The aim of this study was the development of analytical methods for the simultaneous determination of 25 selected pharmaceuticals, metabolites, and pesticides, belonging to the various chemical classes, in river sediments and their corresponding surface and ground water with the purpose of monitoring the contamination levels. The methods were based on the solid-phase extraction as the sample preparation method for water samples, and the ultrasonic solvent extraction for the sediment samples, followed by the liquid chromatography-tandem mass spectrometry. High recoveries were achieved for extraction from both water and sediment samples for the majority of analytes. Low limits of detection were achieved for all investigated compounds in the water sample (1-5 ng L(-1)) as well as in the sediment (1-3 ng g(-1)). Applicability of the developed methods was demonstrated by determination of pharmaceutical and pesticide residues in 30 surface water, 44 groundwater, and 5 sediment samples from the Danube River Basin in Serbia. Sixty percent of target compounds were detected in environmental samples. The most frequently detected analytes in river sediments were the pesticides dimethoate and atrazine, while carbamazepine and metamizole metabolites 4-AAA and 4-FAA were the most frequently found in water samples.
The
electrophoretic deposition process (EPD) was utilized to produce
bioactive hydroxyapatite/chitosan (HAP/CS) and hydroxyapatite/chitosan/gentamicin
(HAP/CS/Gent) coatings on titanium. The bioactivity of newly synthesized
composite coatings was investigated in the simulated body fluid (SBF)
and examined by X-ray diffraction, Fourier transform infrared spectroscopy,
and field emission scanning electron microscopy. The obtained results
revealed carbonate-substituted hydroxyapatite after immersion in SBF,
emphasizing the similarity of the biomimetically grown HAP with the
naturally occurring apatite in the bone. The formation of biomimetic
HAP was confirmed by electrochemical impedance spectroscopy and polarization
measurements, through the decrease in corrosion current density and
coating capacitance values after 28-day immersion in SBF. The osseointegration
ability was further validated by measuring the alkaline phosphatase
activity (ALP) indicating the favorable osseopromotive properties
of deposited coatings (significant increase in ALP levels for both
HAP/CS (3.206 U mL–1) and HAP/CS/Gent (4.039 U mL–1) coatings, compared to the control (0.900 U mL–1)). Drug-release kinetics was investigated in deionized
water at 37 °C by high-performance liquid chromatography coupled
with mass spectrometry. Release profiles revealed the beneficial “burst-release
effect” (∼21% of gentamicin released in the first 48
h) as a potentially promising solution against the biofilm formation
in the initial period. When tested against human and mice fibroblast
cells (MRC-5 and L929), both composite coatings showed a noncytotoxic
effect (viability >85%), providing a promising basis for further
medical
application trials.
The possibility of using the protonated methanol-adduct of antimicrobial amoxicillin for its identification and quantification at residue levels has been investigated, since it is impossible to completely suppress the formation of these adducts when methanol is present in the solvent system. This process has been monitored over time and as a function of concentration. It was determined that adducts were instantly formed and that the abundance of the protonated methanol-adduct at m/z 398 increased at the expense of the protonated molecule m/z 366 with storage time. The effect of several common solvents and mobile-phase additives on the ionization efficiency of amoxicillin and the formation of the methanol adduct has also been investigated. It was shown that the mass spectra of amoxicillin were strongly influenced by the solvent in which the analyte is dissolved and by the analyte concentration, as well as by the composition of mobile phase. Methanol was determined to be the best spray solvent, as it provided spectra with the lowest abundance of dimer ions. It was also determined that acetic acid as the mobile-phase additive provided the highest signal intensities, while ammonium acetate should not be used as an additive for the determination of amoxicillin at residue levels. Using high-performance liquid chromatography/electrospray ionization tandem mass spectrometry (HPLC/ESI-MS/MS), fragmentation of the protonated molecules and the protonated methanol-adduct ions, in both positive and negative ion mode, has been performed. The fragmentation was stable and strong product ion spectra were obtained. The linearity of the MS detector response, and that of the chromatographic method, was tested. Due to the linear behaviour it was concluded that the protonated methanol-adduct ion can be used for analytical purposes, i.e. for identification and quantification of amoxicillin at trace levels.
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