J 2004

Využití katalytických reakcí na rtuťové elektrodě pro elektrochemické stanovení metalothioneinů

KIZEK, René, Jan VACEK, Libuše TRNKOVÁ, Bořivoj KLEJDUS, Ladislav HAVEL et. al.

Basic information

Original name

Využití katalytických reakcí na rtuťové elektrodě pro elektrochemické stanovení metalothioneinů

Name (in English)

Utilization of catalytic reactions on mercury electrode for the electrochemical determination of metalothioneins

Authors

KIZEK, René (203 Czech Republic), Jan VACEK (203 Czech Republic), Libuše TRNKOVÁ (203 Czech Republic, guarantor), Bořivoj KLEJDUS (203 Czech Republic) and Ladislav HAVEL (203 Czech Republic)

Edition

Chem. listy, Praha, Česká společnost chemická, 2004, 0009-2770

Other information

Language

Czech

Type of outcome

Článek v odborném periodiku

Field of Study

10405 Electrochemistry

Country of publisher

Czech Republic

Confidentiality degree

není předmětem státního či obchodního tajemství

Impact factor

Impact factor: 0.348

RIV identification code

RIV/00216224:14310/04:00009640

Organization unit

Faculty of Science

Keywords in English

metalothioneins; electrochemical analysis;HMDE; catalytic signals;prenatrium wave; peak H;Brdicka reaction

Tags

Brdicka reaction, catalytic signals, electrochemical analysis, HMDE, metalothioneins, Peak H, prenatrium wave
Změněno: 21/5/2004 20:46, prof. RNDr. Libuše Trnková, CSc.

Abstract

ORIG EN

V originále

Metallothioneins (MTs) belong to a group of oligo- and polypeptides which play an important role in the metabolism of metals in animals, plants and microorganisms. The metabolic function of MTs consists not only in detoxication of an organism but also in the homeostasis of essential metals. This paper reports a novel approach to electroanalysis of MTs. The electrochemical determination of MTs is based on catalytic processes which proceed at very negative potentials on mercury electrodes (from -1.7 V to -1.9 V vs. Ag/AgCl/KCl). These processes accompanied by evolution of hydrogen from supporting electrolyte components, include the Heyrovsky presodium wave and/or Brdicka reaction. It was found that SH groups present in MTs are responsible for catalytic processes. The catalytic signal of a MT at nanomolar concentrations can be detected on mercury electrodes using potentiostatic electrochemical methods. The highest sensitivity in the determination of MTs was observed with a galvanostatic method such as derivative potentiometric stripping analysis (CPSA) which produces the peak H. The coupling of CPSA with the adsorptive transfer stripping technique (AdTS) allows the determination of MTs at a femtomole level in a low amount of sample (5 ěl). Our recent results obtained by AdTS + CPSA show that detection limits for particular MTs can be improved by adding [Co(NH3)6] Cl3 to the sample analyzed. This is probably due to the formation of a complex between [Co(NH3)6] Cl3 and MT. We think that the peak H can be used in physiological studies of metal metabolism.

In English

Metallothioneins (MTs) belong to a group of oligo- and polypeptides which play an important role in the metabolism of metals in animals, plants and microorganisms. The metabolic function of MTs consists not only in detoxication of an organism but also in the homeostasis of essential metals. This paper reports a novel approach to electroanalysis of MTs. The electrochemical determination of MTs is based on catalytic processes which proceed at very negative potentials on mercury electrodes (from -1.7 V to -1.9 V vs. Ag/AgCl/KCl). These processes accompanied by evolution of hydrogen from supporting electrolyte components, include the Heyrovsky presodium wave and/or Brdicka reaction. It was found that SH groups present in MTs are responsible for catalytic processes. The catalytic signal of a MT at nanomolar concentrations can be detected on mercury electrodes using potentiostatic electrochemical methods. The highest sensitivity in the determination of MTs was observed with a galvanostatic method such as derivative potentiometric stripping analysis (CPSA) which produces the peak H. The coupling of CPSA with the adsorptive transfer stripping technique (AdTS) allows the determination of MTs at a femtomole level in a low amount of sample (5 ěl). Our recent results obtained by AdTS + CPSA show that detection limits for particular MTs can be improved by adding [Co(NH3)6] Cl3 to the sample analyzed. This is probably due to the formation of a complex between [Co(NH3)6] Cl3 and MT. We think that the peak H can be used in physiological studies of metal metabolism.

Links

GA203/02/0422, research and development project
Name: Nové směry v elektrochemii nukleových kyselin a jejich aplikace v chemii životního prostředí
Investor: Czech Science Foundation, New trends in electrochemistry of nucleic acids and their applications in enviromental chemistry
IAA1163201, research and development project
Name: Využití adsorptivní přenosové a eliminační techniky pro elektrochemickou analýzu oligonukleotidů a nukleových kyselin
Investor: Academy of Sciences of the Czech Republic, Application of adsorptive transfer and elemination techniques in oligonucleotides and nucleic acids analysis.
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