Cytochrome C biosensor for the determination of trace level arsenic and cyanide compounds

Fuku, Xolile Godfrey

January 2011

In this work, an electrochemical method based on a cyt c biosensor has been developed, for the detection of selected arsenic and cyanide compounds. Boron Doped Diamond (BDD) electrode was used as a transducer, onto which cyt c was immobilised and used for direct determination of Prussian blue, potassium cyanide and arsenic trioxide by inhibition mechanism. The sensitivity as calculated from cyclic voltammetry (CV) and square wave voltammetry (SWV), for each analyte in phosphate buffer (pH= 7) was found to be (1.087- 4.488 ×10-9 M) and the detection limits ranging from 0.0043- 9.1 μM. These values represent a big improvement over the current Environmental Protection Agency (EPA) and World Health Organisation (WHO) guidelines.

Cytochrome c (cyt c)

Boron doped diamond (BDD)

Prussian blue (PB)

Arsenic trioxide (As)

Incubation

Drop coating

Intoxication

Toxicity

Electron-transport chain

Asphyxiates

Cyclic voltammetry (CV)

Square wave voltammetry (SWV)

UV/vis spectroscopy

Cytochrome C biosensor for the determination of trace level arsenic and cyanide compounds

Fuku, Xolile Godfrey

January 2011

Magister Scientiae - MSc / In this work, an electrochemical method based on a cyt c biosensor has been developed, for the detection of selected arsenic and cyanide compounds. Boron Doped Diamond (BDD) electrode was used as a transducer, onto which cyt c was immobilised and used for direct determination of Prussian blue, potassium cyanide and arsenic trioxide by inhibition mechanism. The sensitivity as calculated from cyclic voltammetry (CV) and square wave voltammetry (SWV), for each analyte in phosphate buffer (pH= 7) was found to be (1.087- 4.488 ×10-9 M) and the detection limits ranging from 0.0043- 9.1 μM. These values represent a big improvement over the current Environmental Protection Agency (EPA) and World Health Organisation (WHO) guidelines. / South Africa

Cytochrome c (cyt c)

Boron doped diamond (BDD)

Prussian blue (PB)

Arsenic trioxide (As)

Incubation

Drop coating

Intoxication

Toxicity

Electron-transport chain

Asphyxiates

Cyclic voltammetry (CV)

Square wave voltammetry (SWV)

UV/vis spectroscopy

Desenvolvimento de métodos eletroanalíticos empregando análise por injeção em batelada para a determinação de nafazolina, zinco, feniramina e clorfeniramina em formulações farmacêuticas

Oliveira, Thiago da Costa

24 July 2015

Fundação de Amparo a Pesquisa do Estado de Minas Gerais / In this work we investigated the potentiality of batch injection analysis with square-wave voltammetry (BIA-SWV) detection for simultaneous determination of Zn and naphazoline (NAF) and batch injection analysis with multiple pulse amperometric (BIA-MPA) detection for simultaneous determination of NAF and pheniramine (FEN) or NAF and chlorpheniramine (CLO). In both methods, boron-doped diamond (BDD) was used as working electrode. For the simultaneous determination of Zn and NAF by BIA-SWV, the following conditions have been optimized: supporting electrolyte: acetate buffer 0.05 mol L-1 (pH = 4.7), injection volume: 100 μL, deposition time (Zn): 5 s, deposition potential (Zn) -1.5 V, : 100 s-1, a: 60 mV, ΔEs: 6 mV. Under these conditions, the method showed linear response range between 10 and 60 μmol L-1 for Zn (r = 0.992) and between 3.0 e 21 μmol L-1 for NAF (r = 0.999), high analytical frequency (70 injections h-1) and LOD of 0.126 μmol L-1 and 0.04 μmol L-1 for Zn and NAF, respectively. In the study of repeatability (n = 20), the calculated RSD were 0.98% and 0.97% for Zn and NAF, respectively. The simultaneous determination of NAF and FEN or NAF and CLO by BIA-MPA was performed with the application of three sequential pulses in function of time to the BDD electrode using Britton-Robinson Buffer solution 0.12 mol L-1 (pH = 10.0) as supporting electrolyte. At +1.1 V/50 ms, FEN or CLO was detected (oxidation) without interference of NAF. At +1.3 V/50 ms, both compounds (FEN + NAF or CLO + NAF) were oxidized. The current of NAF can then be obtained by subtraction of the currents detected during application of both potential pulses using a correction factor. The proposed method presented good ability (RSD = 1.7 and 4.0% for FEN and NAF; 2.1% and 3.6% for CLO and NAF, respectively; n=20); high analytical frequency (110 injections h-1), linear concentration range between 16 e 100 μmol L-1 for FEN and CLO (r > 0.996) and between 2 e 15 μmol L-1 for NAF (r > 0.997). The LOD calculated were 0.367, 0.361 e 0.148 μmol L-1, for FEN, CLO and NAF, respectively. The proposed methods were used for determination of these compounds in pharmaceutical samples. The obtained results were statistically similar to that obtained by HPLC (NAF, FEN and CLO) and atomic spectroscopy (Zn). / No presente trabalho investigou-se a potencialidade do sistema de análise por injeção em batelada com detecção por voltametria de onda quadrada (BIA-SWV) para determinação simultânea de Zn e nafazolina (NAF) e do sistema análise por injeção em batelada com detecção por amperometria de múltiplos pulsos (BIA-MPA) para determinação simultânea de NAF e feniramina (FEN) ou NAF e clorfeniramina (CLO). Em ambos os métodos, diamante dopado com boro (BDD) foi usado como eletrodo de trabalho. Para determinação simultânea de Zn e NAF empregando BIA-SWV, as seguintes condições foram otimizadas: eletrólito de suporte: tampão acetato 0,05 mol L-1 (pH = 4,7), volume de injeção: 100 μL, tempo de deposição (Zn): 5 s, potencial de deposição (Zn): -1,5 V, : 100 s-1, a: 60 mV, ΔEs: 6 mV. Nestas condições, o método apresentou faixa linear de resposta entre 10 e 60 μmol L-1 para Zn (r = 0,992) e entre 3,0 e 21 μmol L-1 para NAF (r = 0,999), frequência analítica de 70 injeções h-1 e limites de detecção de 0,126 μmol L-1e 0,04 μmol L-1 para Zn e NAF, respectivamente. No estudo de repetibilidade (n = 20), os DPRs foram calculados 0,98% e 0,97% para Zn e NAF, respectivamente. A determinação simultânea de NAF e FEN ou NAF e CLO por BIA-MPA foi realizada através da aplicação de dois pulsos de potenciais em função do tempo ao eletrodo de BDD usando tampão BR 0,12 mol L-1 (pH = 10) como eletrólito suporte. Em +1,1 V/50 ms, FEN ou CLO foram oxidadas livre da interferência de NAF. Em +1,3 V/50ms, ambos os compostos (NAF + FEN ou NAF + CLO) foram oxidados. A corrente proveniente da oxidação da NAF foi obtida pela subtração entre as correntes detectadas em ambos os pulsos de potenciais com auxílio de um fator de correção (FC). O método proposto apresentou boa estabilidade (DPR = 1,7 e 3,95% para FEN e NAF; 2,1 e 3,6% para CLO e NAF, respectivamente; n=20), alta frequência analítica (110 injeções h-1), faixa linear de resposta entre 16 e 100 μmol L-1 para FEN e CLO (r > 0,996) e entre 2 e 15 μmol L-1 para NAF (r > 0,997). Os limites de detecção foram de 0,367, 0,361 e 0,148 μmol L-1 para FEN, CLO e NAF, respectivamente. Os métodos propostos foram usados na determinação destes compostos em formulações farmacêuticas. Os resultados obtidos com os métodos propostos foram estatisticamente similares aos obtidos por HPLC (NAF, FEN e CLO) ou absorção atômica (Zn). / Mestre em Química

Voltametria de onda quadrada (SWV)

Análise por injeção em batelada (BIA)

Amperometria de múltiplos pulsos (MPA)

Diamante dopado com boro (BDD)

Nafazolina

Zinco

Feniramina

Clorfeniramina

Voltametria

Análise por injeção em batelada

Square-wave voltammetry (SWV)

Batch injection analysis (BIA)

Multiple pulse amperommetry (MPA)

Boron-doped diamond (BDD)

Naphazoline

Zinc

Pheniramine

Chlorpheniramine

Nové přístupy k chemické modifikaci diamantových povrchů / Novel approaches to chemical modification of diamond surface

Bartoň, Jan

January 2020

1 Abstract Diamond is a unique material for its physical and chemical stability. However, many advance applications rely on surface functionalisation. Here, two types of diamond were modified on the surface - thin layer of chemical vapor deposition (CVD) and nanodiamond particles (NDs) high pressure and high temperature (HPHT). The aim of CVD surface modification was to prepare photosensitised, conductive, diamond electrodes for dye sensitized solar cells (DSSC). For this purpose, a thin diamond layer doped with boron was deposited on the silicon wafer. Boron doping provided p-type (semi)conductivity to diamonds. The surface of the diamond was hydrogenated with H-plasma, and a short carbon linker with a protected amino group was UV-photografted to the surface. In another study, a photoconverting dye (P1) was covalently attached to the amine-linker. Furthermore, a dye designed based on donor-π-acceptor (D-π-A) concepts was attached to the surface. Finally, a systematic study was done for differently conductive diamond layer and the underlying silicon wafer These experiments gradually lead to the highest ever reported photocurrents of 6.6 µA cm2 for a flat photosensitised boron-doped-diamond (BDD) electrode. Monomolecular layer surface functionalizations on CVD diamond are difficult to detect or even quantify...