Kadir Yurdakoc

Reduction of Ochratoxin A Levels in Red Wine by Bentonite, Modified Bentonites, and Chitosan

Adsorption method may play an important role to remove ochratoxin A (OTA) from wine by bentonite (B), nonylammonium bentonite (NB), dodecylammonium bentonite (DB), KSF-montmorillonite (KSF), and chitosan bead (CB). The optimum conditions of OTA adsorption from synthetic solutions were revealed at room temperature and pH 3.5. The adsorption equilibria of B and NB were almost established within 120 and 240 min, respectively. DB, KSF, and CB had about 90 min of equilibration time. The adsorption efficiency carried out in the synthetic OTA solution did not change remarkably when the amounts of adsorbents were 25 mg for bentonite, DB, and KSF and 100 mg for NB and CB. Furthermore, 25 mg of adsorbents was used at all adsorption studies in synthetic solution. The adsorption isotherm was fitted with mostly a Freundlich equation with respect to the correlation coefficients. The adsorption data were evaluated using Langmuir and Freundlich equations having Kf values ranging from 0.011 to 9.5 with respect to correlation coefficients (R2 = 0.900-0.977). DB and KSF have the highest adsorption capacity for OTA in synthetic solutions. In wine, the removal of OTA was succeeded at a percentage of 60-100 by KSF and CB. Furthermore, the highest adsorption capacity of OTA for red wine was obtained by using 250 mg of KSF, which caused less damage to the nature of wine and also low adsorption of polyphenols and anthcyans.

Chitosan/poly(vinyl alcohol) hydrogels for amoxicillin release

Chitosan and poly(vinyl alcohol)-based hydrogel films were synthesized using tartaric acid as a crosslinking agent. The films denoted as CVT were then characterized using Fourier transform infrared, Nuclear magnetic resonance, X-ray diffraction, and scanning electron microscopy analysis. TG/DTG and DSC analysis were also carried out for the determination of thermal properties of hydrogel films. Swelling properties of these hydrogel films were investigated at two different pHs and temperatures. The swelling behaviors of all samples were increased in acidic medium, while decreased in alkaline medium. The enzymatic degradation of the hydrogels was studied using lysozyme, and degradation rates were found to be parallel with the swelling ratio for CVT hydrogel. The hydrogels were also used for the amoxicillin release in KCl/HCl and PBS buffer solutions. The release behaviors of CVT hydrogel films were slower and can be controlled as compared with commercial drug release systems. CVT hydrogel films may be more appropriate for controlled release of amoxicillin.

Zearalenone removal in synthetic media and aqueous part of canned corn by montmorillonite K10 and pillared montmorillonite K10.

The capacities of montmorillonite K10 (K10), aluminum pillared K10 (Al-K10), and iron pillared K10 (Fe-K10) to eliminate zearalenone (ZEN) from synthetic media and the aqueous part of canned corn were studied. Original clay and pillared clays were characterized in terms of X-ray powder diffraction analysis and N(2) adsorption-desorption isotherms. The maximum amounts of adsorption of ZEN by K10, Al-K10, and Fe-K10 at 25°C and pH 7 were 0.202, 1.305, and 1.028 mg/g and 0.264, 0.096, and 0.255 mg/g, calculated from Langmuir and Freundlich isotherms, respectively. The adsorption of ZEN was also studied as a function of adsorbent amount (1 to 30 mg), ZEN concentration (2 to 20 mg/liter), pH of solution (pH 4 to 10), and contact time. Pillared clays could be an excellent alternative for removing ZEN in contaminated food samples and are potentially low-cost adsorbents with a promising future as an alternative to more costly materials.