Effect of the addition of liquid whey from cheese making factory on the physicochemical properties of whey protein isolate gels made by high hydrostatic pressure.

The objective of the present work was to study the effect of liquid whey from the cheese production process on the gels developed by high hydrostatic pressure from whey protein isolate powder (WPI). Changes in pH, color, textural parameters, and water retention capacity of the gels obtained were analyzed during storage for 28 days at refrigeration temperature (4 °C). Mixtures of liquid whey from cheese making processes and different WPI percentages gave gels with different characteristics after being processed by high hydrostatic pressures. The pH values and color parameters (L*, a*, b*) varied slightly, depending directly on WPI concentration and storage time. The values of hardness, elasticity, and cohesiveness were dependent on the liquid medium used to dissolve the WPI (liquid cheese whey or distilled water), WPI concentration, and storage time. The use of liquid cheese whey for gel formation favored water retention, reducing the appearance of syneresis (exudation). The results obtained in the present study indicated a possible use and revalorization of cheese whey obtained in cheese production to obtain WPI gels with improved physicochemical properties, using high hydrostatic pressure as technology for their production.

The gut microbiota of Colombians differs from that of Americans, Europeans and Asians.

BACKGROUND: The composition of the gut microbiota has recently been associated with health and disease, particularly with obesity. Some studies suggested a higher proportion of Firmicutes and a lower proportion of Bacteroidetes in obese compared to lean people; others found discordant patterns. Most studies, however, focused on Americans or Europeans, giving a limited picture of the gut microbiome. To determine the generality of previous observations and expand our knowledge of the human gut microbiota, it is important to replicate studies in overlooked populations. Thus, we describe here, for the first time, the gut microbiota of Colombian adults via the pyrosequencing of the 16S ribosomal DNA (rDNA), comparing it with results obtained in Americans, Europeans, Japanese and South Koreans, and testing the generality of previous observations concerning changes in Firmicutes and Bacteroidetes with increasing body mass index (BMI). RESULTS: We found that the composition of the gut microbiota of Colombians was significantly different from that of Americans, Europeans and Asians. The geographic origin of the population explained more variance in the composition of this bacterial community than BMI or gender. Concerning changes in Firmicutes and Bacteroidetes with obesity, in Colombians we found a tendency in Firmicutes to diminish with increasing BMI, whereas no change was observed in Bacteroidetes. A similar result was found in Americans. A more detailed inspection of the Colombian dataset revealed that five fiber-degrading bacteria, including Akkermansia, Dialister, Oscillospira, Ruminococcaceae and Clostridiales, became less abundant in obese subjects. CONCLUSION: We contributed data from unstudied Colombians that showed that the geographic origin of the studied population had a greater impact on the composition of the gut microbiota than BMI or gender. Any strategy aiming to modulate or control obesity via manipulation of this bacterial community should consider this effect.

Use of spent osmotic solutions for the production of fructooligosaccharides by Aspergillus oryzae N74.

In the food industry, osmotic dehydration can be an important stage to obtain partially dry foodstuffs. However, the remaining spent osmotic solution at the end of the process could become a waste with an important environmental impact due to the large amount of organic compounds that it might contain. Since one of the most important osmotic agents used in osmotic dehydration is sucrose, this spent osmotic solution could be used to be biotransformed to produce fructooligosaccharides by a fructosyltransferase. This study evaluated the production of fructooligosaccharides using the fructosyltransferase produced by Aspergillus oryzae N74, and the spent osmotic solution that resulted in the osmotic dehydration of Andes berry (Rubus glaucus) and tamarillo (Cyphomandra betacea). Assays were conducted at small and bioreactor scales, using spent osmotic solution with or without re-concentration. At small scale no significant difference (p > 0.05) was observed in the fructooligosaccharides production yield, ranging from 31.18% to 34.98% for spent osmotic solution from tamarillo osmotic dehydration, and from 33.16% to 37.52% for spent osmotic solution from Andes berry osmotic dehydration, using either the SOS with or without re-concentration. At bioreactor scale the highest fructooligosaccharides yield of 58.51 ± 1.73% was obtained with spent osmotic solution that resulted from tamarillo osmotic dehydration. With the spent osmotic solution from Andes berry osmotic dehydration the yield was 49.17 ± 2.82%. These results showed the feasibility of producing fructooligosaccharides from spent osmotic solution that is considered a waste in food industry.

Producción de Astaxantina en Haematococcus pluvialis bajo diferentes condiciones de estrés / Astaxanthin Production in Haematococcus pluvialis under different stress conditions

Las microalgas son fuente de un gran número de compuestos bioactivos de interés industrial, como los carotenoides que se utilizan como colorantes naturales en alimentación animal y humana, así como en la industria farmacéutica, cosmética y en la acuicultura. Además se han propuesto como agentes efectivos en la prevención de una variedad de enfermedades, debido a su capacidad antioxidante, inmunoregulaora, anti-inflamatoria y anti-cancerígena. El ketocarotenoide astaxantina es el más importante desde el punto de vista biotecnológico. Hoy la mayor cantidad de astaxantina es producida por síntesis química y es vendida a un precio de US $2500/kg. El alto precio y el incremento en la demanda para este compuesto, especialmente de origen natural, en las diferentes industrias, hace que sea de interés la producción astaxantina a partir de microalgas como el Haematococcus pluvialis, que acumula cantidades importantes (más del 4%/g de peso seco) y de mejor calidad que las obtenidas por otras fuentes como levaduras y plantas. La acumulación del pigmento en H. pluvialis ocurre durante la transformación de la microalga desde el estado vegetativo (fase verde) a aplanospora (fase roja) cuando cesa su crecimiento en la fase estacionaria. Los tipos de estrés que inducen a la acumulación de astaxantina son temperatura, intensidad lumínica, ciclos de luz/oscuridad, concentración de nutrientes, pH, especies reactivas de oxígeno, sales y presencia de inhibidores de procesos metabólicos a diferente nivel. Es importante resaltar que esta microalga es de difícil cultivo; así como en la obtención del pigmento en cantidades de interés, debido a su ciclo celular complejo. De igual forma, un mayor entendimiento de las bases moleculares de la relación -condiciones de estrés-inducción- acumulación de astaxantina en H. pluvialis, podría ser útil para aumentar la productividad de astaxantina.

Microalgae are a source of a large number of bioactive compounds of industrial importance, such as carotenoids used as natural colorants in food and feed, as well as in pharmaceuticals, cosmetics and aquaculture. They also have been studied as effective compounds for the prevention of different diseases due to their antioxidant, immunoregulatory, anti-inflammatory and anticarcinogenic properties. In biotechnology applications astaxanthin is the most important ketocarotenoide. Currently most astaxanthin is produced by chemical synthesis and sold at U.S. $ 2500/kg. The high price and increasing demand of this compound in different industries, especially of natural origin creates an interest in the astaxanthin production from microalgae as Haematococcus pluvialis that accumulate significant amounts (more than 4%/g dry weight) and better quality what is obtained from sources such as yeast and plants. The pigment accumulation in H. pluvialis occurs during the transformation of microalgae from the vegetative state (green phase) to aplanospora (red phase) when growth ends in the stationary phase. The types of stress that induce astaxanthin accumulation are temperature, light intensity, cycles of light / dark, nutrient concentration, pH, reactive oxygen species, salts and presence of metabolic processes inhibitors at different levels. Is important to take in account that this microalgae is hard to grow and obtain the pigment in amounts of interest could be complicated due to complex cell cycle. Similarly, a better understanding of the molecular basis of the relationship, stress-inducing conditions, astaxanthin accumulation in H. pluvialis, might be helpful for increasing productivity of astaxanthin.

Antagonistic effect of Lactobacillus strains against Escherichia coli and Listeria monocytogenes in milk.

The current work studied four types of binary antagonist/pathogen bacterial culture system, in order to determine the effect of interaction between two strains of Lactobacillus plantarum and two food-borne pathogens, Listeria monocytogenes and Escherichia coli, in whole UHT milk at 37°C. To determine the type of interaction between the two bacterial populations in co-cultures and to evaluate the antagonistic activity of the lactic acid bacteria (LAB) on the pathogenic bacteria, the growth curves, the kinetic parameters, and the pH profiles of mono- and co-cultures were compared. The Lb. plantarum strains showed different bacteriocin-like inhibitory substance (BLIS) production, auto- and co-inducible. The antibacterial effect of neutralized supernatants of mono and co-cultures harvested at different times of incubation was assessed in order to establish the presence of bacteriocin-like inhibitory-substances (BLIS) and their possible relation to the growth inhibition of the pathogen. The LAB reduced the growth of Esch. coli and of List. monocytogenes by 4 and ∼5 log cycles, respectively and influenced other growth kinetic parameters, such as µ(max) and lag phase, in the different binary combinations. The growth of the LAB was not relevantly altered by simultaneous growth with the pathogenic strains showing an interaction of amensalism. The pattern of inhibition exerted by the LAB on the pathogens was different; Lb. plantarum LB279 inhibited the growth of List. monocytogenes more effectively than that of Esch. coli. The behaviour of Esch. coli in co-culture with Lb. plantarum WS4174 suggested the presence of metabolic crowding in the mechanism of growth suppression. This exploratory study showed the complexity and specific particularities of the inhibition phenomena between bacterial communities.

The relationship between membrane damage, release of protein and loss of viability in Escherichia coli exposed to high hydrostatic pressure.

The aim of this work was to examine a possible association between resistance of two Escherichia coli strains to high hydrostatic pressure and the susceptibility of their cell membranes to pressure-induced damage. Cells were exposed to pressures between 100 and 700 MPa at room temperature (approximately 20 degrees C) in phosphate-buffered-saline. In the more pressure-sensitive strain E. coli 8164, loss of viability occurred at pressures between 100 MPa and 300 MPa and coincided with irreversible loss of membrane integrity as indicated by uptake of propidium iodide (PI) and leakage of protein of molecular mass between 9 and 78 kDa from the cells. Protein release increased to a maximum at 400 MPa then decreased, possibly due to intracellular aggregation at the higher pressures. In the pressure-resistant strain E. coli J1, PI was taken up during pressure treatment but not after decompression indicating that cells were able to reseal their membranes. Loss of viability in strain J1 coincided with the transient loss of membrane integrity between approximately 200 MPa and 600 MPa. In E. coli J1 leakage of protein occurred before loss of viability and the released protein was of low molecular mass, between 8 and 11 kDa and may have been of periplasmic origin. In these two strains differences in pressure resistance appeared to be related to differences in the ability of their membranes to withstand disruption by pressure. However it appears that transient loss of membrane integrity during pressure can lead to cell death irrespective of whether cells can reseal their membranes afterwards.

New mathematical modeling approach for predicting microbial inactivation by high hydrostatic pressure.

A new primary model based on a thermodynamically consistent first-order kinetic approach was constructed to describe non-log-linear inactivation kinetics of pressure-treated bacteria. The model assumes a first-order process in which the specific inactivation rate changes inversely with the square root of time. The model gave reasonable fits to experimental data over six to seven orders of magnitude. It was also tested on 138 published data sets and provided good fits in about 70% of cases in which the shape of the curve followed the typical convex upward form. In the remainder of published examples, curves contained additional shoulder regions or extended tail regions. Curves with shoulders could be accommodated by including an additional time delay parameter and curves with tails shoulders could be accommodated by omitting points in the tail beyond the point at which survival levels remained more or less constant. The model parameters varied regularly with pressure, which may reflect a genuine mechanistic basis for the model. This property also allowed the calculation of (a) parameters analogous to the decimal reduction time D and z, the temperature increase needed to change the D value by a factor of 10, in thermal processing, and hence the processing conditions needed to attain a desired level of inactivation; and (b) the apparent thermodynamic volumes of activation associated with the lethal events. The hypothesis that inactivation rates changed as a function of the square root of time would be consistent with a diffusion-limited process.