In vitro selection of DNA aptamers and their integration in a competitive voltammetric biosensor for azlocillin determination in waste water.

The uncontrolled usage of veterinary antibiotics has led to their widespread pollution in waterways and milk products. Potential impact of antibiotic residues on the environment and human health such as increased antibiotic resistance of microorganisms and triggering allergic reactions in humans have been reported. In this work, we developed a highly selective and sensitive voltammetric aptasensor for on-step, sensitive and low cost detection of azlocillin antibiotic, one of the broad spectrum ß-lactam antibiotics. The successful selection of DNA aptamers against azlocillin was accomplished using systemic evolution of ligands by exponential enrichment (SELEX) method. Fluorescence-binding assays showed dissociation constant of 55 nM for one of the selected aptamers (Az9). This aptamer was used to construct a competitive voltammetric aptasensor for azlocillin. A limit of detection of 1.2 pg/mL as well as remarkable selectivity against potential interfering agents, including amoxicillin, were achieved. This signal-off competitive sensor takes 30-50 min to complete the quantification of the target antibiotic. The sensor was challenged by detecting the target directly in complex environments such as tap and waste water where good recovery percentages were achieved.

A fast and simple FIA-chemiluminescence method for the evaluation of Roselle flowers as scavenger of the free radicals generated by UV irradiated antibiotics.

This work proposes a new method for the in vitro evaluation of the effect of UV irradiation on the production of free radicals and other reactive species during the photodecomposition of drugs. The method was based on the UV irradiation of antibiotics molecules to generate excited states that undergo to homolytic bond cleavages. These reactive species can be detected by their ability to oxidize the luminol, producing the electronically excited aminophtalate, which decays to the ground state releasing electromagnetic radiation in the visible zone of the spectrum. This method was applied to penicillin G, nafcillin, azlocillin and neomycin dissolved in water. It was found that the intensity of the luminol chemiluminescence emission (CL) was proportional to the concentration and dependent on the molecular structure of these drugs. Under the optimized conditions, it was found that penicillin and azlocillin were the most susceptible to photodegradation, while neomycin sulfate was the less affected by the UV light. It was observed that the addition to the antibiotics dissolutions of a hydro-alcoholic extract of petals of calyxes of Roselle reduced the CL intensity, indicating that the extract was able to scavenge the free radicals in the irradiated drugs. This result suggest that its addition to the antibiotics can help in the protection against the radicals formed during the exposition to solar light of patients treated with topic similar antibiotics.

Crystal structures of penicillin-binding protein 3 in complexes with azlocillin and cefoperazone in both acylated and deacylated forms.

Penicillin-binding protein 3 (PBP3) from Pseudomonas aeruginosa is the molecular target of ß-lactam-based antibiotics. Structures of PBP3 in complexes with azlocillin and cefoperazone, which are in clinical use for the treatment of pseudomonad infections, have been determined to 2.0 Å resolution. Together with data from other complexes, these structures identify a common set of residues involved in the binding of ß-lactams to PBP3. Comparison of wild-type and an active site mutant (S294A) showed that increased thermal stability of PBP3 following azlocillin binding was entirely due to covalent binding to S294, whereas cefoperazone binding produces some increase in stability without the covalent link. Consistent with this, a third crystal structure was determined in which the hydrolysis product of cefoperazone was noncovalently bound in the active site of PBP3. This is the first structure of a complex between a penicillin-binding protein and cephalosporic acid and may be important in the design of new noncovalent PBP3 inhibitors.

Interactions of some commonly used drugs with human α-thrombin.

Adverse side effects of drugs are often caused by the interaction of drug molecules to targets other than the intended ones. In this study, we investigated the off-target interactions of some commercially available drugs with human α-thrombin. The drugs used in the study were selected from Super Drug Database based on the structural similarity to a known thrombin inhibitor argatroban. Interactions of these drugs with thrombin were initially checked by in silico docking studies and then confirmed by thrombin inhibition assay using a fluorescence microplate-based method. Results show that the three commonly used drugs piperacillin (anti-bacterial), azlocillin (anti-bacterial), and metolazone (anti-hypertensive and diuretic) have thrombin inhibitory activity almost similar to that of argatroban. The Ki values of piperacillin, azlocillin, and metolazone with thrombin are .55, .95, and .62 nM, respectively. The IC50 values of piperacillin, azlocillin, and metolazone with thrombin are 1.7, 2.9, and 1.92 nM, respectively. This thrombin inhibitory activity might be a reason for the observed side effects of these drugs related to blood coagulation and other thrombin activities. Furthermore, these compounds (drugs) may be used as anti-coagulants as such or with structural modifications.

Uni-molecular detection and quantification of selected ß-lactam antibiotics with a hybrid α-hemolysin protein pore.

Single-nanopores have recently been used to electrically detect a wide range of analytes. Similarly, using electrophysiology, we demonstrate how a system comprised of an ion channel formed by α-hemolysin (α-HL) and single-cyclic γ-cyclodextrin (γ-CD) molecule permits the detection of, and differentiation between three different antibiotics from the ß-lactam family. Specifically, histograms of the time between the successive binding events, and the residence time distributions of the antibiotic in the γ-CD molecular adapter vary with the antibiotic type. The results show that the association times of amoxicillin, azlocillin, and ampicillin are τ(on) = 2.1 ± 0.2, 2.2 ± 0.3, and 3.1 ± 0.4 ms, respectively. Interestingly, we found that the residence time of the bulkier and negatively charged azlocillin (τ(off) = 0.008 ± 0.0005 ms) is much less than that of ampicillin (τ(off) = 0.07 ± 0.005 ms) and amoxicillin (τ(off) = 0.1 ± 0.02 ms), even though the γ-CD-α-HL complex is anionic selective. The data were also used to estimate the standard free energy of binding between ampicillin to γ-CDs binding (-12 kJ mol(-1) [corrected]). The difference in association times might be due to γ-CDs-imposed steric hindrance or an energetically more expensive desolvation step for the antibiotics to gain access to the binding site in the CD. We suggest that this technique may be used to detect other analytes used in pharmaceutical applications.

Atividade de 3 ureidopenicilinas sobre bacilos gram negativos isolados no Recife / Activity of 3 ureidopenicillins on gram negative bacillus isolated in Recife

O estudo comparativo da atividade da azlocilina, da mezlocilina e da piperacilina sobre 123 cepas de bactérias Gram-negativas isoladas nos hospitais do Recife foi efetuado mediante a determinaçäo das CIM e das CBM pela microtécnica de diluiçäo em caldo. Estas três ureidopenicilinas apresentaram uma boa atividade contra E. coli, Salmonella, Shigella, Proteus indol positivo e Klebsiella. Todas as cepas de Pseudomonas foram sensíveis à Azlocilina e à Piperacilina