Removal and toxicity evaluation of a diverse group of drugs from water by a cyclodextrin polymer/pulsed light system.

The presence of pharmaceutical compounds (PhCs) in the effluents of wastewater treatment plants (WWTPs) is an ecological concern. The issue could be alleviated by trapping those substances by cyclodextrin (CD) polymers or photolyzing them by pulsed light (PL). Consequently, a sequential CD polymer/PL system was tested for the removal of PhCs. Firstly, a survey detected the presence of recurrent PhCs in the effluents of local WWTPs. Then, pure water was spiked with 21 PhCs, 100 µg/L each one. The three-dimensional network provides amphiphilic features to the CD polymer that reduced the pollutant concentration by 77 %. Sorption involves a plead of physical and chemical mechanisms hindering the establishment of a general removal model for all compounds. The performed simulations hint that the retention capacity mainly correlates with the computed binding energies, so that theoretical models are revealed as valuable tools for further improvements. The complementary action of PL rose the elimination to 91 %. The polymer can be reused at least 10 times for ibuprofen (model compound) removal, and was able to eliminate the ecotoxicity of an ibuprofen solution. Therefore, this novel sequential CD polymer/PL process seems to be an efficient alternative to eliminate PhCs from wastewater.

Protective effect of cyclodextrins on the quality parameters of roast preserved pepper.

Total phenolics (TP), vitamin C, antioxidant activity and colour of preserved peppers were evaluated at 4, 25 and 50 ℃ storage during 30-day intervals. Except for 4 ℃, TP decreased during storage at 25 ℃ and 50 ℃, being softer for fortified samples with ß-CDs. The protective effect was evident, since 50 ℃ samples containing ß-CDs exhibited lower TP loss (19%) than control samples (38%) for 5 months storage. A decrease in the vitamin C content was observed for both samples as time and temperature progressed. In samples stored at 50 ℃ the protective effect of ß-CD only was evident at the first month, since fortified samples showed lower vitamin C loss (10%) than control samples. The fortified samples with ß-CDs exhibited lowest antioxidant activity loss (40%) during 90-day storage at 50 ℃, than control samples (64%). The colour changes were in line with those observed for total phenolics and at the end of study, the presence of 1% ß-CDs delayed the darkening of samples at both (25 and 50 ℃) storage conditions.

Red cabbage ( Brassica oleracea ) as a new source of high-thermostable peroxidase.

Soluble and membrane-bound peroxidases (PODs) were extracted from red cabbage using Triton X-114. Optimum activity was obtained at pH 4.0 for both enzymes, and both were inactivated by sodium dodecyl sulfate (SDS). The K(M) and V(m) values for H(2)O(2) were found to be 0.98 mM and 8.1 µM/min, respectively, for soluble POD and 0.82 mM and 6.1 µM/min, respectively, for membrane-bound POD. When the 2,2'-azinobis(3-ethylbenzothiazolinesulfonic acid (ABTS) concentration was increased, maintaining a steady concentration of H(2)O(2), the activity was inhibited at the highest ABTS concentrations in soluble POD. Ascorbic acid was found to be the most active modulator of POD activity. The effect of cyclodextrins was also studied, and the complexation constant between ABTS and hydroxypropyl-ß-cyclodextrins (HP-ß-CDs) was calculated (K(c) = 312 M(-1)). Membrane-bound POD is more thermostable than soluble POD, losing >90% of relative activity after 5 min of incubation at 76.6 and 30.2 °C, respectively.

Kinetic characterisation and thermal inactivation study of red alga (Mastocarpus stellatus) peroxidase.

Peroxidase (POD) was extracted from red alga (Mastocarpus stellatus) using Triton X-114 and characterised by UV-spectrophotometry. Optimum activity using 2,2´-azinobis(3-ethylbenzothiazolinesulphonic acid) (ABTS) as the H-donor was obtained at pH 5.0. In the presence of the anionic detergent, sodium dodecyl sulphate (SDS), however, POD was inactivated at all the pH values studied and totally inactivated at 1mM SDS. When the enzyme was kinetically characterised, the KM and Vm values for ABTS were found to be 13mM and 40µM/min, respectively. In addition, when the H2O2 concentration was increased, at a fixed concentration of ABTS, the activity was inhibited at the highest H2O2 concentrations. In a study of the effect of several reducing agents, l-cysteine was found to be the most active. A thermal inactivation study showed a first-order inactivation kinetic, and the Arrhenius plot yielded a straight line with a slope equivalent to an activation energy of 121.6kJ/mol. Significant inactivation occurred at temperatures of>35°C, with>90% of the relative activity being lost after only 5min of incubation at 48.4°C.

Preparation and characterization of the inclusion complex of chlorpyrifos in cyclodextrins to improve insecticide formulations.

The chemical control of crops by organophosphate insecticide treatment is usually limited because the insecticides do not maintain their efficiency for long periods for several reasons, including environmental conditions or rapid degradation of the active ingredient. Chlorpyrifos is an organophosphate insecticide used worldwide to control a variety of soil insects and arthropods in a wide range of crops. It is easily soluble in organic solvents but shows poor water solubility. The inclusion of chrorpyrifos in cyclodextrins (CDs) improves its water solubility, bioavailability, and insecticidal activity and helps prevent overdosing, leading to more cost-effective and more environmentally friendly agricultural practices. Solubility studies of chlorpyrifos in the presence of different types of CDs show G2-beta-CDs to be the most effective CDs in the complexation process, giving 1:2 complexes, with complexation constant (Kc) values of 12.34 +/- 3.1 M(-1) for K1 and 3895 +/- 183 M(-1) for K2. These complexation constant values were corroborated by applying a fluorimetric method.

ORAC-fluorescein assay to determine the oxygen radical absorbance capacity of resveratrol complexed in cyclodextrins.

The effect of the complexation of resveratrol with hydroxypropyl-beta-cyclodextrins (HP-beta-CDs) on the antioxidant capacity of the polyphenol is studied for the first time by means of the oxygen radical absorbance capacity (ORAC) method, using fluorescein (FL) as the fluorescent probe. The method is validated through its linearity, precision, and accuracy for measuring the ORAC of resveratrol in the absence or presence of cyclodextrins (CDs). The complexation of resveratrol in CDs increased the net area under the FL decay curve (net AUC) of resveratrol up to its saturation level, at which the polyphenol showed almost double the antioxidant activity it shows in the absence of CDs. The complexation constant ( K c) between resveratrol and HP-beta-CDs was calculated by linear regression of the phase solubility diagram ( K c = 18048 M (-1)). The antioxidant activity of resveratrol was dependent on the complexed resveratrol because CDs acts as a controlled dosage reservoir that protects resveratrol against rapid oxidation by free radicals. In this way, its antioxidant activity is prolonged and only reaches its maximum when all the resveratrol is complexed.

Unravelling the interaction of thapsigargin with the conformational states of Ca(2+)-ATPase from skeletal sarcoplasmic reticulum.

Preincubation of thapsigargin with sarcoplasmic reticulum vesicles in the presence of high Ca(2+) or the addition of high Ca(2+) to microsomal vesicles preincubated with thapsigargin in the absence of Ca(2+) allowed full enzyme phosphorylation by ATP. However, the enzyme activity was not protected by high Ca(2+) even when the samples were subjected to gel filtration before ATP addition. Our data indicate that: (i) the enzyme in the Ca(2+)-bound conformation can be stabilized in the presence of thapsigargin; (ii) the conformational transition from the Ca(2+)-free to the Ca(2+)-bound state can be elicited by Ca(2+) when thapsigargin is present; (iii) thapsigargin binding occurs whether or not the enzyme is in the presence of Ca(2+), and so a ternary complex enzyme-Ca(2+)-thapsigargin may be formed; (iv) thapsigargin can be dissociated from the enzyme with a slow kinetics after dilution under drastic conditions; (v) the kinetics of Ca(2+) binding is clearly slowed down by thapsigargin; and (vi) thapsigargin does not affect the hydrolysis rate of phosphorylating substrates when measured in the absence of Ca(2+), indicating that thapsigargin specifically inhibits the Ca(2+)-dependent activity.

Testing the versatility of the sarcoplasmic reticulum Ca(2+)-ATPase reaction cycle when p-nitrophenyl phosphate is the substrate.

A detailed characterization of p-nitrophenyl phosphate as energy-donor substrate for the sarcoplasmic reticulum Ca(2+)-ATPase was undertaken in this study. The fact that p-nitrophenyl phosphate can be hydrolyzed in the presence or absence of Ca(2+) by the purified enzyme is consistent with the observed phenomenon of intramolecular uncoupling. Under the most favorable conditions, which include neutral pH, intact microsomal vesicles, and low free Ca(2+) in the lumen, the Ca(2+)/P(i) coupling ratio was 0.6. A rise or decrease in pH, high free Ca(2+) in the lumenal space, or the addition of dimethyl sulfoxide increase the intramolecular uncoupling. Alkaline pH and/or high free Ca(2+) in the lumen potentiate the accumulation of enzyme conformations with high Ca(2+) affinity. Acidic pH and/or dimethyl sulfoxide favor the accumulation of enzyme conformations with low Ca(2+) affinity. Under standard assay conditions, two uncoupled routes, together with a coupled route, are operative during the hydrolysis of p-nitrophenyl phosphate in the presence of Ca(2+). The prevalence of any one of the uncoupled catalytic cycles is dependent on the working conditions. The proposed reaction scheme constitutes a general model for understanding the mechanism of intramolecular energy uncoupling.

Insight into the uncoupling mechanism of sarcoplasmic reticulum ATPase using the phosphorylating substrate UTP.

Ca(2+) transport and UTP hydrolysis catalyzed by sarcoplasmic reticulum Ca(2+)-ATPase from skeletal muscle was studied. A passive Ca(2+) load inside microsomal vesicles clearly decreased the net uptake rate and the final accumulation of Ca(2+) but not the UTP hydrolysis rate, causing energy uncoupling. In the absence of passive leak, the Ca(2+)/P(i) coupling ratio was 0.7-0.8. UTP hydrolysis did not maintain a rapid component of Ca(2+) exchange between the cytoplasmic and lumenal compartments as occurs with ATP. The uncoupling process in the presence of UTP is associated with: (i) the absence of a steady state accumulation of ADP-insensitive phosphoenzyme; (ii) the cytoplasmic dissociation of Ca(2+) bound to the ADP-sensitive phosphoenzyme; and (iii) the absence of enzyme inhibition by cyclopiazonic acid. All these characteristics confirm the lack of enzyme conformations with low Ca(2+) affinity and point to the existence of an uncoupling mechanism mediated by a phosphorylated form of the enzyme. Suboptimal coupling values can be explained in molecular terms by the proposed functional model.