Brownian motion of polyphosphate complexes in yeast vacuoles: characterization by fluorescence microscopy with image analysis

In the vacuoles of Saccharomyces cerevisiae yeast cells, vividly moving insoluble polyphosphate complexes (IPCs) <1 µm size, stainable by a fluorescent dye, 4′,6‐diamidino‐2‐phenylindole (DAPI), may appear under some growth conditions. The aim of this study was to quantitatively characterize the movement of the IPCs and to evaluate the viscosity in the vacuoles using the obtained data. Studies were conducted on S. cerevisiae cells stained by DAPI and fluorescein isothyocyanate‐labelled latex microspheres, using fluorescence microscopy combined with computer image analysis (ImageJ software, NIH, USA). IPC movement was photorecorded and shown to be Brownian motion. On latex microspheres, a methodology was developed for measuring a fluorescing particle's two‐dimensional (2D) displacements and its size. In four yeast cells, the 2D displacements and sizes of the IPCs were evaluated. Apparent viscosity values in the vacuoles of the cells, computed by the Einstein–Smoluchowski equation using the obtained data, were found to be 2.16 ± 0.60, 2.52 ± 0.63, 3.32 ± 0.9 and 11.3 ± 1.7 cP. The first three viscosity values correspond to 30–40% glycerol solutions. The viscosity value of 11.3 ± 1.7 cP was supposed to be an overestimation, caused by the peculiarities of the vacuole structure and/or volume in this particular cell. This conclusion was supported by the particular quality of the Brownian motion trajectories set in this cell as compared to the other three cells. Copyright © 2010 John Wiley & Sons, Ltd.     

Vacuole Segregation in the Saccharomyces cerevisiae vac2-1 Mutant: Structural and Biochemical Quantification of the Segregation Defect and Formation of New Vacuoles

The conditional vacuolar segregation mutant vac2-1 [Shaw and Wickner (1991) EMBO J. 10, 1741–1748] shifted to non-permissive temperature (37°C), forms large-budded cells without a vacuole in the bud, and daughter cells without an apparent vacuole. Some cells still contain normal segregation structures. Structural and biochemical quantification of the segregation defect showed that (i) about 10% of the full-grown buds did not contain a vacuole, (ii) about 15% of the small cells washed out of a population growing in an elutriation chamber at 37°C, did not contain a visible vacuole, and (iii) 15% of the cells per generation lost carboxypeptidase Y activity after proteinase A depletion. Thus, 10–15% of the daughter cells did not inherit vacuolar structures or vacuolar proteolytic activity from the mother cell. To investigate the fate of vacuole-less daughters, these cells were isolated by optical trapping. The isolated cells formed colonies on agar plates that consisted of cells with normal vacuoles, both at 23 and 37°C. Thus, the vacuole-less cells that failed to inherit proteolytic activities from the mother cell apparently give rise to progeny containing structurally normal vacuoles. Time-lapse experiments showed that vacuole-less daughter cells formed vacuolar vesicles that fused into a new vacuole within 30 min. Although new buds only emerged after a vacuole had formed in the mother cell, the temporary lack of a vacuole had little effect on growth rate. The results suggest that an alternative pathway for vacuole formation exists, and that yeast cells may require a vacuole of some minimal size to initiate a new round of budding. © 1997 by John Wiley & Sons, Ltd.     

Lily Starch—An Underutilized and Non-Conventional Source: Properties and Applications

Lily belongs to the genus Lilium of the family Liliaceae. Starch is the main component of lily bulbs which accounts for 53–69% of their dry weight. Lily starch (LS) has B-type X-ray diffraction characterized by a peak at 5.6°, 17°, 22°, and 24°. The swelling and solubility of the LS are significantly higher than rice and corn starches. The gelatinization temperatures of the LS are much lower than maize but higher than wheat and potato starches. The pasting temperature, peak, breakdown, and setback viscosities of lily starches are falling within the range; 66.1–72.7 °C, 1409–3940 cP, 88–1206 cP, and 445–1952 cP, respectively. The range for initial temperature, gelatinization temperature range, and enthalpy for lily starches is also 56.5–64.0 °C, 3.8–10.3 °C, and 3.9–13.9 J g⁻¹, respectively. This review focuses on the recent advances in the understanding of the composition, structure, and properties of lily starches. Furthermore, the limited modification associated with lily starches is also discussed. There is a bold attempt to compare the properties of lily starch with that of the commercial starches of corn and potato.     

Structural properties of chemically modified Chinese yam starches and their films

Modified yam starch and dual-modified yam starch were produced with propylene oxide, sodium trimetaphosphate and sodium tripolyphosphate. Gelatinization temperature and final viscosity of native yam starch were 79.2 ± 0.4°C and 5702 ± 3 cP. Results showed that the molar substitution and degree of substitution were increased with the volume fraction of propylene oxide from 6–12%, the highest of molar substitution and degree of substitution were 0.0445 ± 0.0003 and 0.0065 ± 0.0006, the final viscosity and setback of dual-modified yam starch were also similar. However, the gelatinization parameters showed an inverse trend. Starch modified with a mixture of sodium trimetaphosphate and sodium tripolyphosphate had higher phosphorus content and increased viscosity compared to starch modified with sodium trimetaphosphate. The peak viscosity of starch modified with propylene oxide was higher than that of native yam starch and the highest was HP12. The granular surface of modified yam starch and dual-modified yam starch appeared significantly embossed and indented, while. Modified yam starch film treated with 12% propylene oxide showed a more homogeneous fractured surface. The tensile strength and elongation at break (E) of starch films were affected by crosslinking reagents and propylene oxide, respectively. The best transparence and E were demonstrated in starch film that was modified with 12% propylene oxide. However, the best tensile strength was demonstrated in starch film that was modified with 8% propylene oxide, sodium trimetaphosphate, and sodium tripolyphosphate. The final viscosity of HP6C1 and HP6C2 was 27 ± 7 and 45 ± 9 cP, which was too low to form film.     

High-fiber date pits pudding: formulation,processing, and textural properties

The aim of this project was to prepare high-fiber pudding using date pits to meet the FDA requirement for health claim. Pudding desert was prepared with dates pits (DP), starch, sugar, xanthan gum (DX), flaxseeds gum (DF), and powdered milk. DP were milled, sieved through 149-µm sieve, and used for formulating high-fiber pudding. The pudding formulation included yeast, DX, or DF, and without gum (DP). Danette chocolate pudding, a commercial sample, was used as a reference. The formulation was cooked using rapid visco analyzer (RVA), and the gel was further analyzed by Brookfield viscometer and texture analyzer. The RVA profile of the formulation included peak viscosity, setback, and final viscosity. The data obtained from the RVA showed that pudding samples containing DX or DF gums exhibited higher peak viscosities (3,012.7 ± 22.5, 1,236.3 ± 110.9 cP, respectively) as compared to the DP pudding 735.3 ± 38.3 cP. The presence of DX instigated higher gel hardness than DF and DP, whereas DF caused higher cohesiveness than DP and DX. The shear stress as a function of shear rate profile indicated that DF was closer to Danette pudding sample. The consistency coefficient index (K), which was obtained from the power law, was higher for both DX and DF, indicating higher viscosity, whereas lower flow behavior index (n) signifies a more pseudoplastic system of these samples. Based on the Ea values, it can be concluded that DX sample is less temperature dependent (lower Ea) than DF (higher Ea). The sensory testing showed that yeast treatment brought the formulation closer to the control in terms of panel acceptance.     

Rheological Behavior of Comminuted Meat Batters

Good agreement was observed between the shear stress-shear rate results obtained with a capillary extrusion viscometer and the yield stress as determined with a rotational viscometer. The frankfurter batter used in this study was pseudoplastic with a flow behavior index of 0.2–0.4, and a yield stress of approximately 840 Pa at 10°C. To compare the effects of batter composition, an apparent viscosity term was defined. Dilution of the batter resulted in reduced apparent viscosities, while increased fat led to increased apparent viscosities. Although chopping time significantly altered the stability of the batter and the visco-elastic properties of the cooked product, no significant difference in the apparent viscosity was detected. This observation was discussed in light of the apparent insensitivity of viscosity measurements to the degree of fat comminution.     

Influence of milk protein concentrates with modified calcium content on enteral dairy beverage formulations: Storage stability

Control of calcium-mediated storage defects, such as age gelation and sedimentation, were evaluated in enteral high-protein dairy beverages during storage. To investigate the effects of reduced-calcium ingredients on storage stability, 2 batches each of milk protein concentrates (MPC) with 3 levels of calcium content were acquired [control, 20% calcium-reduced (MPC-20), and 30% calcium-reduced (MPC-30)]. Control and calcium-reduced MPC were used to formulate 8% (wt/wt) protein enteral dairy beverages. The formulation also consisted of other ingredients, such as gums, maltodextrin, potassium citrate, and sucrose. The pH-adjusted formulation was divided into 2 parts, one with 0.15% sodium hexametaphosphate (SHMP) and the other with 0% SHMP. The formulations were homogenized and retort sterilized at 121°C for 15 min. The retort-sterilized beverages were stored at room temperature for up to 90 d and particle size and apparent viscosity were measured on d 0, 7, 30, 60, and 90. Beverages formulated using control MPC with 0 and 0.15% SHMP exhibited sedimentation, causing a decrease in apparent viscosity by approximately 10 cP and clear phase separation by d 90. The MPC-20 beverages with 0% SHMP exhibited stable particle size and apparent viscosities during storage. In the presence of 0.15% SHMP, particle size increased rapidly by 40 nm on d 90, implying the start of progressive gelation. On the other hand, highest apparent viscosities leading to gelation were observed in MPC-30 beverages at both concentrations of SHMP studied. These results suggested that beverages formulated with MPC-20 and 0% SHMP would have better storage stability by maintaining lower apparent viscosities. Further reduction of calcium using MPC-30 resulted in rapid gelation of beverages during storage.     

超声处理对糙米淀粉的结构与理化特性的影响

以糙米淀粉为原料,探究不同超声时间处理对糙米淀粉的分子结构及理化特性的影响.结果 表明:与原淀粉相比,超声处理10 min的改性淀粉的官能团和化学键组成没有变化.超声处理10 min能够将糙米淀粉的粒径显著降低43.18％,崩解值从577 cP降低到388 cP,峰值黏度经过超声处理后降低,在30 min达到最低157...     

Physicochemical and functional properties of flours from three Black gram (Phaseolus mungo L.) cultivars

Flours processed from three black gram cultivars (Mash1‐1, PU‐19 and T‐9) were studied for proximate composition, physicochemical and functional properties. Protein, fat, ash and crude fibre content varied significantly (P ≤ 0.05) from 24.5 – 28.4%, 1.1–1.4%, 2.7–3.3% and 2.7–3.4%, respectively, among the cultivars. Significant differences were also observed in other physicochemical properties. Pasting properties like peak viscosity, breakdown viscosity and setback viscosity were in the range of 2078.7–2473.0 cP, 644.0–863.7 cP and 588.3–804.0 cP, respectively. Textural profile analysis of flour gels displayed significant differences in hardness (13.0–18.9 g), gumminess (2.8–5.9 g), chewiness (2.0–5.7 g) and adhesiveness (21.0–40.9 g). Differential scanning calorimetry revealed starch gelatinisation from 63.5 to 75.6 °C and amylose lipid complex melting from 105.0 to 136.1 °C. Protein solubility profile in the pH range of 2–9 varied from 6.3 to 97.3%. Emulsifying activity index and Emulsifying stability index at pH 3, 5 and 7 varied correspondingly from 6.0 to 14.5 m² g^?1 and 18.8 to 64.9 min. Foaming capacity of 2% flour suspensions at pH 2, 4, 6, 8 and 10 varied significantly from 67.3 to 130% among the cultivars. Foam stability varied at different pH and was observed between 0 and 70.8% among the cultivars.     

Development of peanut milk–based fermented curd

Fermented milk product (Indian curd) was developed by using peanut milk. The level of incubation period (IP), skimmed milk powder (SMP), carboxymethyl cellulose (CMC) was optimised using response surface methodology (RSM). Central composite rotatable design was used with three independent variables i.e. IP (16–20 h), SMP (3–5%) and CMC (0.1–0.3%). SMP had significant (P ≤ 0.05) positive effect on overall acceptability (OAA) of curd because of increase in the total solids that ultimately increased firmness of the curd. CMC was found effective in reducing the synersis of curd samples. The developed curd samples had moisture 84.8 ± 0.28%, protein 3.2 ± 0.12%, fat 3.5 ± 0.10%, ash 0.5 ± 0.05%, carbohydrate 8.0% (wb), peak viscosity 291.4 ± 3.52 cP, firmness 1.3 ± 0.15 N, synersis 32.1 ± 0.2 mL 100 g^?1 and acidity (as % lactic acid) 0.58 ± 0.02. It had OAA score of 7.8 ± 0.2 on nine‐point hedonic scale. Based on compromise optimisation, the conditions recommended were IP as 18 h, SMP, 4.24% and CMC, 0.19% for making peanut milk–based fermented curd with 83.4% desirability.     

Microfluidic rapid quantification of Salmonella enterica serovar Typhimurium collected from chicken meat using immunomagnetic separation after formaldehyde treatment

Foodborne pathogens such as Salmonella enterica serovar Typhimurium, which cause self-limiting gastroenteritis, are important in food safety and public health. Detection of Salmonella in complex food matrices is required for rapid and effective monitoring of contaminated food products. In this study, we collected Salmonella Typhimurium in chicken using immunomagnetic separation after formaldehyde treatment. Collected Salmonella Typhimurium cells were then quantified microfluidic device or fluorescence microscopy. The recovery ratio obtained with immunomagnetic separation after formaldehyde treatment was 77 (±5)% for the microscope count and 63 (±9)% for the microfluidic count. According to the fluorescence microscope images, the food matrix was effectively removed from the collected cell suspension. The counts of Salmonella Typhimurium cells obtained by the microfluidic device and fluorescence microscope were closely correlated (R² = 0.993) with a range of 3.3 (±0.5) × 10³ to 1.2 (±0.5) × 10⁶ cells g⁻¹. Our method provides quantitative detection of Salmonella Typhimurium within 3–4 h and could be used to efficiently evaluate microbial risk of quality control of foodstuffs and prevention of foodborne disease.     

Rheology of Ice Cream Mix Flavored with Black Tea or Herbal Teas and Effect of Flavoring on the Sensory Properties of Ice Cream

Rheological characteristics and physicochemical properties of ice cream mix flavored with black tea or some herbal teas and sensory profile of flavored ice cream was investigated. In this respect, black tea and three different herbal tea samples (sage, chamomile, and linden) were used to produce a new ice cream formulation. Some physicochemical properties and sensory characteristics of samples were determined. Total phenolic content of ice cream samples increased with the use of tea or herbal teas and it was in the range of 123.37–415.20 mg kg^?1. Incorporation of black tea and herbal tea except chamomile decreased the sensory scores of ice cream compared to control sample. The apparent viscosities of samples were measured as a function of shear rate and consistency coefficient and flow behavior index were calculated by using power law model. All ice cream mix samples showed non-Newtonian pseudoplastic behavior. The apparent viscosities of ice cream mixes treated with no tea at the shear rate of 50 s^?1 were 1.13, 0.91, and 0.76 Pa s at 10, 20, and 30 °C, respectively. The activation energy for the viscosity change of the samples ranged between 10.87–20.25 J?mol^?1 at 50 s^?1.     

基于Caco-2单层细胞模型的兜唇石斛多糖的转运机制研究

以兜唇石斛多糖(DAP)为研究对象,借助人小肠上皮细胞Caco-2(the human colon carcinoma cell line)单层细胞模型,体外模拟DAP在小肠中的转运情况。在前期得到的DAP为基础,探究DAP的粘度对其转运情况的影响,同时建立Caco-2细胞的模型,采用MTT法测定DAP对Caco-2细胞存活率的影响,并考察了DAP在小肠的吸收转运的特征。实验表明:DAP的粘度与其在Caco-2细胞中的转运能力呈负相关趋势,粘度越大,转运速率越慢;在测定TEER值及荧光素钠渗透情况,观察Caco-2细胞的形态,建立了良好的细胞模型;DAP的存在下,Caco-2细胞的存活率为91.8%以上,因此DAP对Caco-2细胞存活无影响;DAP在Caco-2不同单边层的转移率分别为0.35%±0.02%和0.32%±0.02%,表观渗透率分别为(0.42±0.02)×10-6 cm/s和(0.19±0.18)×10-6 cm/s,表明DAP在小肠中不易被吸收。本研究所得结果为进一步研究DAP在肠道中的吸收机制奠定基础。     

Viscosity Pattern of Native and Fermented Black Gram Flour and Starch Dispersions

The effects of fermentation and added NaCl on aqueous dispersions of black gram flour were studied. After fermentation the apparent viscosities of cold pastes increased significantly over that of native flour dispersions (NFD). Addition of NaCl caused considerable decrease in apparent viscosities of NFD but only marginal decrease in fermented flour dispersions (FFD). Studies on rheological constants showed that changes brought about in these by fermentation were greater than that exerted by adding NaCl. Brabender viscography indicated that peak viscosity (PV) decreased by both NaCl and fermentation. FFD with salt showed 15% increase in PV over that without salt. FFD with or without NaCl showed greater breakdown (BV) and set back (SV) viscosities, but the values were lower in comparison to NFD. Starch was isolated in 33–35% yield from native and fermented batters. Apparent viscosity in 1M KOH showed increase due to fermentation. Brabender viscography indicated a GT of ∽81°C for both starches. The PV of fermented starch increased by 13%, BV by 15% and SV by 30% over that of native. Intrinsic viscosity of starch increased considerably while solubility and swelling power increased only marginally after fermentation.     

RELATIONSHIPS BETWEEN SENSORY VISCOSITY AND APPARENT VISCOSITY OF CORN STARCH PASTES

Sensory viscosity and apparent viscosity of corn starch pastes were studied at 15°, 25°, 37° and 50C, within the concentration range 0.9%–6.2%. The oral and visual sensory viscosity estimations were obtained by the converging limits method, a modified version of magnitude estimation. The exponents (perceptual growth rate) were similar (0.40 oral and 0.41 visual). No significant differences were detected between the two evaluations. Visual stimulation yielded results with a lower deviation, suggesting that this type of judgment is easier for the subject. The consistency of results obtained by the converging limits was determined by comparison of the viscosity of starch pastes with silicone oil by cross-modality matching. The ratio upper/lower limit of physical range used (13/0.03 for corn starch ∼ 1100/1.80 for silicone oil) is approximately the same for both substances. This is also shown by the fact that the slope of the log-log function relating them equals 1.11 ± 0.21. No significant effect of temperature was observed on the oral viscosity estimates. The effective range of sensory viscosity for corn starch pastes was between 340 and 1300 cP.     

Characteristics of a novel bacterial polysaccharide consisted of glucose and mannose as major components

A bacterial strain, designated KMBL 5781, producing a high level of extracellular biopolymer was isolated from soil and identified as Mitsuaria chitosanitabida based on the 16S rRNA gene sequences. The biopolymer was purified by the sequential precipitation using ethanol, cethyl trimethyl ammonium bromide and then ethanol again. Its molecular weight was estimated to be about 54.7 kDa by the MALDI-TOF analysis. GC–MS analysis revealed that it is a polysaccharide consisting of glucose, mannose and galactose with approximate molar ratio of 18:6:1. In lower concentrations such as 0.5% and 1% viscosities of the EPS solution was higher than that of the xanthan gum used as a control. At the final range of shear rate the viscosity of 0.5% EPS was 34 cP while 0.5% xanthan showed 19.8 cP. The 1% EPS solution at the same rate has shown 59 cP and the viscosity of 1% Xanthan was 35 cP. When heated from 20 to 92 °C, the EPS solution (2%) remain stable from room temperature until 60 °C and showed significantly higher viscosity at 92 °C than 2% xanthan. The EPS hydrogel (2%) was strongly stable, which released no water during the incubation at 4 °C for 20 days and even after the tubes containing the gel was centrifuged at 4000× g for 10 min. Addition of the EPS into the starch solution resulted in the increase the weight and volume of the gel.     

Influence of microwave heating and time on functional,pasting and thermal properties of cassava starch

The effect microwaving power and time on the functional, pasting and thermal properties of cassava starch was investigated. Cassava starch at a moisture content of 30% was microwaved at 600 and 700 W for 0, 5, 15, 30 and 60 s following a preliminary study. Microwaving power and time did not alter the crystalline pattern of the starch, but there were obvious changes in the starch morphology. Starch colour was significantly (P ≤ 0.05) altered by microwave heating, with the total colour difference increasing from 4.85 to 43.01. Microwave treatment increased starch gelatinisation temperatures but decreased the swelling power, water absorption capacity and the relative crystallinity. These changes were influenced by microwave heating power and time. The results further revealed that the peak viscosity (3714.00–1947.00 cP) and setback ratio (1.70–1.49) decreased with increasing microwave heating time. However, breakdown viscosity (322.67–897.63 cP) and pasting temperature (1947.00–3714.00 °C) increased.     

Effects of β‐Glucans and Environmental Factors on the Viscosities of Wort and Beer

This paper reports on the influence of molecular weight and concentration of barley β‐glucans on the rheological properties of wort and beer. Environmental conditions such as pH, maltose level in wort, ethanol content of beer, shearing and shearing temperature were also examined for their effects on wort and beer viscosities. In the range of 50–1000 mg/L, β‐glucans increased solution viscosity linearly with both molecular weights (MW) of 31, 137, 250, 327, and 443 kDa and concentration. The influence of MW on the intrinsic viscosity of β‐glucans followed the Mark‐Houwink relationship. Shearing wort and beer at approximately 13,000 s^?1for 35 s was found to increase the wort viscosity but reduce beer viscosity. Shearing wort at 20°C influenced β‐glucan viscosity more than shearing at 48°C and 76°C whereas the shearing temperature (0, 5 and 10°C) did not effect the viscosity of beer. At lower pHs, shearing was found to reduce the viscosity caused by β‐glucans in wort but had no effect in beer. Higher concentrations of maltose in wort and ethanol in beer also increased the viscosity of β‐glucan polymers. It was found that β‐glucans had higher intrinsic viscosities in beer than in wort (5°C), and lower critical overlap concentrations (C^*) in beer than in wort.     

ANTIOXIDANT ROLE OF CHITOSAN IN A COOKED COD (GADUS MORHUA) MODEL SYSTEM

Chitosan with different molecular weights (14, 57 and 360 cP apparent viscosity) was effective in controlling the oxidation of lipids of comminuted cod (Gadus morhua) following cooking. Both peroxide (PV) and 2-thiobarbituric acid reactive substances (TBARS) values were reduced as a result of treatment of fish prior to cooking with 50, 100 and 200 ppm of 14, 57 and 360 cP chitosans. Inhibition of oxidation was concentration-dependent and highest for the 14 cP chitosan.     

Selected Quality and Shelf Life of Eggs Coated with Mineral Oil with Different Viscosities

ABSTRACT:  Selected quality and shelf life of eggs coated with mineral oil having 6 different viscosities (7, 11, 14, 18, 22, and 26 cP) were evaluated during 5 wk of storage at 25 °C. As the storage time increased, weight loss and albumen pH increased whereas Haugh unit and yolk index values decreased. After 5 wk of storage, eggs coated with 11, 14, 18, 22, or 26 cP oil possessed better quality than the control noncoated eggs and eggs coated with 7 cP oil. Oil coating, irrespective of viscosities, did not improve the emulsion capacity. There was an observable trend that coating with 26 cP oil was more effective in preventing weight loss and in maintaining the Haugh unit of eggs compared with coating with other viscosities of mineral oil. Based on the Haugh unit, the grade of noncoated eggs changed from "AA" at 0 wk to "C" after 3 wk whereas that of 26 cP oil-coated eggs from "AA" at 0 wk to "A" at 3 wk and "B" at 5 wk of storage. Coating with 26 cP oil reduced the weight loss of eggs by more than 10 times (0.85% compared with 8.78%) and extended the shelf life of eggs by at least 3 more weeks compared with the noncoated eggs.