Oxidative stability and sensory evaluation of microencapsulated flaxseed oil.

Cold pressed flaxseed oil was microencapsulated by spray drying using an emulsion containing modified starch. The fatty acid composition, moisture, water activity, wettability, water holding capacity, water solubility, crystallinity, and particle size distribution of the microcapsules were determined. The stability of the microcapsules and the crude oil were assessed. An acceptance test was used for the sensory evaluation of a powdered supplement containing the microcapsules. The fatty acid composition was not significantly affected by the microencapsulation. The moisture, water activity, wettability, water solubility and crystallinity were appropriate for dry powders. The microcapsules had no cracks and showed better oxidative stability compared with the crude oil. Storage under vacuum prevented oxidation of the microcapsules. In sensory evaluation, all quality scores of the supplement containing microcapsules were mid-range or higher. The microencapsulation improved the oxidative stability of the oil and this procedure was satisfactorily applied in powdered food.

Characterization of antibiotic-loaded alginate-OSA starch microbeads produced by ionotropic pregelation.

The aim of this study was to characterize the penicillin-loaded microbeads composed of alginate and octenyl succinic anhydride (OSA) starch prepared by ionotropic pregelation with calcium chloride and to evaluate their in vitro drug delivery profile. The beads were characterized by size, scanning electron microscopy (SEM), zeta potential, swelling behavior, and degree of erosion. Also, the possible interaction between penicillin and biopolymers was investigated by differential scanning calorimetry (DSC), powder X-ray diffraction (XRD), and Fourier transform infrared (FTIR) analysis. The SEM micrograph results indicated a homogeneous drug distribution in the matrix. Also, based on thermal analyses (TGA/DSC), interactions were detected between microbead components. Although FTIR spectra of penicillin-loaded microbeads did not reveal the formation of new chemical entities, they confirmed the chemical drug stability. XRD patterns showed that the incorporated crystalline structure of penicillin did not significantly alter the primarily amorphous polymeric network. In addition, the results confirmed a prolonged penicillin delivery system profile. These results imply that alginate and OSA starch beads can be used as a suitable controlled-release carrier for penicillin.

Study of trans-trans farnesol effect on hyphae formation by Yarrowia lipolytica.

Dimorphism is an ability of certain fungi related to its adaptation to the environment and provides a selective advantage under stress conditions and is associated to the development of human diseases. Hyphae inducing- and inhibitory-effect of farnesol on hyphae formation by the dimorphic yeast Yarrowia lipolytica was evaluated through digital image analysis. The agitation speed of the culture was the most effective hyphae inducer in comparison to bovine calf serum and N-acetylglucosamine. In low agitation system, bovine calf serum was more effective for hyphae formation inducing 57 % of hyphae transition. Farnesol inhibited hyphae formation even in low concentration (300 µM) and this effect increased with increasing concentrations. In the presence of N-acetylglucosamine, this effect was more evident in comparison to the presence of bovine calf serum, which might have protected the cells from farnesol. Digital image analysis was an important tool to evaluate this phenomenon.

Factors influencing crude oil biodegradation by Yarrowia lipolytica

Yarrowia lipolytica is unique strictly aerobic yeast with the ability to efficiently degrade hydrophobic substrates such as n-alkenes, fatty acids, glycerol and oils. In the present work, a 2(4) full factorial design was used to investigate the influence of the independent variables of temperature, agitation, initial cell concentration and initial petroleum concentration on crude oil biodegradation. The results showed that all variables studied had significant effects on the biodegradation process. Temperature, agitation speed and initial cell concentration had positive effects, and initial petroleum concentration had a negative effect. Among the crude oil removal conditions studied, the best temperature and agitation conditions were 28ºC and 250 rpm, respectively.

A strategic study using mutant-strain entrapment in calcium alginate for the production of Saccharomyces cerevisiae cells with high invertase activity.

Entrapped cells and entrapped cells grown inside of a calcium alginate matrix as well as free cells have been investigated using Saccharomyces cerevisiae mutant strains with regard to their pattern of growth and invertase activity. The repression of invertase by glucose and glucose-consumption ability were considered in the selection process of the mutants. Efficient sucrose bioconversion due to high invertase activity was obtained when entrapped mutant strain Q6R2 cells were grown within calcium alginate gel beads using sucrose plus glucose as the carbon source. Under these conditions, 1 mg (dry weight) of entrapped cells is able to produce 20 micromol of inverted sugar in 3 min (the maximum activity obtained was 20 units x mg(-1)). The experiments were carried out for 6 months without appreciable loss of either bead integrity or invertase activity. The biocatalyst was also stored at 4 degrees C for 6 months without appreciable loss of the invertase activity. This work shows that entrapped yeast cells with a weak ability to consume sugar may be used to produce inverted sugar.