly called nanogold. These nanoparticles ranges in size from 5nm to 400nm. This section will discuss about the effect of gold nanoparticle in wound healing application together with the effect of gold in lotion and cream products.

Properties of Gold Nanoparticles
Gold nanoparticles usually have colors ranging from red to purple to blue and black depending on the size and aggregation state. They also come in various shapes and sizes: nanosphere, nanoshell, nanocluster, nanorod, nanostar, nanocube, branched, and nanotriangle. The shape of the gold nanoparticles is the main determinant for uptake into cells and for optical properties. Gold nanoparticles are stable and chemically inert. Moreover, they are also biocompatible, which is the main reason why nanogold is commonly integrated in skincare and cosmetics. Furthermore, gold nanoparticles have been investigated for antifungal and antibacterial properties, which are very valuable properties in cosmeceutical industries and in wound healing applications.

Gold Nanoparticles in Wound Healing Applications
In 2016, a paper published in the Journal of Biomaterials Application, titled “Collagen/gold nanoparticle composites: A potential skin wound healing biomaterial,” discussed that in vivo studies of gold nanoparticle and collagen composites demonstrated high wound closure percentage, reduced inflammatory response, increased neovascularization, and granulation tissue formation. It was also shown that these improvements in healing effects increase proportionally with the amount of gold nanoparticles worked into the collagen scaffold.

In another study, the effect of spherical gold nanoparticles as a wound healing agent was tested in rat model by coupling gold nanoparticles with photobiomodulation therapy (PBMT). PBMT is a light stimulated therapy that is used for wound healing treatment without any significant temperature changes. The coupling of gold nanoparticles and PBMT increase the wound contraction rate by approximately 1.25 times than the control group that received no gold. nanoparticle treatment.

Gold in Lotion and Face Masks
Gold has been widely used in facial masks. Aside from antifungal and antibacterial properties, gold is also known to have anti-ageing benefits, anti-inflammatory properties as well as radiance-boosting qualities. Gold nanoparticles can help repair skin damage and improve skin texture which improves skin elasticity and suppleness. Its anti-inflammatory properties makes it an excellent agent for treating acne, sun-damaged, and or sensitive skin. Furthermore, due to gold’s natural light-reflecting color, gold nanoparticle can also create a brightening effect by making skin radiant and luminous. Over the course of the treatment, gold nanoparticle can make the skin appear smoother and even in color. A study in 2010 titled, “Novel Vitamin and Gold-Loaded Nanofiber Facial Mask for Topical Delivery” investigated how gold nanoparticle can be incorporated to facial mask along with Vitamin C (L-ascorbic acid), retinoic acid, and collagen using electrospinning. All of these properties and studies have suggested that gold nanoparticles can be beneficial when included in cream, lotion, or mask formulations for topical applicartions.