Eliana F. C. Simões

Carbon dots from tryptophan doped glucose for peroxynitrite sensing.

Tryptophan doped carbon dots (Trp-CD) were microwave synthesized. The optimum conditions of synthesizing of the Trp-CD were established by response surface multivariate optimization methodologies and were the following: 2.5 g of glucose and 300 mg of tryptophan diluted in 15 mL of water exposed for 5 min to a microwave radiation of 700 W. Trp-CD have an average size of 20 nm, were fluorescent with a quantum yield of 12.4% and the presence of peroxynitrite anion (ONOO(-)) provokes quenching of the fluorescence. The evaluated analytical methodology for ONOO(-) detection shows a linear response range from 5 to 25 μM with a limit of detection of 1.5 μM and quantification of 4.9 μM. The capability of the ONOO(-) quantification was evaluated in standard solutions and in fortified serum samples.

Flow injection analysis for nitric oxide quantification based on reduced fluoresceinamine

A fluorescence flow injection analysis (FIA) methodology for nitric oxide (NO) quantification was optimized by factorial analysis for the lowest limit of detection of nitric oxide. This methodology is based on the reaction of the NO with the non-fluorescent reduced fluoresceinamine given a high fluorescent oxidized fluoresceinamine. Box–Behnken and central composite optimization experimental design methodologies were used. The factors initially analysed by a screening experimental design methodology were the flow rate of the pump (Q), loop volume (L), reactor length (R), reduced fluoresceinamine concentration (CFl) and cobalt chloride concentration (CCoCl2). The response variables under analysis were the maximum fluorescence intensity, response repeatability and peak width. The optimum conditions were: one flow stream FIA configuration, Q = 0.60 mL min−1, L = 100 μL, R = 2 m, CFl = 1.50 mM and without CoCl2. A linear working range between 5 to 40 μM was evaluated with a limit of detection of 1.20 μM. Hydrogen peroxide, superoxide, nitrite and nitrate did not interfere with the NO detection. Good results were found in the quantification of NO liberated by a NO donor at pH 7.4 and in fortified serum samples.

PARAFAC based methods for the analysis of Diltiazem drug excitation emission matrices of fluorescence obtained by a derivatization reaction

A fluorescent derivatization reaction for Diltiazem drug quantification based on the condensation reaction of citric or malonic acid with acetic anhydride, catalyzed by the tertiary amine group of Diltiazem, was developed. Excitation emission matrices (EEMs) of fluorescence of the pure solvent (ethanol), standard and sample solutions following a standard addition methodology were analysed by PARAFAC based methods (PARAFAC, PARAFAC2 and PARALIND) to obtain robust calibration methodologies. The quantification results of the sample were compared with the official US Pharmacopeia high performance liquid chromatography-ultraviolet method (USP HPLC-UV). Although the experimental sets of EEM show linearity deviations all the PARAFAC based methods allow correct robust estimation of Diltiazem concentration in pharmaceutical formulations. The closest results were: derivatization with citric acid and PARAFAC2 six components non-negativity constraint model with a detection limit of 0.088 ppm; and, derivatization with malonic acid and PARAFAC six components non-negativity constraint model with a detection limit of 0.066 ppm for the malonic acid was observed. The simultaneous utilization of the three PARAFAC methods gives further information about the intrinsic structure of the data sets under analysis, i.e., it works as an efficient diagnostic tool for the existence of non-linearity and colinearity.