Nanoscale Ingredients Research Articles

Unraveling the physicochemical and toxicological properties of food product isolated E341/E171

AbstractNanostructured materials have been extensively exploited in the food sector for nutrient delivery, sensing, packaging, and food additives. It has exhibited size, shape, chemical nature, and surface area‐dependent physicochemical and biological properties. Currently, nanoscale ingredients are identified in approved food additives. Still, food‐grade nanostructured material's impact on biological systems is unexplored well. Thus, in this study, we have identified and analyzed the physicochemical properties of nanoscale ingredients in commercial food product isolate E341 and E171 combinations. Also, we have evaluated the E341/E171 combination cytotoxic potential on human mesenchymal stem cells. The food isolated E341/E171 exhibits spherical nature with a 60–200 nm diameter. The E341 and E171 combination exposure increased the cell viability loss to ~36% at a high dose in human mesenchymal stem cells (hMSCs). The E341/E171 treatment‐induced cellular and nuclear damage at a moderate dose. The mitochondrial membrane potential loss and ROS generation were observed in E341/E171 treated cells. The E341/E171 alters the gene expression pattern in hMSCs dose‐dependently. The GSR and POR gene expression is upregulated significantly in E341/E171 treatment. Our study results revealed that E341/E171 induced toxicity in hMSCs at high concentrations. Thus, E341/E171 potential impact on the biological system should be reexamined for food industrial implications.

Co-exposure to commercial food product ingredient E341 and E551 triggers cytotoxicity in human mesenchymal stem cells.

Several nano-toxicological studies have assessed the prospective health risks of engineered nanostructures. Still, nanoscale ingredients from food products are not explored well, and only a few have attended to the possible effects of food additive-based nanoparticles in food. The physicochemical properties of food additives and their fate on human health are still unknown. To fill this knowledge gap, we examined the physicochemical characteristics of food product isolate E341/E551. Additionally, we assessed the consequence of these nanoscale E341 and E551 as co-exposure on human mesenchymal stem cells (hMSCs). The transmission electron microscope (TEM) images revealed that food product isolate (E341/E551) consists of nanoscale particles. The E551 and E341 have 20-50nm and 70-200nm diameters, respectively. Co-exposure of food additives SiO2 (E551) and Tricalcium phosphate (E341) effect on the cell viability, morphology, mitochondrial membrane potential, and reactive oxygen species (ROS) level of hMSCs were studied. The cell viability reduction, mitochondrial membrane potential loss, and ROS generation in E341/E551 co-exposed cells were observed. Our study suggests that E341/E551 co-exposure elevated the ROS level and mitochondrial membrane potential depletion at a high dose. The oxidative stress-related genes MDM3, TNFSF10, and POR have exhibited significant upregulation in the E341/E551 treatment group. These results conclude that long-term over-exposure to E341/E551 may be triggers health risks in a human. Further in vivo studies are required for food industry implications due to nanoscale ingredients in E341 and E551.

Public Perceptions and Willingness-to-Pay for Nanopesticides.

The usage of pesticides is deemed essential to ensure crop production for global food security. Conventional chemical pesticides have significant effects on ecosystems. Nanopesticides are increasingly considered an emerging alternative due to their higher efficiency and lower environmental impacts. However, large knowledge gaps exist in the public perceptions and willingness-to-pay (WTP) for nanopesticides. Thus, we conducted a regional survey of pesticide users and food consumers on perceptions and WTP for nanopesticides across China. We found that 97.4% pesticide users were willing to pay for nanopesticides, with a main price from 25% to 40% higher than for conventional pesticides. Experience with applying pesticides, income, familiarity with and attitude toward nanopesticides, and trust in industries were significant determinants of WTP. Although the public were not familiar with nanopesticides, they had positive attitudes toward their future development and supported labeling nanoscale ingredients on products. Pesticide users presented high trust levels in governments and industries, while 34% of food consumers neutrally or distrusted industries in selling and production. This study highlights the socioeconomic and technological aspects of nanopesticides, which could provide guidance for industries to develop market strategies and for governments to design relevant regulation policies effectively, contributing to crop yield improvement and sustainable agriculture.

Measurement of TiO2 Nanoscale Ingredients in Sunscreens by Multidetector AF4, TEM, and spICP-MS Supported by Computational Modeling

There is a growing need to disclose the presence of nanostructures on the labeling of commercial products in South Africa. This work deals with complementary analytical techniques for the separatio...

Efficacy of nanoparticles as nanofertilizer production: a review.

Owing to the ever-increasing demand for food, the growing global population has forced farmers to increase fertilizer use. The overall use of fertilizers increased by 13 times between 1950 and 2020, from 15 to 194 million tons. Due to the resource shortages of chemical fertilizers on the market, agricultural costs are rising drastically every day because they cause an adverse impact on the environment by releasing chemical particulates and run-off agriculture. Biofertilizers have thus become a safer supplement to increase crop production without doing any harm to the environment, as they are produced industrially from a selected community of microorganisms that either develop a mutually beneficial relationship with plants or are part of their rhizosphere. They still have some drawbacks, which led to the development of a new avenue for the application of nanotechnology-mediated nanofertilizers. Nanotechnology recommends significant prospects for tailoring nanofertilizer production. They are typically coated with desired chemical composition having controlled release and targeted delivery of effective nanoscale ingredients, ability to improve plant productivity and to minimize environmental pollutants. The present review focuses primarily on the usefulness of nanofertilizers, as well as its environmental and safety concerns. The research would also include useful knowledge related to the introduction of different forms of nanoparticles within the agricultural field, contributing to the opening of a new route to nanorevolution.

Nanomaterials in Cosmetics: Recent Updates.

This review paper collects the recent updates regarding the use of nanomaterials in cosmetics. Special focus is given to the applications of nanomaterials in the cosmetic industry, their unique features, as well as the advantages of nanoscale ingredients compared to non-nanoscale products. The state-of-the-art practices for physicochemical and toxicological characterization of nanomaterials are also reviewed. Moreover, special focus is given to the current regulations and safety assessments that are currently in place regarding the use of nanomaterials in cosmetics—the new 2019 European guidance for the safety assessment of nanomaterials in cosmetics, together with the new proposed methodologies for the toxicity evaluation of nanomaterials. Concerns over health risks have limited the further incorporation of nanomaterials in cosmetics, and since new nanomaterials may be used in the future by the cosmetic industry, a detailed characterization and risk assessment are needed to fulfill the standard safety requirements.

Extraction of ultrafine carbon nanoparticles from samooli Bread and evaluation of their in vitro cytotoxicity in human mesenchymal stem cells

Modern technological strategies of food manufacturing may inevitably produce an unknown quantity of nanoscale ingredients or impurities in many processed or packaged foods. The indirect formation of these nanoscale contaminants, which are predicted to be emulsifier-like complex lipidaceous materials that form during heat-induced food processing, has not been studied. Moreover, the effects of chronic exposure to nanoscale contaminants on human health and the environment are also unknown. In this present study, we identify and extract emulsifier-like ultrafine carbon nanostructures (UFCNs) from bread using a facile method. The physico-chemical properties of the isolated particles were analyzed using UV–vis-NIR spectroscopy, X-ray diffraction (XRD) and transmission electron microscopy (TEM). The isolated nanoparticles exhibited fluorescence and a crystalline nature. TEM images revealed that carbon particles are 2–10 nm in diameter. An in vitro toxicological assessment was carried out in human mesenchymal stem cells (hMSCs) as a cellular model. Acute dose-response relationships were analyzed using an MTT assay, cell morphological assessments, and assessments of intra-cellular stress, i.e., ROS and mitochondrial trans-membrane potential and analysis cell cycle progression. The expression of oxidative stress-related genes was analyzed using real-time qPCR. Cell viability and morphology analysis results indicated that UFCNs slightly reduced cell viability and induced cellular morphological changes. UFCNs induced acute mitochondrial membrane damage at 400 μg/mL and generated ROS in hMSCs in a dose-dependent manner. The expression of GPX1, Bcl2, CAT and SOD genes showed dose- and time-dependent relationships in UFCN-treated cells. Our findings suggest that UFCNs induced cytotoxicity at 400 μg/mL in hMSCs.

A weight-of-evidence approach to identify nanomaterials in consumer products: a case study of nanoparticles in commercial sunscreens.

Nanoscale ingredients in commercial products represent a point of emerging environmental concern due to recent findings that correlate toxicity with small particle size. A weight-of-evidence (WOE) approach based upon multiple lines of evidence (LOE) is developed here to assess nanomaterials as they exist in consumer product formulations, providing a qualitative assessment regarding the presence of nanomaterials, along with a baseline estimate of nanoparticle concentration if nanomaterials do exist. Electron microscopy, analytical separations, and X-ray detection methods were used to identify and characterize nanomaterials in sunscreen formulations. The WOE/LOE approach as applied to four commercial sunscreen products indicated that all four contained at least 10% dispersed primary particles having at least one dimension <100 nm in size. Analytical analyses confirmed that these constituents were comprised of zinc oxide (ZnO) or titanium dioxide (TiO2). The screening approaches developed herein offer a streamlined, facile means to identify potentially hazardous nanomaterial constituents with minimal abrasive processing of the raw material.

Identification of nanoscale ingredients in commercial food products and their induction of mitochondrially mediated cytotoxic effects on human mesenchymal stem cells.

Titanium dioxide (E171) and silicon dioxide (E551) are common additives found in food products, personal-care products, and many other consumer products used in daily life. Recent studies have reported that these food additives (manufactured E171 and E551) contain nanosized particles of less than 100 nm. However, the particle size distribution and morphology of added TiO2 and SiO2 particles are not typically stated on the package label. Furthermore, there is an increasing debate regarding health and safety concerns related to the use of synthetic food additives containing nanosized ingredients in consumer products. In this study, we identified the size and morphology of TiO2 and SiO2 particles in commercially available food products by using transmission electron microscope (TEM). In addition, the in vitro toxicological effects of E171 and E551 on human mesenchymal stem cells (hMSCs), an adult stem cell-based model, were assessed using the MTT assay and a flow cytometry-based JC-1 assay. Our TEM results confirmed the presence of nanoscale ingredients in food products, and the in vitro toxicology results indicated that the nanoscale E171 and E551 ingredients induced dose-dependent cytotoxicity, changes in cellular morphology, and the loss of mitochondrial trans-membrane potential in hMSCs. These preliminary results clearly demonstrated that the nanoscale E171 and E551 particles had adverse effects on hMSCs by inducing oxidative stress-mediated cell death. Accordingly, further studies are needed to identify the specific pathway involved, with an emphasis on differential gene expression in hMSCs.

NANOMATERIALS AND COSMETICS

SUMMARY This review has overviewed the nanotechnology approaches and safety concerns in cosmetics. Nanotechnology based nanomaterials have been widely use in cosmetics for recent few years such as in sunscreens, hair products, skincare products, etc. However debate on their definition and insufficient quantification methods are major problems still occur in the nanomaterial field. Moreover the frequent use of cosmetics, safety of nanoscale ingredients of them has gain importance mainly by means of their dermal exposure. Although the proposed benefits that may occur by incorporating nanoparticles in cosmetics are increased efficiency, transparency, unique texture, protection of active ingredient, and overall higher consumer compliance, there still have not enough studies proved whether they are completely safe or not. As a conclusion major issues related nanomaterials such as developing, using and researching is going to increase in the near future due to their economically importance. Key words: Nanotechnology, nanomaterial, dermal, safety, cosmetics. *Correspondence: evrenalgin@yahoo.com, algin@pharmacy.ankara.edu.tr

Engineered Nanoparticles in Consumer Products: Understanding a NewIngredient

In October 2010 the National Organic Standards Board recommended that engineered nanomaterials (ENMs) be prohibited from food products bearing the U.S. Department of Agriculture’s coveted Organic label.1 If the department adopts the recommendation, ENMs will find themselves in the same officially taboo category as genetically modified organisms when it comes to organic foods—nanotechnology-enabled innovations like flavor- and texture- enhancing ingredients and shelf life– extending packaging will be off the menu. Prior to issuing its recommendation, the board received thousands of public comments and petition signatures supporting the ban and virtually none opposing it. Although an official decision could take years, supporters are confident the recommendation will be adopted, and it will go down as one of the first lines drawn in the sand when it comes to the reach of this relatively new and potentially transformative technology in the American marketplace. Nanotechnology-enabled products are quietly proliferating on U.S. store shelves, despite nagging questions about the safety of synthetic nanoparticles and the products that contain them. “[I]n our regulation of food and most consumer products, we don’t implement the precautionary principle. Things go to market before we know whether or not they’re really safe for human beings over the long term,” says Alexis Baden-Mayer, a lawyer with the Organic Consumers Association, an advocacy group, who attended the meeting and campaigned for the ban. Baden-Mayer and other observers perceive a distinct lack of public awareness about how common ENMs are becoming in the market-place, and she hopes discussion among consumers of organic products will help change that. “Consumers don’t know much about nanotechnology, and the first time they may hear about it is now when they learn that the organic regulations are going to prohibit [it],” she says. The International Organization for Standardization defines a nanomaterial as a material with any external dimension between 1 and 100 nm.2 (By comparison, a double strand of DNA is about 2 nm thick.) Nanoparticles, which have been the focus of most nanotoxicology studies to date,3 are one subset of nanomaterials. Nanoparticles include structures of various shapes, such as nanotubes, nanowires, quantum dots, and fullerenes. They also occur naturally in substances like air, smoke, and sea spray, and “incidental” nanoparticles are created during processes such as combustion and food milling, churning, freezing, and homogenization. (Naturally occurring and incidental nanoparticles were not included in the National Organic Standards Board’s recommendation to ban ENMs.) Nanotechnology—the deliberate synthesis and manipulation of nanomaterials—began in the 1980s. Today thousands of ENMs are manufactured in a kaleidoscope of substances, shapes, and sizes for use in a wide range of products and industrial processes that take advantage of their novel physical, thermal, optical, and biological properties. These properties may be determined by the ENM’s chemical composition, size or shape, crystal structure, solubility, adhesion (the force that holds the nanoparticle components together), or surface chemistry, charge, or area.3 Industry analysts have been forecasting “game-changing” advances as a result of nanotechnology in renewable energy, computers, communications, pollution cleanup, agriculture, medicine, and more.4 Clothing, sunscreens, cosmetics, sporting equipment, batteries, food packaging, dietary supplements, and electronics are just a few of the types of nanotechnology-enabled goods in use by U.S. consumers. But safety questions arise around the nanoparticles in some of these products. The novel biological and physical properties of some ENMs pose unique challenges to comprehensive safety research, and investigators are working to figure out just how hazardous they might be to people, wildlife, and the environment. Compared with larger particles, nanoparticles’ tiny size means tissues may take them up more readily. It also can give them an unusual ability to travel throughout the body, including into cells and cell nuclei, and across the placenta and the blood–brain barrier, as demonstrated in rodent studies.5,6 No cases of human illness or death have been definitively attributed to ENMs. However, a number of researchers and consumer and environmental advocates have warned that the abundant unknowns make it necessary to proceed with caution lest we repeat the history of asbestos, polychlorinated biphenyls, the insecticide DDT, and other innovations that seemed valuable when they were introduced, proceeded with little oversight, and ultimately caused major health or environmental problems.