Synergistic effects of parabens and plastic nanoparticles on proliferation of human breast cancer cells

Željka Roje 1 , Krunoslav Ilić 2 , Emerik Galić 2 , Ivan Pavičić 2 , Petra Turčić 3 , Zdenko Stanec 4 , and Ivana Vinković Vrček 2
  • 1 Department for Plastic, Reconstructive and Aesthetic Surgery, University Hospital Dubrava, Zagreb, Croatia
  • 2 Institute for Medical Research and Occupational Health, , Zagreb, Croatia
  • 3 Faculty of Pharmacy and Biochemistry, University of Zagreb, Zagreb, Croatia
  • 4 School of Medicine, University of Zagreb, Zagreb, Croatia

Abstract

Many personal care products on the market contain endocrine disrupting chemicals, including parabens. Parabens are well known chemical additives used as preservatives. They have been found in mammary glands and breast cancer tissues. At the same time, the general public is increasingly exposed to plastic micro- and nanoparticles generated during plastic production and waste disposal. Exposure to chemical cocktails is a realistic scenario of high public health interest, in which many types of compounds such as these two may exhibit synergistic or additive adverse effects. This study evaluated the effects of plastic nanoparticles, parabens, and their mixture on the viability and proliferation of two human breast cancer cell lines: MDA-MB 231, which lacks oestrogen receptors, and MCF-7, which expresses these receptors. Parabens increased proliferation of oestrogen-sensitive breast cancer cells, and this effect became synergistic in the presence of plastic nanoparticles. The mechanism behind synergy may be related to the translocation and adsorption properties of nanoplastics, which served as a Trojan horse to expose cells to parabens more efficiently. These preliminary findings support growing evidence warning about the urgent problem of human exposure to combinations of plastic waste and contingent chemicals.

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