利用大豆乳清废水生产SCP的研究

以大豆乳清废水为原料,通过对产朊假丝酵母的培养,使大豆乳清废水中的营养成分被酵母菌吸收利用,从而使菌体生长繁殖产生单细胞蛋白。单细胞蛋白(SCP)产量为8.7 mg/mL,蛋白含量为51.3%;且废水COD去除率达到73.4%,达到了国家乳清废水的标准,从而实现了废水资源化利用的目的。     

Whey disposal by deproteinization and fermentation

The non-pollutant plant support material of the dwarf duckweed Wolffia arrhiza (Fam. Lemnaceae) was used for the entrapment of living yeast cells (Kluyveromyces fragilis) which hydrolyse lactose with the subsequent fermentation of glucose and galactose at high cell densities (up to 7.0 × 10⁸/ml support). The stabile yeast-plant cell immobilizates are able to produce ethanol from lactose-containing media (e.g. whey) by batch fermentation (on a rotary shaker) or continuous fermentation (in a turbulence reactor) for several days (at a pH below 4.2 and a temperature of 30°C). The removal of whey proteins by a preceding heat denaturation of whey, high dilution rates, C_So values of 50 to 60 g lactose per litre whey and the preferential use of the K. fragilis strain DSM 7238 were determined as the prerequisites for an optimum continuous fermentation. Economically interesting productivities (P_max ? 15 g ethanol/1 · h, D = 0.72 h^?1) with an actual lactose turnover of 90% were obtained by using these parameters.     

Proteomics-Driven Analysis of Ovine Whey Colostrum

The aim of this study was to shed light in to the complexity of the ovine colostrum proteome, with a specific focus on the low abundance proteins. The ovine colostrum is characterized by a few dominating proteins, as the immunoglobulins, but it also contains less represented protein species, equally important for the correct development of neonates. Ovine colostrum, collected immediately after lambing, was separated by 1D SDS-PAGE. Proteins bands were digested with trypsin and the resulting peptides were analyzed by LC-MS/MS. On the basis of the Swiss-Prot database, a total of 343 unique proteins were identified. To our knowledge, this study represents the most comprehensive analysis of ovine colostrum proteome.     

Whey clarification by a soluble polycationic agent

A soluble polycationic agent (Disperfloc C-500) was used for whey clarification. Turbidity was decreased by more than 90% with the addition of only 0.8 g/l of the agent, at pHs ranging from 7.3 and 7.6 and with a temperature step of 5 min at 50° C. The calcium and phosphate content of whey was decreased by more than 50% while 98% of the total protein content still remained soluble.     

Large-Scale Production of Rhizobium meliloti on Whey

Whey, a by-product of the cheese industry, can sustain the growth of fast-growing rhizobia. To avoid any latency of growth, rhizobial inoculum must be prepared under inducing conditions. In unsupplemented whey, the number of cells of Rhizobium meliloti Balsac reached 5 × 10⁹ CFU/ml in 48 h of incubation. This is comparable to the yield obtained with yeast-mannitol broth, the standard medium for the growth of rhizobia. In raw whey supplemented with yeast extract (1.0 g/liter) and phosphate (0.5 g/liter), the number of cells reached 10¹⁰ CFU/ml in 48 h of incubation. This is a twofold increase compared with the population normally obtained in industrial production. Whey represents a relatively inexpensive and efficient substrate medium for the large-scale production of fast-growing rhizobia.     

Use of Cheese Whey for Vitamin B12 Production: I. Whey Solids and Yeast Extract Levels1

The suitability of cheese whey as a substrate for vitamin B(12) production by Propionibacterium shermanii was studied. It was found that with a given level of whey solids a definite amount of yeast extract was required to give maximal yields of vitamin B(12). Of the levels of materials studied, 10% whey solids and 1.5% yeast extract gave the best yields of vitamin B(12). Most of the lactose of the whey had been utilized in all flask cultures after 168 hr at 29 C.     

Whey fermentation by immobilized cells of Propionibacterium shermanii

Growth of Propionibacterium shermanii B-123 was faster on media containing lactate than on that containing lactose. Cheese whey was therefore fermented with Lactobacillus helveticus and neutralized with NaOH or Ca(OH)₂, before inoculation with B-123. Fermentation rate by immobilized propionibacteria was best in Ca(OH)₂-neutralized whey, and at lactate concentrations between 1 and 2%. Calcium propionate concentrations of 1 and 3% reduced fermentation rates by 40% and 55% respectively. Optimum temperature for propionate fermentation by immobilized cells was 37°C. Ratios of propionic acid to acetic acid increased as incubation temperature was increased. Agitation increased propionic acid fermentation rates but lowered the ratio of propionic acid to acetic acid. Beads containing immobilized propionibacteria were re-utilized for ten consecutive fermentations. Fermentation rates increased upon re-utilization. Escherichia coli and Staphylococcus aureus were inhibited by the propionic fermentation but did not die; they kept growing at a reduced rate.     

Continuous Propagation of Trichosporon cutaneum in Cheese Whey

Trichosporon cutaneum, a nonfermenting yeast, was used to convert cheese whey lactose into microbial cell material. The doubling time for this organism in a laboratory-scale continuous propagator was 2 hr in a whey medium fortified with ammonium sulfate and corn steep liquor. Cellular growth and efficiency of conversion of lactose to cell material was higher than with Saccharomyces fragilis. When grown in whey, the nitrogen content of T. cutaneum was 3.5% and the distribution of amino acids per gram of cell protein was similar to that of commercial food yeasts.     

Downstream Processing of Bovine Lactoferrin from Sweet Whey

The development of a downstream process for the isolation of bovine lactoferrin (bLF) from sweet whey is presented. Whey is a by‐product from the cheese manufacturing process that is often used to produce whey protein concentrate powders for food applications. Besides the major whey proteins such as lactalbumin or BSA, minor whey proteins are present such as lactoperoxidase and bLF. In addition to the well‐known biological functions as an antimicrobial and antiviral agent, bLF shows immunomodulatory functions in the host defence system. For the isolation of bLF, a two‐step downstream process was developed based on membrane systems. This paper discusses the application of several membrane types for a crossflow filtration of sweet whey to remove insoluble particles and lipids from the whey with the aim of obtaining a permeate which can be directly used for downstreaming the minor component via ion exchange membrane adsorber systems. The application of such a membrane adsorber is demonstrated.     

Caseinate-Induced Competitive Displacement of Whey Protein from Interfaces

The caseinate-induced competitive displacement of whey protein from planar air-water interfaces was investigated based on atomic force microscopy (AFM) imaging and that from the surfaces of oil droplets immersed in aqueous solution based on AFM force spectroscopy. After the addition of sodium caseinate to the sub-phase, the surface pressure of planar interfacial films of pre-adsorbed whey protein increased from 8 mN/m to up to 21 mN/m. The thicknesses of interfacial films were uniform and remained to be approximately 2 nm at relatively low surface pressures up to 18 mN/m, while they became uneven at higher surface pressures and increased to up to 7.1 nm, presumably due to the compression of interfacial whey protein networks by adsorbed caseinate. The rigidity of oil droplets coated with protein adsorbed to their surfaces was then evaluated based on the slope of approximately linear force-distance curves obtained by pressing an oil droplet against another. The adsorption of whey protein to oil droplet surfaces increased droplets’ rigidity. The subsequent addition of caseinate to the bulk solution surrounding oil droplets coated with pre-adsorbed whey protein further increased droplets’ rigidity. The present results suggest that caseinate adsorbed to an interface to which whey protein had adsorbed in advance did not completely expel pre-adsorbed whey protein molecules into the aqueous phase but caused a compaction of interfacial whey protein networks and thereby strengthened the interfacial film.     

乳清蛋白质的生物学特性和保健功能

本文综述了乳清蛋白质分离、改性技术的最新进展,乳清蛋白质的理化和生物学特性,乳清蛋白质的功能性及应用开发的前景。     

瑞士乳杆菌水解乳清蛋白发酵条件的研究

利用益生菌发酵制备具有生物学功能特性的发酵乳制品,特别是在构建功能性食品方面,对人类的健康及人体内共生菌群的开发具有重大意义。以瑞士乳杆菌(Lactobacillushelveticus)为研究菌种,对瑞士乳杆菌利用乳清粉的发酵条件进行了系统的研究,并对发酵条件进行了优化。实验结果表明,瑞士乳杆菌在33℃,发酵液的初始pH为5.5,接种量为1.5%时蛋白酶活力最强,发酵液中游离氨基酸含量为3.004μg/ml活菌数达到108cfu/ml。通过对瑞士乳杆菌的发酵动力学的研究,确定了该菌生长特性,以及乳清蛋白水解进程曲线和产酸情况。     

乳清蛋白在临床营养中的应用

乳清蛋白被认为是"蛋白之王",是人乳蛋白的主要成分。乳清蛋白的临床功用包括维持和提高机体免疫力、抗自由基延缓衰老、维持肾功能和促进创伤愈合。疾病防治作用包括防治"四高症"、心脑血管疾病和消化系统疾病,以及有助于癌症康复和AIDS患者的治疗。     

Cold-Set Whey Protein Gels with Addition of Polysaccharides

Cold-set whey protein (WP) gels with addition of xanthan or guar were evaluated by mechanical properties and scanning electron microscopy. Gels were formed after the addition of different amounts of glucono-δ-lactone to thermally denatured WP solutions, leading to different acidification rates and final pH values. At lower acidification rates and higher final pH, gels showed more discontinuous structure and weaker and less elastic network, which was attributed to a predominance of phase separation during gel formation due to slower gelation kinetics. In contrast, at higher acidification rates and lower final pHs, gelation prevailed over phase separation, favoring the formation of less porous structures, resulting in stronger and more elastic gels. The gels’ fractal dimension (D _f; structure complexity) and lacunarity were also influenced by the simultaneous effects of gelation and phase separation. For systems where phase separation was the prevailing mechanism, greater lacunarity parameters were usually observed, describing the heterogeneity of pore distribution, while the opposite occurred at prevailing gelation conditions. Increase in guar concentration or lower final pH of xanthan gels entailed in D _f reduction, while the increase in xanthan concentration resulted in higher D _f. Such a result suggests that the network contour length was rugged, but this pattern was reduced by the increase of electrostatic interactions among WP and xanthan. Guar addition caused the formation of gel network with smoother surfaces, which could be attributed to the guar–protein excluded volume effects leading to an increase in protein–protein interactions.     

Production of Bakers' Yeast in Cheese Whey Ultrafiltrate

A process for the production of bakers' yeast in whey ultrafiltrate (WU) is described. Lactose in WU was converted to lactic acid and galactose by fermentation. Streptococcus thermophilus was selected for this purpose. Preculturing of S. thermophilus in skim milk considerably reduced its lag. Lactic fermentation in 2.3×-concentrated WU was delayed compared with that in unconcentrated whey, and fermentation could not be completed within 60 h. The growth rate of bakers' yeast in fermented WU differed among strains. The rate of galactose utilization was similar for all strains, but differences in lactic acid utilization occurred. Optimal pH ranges for galactose and lactic acid utilization were 5.5 to 6.0 and 5.0 to 5.5, respectively. The addition of 4 g of corn steep liquor per liter to fermented WU increased cell yields. Two sources of nitrogen were available for growth of Saccharomyces cerevisiae: amino acids (corn steep liquor) and ammonium (added during the lactic acid fermentation). Ammonium was mostly assimilated during growth on lactic acid. This process could permit the substitution of molasses by WU for the industrial production of bakers' yeast.     

乳清蛋白在运动营养中的功能特性和作用

乳清蛋白是牛乳中一类营养价值较高的优质蛋白,必需氨基酸种类齐全,组成模式与人体相似,并含有丰富的支链氨基酸和多种生物活性物质,能够提高机体的抗氧化能力,增强机体免疫力,促进骨骼肌蛋白质的合成,抑制肌肉蛋白分解,加速训练后体能的恢复,对于运动人群而言,是补充优质蛋白的良好来源.本文就合理的补充乳清蛋白对缓解运动性疲劳、提高运动能力的研究进展进行了综述.     

Whey as a medium for biomass production ofSulfolobus solfataricus

Summary The use of whey, a liquid by-product of dairy industry without any pre-treatment as growth medium for the thermophilic archaeonSulfolobus solfataricus, is reported.     

Evaluation of Whey for Bioremediation of Trichloroethene Source Zones

The effectiveness of whey as an electron donor that stimulates bioremediation and enhances dissolution of trichloroethene (TCE) dense non-aqueous phase liquid (DNAPL) was investigated. Laboratory experiments were conducted to evaluate increased mass transfer of TCE from the DNAPL to the aqueous phase in abiotic batch microcosms amended with several concentrations of whey, and in abiotic columns using high- and low-concentration whey mixtures. The effective solubility of TCE was a factor of 6 higher in microcosms amended with 10% w/w whey compared to 1% w/w whey or nanopure water. Increased aqueous-phase concentrations of TCE were a function of both the concentration of whey and time. In the columns, a factor of 5 increase in TCE concentrations was observed in the effluent during amendment with 10% w/w whey compared to potable water and 1% w/w whey. A field study involving three whey injections was performed at a site that had been actively undergoing bioremediation in a residual source area using lactate for 5 years. Results of the field test show a factor of 3 increase in total molar concentrations of chloroethenes and ethene following injection of 10% w/w whey compared to 5% lactate. In addition, complete dechlorination of TCE to ethene continued.