Copper-Specific Chelators as Synergists to Herbicides:  1. Amphiphilic Dithiocarbamates, Synthesis, Transport through Lipid Bilayers, and Inhibition of Cu/Zn Superoxide Dismutase Activity

Warshawsky, Abraham; Rogachev, Ilana; Patil, Yogita; Baszkin, Adam; Weiner, and Lev; Gressel, Jonathan

doi:10.1021/la010299e

Cited by 26 publications

(10 citation statements)

References 47 publications

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“…Dithiocarbamates form particularly stable complexes with Cu 2þ . They are able to abstract the Cu 2þ cofactor from enzymes, leading to inhibition of enzymatic activity as was shown for the superoxide dismutase [226]. The dithiocarbamate-Cu complexes are membrane-permeable without causing leakages of the lipid bilayer, as was shown by stability experiments with liposomes [226].…”

Section: Hydrophobic Metal Complexesmentioning

confidence: 93%

Chemical Speciation of Organics and of Metals at Biological Interphases

Escher

Sigg

2004

Physicochemical Kinetics and Transport at Biointerfaces

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Section: Hydrophobic Metal Complexesmentioning

confidence: 93%

Chemical Speciation of Organics and of Metals at Biological Interphases

Escher

Sigg

2004

Physicochemical Kinetics and Transport at Biointerfaces

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“…It can be expected, however, that dissociated dodtc is distributed to the aqueous phase at higher pH values. Moreover, amphiphilic dithiocarbamates with longer alkyl chains have relatively lower critical micelle concentrations (cmc) in the range of 10 −6 −10 −7 M [9]. Indeed, %E values were improved when lower dodtc concentrations were employed (Fig.…”

Section: Kinetic Study In the Two-phase Microflow Systemmentioning

confidence: 96%

Extraction of Cu(II) with Dioctyldithiocarbamate and a Kinetic Study of the Extraction Using a Two-Phase Microflow System

Morita

Hagiwara

Hirayama

et al. 2010

SERDJ

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Extraction of Cu(II) with dialkyldithiocarbamates and the extraction kinetics have been studied using a two-phase microflow system. The extraction behavior of Cu(II) with potassium dioctyldithiocarbamate (Kdodtc) was investigated using a batch method to determine the propertes of the synthesized Kdodtc. The extraction ability of dodtc was much greater than that of diethyldithiocarbamate (dedtc) under acid conditions. On the other hand, at higher pH values in the range of 8 -13, the extraction of Cu(II) with dodtc decreased with increasing pH. This phenomenon was ascribed to the formation of micelles and/or an emulsion, which was caused by the amphiphilic properties of dodtc. The extraction kinetics of Cu(II) was investigated using a glass microchip which was connected to microsyringe pumps and a UV/Vis capillary LC detector. The initial rate constant (k app ) determined for dodtc was greater than that with dedtc. From the relationship between the dodtc concentration and k app , it was suggested that the extraction rate was governed by the formation of the dodtc complex at the liquid-liquid interface. IntroductionA large number of extractants have been developed for the separation of metals and removal of toxic metals from waste water. Dithiocarbamate derivatives are well-known as useful chelating extractants for heavy metals in analytical chemistry [1,2]. They have two different forms depending on the pH, namely a neutral form and a dissociated form. A major drawback of the dissociated dithiocarbamate is its protonation in acidic solution and its subsequent decomposition into carbon disulfide and the protonated amine. In non-aqueous solutions, the neutral form of dithiocarbamates is generally soluble and much more stable. To emphasize the extraction ability of dithiocarbamates in acid condtitions, it is convenient to enhance its hydrophobic nature by introducing longer alkyl chains. Although the neutral form of dithiocarbamate with long alkyl groups exhibits no adsorptivity at the interface and undergoes hardly any distribution into the aqueous phase, the dissociated form shows interfacial adsorptivity [3].Herein we report the synthesis and extraction properties of dioctyldithiocarbamate. In particular, the complexation kinetics of dithiocarbamate derivatives at liquid-liquid interfaces is examined by batch solvent extraction and a two-phase microflow system using microchip equipment. From an analytical point of view, use of a microfluidic device reduces the amount of sample required, compared with that for conventional bulk experiments. Another attractive feature of a microfluidic device is the ability to precisely control the contact time of the two phases, or the distribution rate between the aqueous and the organic phase. Thus, the kinetic study using the two-phase microflow enabled elucidation of the factors characterizing the extraction mechanism, such as diffusion, complexation, and transfer through the liquid-liquid interface.

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“…The mechanism of action remains unclear but it is believed that interaction with oxyhemoglobin results in the formation of reactive radicals which spontaneously react with thiols resulting in intracellular glutathione depletion and other intracellular enzyme deactivation. Copper complexes of amino acids show SOD-like activity with those having longchain oligoether substituents being especially active [80] probably relating to their enhanced hydrophobicity. Copper(II) bis(dithiocarbamate) complexes find applications in radiopharmaceuticals.…”

Section: Copper Chemistrymentioning

confidence: 99%

Metal-dithiocarbamate complexes: chemistry and biological activity

Hogarth¹

2012

MRMC

255

157

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Dithiocarbamates are highly versatile mono-anionic chelating ligands which form stable complexes with all the transition elements and also the majority of main group, lanthanide and actinide elements. They are easily prepared from primary or secondary amines and depending upon the nature of the cation can show good solubility in water or organic solvents. They are related to the thiuram disulfides by a one-electron redox process (followed by dimerisation via sulfur-sulfur bond formation) which is easily carried out upon addition of iodide or ferric salts. Dithiocarbamates are lipophilic and generally bind to metals in a symmetrical chelate fashion but examples of other coordination modes are known, the monodentate and anisobidentate modes being most prevalent. They are planar sterically non-demanding ligands which can be electronically tuned by judicious choice of substituents. They stabilize metals in a wide range of oxidation states, this being attributed to the existence of soft dithiocarbamate and hard thioureide resonance forms, the latter formally resulting from delocalization of the nitrogen lone pair onto the sulfurs, and consequently their complexes tend to have a rich electrochemistry. Tetraethyl thiuramdisulfide (disulfiram or antabuse) has been used as a drug since the 1950s but it is only recently that dithiocarbamate complexes have been explored within the medicinal domain. Over the past two decades anti-cancer activity has been noted for gold and copper complexes, technetium and copper complexes have been used in PET-imaging, dithiocarbamates have been used to treat acute cadmium poisoning and copper complexes also have been investigated as SOD inhibitors.

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Copper-Specific Chelators as Synergists to Herbicides: 1. Amphiphilic Dithiocarbamates, Synthesis, Transport through Lipid Bilayers, and Inhibition of Cu/Zn Superoxide Dismutase Activity

Cited by 26 publications

References 47 publications

Chemical Speciation of Organics and of Metals at Biological Interphases

Chemical Speciation of Organics and of Metals at Biological Interphases

Extraction of Cu(II) with Dioctyldithiocarbamate and a Kinetic Study of the Extraction Using a Two-Phase Microflow System

Metal-dithiocarbamate complexes: chemistry and biological activity

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