Titanium Dioxide in Food
Video & guest post by Carolyn Meyers & Edgar Rodriguez
Titanium dioxide isn’t something we usually request as a donut topping from the local bakery. However, most of the sweets we eat on a daily basis contain this chemical.
What is titanium dioxide?
Titanium dioxide has a solid tetragonal crystalline structure and is derived from three main natural minerals: rulite, anatase, and brookite.
Where does titanium dioxide come from?
U.S. Companies, such as DuPont, Cristal Global, Louisiana Pigment Co. L.P., and Tronox Ltd. process the mineral into a white powder, which has a refractive index of 2.5837, making it ideal for use as a filler or pigment that adds opacity to things like sunblock, shampoo, chewing gum, chocolate, and powdered donuts. Production of pure titanium dioxide is achieved through a method called the chloride process, wherein the raw minerals are first reduced with carbon and then oxidized with chlorine. Liquid titanium chloride (TiCl4) is then distilled and converted back into titanium dioxide by heating it to high temperatures in a pure oxygen flame.
Titanium dioxide nanoparticles (TiO2) are widely used as a food additive and are consumed by millions of consumers on a daily basis, as manufactures incorporate it into their food products. TiO2 nanoparticles are used as an additive mainly to prevent UV light from penetrating the food, effectively increasing the shelf life. It is also used as a color enhancer to make foods appear white by enhancing the opacity.
How much TiO2 is in your food?
Many popular consumer products such as candies, gum, and baked goods contain 0.01 to 1 mg Ti per serving. The products with the highest titanium contents are sweets or candies . For example, powdered donuts can contain up to 100 mg Ti per serving.What are the health effects of ingesting titanium dioxide?
Titanium dioxide is marketed by DuPont as an inert chemical, meaning it shouldn’t react with other chemicals. Given the fact that powdered donuts include 100 mg per serving of titanium dioxide and the lethal dosage, measured as the LD50 or the amount needed for 50% of the population to perish from consuming the chemical, was measured in rats to be 5,000 mg/kg, A 200 lb human (90.7kg) would need to eat 4,535 powdered donuts and have a 50% chance of survival. (5000)X90.7= 453500 mg. Although it is impossible for a human to consume this many donuts at once, Dunkin Donuts recently stopped using titanium dioxide in their powdered sugar donuts after being pressured by the public to do so.
There have been numerous scientific studies done on how titanium dioxide affects the health. Many of these studies are performed using animal models, such as mice. Both positive and negative health effects have been found. One possibly positive health effect of ingesting titanium dioxide is a substantial increase in the levels of dopamine, the happiness hormone . Negative health effects due to the ingestion of TiO2 nanoparticles include damage to the liver, kidneys, testes, brain and heart of mice and rats, as described below [3,4,5]:
- Mice given doses as low as 50 mg/kg body weight experience hepatic damage in the form of: hepatic cell death, increased levels of reactive oxygen species, and altered antioxidant activity, as well as kidney damage [2,3,6].
- Oral exposure to Ti nanoparticles have been shown to produce significant negative effects in the brain such as major degenerative changes in the visual cotex and inflammation in the hippocampus [2, 7, 8, 9].
- Titanium dioxide particles have been shown to cross the blood-testis barrier in mammals, leading to reproductive toxicity in males, including a decrease in sperm motility percentage, sperm cell concentration, sperm viability and serum testosterone level, as well as a significant increase in sperm abnormalities [7, 10].
- In humans, clinical research shows that patients with ulcerative colitis, a chronic inflammatory disease of the large intestine, have elevated levels of titanium in the blood and an accumulation of the chemical in the spleen .
Given this information, it remains the consumers’ responsibility, as always, to make an informed decision on the foods they eat and follow rules of moderation in everyday life.
- Weir, Alex, Paul Westerhoff, Lars Fabricius, Kiril Hristovski, and Natalie Von Goetz. “Titanium Dioxide Nanoparticles in Food and Personal Care Products.” Environmental Science & Technology Environ. Sci. Technol. 46.4 (2012): 2242-250. Web.
- Shrivastava R, Raza S, Yadav A, Kushwaha P, Flora SJS (2014) Effects of sub-acute exposure to TiO2, ZnO and Al2O3 nanopar- ticles on oxidative stress and histological changes in mouse liver and brain. Drug Chem Toxicol 37(3):336–347. doi:10.3109/ 01480545.2013.866134
- El-Sharkawy NI, Hamza SM, Abou-Zeid EH (2010) Toxic impact of titanium dioxide (TiO2) in male albino rats with special refer- ence to its effect on reproductive system. J Am Sci 6(11):865–872
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- BuQ,YanG,DengP,PengF,LinH,XuY,CaoZ,ZhouT,XueA, Wang Y, Cen X, Zhao YL (2010) NMR-based metabonomic study of the sub-acute toxicity of titanium dioxide nanoparticles in rats after oral administration. Nanotechnol 21(12):125105. doi:10. 1088/0957-4484/21/12/125105
- Vasantharaja D, Ramalingam V, Aadinaath Reddy G (2015) Oral toxic exposure of titanium dioxide nanoparticles on serum bio- chemical changes in adult male Wistar rats. Nanomedicine J 2(1):46–53
- Elbastawisy YM, Saied HA (2013) Effects of exposure to titanium dioxide nanoparticles on albino rat visual cortex Belectron micro- scopic study. J Am Sci 9(5):432–439
- ZeY,ShengL,ZhaoX,HongJ,ZeX,YuX,PanX,LinA,Zhao Y, Zhang C, Zhou Q, Wang L, Hong F (induced hippocampal neuroinflammation in mice. PLoS ONE 9(3), e92230. doi:10.1371/journal.pone.0092230
- Mohammadipour A, Hosseini M, Fazel A, Haghir H, Rafatpanah H, Pourganji M, Ebrahimzadeh Bideskan A (2013) The effects of exposure to titanium dioxide nanoparticles during lactation period on learning and memory of rat offspring. Toxicol Ind Health. doi: 10.1177/0748233713498440
- Hong, F., Y. Wang, Y. Zhou, W. Zhang, Y. Ge, M. Chen, J. Hone, and L. Wang. “Exposure to TiO2 Nanoparticles Induces Immunological Dysfunction in Mouse Testitis.” PubMed. – Journal of Agricultural and Food Chemistry (ACS Publications), 13 Jan. 2016. Web. 22 Feb. 2016.
- Ruiz, PA, B. Moron, HM Becker, S. Lang, K. Atrott, MR Spalinger, M. Scharl, KA. Wojtal, A. Fishbeck-Terhalle, I. Frey-Wagner, M. Hausmann, T. Kraemer, and G. Rogler. “Titanium Dioxide Nanoparticles Exacerbate DSS-induced Colitis: Role of the NLRP3 Inflammasome.” PubMed. BJM, 4 Feb. 2016. Web.