Abstract
Arsenic (As) is widely used in the modern industry, especially in the production of pesticides, herbicides, wood preservatives, and semiconductors. The sources of As such as contaminated water, air, soil, but also food, can cause serious human diseases. The complex mechanism of As toxicity in the human body is associated with the generation of free radicals and the induction of oxidative damage in the cell. One effective strategy in reducing the toxic effects of As is the usage of chelating agents, which provide the formation of inert chelator–metal complexes with their further excretion from the body. This review discusses different aspects of the use of metal chelators, alone or in combination, in the treatment of As poisoning. Consideration is given to the therapeutic effect of thiol chelators such as meso-2,3-dimercaptosuccinic acid, sodium 2,3-dimercapto-1-propanesulfonate, 2,3-dimercaptopropanol, penicillamine, ethylenediaminetetraacetic acid, and other recent agents against As toxicity. The review also considers the possible role of flavonoids, trace elements, and herbal drugs as promising natural chelating and detoxifying agents.
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Introduction
Arsenic (As) is a metalloid element (atomic weight 74.9216 amu, atomic number 33, group 15 of the periodic system). As in trace amounts is an essential nutrient for energy generation in prokaryotes and several eukaryotes, including birds and mammals. It is also possible that As is an essential trace element for humans, although its role in metabolism has not been clearly defined (Oremland and Stolz 2003; Uthus 1992; Zoroddu et al. 2019). The human body contains approximately 0.08–0.02 mg As/kg, which mainly is concentrated in liver, kidneys, lungs, bones, and hair. The environmental presence of As imposes a major health problem worldwide since it has been clearly shown that excessive or prolonged exposure to its compounds results in severe acute or chronic toxicity leading to a range of medical complications termed as “Arsenicosis” (Abdul et al. 2015; McCarty et al. 2011; Straif et al. 2009).
Arsenic commonly occurs naturally in two oxidation states, As(III) and As(V), and rarely in the 0 or –3 state.
Both As(III) and As(V) compounds cause acute and chronic adverse health effects. Trivalent arsenicals have more potent toxicological properties than pentavalent arsenicals (Ratnaike 2003). In mice, the LD50 for oral intake of arsenic trioxide is 26 mg/kg (Hughes 2002). When As reacts with metals, arsenides are formed. With halogens, As results in the formation of halides. With halogens, As results in the formation of halides. As salts are soluble in water, resulting in its easy release from the earth's crust into water due to the natural processes of geogenic leaching of rocks and sediments containing this element.
Moreover, anthropogenic geothermal energy extraction and mining activities, as well as excess pumping of shallow groundwater, increase As dissipation in the environment (Masuda 2018). Since the number of people who are at risk of chronic As poisoning for a long-term intake of contaminated water and food is extremely high, the development of specific therapies is required. There are two main approaches to minimize the human health impact of As poisoning and As-contaminated groundwater: prevention and cure. However, there is no particular therapy for chronic As exposure that is more frequently caused by the long-term ingestion of contaminated water and food. Many factors can affect the bio-accessibility, metabolism, and toxicity of As, such as chelation mechanisms, diet, and nutrition. Measures are urgently required to focus on reduction in As toxicity, early diagnosis, and therapy of As-induced outcomes. Treatment options advocated are chelation therapy, vitamin and mineral supplements, and antioxidant therapy (Nurchi et al. 2020; Ratnaike 2003).
In the present review, after the description of the multiple causes of As exposure and the related clinical features, a particular focus is given on updated knowledge of the treatments/interventions on As poisoning through chelation therapy, natural dietary supplementation, nutritional interventions. Moreover, we provide indications to decrease the disease impact through counseling and proper nutritional education.
Routes of arsenic exposure
Environmental and anthropogenic causes
Large environmental amounts of As are coming both from natural and anthropogenic sources, the latter being predominant due to extensive metal mining and smelting activities (Ravenscroft et al. 2011).
Arsenic is the 53rd most abundant element and is widely distributed in the earth's crust in many minerals, often together with other metals in sulfide ores as MAsS or MAs2 (Mandal and Suzuki 2002; Smedley and Kinniburgh 2002). Although the content of As in the earth's crust is only 0.0005%, this element is part of more than 200 different mineral forms. The main mineral hosts of As are sulfides, as arsenopyrite (FeAsS), orpiment (As2S3), and realgar (As4S4) (Garelick et al. 2008). FeAsS, with 46% As content, is the leading industrial mineral (Wang and Mulligan 2006). As is also widely distributed in nature in the form of arsenite (As2O3) and arsenate (As2O5). Small As concentrations are often associated with lead (Pb), copper (Cu), and silver (Ag) ores. When the minerals are smelted, gaseous As is trapped and transformed in arsenic trioxide (As2O3). Thus, As2O3 is mainly obtained as a by-product of the smelting of Cu, Pb, or gold (Au) ores, from which the most commercially available As compounds are obtained (Pinto and McGill 1953). In China, the Philippines and Peru, As has been recovered from orpiment and realgar, in Chile from copper–gold ores, whereas it is associated with Au occurrences in Canada and cobalt arsenide in Morocco. In 2018, the average annual global production of As was approximately estimated in 35,000 metric tons, with China (24,000), Morocco (6000), Namibia (1900), and Russia (1500) as the world leaders in As2O3 production (USGS 2019). In the past decades, As production increased by 25% every 10 years. Consequently, the technogenic pollution by As compounds related to metal processing and burning brown coal poses a critical threat (Garelick et al. 2008).
All around the world, mining-related As contamination of soils, sediments, surface waters, and groundwater has been reported (Costagliola et al. 2008; Gao et al. 2019; Garcia-Sanchez et al. 2010; Garelick et al. 2008; Ravenscroft et al. 2011). Moreover, As is used in alloys mainly in association with Pb or Cu in semiconductors, pigment, glass, car batteries, and enamels. In developing countries, As compounds are widely utilized in agriculture as herbicides, pesticides, and insecticides as sodium arsenate, calcium arsenate, cacodylic acid, and other compounds. Therefore, the use of As-containing chemicals in agriculture transfers this toxic metal into food of both animal and vegetable origin (Han et al. 2003; Upadhyay et al. 2019). Millions of people worldwide are significantly exposed to high As levels contained in meat, fish, grains, and vegetables, health supplement products (herbal-based medicines), as well as through food that has been processed using As contaminated water. Foodborne As exposure causes a significant global burden of human disease (Oberoi et al. 2014). The organoarsenic compounds roxarsone (4-hydroxy-3-nitrobenzenearsonic acid), nitarsone (4-nitrophenyl)arsonic acid), arsanilic acid (4-aminophenylarsonic acid), and carbarsone ([4-(carbamoylamino)phenyl]arsonic acid) are still widely used as feed additives in poultry and swine production as antiparasitics and weight gainers (Nachman et al. 2013, 2017; Zhao et al. 2020). Several As compounds are used as preservatives for wood (arsenate of Cu and chromium), cotton desiccants (arsenic acid), ammunition, and in some pharmaceuticals.
Moreover, tobacco smokers can be exposed to concentrations of inorganic As from tobacco plants that have been cultivated in As rich soil or treated with lead arsenate insecticide. Furthermore, As alone or in the co-exposition with other known or suspected carcinogens results in very high risks of lung or bladder cancer (Ferreccio et al. 2013). The widespread use of As compounds has caused and still leads to numerous chronic and acute poisonings, and for this reason, As is listed as one of ten chemical elements posing significant threats to the global public health (Quansah et al. 2015; WHO 2004).
Arsenic-contaminated aquifers are estimated to affect 300 million people in more than one-third of the countries worldwide (Hassan 2018). Normally, As concentration in natural water is lower than 10 μg/l, which is the standard safety limit recommended by WHO. Water frequently contains less than 1 μg As/l, although some areas of the world have higher levels than 5000 μg As/l. Regions with high As groundwater levels are found in the United States, Argentina, Chile, Mexico, China, Hungary, India, Taiwan, Bangladesh, and Vietnam (Naujokas et al. 2013; Smedley and Kinniburgh 2002). Countries such as India and Bangladesh admit, in the absence of an alternative water source, the limit of 50 μg As/l.
Use of arsenic in medicine
It is well established that As is a traditional poison responsible for various human diseases, including cancer as well as deleterious effects on the urinary bladder, lung, kidney, and skin. Beyond these effects, As-based preparations have been shown to possess beneficial therapeutic properties. The medical use of As has been known since at least 4000 years ago, and even today, some As compounds are administered and used in several countries. Historically, arsenic trioxide has been applied in traditional ancient Chinese medicine and later in western medicine. In the middle of the nineteenth century, As-based preparations were the first effective chemotherapy agents against syphilis, parasites, and leukemia (Au 2011). Since 1845, Fowler’s solution, which contains 1% potassium arsenite (KAsO2), has been used to treat leukemia, chronic bronchial asthma, malaria, and psoriasis (Ho and Lowenstein 2016). Until the late 1950s, its use continued in the US for the treatment of syphilis, malaria, and other diseases (Jolliffe 1993). Preparations also based on organic As compounds have also found clinical application due to their positive therapeutic effects. For instance, arsenobenzene has been administered to treat protozoal infections. Arsphenamine (salvarsan, 4,4′,4″-(1,2,3-Triarsirantriyl)tris(2-aminophenol)) has been used to treat syphilis. A significant disadvantage of the As-drugs is related to their high toxicity, as the induction of severe side effects already mentioned (Cooper et al. 2007; Liu et al. 2020). Nowadays, chronic and fatal acute As poisoning from traditional Chinese medicine use is still a threat (Chang et al. 2018; Wu et al. 2013; Zheng et al. 2019). In a clinical case of a Chinese man suffering from fatigue, weakness, numbness, together with hyperkeratosis in his hands and feet, the inorganic As level in urine was more than 120 times higher (1235 µg/l) than normal. The patient reported consuming for 5 years homemade traditional “herbal balls” containing up to 80 ingredients, comprising As (Spilchuk and Thompson 2019). The homeopathic drug “Arsenicum album 30C”, for which a scientific debate continues particularly in India about its effectiveness in treating different disease states [as in ameliorating the health condition from chronic As poisoning (Mallick et al. 2003)], is currently advertised in the preventive and prophylactic treatment against the dangerous and contagious epidemic coronavirus COVID-19. Such a drug is made by sequential centesimal dilution of arsenic trioxide mother solution for thirty times until there is not a trace of As in solution or even a single water molecule that has encountered any of the original As atoms. Scientists globally consider homeopathy as a scientifically failed medical practice (Ernst 2002) and reject that “Arsenicum album 30C” can act against the new virus. Furthermore, these claims can be counterproductive in dealing with a serious health emergency, and they can lead to potentially dangerous consequences, i.e., cases of acute As poisoning for those people who might think of preparing homemade As-based drugs without proper dilution.
Nevertheless, the current interest in the application of As-based drugs as therapeutic remedies in medicine is particularly flourishing and precisely focused in the cancer research area (Alipour et al. 2019; Wahiduzzaman et al. 2020). In 2001, US FDA and in 2002 EU commission approved an arsenic trioxide drug for its high effectiveness in the treatment of acute and promyelocytic leukemia (Au 2011; Chen et al. 2011; Iland and Seymour 2013; Liu et al. 2012). Recently As2O3 has also been proposed as a promising candidate for lung cancer treatment, alone or in combination with the classic cisplatin drug (Huang and Zeng 2019; Medici et al. 2015; Miodragović et al. 2019; Yang et al. 2019). The synergic effect of As2O3 with a B cell lymphoma-2 (Bcl-2) family inhibitor (ABT-737) in uterine cervical cancer cells was also evidenced to ameliorate ABT-737 target therapy (Hsin et al. 2019). Recently, a controlled-release of As2O3 by multifunctional nanoparticles strategy (nano-ZrO2 carriers with mitochondrial targeting) in order to improve the treatment of hepatocellular carcinoma and reduce the toxic side effects, has been investigated with positive results (Wu et al. 2020). Arsenene nanosheets have been proposed as biosafe new therapeutic agents for acute promyelocytic leukemia cells (Wang et al. 2019). Arsenic sulfide (As4S4) has been suggested as a potential antitumor agent for gastric cancer since it effectively inhibits human gastric adenocarcinoma cell line proliferation by inducing apoptosis both in vitro and in vivo through a p53-dependent pathway (Zhang et al. 2015). Mild or moderate side effects are common (10–30%), but severe and sometimes fatal complications can occur when As exceeding toxicity thresholds. Therefore, the administration of these drugs should be evaluated when beneficial effects outweigh metal toxicity. The development of new strategies employing the use of As-based drugs in coated NPs systems provides a promising alternative for safe and effective tumor treatment (Lian et al. 2019). However, consideration of the individual genetic predisposition, co-exposure to other toxins, diet, and particularly vulnerable neurological conditions should be taken carefully into account in prescribing these treatments (Bjørklund et al. 2020).
Arsenic in chemical weapons
From World War I and particularly during World War II started the era of the use of chemical poisoning weapons, including toxic As compounds. Figure 1 reports the list of the most used As-based blister or vesicant, vomiting, and blood agents used as chemical weapons to date (Hoenig 2007). These very last warfare agents affect the body by being absorbed into the blood with the routes of inhalation or ingestion. All these As-based agents possess the characteristics of high toxicity, rapidity of action after environmental distribution, and long persistence (Li et al. 2016).
The most famous poisonous substance, 2-chlorovinyldichloroarsine (Fig. 1), known with the common names of Lewisite (Germany), L (USA), and P-43A (Russia), is a colorless liquid with an irritating geranium odor acting as a powerful blister agent and lung irritant. The boiling point of Lewisite is + 190 °C, which allows it to be classified as a persistent toxic substance. The freezing point is − 45 °C, meaning that there are no climatic restrictions on its use in different seasons of the year. In summer, its poisonous properties remain on the ground for 4–12 h, while in winter, several days. The volatility at 20 °C is 4.5 g/m3, and since the vapor is heavier than air, it will settle in low-lying areas. Lewisite causes damage both in the drip-liquid state and in the form of steam or fog. Following contact and aerosol exposure, its toxic properties occur in the skin, lungs, and eyes, while in the case of penetration into the gastrointestinal tract, abdominal pain, nausea, vomiting, diarrhea, and anorexia occur. The skin-resorptive LD50 for humans is 20 mg/kg. By absorption through the skin, Lewisite causes general intoxication of the body. The most sensitive organs to the action of vapors are the eyes and upper respiratory tract. The threshold concentration causing eye irritation is 0.002 mg/l. Severe eye irritation and damage to the upper respiratory tract occurs after 15 min at a Lewisite concentration of 0.01–0.03 mg/l. The relative toxicity of Lewisite during inhalation LCτ 50 is 1.3 mg/l/min (Goldman and Dacre 1989; Hoenig 2007; NIOSH 2011; Dyadchenko et al. 2018).
In 1941, As pollution of the Black Sea waters was due to the flooding of containers of Lewisite and other warfare agents (sometimes mixed to alter their properties for military effectiveness). The Black Sea is the world's largest natural anoxic closed water basin with a very high degree of isolation, which causes persistent pollution from numerous sources. Economic activity such as fishing, collection of rapans and mussels, common sources of local food, is usually carried out also in the contaminated areas. Therefore, there is a severe risk to the health of the population living around these regions. The concentration of As in seawater of Kerch Strait (the strait connecting the Black Sea and the Sea of Azov) ranged from 4.58 to 132 mg/l in 2007, and from 0.21 to 6.27 mg/l in 2008 (Prokhach and Mykhalska 2009). In 2010, the deadline for the destruction of container shells expired, and toxic substances started leaking into the sea.
As of 7 June 2010, only 113 containers of yperite (sulfur mustard, 1-chloro-2-[(2-chloroethyl)sulfanyl]ethane) and Lewisite were deactivated of the 1200 flooded ones in 11 sites along the coast of the Crimean peninsula. Near the Swallow’s Nest, where 24 barrels were flooded, some of the containers were destroyed; and due to their As content, the water exceeded the norm by more than 100 times (Samar 2013). Conversely, in a study devoted to the determination of toxic metals, including As, in selected Black Sea fish species in the Bulgarian region (sampling season 2010) gave encouraging results within acceptable limits for human consumption and decreased total metal concentration according to the analysis performed in the period 2004–2006 (Makedonski et al. 2017).
Currently, chemical warfare agents are destroyed via chemical neutralization processes or high-temperature incineration. Before the international treaty “Convention on the Prevention of Marine Pollution by Dumping of Wastes and Other Matter”, signed in 1972 in London by a majority of nations, millions of tons of munitions have been disposed throughout the world's oceans determining an environmental risk for its natural resources (Bełdowski et al. 2016; Czub et al. 2018; Edwards and Bełdowski 2016; Szubska 2018). The current use of chemical weapons poses a serious threat to people from short to a long spread of As in the environment. Most states have joined the Chemical Weapons Convention (Convention on the Prohibition of the Development, Production, Stockpiling and Use of Chemical Weapons and on their Destruction), which obligates the destruction of all chemical weapons by 2012 (OPCW 1992). However, about 25 nations currently possess weapon stockpiles or are suspected of secretly stockpiling or possessing chemical weapons research programs. In Syria, for example, at least four plants for the production of toxic substances as weaponries have been counted. The access to weapon stockpiles by terrorists or accidental exposure could be highly dangerous for people and the environment. In July 2012, Syrian authorities officially recognized the availability of chemical weapons in the country, and according to the United Nations, their stocks reached thousands of tons before the Civil War. From 2013 to the end of 2016, chemical attacks took place in the suburbs of Damascus and in the Hama provinces (2014), in Idlib (2014 and 2015), Homs (2015) and Aleppo (2016).
Clinical features of arsenic toxicity
The toxic mechanism for As is explained by its ability to block sulfhydryl (–SH) groups in enzymes and other biologically active compounds and thus disrupt the biochemical processes of metabolism. In addition, As can replace iodine (I), selenium (Se), and phosphorus (P) (Hughes et al. 2011). As exhibits its toxicity by causing lipid peroxidation, inactivating up to 200 enzymes, especially those involved in cellular energy processes, as well as in DNA synthesis and reduction.
In acute As exposure, a metallic taste occurs in the mouth with a slight odor of garlic in the breath and dysphasia, followed by nausea, vomiting, burning in the stomach and esophagus, abdominal pain, and diarrhea. Moreover, cyanosis, hypoxic encephalopathy, convulsions, acute tubular necrosis, cardiovascular, and respiratory symptoms such as hypotension, pulmonary edema, and heart failure can occur. Death follows in the first few hours from shock or some days later from acute renal or liver failure (Fowler et al. 2015) (Fig. 2).
Prolonged As poisoning has a wide range of clinical features and leads to multisystemic diseases (Fig. 2). In a chronic As poisoning, the element accumulates in liver, kidneys, heart, and lungs, muscle tissues, nervous system, gastrointestinal tract, spleen, and other tissues containing keratin. After about 2 weeks since As ingestion, it starts to deposit in the hair and nails. The highest concentration of As is observed in the kidneys and liver (Fowler et al. 2015). Cases of encephalopathy and peripheral neuropathy have been reported (Berbel-Garcia et al. 2004). Because of biochemical transformations of the absorbed As, monomethylarsonic and dimethylarsinic acids are formed in the liver, which are less toxic. About 50% of the absorbed dose can be excreted in the urine in 3–5 days (Abernathy et al. 1999; Ratnaike 2003; Thompson 1993).
Arsenic causes myocardial injury, cardiac arrhythmias, and cardiomyopathy by reducing the activity of antioxidant enzymes of the heart, namely superoxide dismutase, catalase, glutathione S-transferase, glutathione reductase and glutathione peroxidase (Manna et al. 2008). Toxic polyneuropathy and peripheral neuropathy often occur. Tetraplegia or paresis develop with the prevalence of lesions of the peroneal muscles. In rare cases, there are injuries of the individual cranial nerves: facial, trigeminal, vagus, and sublingual ones. Toxic polyneuropathy is usually accompanied by pronounced vegetative trophic disorders: hyperkeratosis, over-exfoliation of the skin on the extremities, hair loss, ulcerative processes on the gums, and vasomotor disorders. The development of clinical symptoms of toxic polyneuropathy initially occurs with symptoms of irritation of the nerve trunks. This leads to sharp pains in the extremities, accompanied by the phenomena of hyperpathia, ataxia, and a marked decrease in vibrational sensitivity. The progressive development of movement disorders, muscle weakness, and paresis can lead to complete paralysis. Behavioral changes, obfuscation, and memory loss are also observed. It has also been reported psychoses due to As poisoning (Fajzulina and Atamanjuk 2007; Jomova et al. 2011; Schenk and Stolk 1967; Wu et al. 2017). Epidemiological evidence indicated that low dose chronic exposure to As, especially in the form of arsenite, increases the risk of developing skin, kidney, bladder, liver, lung, and prostate cancer (Arita and Costa 2009; Benbrahim-Tallaa and Waalkes 2008). Since arsenite is weakly mutagenic, carcinogenesis may be mediated by epigenetic mechanisms, as in the case of other carcinogens (Chervona et al. 2012; Peana et al. 2013; Zoroddu et al. 2010).
Both inorganic and organic As compounds pass the human placenta in late pregnancy, where they accumulates as well as in the fetus. Existing studies on the effects of As in high doses indicate a risk for pregnancy, whereas the effects in small doses start to appear in the literature (Milton et al. 2017). As-containing compounds cause an abnormal pregnancy outcome in experimental animals at sufficiently high levels. Abnormal pregnancy outcomes, including miscarriages, stillbirths, and infant deaths have been reported in communities that consumed drinking water with As concentrations above 50 ppb (µg/l) and often above this level (Amadi et al. 2017; Concha et al. 1998; Rahman et al. 2019). Epidemiological studies of areas with high levels of As in drinking water indicate an association between in utero As exposure and the development of adult diseases such as cancer, chronic pulmonary disease, cardiovascular disease, and diabetes (Sanchez et al. 2016; Steinmaus et al. 2014; Vahter 2008; Young et al. 2018).
Urinary As concentration is used to quantify and monitor recent As poisoning. Analyses of blood, hair, and fingernails samples are also good indicators of exposure. Because of the short half-life of As in blood, hematological estimation is useful in particular in the diagnosis of acute intoxication. Inorganic As incorporates into hair and fingernails due to its affinity to the sulfhydryl groups in keratin. The metal deposition requires at least 2 weeks after exposition to appear. In chronic poisonings, As levels found in hair samples are in the range 0.1–0.5 mg/kg, while in acute poisonings, the As concentrations reach values between 1.0 and 3.0 mg/kg. Another common clinical manifestation of chronic As exposure is the appearance of Mee’s lines in the nails. Hair and nail tests are particularly useful to determine the level of As exposure in the previous 6–12 months (in these case, long hair are needed to define the history associated with exposure). Other key characteristic features as skin lesions, melanosis, keratosis, and pigmentation are often used for diagnosing chronic As poisoning since they usually develop from 5 to 10 years after initial exposure. Analytical methods used to measure As levels are based on anodic stripping voltammetry (ASV), atomic absorption spectroscopy (AAS), radiochemical methods, X-ray spectroscopy, high-performance liquid chromatography-atomic fluorescence spectrometry (HPLC-AFS), inductively coupled plasma-optical emission spectroscopy (ICP-OES), inductively coupled plasma-mass spectrometry (ICP-MS), or graphite furnace atomic absorption spectrometry (GFAAS) (Caussy 2006; Keil et al. 2011; WHO 2001).
Fundamental principles for application of chelation therapy and major arsenic chelating agents
The employment of chelation mechanisms in the treatment of arsenical intoxication began during World War II, with the synthesis of British Anti-Lewisite antidote (BAL). Chelation therapy is considered as an efficient and well-known primary treatment for As poisoning as well as other toxic metals (Gerhardsson and Kazantzis 2015; Kazantzis 2007; Nurchi et al. 2019). Chelation is a chemical event in which what is called a ligand binds metal atom/ion via a coordination bond in a cyclic or ring-like structure. A ligand is an ion or neutral molecule that has two or more donor atoms capable of donating a pair of electrons and forming a covalent bond with the metal ion. Good chelating agents form chemically inert and non-toxic metal complexes. Chelating agents should rapidly and easily be excreted from the body by glomerular filtration, and about 50% appears in the urine within 1 h without any further interaction with the vital organs (Gerhardsson and Kazantzis 2015). They can also enter the cell membrane to remove intracellular toxic metals. A good chelating agent can compete with endogenous ligands and must have a relatively higher affinity and selectivity for toxic metals than for the desired and essential body metals, whose homeostasis must not be disturbed (Aaseth et al. 2016b; Crisponi et al. 2015; Kim et al. 2019).
Nonetheless, chelation can lead to the removal of not only toxic metals but also the essential ones, or cause a redistribution of toxic metals into other tissues or organs, such as the brain (Aaseth et al. 2016a; Lachowicz et al. 2018). Chelators are routinely used in the treatment of the overload of essential elements, such as in the case of transfusional siderosis in thalassemic patients, and also in some other hemoglobinopathies (Nurchi et al. 2016). Some chelators may also have toxic effects or exert severe side effects per se (Crisponi et al. 2015; Kazantzis 2007). Chelation therapy for As toxicity is thought to be the specific therapy for the relief of systemic clinical manifestations and reduction of As stores in the body, which subsequently reduces several severe outcomes and cancer risk. Chelation prohibits As from interacting with biological targets like proteins and DNA and facilitates its removal from the body (Flora et al. 2007; Kosnett 2013).
One of the mechanisms involved in the pathogenesis of As-mediated toxicity is associated with its high affinity to thiol groups in molecules, Cysteine-rich motifs on proteins, and enzymes such as metallochaperones and zinc fingers (Pfaff et al. 2019; Shen et al. 2013; Shi et al. 2004). Monomethylarsenite strongly inhibits pyruvate dehydrogenase (PDH) and α-ketoglutarate dehydrogenase (KGDH) complex, whereas inorganic arsenite exerts a more significant effect to PDH. This has been attributed to the affinity of the metalloid to the proximal 1,3 sulfhydryl groups of the lipoic acid, cofactor of PDH and KGDH, whose inhibition has a deleterious effect on cellular respiration due to the indirect and direct roles of these enzymes in the citric acid cycle (Bergquist et al. 2009). Based upon thiol affinity, exposure to arsenite also decreases the cellular concentration of reduced glutathione (GSH) and results in cellular redox imbalance (Jomova et al. 2011; Rubino 2015). It was reported that N-acetylcysteine (NAC) (Fig. 3) as a thiol-containing antioxidant decreased As-mediated oxidative damage and NAC reduction of As poisoning may be carried out thanks to the improvement of the GSH/GSSG ratio and through chelation in U937 monocytes and macrophages (Ghani et al. 2014; Rossignol 2019).
During arsenite stress in Saccharomyces cerevisiae, two key residues in histone proteins H3 and H4 have been identified which are important for the regulation of Hog1 (Mitogen-activated protein kinase) signaling, Fps1 activity (aquaglyceroporin), and ACR3 (arsenical resistance-3 family) expression (Thakre et al. 2020). These are H3K4 and H4K16, both targets of methylation and acetylation processes, whose disruption has been involved in gene dysregulation and cancer genesis (Zoroddu et al. 2010).
Chelating agents commonly used against As poisoning are specifically thiol chelators like 2,3-dimercaptopropanol, meso-2,3-dimercaptosuccinic acid, and its derivatives sodium 2,3-dimercapto-1-propanesulfonate (DMPS, unithiol), and 3-Mercapto-D-valine (Penicillamine, PCA) (Fig. 3) (Aaseth et al. 2016a; Flora et al. 2007).
The right choice of a chelator (alone or in combination) suitable for As treatment and its proper dosage is of great significance in order to obtain the desired result and minimize the side effects. For acute As poisoning, the aforementioned chelating agents have been applied, whereas effective treatment of chronic As toxicity has not been established yet, though some studies showed satisfactory results in response to the use of DMPS.
BAL
British Anti-Lewisite (BAL) (2,3-dimercaptopropanol) (Fig. 3) was synthesized as a specific antagonist to the vesicant arsenical war gas Lewisite during World War II. It is used as a chelator in chronic As poisoning where the signs of arsenicosis are severe, or the patient has complications (Mathieu et al. 1992). Currently, the clinical use of this drug is restricted for acute As intoxications to only the initial treatment, because of its toxicity and the necessity of frequent painful parenteral administrations (Nurchi et al. 2020). BAL is formulated in peanut oil because of its lipophilic nature and administered intramuscularly at an initial dose of 3–5 mg/kg of body weight every 4 h. This chelating agent demonstrated high systemic distribution and ability to compete effectively with the thiol groups of proteins for binding the As ion (as well as Au, Hg, and Pb), which is then excreted in the urine. This therapy is frequently effective in preventing or neutralizing systemic toxicity, but severe side effects occur. These include hypertension, nephrotoxicity, and the propensity to concentrate As in several organs, including brain and testes (Yadav and Flora 2016).
In most cases, the degree of recovery from neuropathy, aplastic anemia, encephalopathy, and jaundice is limited and directly related to the initial severity of the systemic involvement and the rapidity with which chelation therapy is initiated. When symptoms such as melanosis and keratosis, appear on the skin, BAL, as well the other chelating agents as penicillamine, DMSA and DMPS, support melanosis clearance together with mechanical scraping with the help of urea in cream or Vaseline, followed by 6–10% salicylic acid, for smoothening of skin (Saha 1995). Symptomatic treatment with antibiotics should be implemented when internal complications occur as organ dysfunctions or histological, histochemical abnormalities (Saha et al. 1999). The development of safer agents has rendered BAL almost obsolete except for sporadic cases (Gerhardsson and Aaseth 2016).
DMSA and its derivatives
DMSA is an effective antidote to many toxic metals and metalloids, including As, and is well-tolerated with relatively rare adverse effects (Bjørklund 2015; Bradberry and Vale 2009; Chang et al. 1996; Dart et al. 1994; Maiorino et al. 1989). DMSA is generally administered orally at 8–50 mg/kg/day therapy doses (Chang et al. 1996). DMSA hydrophilicity limits its access to intracellular compartments and is consequently distributed mostly in the extracellular fluid (Bradberry and Vale 2009). It has limited bioavailability and is mostly found covalently bound to plasma proteins with a half-life in humans lower than 4 h (Dart et al. 1994). Of an orally administered dose of DMSA, 10 to 25% is excreted in the urine, the majority within 24 h (Maiorino et al. 1989; Sears 2013). The remainder is primarily eliminated in the feces (Chang et al. 1996; Sears 2013). In a randomized placebo-controlled trial involving 22 patients, DMSA was not effective in the development of any clinical or biochemical benefit or histopathological improvement of skin lesions in patients with chronic arsenicosis (Guha Mazumder et al. 1998). DMSA, as well as BAL, causes Zn and Cu depletion. Some sporadic adverse effects (4% of the patients) are related to skin lesions as papular and herpetic rashes, mucocutaneous eruptions, and pruritus.
A list of DMSA derivatives, manifesting least toxicity and exhibiting better permeability across cell membranes, have also been developed and are currently in different phases of clinical and pre-clinical trials. These include monoisoamyl DMSA (MiDMSA), monocyclohexyl DMSA (MchDMSA), and monomethyl DMSA (MmDMSA) (Fig. 3).
MiDMSA is a derivative that retains a high As affinity through its sulphydryl groups and does not redistribute it, as DMSA, to other organs. The lipophilic nature of MiDMSA enables it to chelate both extracellular and intracellular toxic metal ions, which aids in the removal of As from the cytosol and organelles (Aaseth et al. 2015; Pachauri et al. 2013). The concomitant use of DMSA with these long carbon chain analog, as MiDMSA or MchDMSA, showed an improved efficiency in reducing As levels and alleviating oxidative stress when compared to DMSA alone (Bhadauria and Flora 2007; Kosnett 2013; Mishra et al. 2008; Modi and Flora 2007). Nowadays, one of the strategies in the treatment of As poisoning is also the co-administration of antioxidants (Flora and Pachauri 2010). It has been observed that the combined administration of NAC with MiADMSA was more effective than MiADMSA monotherapy against chronic As poisoning in guinea pigs (Kannan and Flora 2006).
DMPS
DMPS, whose synthesis was first reported in 1956, is capable of forming complexes with a number of metals and metalloids and has been used and proven effective in the treatment of heavy metal poisonings but the efficacy for treating acute As poisoning is limited (Aposhian et al. 1997; Kalia and Flora 2005). DMPS is not able to cross the blood–brain barrier, contrary to BAL. Consequently, it does not redistribute As to the brain (Gerhardsson and Aaseth 2016; Jones 1995). The excretion of DMPS and its metabolites is relatively fast. Within 5–6 h, about 80% is excreted in the urine (Bjørklund 2015). The oral absorption of DMPS is significantly higher than DMSA (Sears 2013). Other administrations are through intravenous, rectal, and transdermal routes. In acute As poisoning, intravenously administration of NAC demonstrated better therapeutic efficacy than intramuscular DMPS (Martin et al. 1990). After intravenous injection of DMPS, the half-life in plasma is 30–45 min, and its metabolites are rapidly eliminated from the body through the kidneys within 2 h (Aposhian et al. 1986).
Some adverse effects during treatment with DMPS include gastrointestinal problems, skin reactions, mild neutropenia, and elevated liver enzymes. As BAL and DMSA, also DMPS enhance Cu and Zn urinary excretion, which in some patients give deficiency symptoms (Flora and Pachauri 2010; Kosnett 2004). The trace elements Cu and Zn are both antagonists in function and essential for living cells (Bjørklund 2013; Chasapis et al. 2012; Zoroddu et al. 2019). Consequently, monitoring their concentrations during chelation treatment is required (Lachowicz et al. 2015). In particular, DMPS influences the mineral equilibrium of the body more than DMSA and is more toxic (Aposhian et al. 1989). Therefore DMSA should be preferred to DMPS (Kazantzis 2007). However, for the treatment of As poisoning in patients with anuria, DMPS is probably the safest and most effective chelating agent, while DMSA should not be used (Hsiao et al. 2019).
PCA
D-Penicillamine (3-Mercapto-D-valine, PCA) (Fig. 3) is an amino acid that contains an additional SH group and belongs to the class of stable non-physiological amino acids; it is a structural component of the penicillin molecule from which is obtained by hydrolysis. PCA is capable of forming non-toxic, water-soluble chelated compounds with heavy metals, which are then excreted in the urine. Due to the presence of a stable sulfhydryl group, PCA can decompose the disulfide bonds of macromolecular complexes. Historically, PCA was the first chelator used for Wilson's disease because of its affinity for Cu (Walshe 1956). It also mobilizes As, but it is not generally a drug of choice (Hall 2002). In the clinical case of poisoning with As, which developed after the administration of contaminated Ayurvedic drugs, the state of patients was improved after the withdrawal of the medications and treatment with PCA (Pinto et al. 2014). Although, in this case, the patient's condition was improved, the effectiveness of PCA for treating As poisoning is contradictory. It has been reported that in animal experiments, the effectiveness of PCA with respect to As toxicity has not been confirmed (Aposhian et al. 1981; Hilmy et al. 1991; Kreppel et al. 1989).
The great advantage of this drug is that it may be orally administered and is well absorbed from the gastrointestinal tract. The peak of plasma concentration is observed 1–4 h after oral intake. PCA has, however, a high frequency of side effects, although this is a minor problem when the body contains large As amounts. Side effects of PCA administration include fever, lymphadenopathy, neutropenia, thrombocytopenia, proteinuria anorexia, nausea, joint pain, allergic reactions, and other phenomena that occur quite rarely (e.g., peripheral neuropathy, exfoliative dermatitis, polymyositis, dermatomyositis, and alopecia) (Friedman 1977; Kreppel et al. 1989; Schardein and Macina 2006).
EDTA
The well-known chelating agent EDTA (ethylenediaminetetraacetic acid) (Fig. 3) has been widely used in medicine, but there is categorically no role for EDTA in As poisoning. The chemical and biological activity exhibited by EDTA is affected by the formation of four or six bonds with its oxygen donors with transition or alkaline metal ions (in particular Ca, Fe, Mn, Cu, Zn, Hg, Pb). The impact of EDTA treatment of disorders associated with pentavalent As poisoning is caused by the effect on paracellular transport. The removal of extracellular Ca2+ causes retraction of the tight-junctional proteins with the formation of large paracellular openings between cells, which leads to a functional increase in permeability of the intestinal epithelium and further removal of arsenical species in Caco-2 cell line as a model (Calatayud et al. 2010). Several side effects are associated with the administration of EDTA including hepatotoxicity, renal failures, respiratory and gastrointestinal symptoms, arrhythmias, tetany, hypocalcemia, hypotension, mucocutaneous lesions, bone marrow depression, convulsions, fatigue, headache, fever, nasal congestion, lacrimation, glycosuria, myalgia, and increased urinary frequency. Moreover, prolonged chelation treatment with EDTA fallouts in the depletion of essential metals as Zn, Cu, and manganese (Mn). One of the negative features of using EDTA in the treatment of chronic As intoxication is its ability to inhibit δ-aminolevulinic acid dehydratase by the removal of Zn from the site and further development of degenerative cellular processes via oxidative stress (Modi and Flora 2007).
NBMI
Recently, NBMI (N,N′-bis-(2-mercaptoethyl) isophthalamide, Emeramide) has been proposed as an alternative to the current chelators (Fig. 3). NBMI has been shown to possess the capacity to penetrate cell membranes and to cross BBB combined with an antioxidant property for scavenging and reducing the toxicity levels of hydroxyl free radicals, dangerous for the normal redox status of the cells. NBMI was first proposed against Hg poisoning but also appears to be, at least in vitro, able to selectively chelate As ions as well as other toxic and non-essential metals such as Pb, cadmium (Cd), and uranium (U) without evidence of toxicity (Schutzmeier et al. 2018). NBMI is based on carboxyl benzoate with two arms made of cysteamine moieties attached to the 1st and 3rd carbon groups of the aromatic ring. The two-SH groups of cysteamines are free to flex and rotate in order to accommodate several toxic soft acid metal ions. Trial phase 1 safety study and phase 2 clinical trials showed no adverse effects in humans (Trial identifier: NCT04183595, Emera008). Currently, NBMI is going through the FDA and the European Medical Agency (EMA) and the drug approval process.
Chelation therapy for arsenic poisoning: a practical approach
Acute As intoxication can occur from the accidental intake of pesticide or insecticide, as the result of medical use of As-based drugs or from intentional poisoning during homicidal purposes as in terroristic attacks or suicide attempts.
In acute As poisoning, metallic taste and dry mouth appear, with difficulty and pain in swallowing. In any way, gastrointestinal disorders occur like colic, nausea, vomiting, which can become irresistible, diarrhea, stool in the form of rice broth with an admixture of blood. The loss of fluids leads to severe dehydration of the body. An increased weakness, headache, dizziness, and decreased body temperature and blood pressure as a result of vascular collapse appear. The occurrence of periorbital edema, visual disturbances, skeletal muscle cramps, oliguria, proteinuria, hematuria is possible. After 8–15 days from the onset of the disease, there is a sharp pain in the extremities, trophic disorders, paresthesia, paresis, with predominant extensor lesions. Death comes from paralysis of the respiratory and vascular centers. In the survivors, there is a severe diffused lesion of the nervous system in the form of toxic encephalopathy (impaired speech, coordination of movements, epileptiform convulsions, hyperkinesia by type of chorea, memory impairment, psychosis), encephalomyelopolyneuritis (Wexler 2000; Ratnaike 2003). In the treatment of acute As poisoning, it is first of all necessary to prevent or minimize its absorption from the gastrointestinal tract; to provide general supportive therapy to aid with breathing, blood circulation, and water-electrolyte balance, and to control the state of the nervous system. The removal of absorbed As may be facilitated by diuresis, bile excretion, hemodialysis, or exchange transfusion (Kazantzis 2007). Arsenic is slowly bound to serum protein ranging from 5.3% (trivalent inorganic As) to 6.5% (pentavalent inorganic As) (Zhang et al. 1998), but has a high volume of distribution (from 3.3 up to 4 l/kg) and rapidly passes from serum to tissues (its half-life in phase I occurs within 1–2 h, where about 90% As redistributes within 3 h) (Lai et al. 2005). Theoretically, there is a therapeutic window in the first few hours after ingestion for early extracorporeal purification of blood without chelation. Nevertheless, the chelator is strongly recommended for all stages of acute As poisoning in patients with anuria, as it always increases the availability of metal in the serum for dialysis (Mathieu et al. 1992) and minimizes the likelihood of further morbidity and mortality. The current recommended treatment for acute As poisoning is the use of specific metal chelators, able to interact with As and to form strong low-toxic complex compounds that are mainly excreted in the urine. Chelation therapy for acute As poisoning is recommended because the benefits exceed the risk of side effects. Even when there are unconfirmed suspicions of As ingestion, the administration of chelating agents is recommended for the prevention of acute renal failure. Thiol-based metal chelators such as DMSA, DMPS, BAL, and PCA are mainly administered in acute As poisoning (Bjørklund 2015; Modi and Flora 2007; Vasken Aposhian et al. 1984). DMPS and DMSA, due to their high water solubility, low toxicity, and high therapeutic indexes, are superior to BAL in the treatment of acute As poisoning and DMPS should be selected as the first choice respect DMSA in both oral and/or parenteral chelation treatment because of its greater antidotal potency (Aaseth et al. 2016a; Kosnett 2013). In acute As poisoning, DMPS is used as a 5% solution for intravenous and intramuscular injection, as well as tablets and capsules for oral administration. The drug is scarcely toxic: LD50 for mice after subcutaneous administration is 5.22 mM/kg (Aposhian et al. 1981). DMPS is well-tolerated, but in some cases of prolonged use, nausea, tachycardia, and allergic reactions may occur. All these effects quickly disappear when the drug is discontinued (Karp and Danova 1997). After 5 h since intravenous administration of DMPS, only 0.9% has been found free, 36.6% is associated with non-protein species. In contrast, the highest amount (62.5%) is found bonded to plasma proteins by a disulfide bond, in particular albumin (84%) and higher molecular weight proteins or aggregates (16%) (Maiorino et al. 1996). It has been suggested that these protein- and non-protein-DMPS species may prolong the chelation activity toward toxic metal ions, representing a reservoir of DMPS, which can be released by disulfide reduction in vivo. In tissues, the maximum concentration of DMPS is detected in the kidneys, the minimum in the brain. It is mainly found in the extracellular fluid, poorly permeating through cell membranes. DMPS is an effective antidote for many inorganic and organic As compounds, including arsenites, arsenates, arylarsenoxides, acetarsolum, etc. (Aposhian et al. 1981; Karp and Danova 1997). DMPS has been shown to reduce the half-life of As from liver tissues by 2.1 times, from whole blood by 12 times, and plasma 1.6 times. The effectiveness of treatment of acute and chronic toxic metal poisoning with one chelating agent is in many cases insufficient, so a number of authors have proposed multi-component poisoning therapy, the advantage of which is the possibility of using several drugs together in lower doses (it leads to the enhancement of overall effectiveness of the combined treatment). For example, when EDTA together with DMPS was given to mice after 1 h since cadmium chloride administration, 100% survival has been observed (Schubert and Derr 1978). The combination of DMSA and MiADMSA, respect to mono-therapy (DMSA alone), has been found to enhance As removal from hepatic tissue and prevent hepatic apoptosis, reducing oxidative stress efficiently, giving lower As concentrations in blood and soft tissues (Mishra et al. 2008). In a recent study, the use of ascorbic acid (vitamin C) and DMSA was evaluated successfully in rats co-exposed to As and fluoride contaminated water. The combination therapy showed reduced As and F burden and oxidative stress (Mittal et al. 2018). The protocols for the treatment of acute poisoning, approved by the Ministry of Health of Ukraine, recommend an internal administration of penicillamine in cases of As poisoning, combining it with Pyridoxine hydrochloride (1; 2.5; 5% solution), followed by gastric lavage (Vlasyk et al. 2009). The beneficial role of the combined chelation therapy with the commonly used iron (Fe) chelators deferasirox and deferiprone was also estimated for As poisoning showing its effectiveness in depleting As concentration from soft tissues in rats (Amiri and Mirhoseiny 2017; Nurchi et al. 2016). Chelation treatment appears a promising therapeutic measure as regards alleviation of symptoms for severe cases of chronic As poisonings (Gerhardsson and Aaseth 2016). In particular, in a study performed with a group of patients suffering from chronic As toxicity due to long term consumption of As-contaminated water demonstrated the efficacy of DMPS with a substantial improvement of neuropathy and lung symptoms respect to the group treated with placebo (Guha Mazumder et al. 2001), whereas DMSA has been found to be unsuccessful (Guha Mazumder et al. 1998).
Natural products as promising chelating and detoxifying agents for chronic arsenic poisoning
The application of natural chemical chelators is one of the traditional methods of removing toxic metals from the body (Bhattacharya 2017). Natural antioxidants found in a correct diet as flavonoids, lipoic acid, carotenoids, vitamin C and E, taurine, gallic acid, curcumin, minerals, amino acids, etc. have shown beneficial effects in counteracting metal toxicity by increasing methylation capacity and free ROS scavenging. Medicinal plants currently attract the scientific interest as potential remedies in case of toxic metal poisoning due to their lesser adverse effects (Mehrandish et al. 2019), since their health benefits for humans are caused by the totality of secondary metabolites, including important antioxidant molecules flavonoids, accompanied by various macroelements and trace elements (Konieczynski et al. 2018) (Table 1). Flavonoids possess a number of properties ranging from in vitro antioxidant and anti-inflammatory effects, ROS scavengers activity, to chelation ability for metal ions (Cherrak et al. 2016; Chirumbolo et al. 2018; Fang et al. 2002; Korkina and Afanas'ev 1997). These polyphenols induce phase II detoxifying enzymes (e.g., glutathione S-transferase) and CYP (Cytochromes P450)-mediated detoxification, which is of significant impact on the inactivation of toxicants (Chirumbolo et al. 2018; Valko et al. 2006). A report on As-induced toxicity in Swiss albino mice treated with naringenin showed significant amelioration in the hematological and serum biochemical profiles and normalization of the hepatic and renal functions (Mershiba et al. 2013; Roy et al. 2014). Other examples include taurine, quercetin, silymarin, rutin, and the mixed polyphenolic flavonoids present in green tea leaves in exerting a protective action against As-caused damage through their antioxidant and chelating ability (Das et al. 2009; Sarkozi et al. 2015; Sharma and Flora 2018).
Besides of secondary plant metabolites flavonoids, herbal drugs, e.g., Hyperici herba, Tiliae flores, and Crataegi fructus, are also important sources of essential elements. Some significant correlations have been determined between the totality of flavonoids and Fe, Zn, and Mn content in the analyzed phytopharmaceuticals (Konieczynski et al. 2018). Total antioxidant capacity depends upon the activities of three enzymes: manganese superoxide dismutase (MnSOD), glutathione peroxidase-1 (GPx1), and catalase, which contribute to the removal of ROS since they are involved in a common detoxification pathway (Bastaki et al. 2006). The GPx1 enzyme functions as a homotetramer with Se and GSH as the cofactors, able to enzymatically reduce hydrogen and lipid peroxides, and result in the formation of oxidized glutathione (GSSG) (Bastaki et al. 2006; Brown et al. 2000; Lubos et al. 2011).
The protective effect of antioxidant trace elements upon simultaneous exposure with toxic metals has been shown on various cell cultures (Binte Hossain et al. 2018). Human selenoproteins protect the cells from damages caused by cellular protein oxidation (Steinbrenner et al. 2016; Zoidis et al. 2018). Selenium counteracts and reduces the toxicity of heavy metals such as Hg, Cd, Pb, and hexavalent chromium in the body (Antonyak et al. 2008, 2018). The relieving action of Se against As toxicity, both in vitro and in vivo has also been investigated. Defense from oxidative injury due to As treatment has been demonstrated as a detoxification pathway by Se supplementation through the selenoproteins upregulation (GPx and thioredoxin reductase) (Rahman et al. 2019). The combination of As and Se enhanced antioxidant defense in As-treated PC12 cells, positively regulating autophagy and apoptosis (Rahman et al. 2018). Selenium-enriched diet caused higher fecal and urinary As excretion and reduction of its residues in kidneys with simultaneous improvement of the GSH levels and health indices in As-treated rats (Sah et al. 2013).
Currently, drug-induced nephrotoxicity is an important concern since the administration of nephrotoxic medicines is unavoidable in modern clinical practice (Kim and Moon 2012). Oxidative stress also contributes to the development of chronic renal disease, as unbalanced lipid peroxidation leads to endothelial dysfunction and loss of plasma SOD and GPx activity and Se levels (Dennis and Witting 2017). Arsenic, interacting with substances consisting of sulphydryl groups, restrains the GSH reductase and produces immoderate ROS in renal tissue (Ghabaee et al. 2017). GSH is involved in detoxification of ROS and xenobiotics via glutathione S-transferase conjugation (Dennis and Witting 2017; Ghabaee et al. 2017). Besides of detoxifying enzymes, processes of ROS scavenging also comprise signaling pathway Nrf2/Keap1/ARE. Some medicines of plant origin are known to be activators of the Nfr2 action (Bjørklund et al. 2018). Treatment with Zn during gestation and lactation developed a protective effect in As-induced (5 mg/kg/day as sodium meta-arsenite) oxidative stress in rats’ renal tissue, which was confirmed by the improvement of the malondialdehyde (MDA) and GSH levels, also as the histopathological changes (Bhardwaj and Dhawan 2019). Zinc improved renal antioxidant status in rats in the models of cyclosporine- and mercuric chloride-induced kidney damage (Ghabaee et al. 2017). The hepatoprotective effect of Zn alleviates chronic As poisoning also in aquatic species (Zhao et al. 2019).
The ameliorative effect of several plants and herbal extracts has been attributed to their antioxidant properties (Oyagbemi et al. 2018; Sharma and Flora 2018; Susan et al. 2019). Several research studies demonstrate the perspectives for application in the treatment of heavy metals poisoning of the following herbal drugs: garlic, milk thistle, cilantro, ginkgo, turmeric, phytochelatins, triphala, some herbal fibers, and green algae (Bhattacharya 2017). Among them, Azadirachta indica (plant, Neem), Nigella Sativa (plant, black cumin), Allium sativum (plant, garlic) and Spirulina (algae) were evaluated in several clinical studies as remedies for As-induced keratosis in humans and were also successful as bioremediators in As exposed aquatic organisms or in reducing As-polluted wastewater (Roy et al. 2017; Sayed et al. 2019). Garlic, onion, leek, and chive, due to their content in organosulfur substances, contribute to detoxification of heavy metals such as Pb and As carried out by the liver (Mehrandish et al. 2019). Curcumin can reduce liver toxicity caused by heavy metals due to its significant antioxidant capacity and chelating ability (Mehrandish et al. 2019). Curcumin-encapsulated chitosan nanoparticles (nano-curcumin) showed to combat As toxicity at a much lower dose compared to free curcumin (Yadav et al. 2012). Recently, synergistic therapeutic effects against As-generated oxidative stress were evidenced by the combinatorial drug delivery strategy employing nano-curcumin and nano-MiADMSA in rats (Kushwaha et al. 2018).
Concluding remarks
Arsenic and its compounds are used in technology and agriculture as pesticides, herbicides, and insecticides in many countries of the world. All this leads to environmental pollution, accumulation of As in groundwater, as well as the contamination of medicinal plants, agricultural products, and food. Cases of accidental or non-accidental poisoning of people by various mineral or organic compounds of As are not infrequent. Chelation therapy is used to treat different types of poisoning. A number of chelating agents are available, in particular, for the treatment of acute arsenicosis, whereas there is still no safe and effective antidote available for treating chronic As intoxication. The above discussion provides an insight into the therapeutic role of classical and new promising chelators in As-induced toxicity. Although there are a variety of chelating agents that have been tested in the treatment of As poisoning, their effectiveness is strongly related to the general health condition of the patient, mode of administration, dose, and resistance to biotransformation. Several strategies occur for the treatment of As poisoning, including monotherapy or a combination of structurally different chelating agents as well as co-administration of natural and synthetic antioxidants. Nano-drug delivery is currently evaluated as a promising future alternative to conventional chelators for its efficacy and safety. Nutritional factors play a critical role in antagonizing free radical species and increasing As methylation. The influence of a correct daily diet and/or the use of nutrient supplements (vitamins, micronutrients, proteins, etc.) helps to reduce the damages caused by arsenicosis and protect from chronic exposure, especially for peoples living in contaminated regions.
Abbreviations
- As:
-
Arsenic
- BAL:
-
2,3-Dimercaptopropanol (British Antilewisite, Dimercaprol)
- DMPS:
-
Sodium 2,3-dimercapto-1-propanesulfonate (unithiol)
- DMSA:
-
Dimercaptosuccinic acid, (Succimer)
- EDTA:
-
Ethylenediaminetetraacetic acid
- EMA:
-
European Medical Agency
- GSH:
-
Glutathione
- GSSG:
-
Glutathione disulfide
- IARC:
-
International Agency for Research on Cancer
- LD50 :
-
Median lethal dose
- MiADMSA:
-
Monoisoamyl 2, 3-dimercaptosuccinic acid
- MnDMSA:
-
Monomethyl DMSA
- MchDMSA:
-
Monocyclohexyl DMSA
- NAC:
-
N-Acetylcysteine
- NBMI:
-
N,N′-Bis-(2-mercaptoethyl) isophthalamide
- NIOSH:
-
National Institute for Occupational Safety and Health
- ROS:
-
Reactive oxygen species
- SOD:
-
Superoxide dismutase
- US FDA:
-
United States Food and Drug Administration
- USGS:
-
United States Geological Survey
- WHO:
-
World Health Organization
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Bjørklund, G., Oliinyk, P., Lysiuk, R. et al. Arsenic intoxication: general aspects and chelating agents. Arch Toxicol 94, 1879–1897 (2020). https://doi.org/10.1007/s00204-020-02739-w
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DOI: https://doi.org/10.1007/s00204-020-02739-w