Cosmetics, preparations repeatedly applied directly to the human skin, mucous membranes, hair and nails, should be safe for health, however, recently there has been increasing concern about their safety. Unfortunately, using these products in some cases is related to the occurrence of unfavourable effects resulting from intentional or the accidental presence of chemical substances, including toxic metals. Heavy metals such as lead, mercury, cadmium, arsenic and nickel, as well as aluminium, classified as a light metal, are detected in various types of cosmetics (colour cosmetics, face and body care products, hair cosmetics, herbal cosmetics, etc.). In addition, necessary, but harmful when they occur in excessive amounts, elements such as copper, iron, chromium and cobalt are also present in cosmetic products. Metals occurring in cosmetics may undergo retention and act directly in the skin or be absorbed through the skin into the blood, accumulate in the body and exert toxic effects in various organs. Some cases of topical (mainly allergic contact dermatitis) and systemic effects owing to exposure to metals present in cosmetics have been reported. Literature data show that in commercially available cosmetics toxic metals may be present in amounts creating a danger to human health. Thus, the present review article focused on the problems related to the presence of heavy metals and aluminium in cosmetics, including their sources, concentrations and law regulations as well as danger for the health of these products users. Owing to the growing usage of cosmetics it is necessary to pay special attention to these problems.
Aronia melanocarpa berries (chokeberries) constitute a very rich source of numerous substances exerting a beneficial impact on health, including mainly polyphenols (proanthocyanidins, anthocyanins, flavonoids, and phenolic acids), possessing antioxidative, anti-inflammatory, antiviral, anticancer, antiatherosclerotic, hypotensive, antiplatelet, and antidiabetic properties. Thus, the consumption of products made from chokeberries is of vital importance for health maintenance and protection. Nowadays, due to the growing prevalence of noncommunicable diseases and ubiquitous human exposure to numerous man-made and naturally occurring toxic substances, some of which are dangerous even at low amounts, it is very important to look for effective means of health protection. An important role in this regard may be played by A. melanocarpa berries; however, up to now the attention of scientists, nutritionists, and health practitioners has been focused mainly on the effectiveness of chokeberry products in the prevention and treatment of noncommunicable diseases, while only little attention has been paid to the possibility of their use to counteract the adverse health effects of exposure to xenobiotics. That is why in this review article the main interest has been focused on the possibility of using chokeberries in the protection against unfavorable health effects caused by the action of substances to which humans may be exposed environmentally and/or occupationally. The available experimental data indicate that not only the fruit but also the leaves of A. melanocarpa and their products may be effective means for prevention and treatment of the effects of toxic action of some xenobiotics in humans; however, further studies on this subject are necessary.
Epidemiological studies provide a growing number of evidences that chronic exposure to relatively low levels of cadmium (Cd), nowadays taking place in industrialized countries, may cause health hazard. Thus, growing interest has been focused on effective ways of protection from adverse effects of exposure to this heavy metal. Because numerous effects to Cd's toxic action result from its prooxidative properties, it seems reasonable that special attention should be directed to agents that can prevent or reduce this metal-induced oxidative stress and its consequences in tissues, organs and systems at risk of toxicity, including liver, kidneys, testes, ears, eyes, cardiovascular system and nervous system as well as bone tissue. This review discusses a wide range of natural (plant and animal origin) and synthetic antioxidants together with many plant extracts (e.g. black and green tea, Aronia melanocarpa, Allium sativum, Allium cepa, Ocimum sanctum, Phoenix dactylifera, Physalis peruviana, Zingiber officinale) that have been shown to prevent from Cd toxicity. Moreover, some attention has been focused on the fact that substances not possessing antioxidative potential may also prevent Cd-induced oxidative stress and its consequences. So far, most of the data on the protective effects of the natural and synthetic antioxidants and plant extracts come from studies in animals' models; however, numerous of them seem to be promising preventive/therapeutic strategies for Cd toxicity in humans. Further investigation of prophylactic and therapeutic use of antioxidants in populations exposed to Cd environmentally and occupationally is warranted, given that therapeutically effective chelation therapy for this toxic metal is currently lacking.
In an experimental model of low-level and moderate environmental human exposure to cadmium (Cd), it was investigated whether the consumption of a polyphenol-rich Aronia melanocarpa L. berries (chokeberries) extract (AE) may influence the body status of zinc (Zn) and copper (Cu). The bioelements’ apparent absorption, body retention, serum and tissue concentrations, total pool in internal organs, excretion, and the degree of binding to metallothionein were evaluated in female rats administered 0.1% aqueous AE or/and Cd in their diet (1 and 5 mg/kg) for 3–24 months. The consumption of AE alone had no influence on the body status of Zn and Cu. The extract administration at both levels of Cd treatment significantly (completely or partially) protected against most of the changes in the metabolism of Zn and Cu caused by this xenobiotic; however, it increased or decreased some of the Cd-unchanged indices of their body status. Based on the findings, it seems that rational amounts of chokeberry products may be included in the daily diet without the risk of destroying Zn and Cu metabolisms; however, their potential prophylactic use under exposure to Cd needs further study to exclude any unfavourable impact of these essential elements on the metabolism.
Nowadays, growing interest in the possibility of prophylactic and therapeutic use of plant products rich in biologically active compounds has been observed. Among them, special interest has been focused on polyphenol-rich products. Owing to the multidirectional favourable action of polyphenols, products rich in these compounds are recommended as functional food in the case of civilization diseases. Moreover, data from studies in animal models show that polyphenols may be a promising preventive/therapeutic strategy for xenobiotics, including toxic heavy metals. The protective impact of polyphenols against metal toxicity may be explained by the presence of many hydroxyl groups in the structure of these compounds, which are capable of forming complexes with metals preventing as a result from their gastrointestinal absorption and accelerating their elimination from the body with urine. However, it should be taken into account that polyphenols may bind not only ions of toxic metals, but also bioelements, what makes a risk of their shortage in the organism. This review provides an overview of implications for humans' and animals' health of complexation of bioelements and toxic metals by polyphenols present in the popular foodstuffs, including phenolic acids, cyanidin derivatives, delphinidin, quercetin, kaempferol, morin, epigallocatechin-3-gallate, and curcumin. Polyphenolic compounds capable of binding both necessary and toxic metals occur in commonly consumed products such as green tea, and some fruit and vegetables, including chokeberries, bilberries, and black currant fruit, grapes, and apples, as well as onion. The mechanisms of complexation of essential and toxic metals by polyphenols and possible implications of these for health are discussed.
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