Search

Your search keyword '"whey utilization"' showing total 18 results
Start Over Descriptor "whey utilization"
18 results on '"whey utilization"'

4. Microalgal conversion of whey and lactose containing substrates: current state and challenges.

Author

Kolesovs, Sergejs and Semjonovs, Pavels

Subjects
WHEY, BIOMASS production, LACTOSE, DAIRY processing, SPIRULINA, INDUSTRIAL costs, ENVIRONMENTAL risk
Abstract

Currently dairy processing by-products, such as whey, still propose a significant threat to the environment if unproperly disposed. Microalgal bioconversion of such lactose containing substrates can be used for production of valuable microalgae-derived bio-products as well as for significant reduction of environmental risks. Moreover, it could significantly reduce microalgae biomass production costs, being a significant obstacle in commercialization of many microalgae species. This review summarizes current knowledge on the use of lactose containing substrates, e.g. whey, for the production of value-added products by microalgae, including information on producer cultures, fermentation methods and cultivation conditions, bioprocess productivity and ability of microalgal cultures to produce β-galactosidases. It can be stated, that despite several limitations lactose-containing substrates can be successfully used for both—the production of microalgal biomass and removal of high amounts of excess nutrients from the cultivation media. Moreover, co-cultivation of microalgae and other microorganisms can further increase the removal of nutrients and the production of biomass. Further investigations on lactose metabolism by microalgae, selection of suitable strains and optimisation of the cultivation process is required in order to enable large-scale microalgae production on these substrates. [ABSTRACT FROM AUTHOR]

Published
2023
Full Text
View/download PDF

5. Whey Management: A Solved Problem or Ongoing Challenge?

Author

0000-0003-3117-3337, Menéndez Díaz, José Ángel, 0000-0003-3117-3337, and Menéndez Díaz, José Ángel

Abstract

Despite technological advances and increasing recognition of the nutritional benefits of whey, a significant portion remains underutilized, especially in small cheese factories. Additionally, the rising production of acid whey, generated from the manufacturing of Greek yogurt, presents a management challenge due to its more complex valorization compared to sweet whey

Published
2024

6. Whey Utilization: Sustainable Uses and Environmental Approach

Author

Elizabeta Zandona, Marijana Blažić, and Anet Režek Jambrak

Subjects
whey utilization, whey proteins, lactose recovery, biorefineries, Biotechnology, TP248.13-248.65, Food processing and manufacture, TP368-456
Abstract

The dairy industry produces large amounts of whey as a by- or co-product, which has led to considerable environmental problems due to its high organic matter content. Over the past decades, possibilities of more environmentally and economically efficient whey utilisation have been studied, primarily to convert unwanted end products into a valuable raw material. Sustainable whey management is mostly oriented to biotechnological and food applications for the development of value-added products such as whey powders, whey proteins, functional food and beverages, edible films and coatings, lactic acid and other biochemicals, bioplastic, biofuels and similar valuable bioproducts. This paper provides an overview of the sustainable utilization of whey and its constituents, considering new refining approaches and integrated processes to convert whey, or lactose and whey proteins to high value-added whey-based products.

Published
2021

7. Concentration of whey proteins using the Pressurized Gas eXpanded (PGX) liquid technology and their characterization

Author

Wong, Emily Y

Subjects
whey protein, waste utilization, Pressurized Gas eXpanded liquid technology, PGX technology, whey utilization, whey protein concentrate
Abstract

Abstract: The Pressurized Gas eXpanded (PGX) liquid technology utilizes CO2-expanded ethanol to simultaneously dry and purify high molecular weight biopolymers, producing micro/nanosized powders and fibrils with low bulk densities and high surface areas. The fractionation, concentration and drying of whey proteins directly from sweet- and acid-type whey was investigated using the PGX technology as a single unit operation to produce concentrated whey protein powders. The feasibility of processing a complex feedstock such as whey was first investigated using sweet whey on a laboratory scale system, followed by a 5x scale up to a bench-scale system and varied mass flow rate ratios (θPGX). Efficiently defatting and removing > 50% lactose from the dairy waste stream, whey powders containing ≥ 45% protein were obtained through the single-step concentration process. The concentrated whey powders were characterized in terms of their physicochemical attributes, specifically untapped bulk density, particle size distribution, specific surface area and pore size, surface morphology as well as the compositional analysis, protein composition and structure by determining the soluble protein content, analyzing the protein secondary structure, intrinsic protein fluorescence and protein hydrophobicity. PGX whey powders were primarily composed of major whey proteins, β-lactoglobulin, α-lactalbumin, and bovine serum albumin in the presence of amorphous lactose and milk minerals such as Ca, K, Mg, Na, P and S. The physicochemical attributes of the PGX whey powders were affected by the varying θPGX linked to the anti-solvent interaction with the biopolymer stream at the nozzle. At intermediate θPGX ratios, the whey proteins had similar protein structures to freeze-dried proteins, indicating that the PGX process is mild. At lower θPGX ratios, a reduced amount of PGX fluid (the CO2-expanded EtOH that breaks up the biopolymer stream) limits the anti-solvent-polymer interaction, thereby favouring biopolymeric polymer-polymer interactions, and overall resulting in fewer disruptions to the protein secondary structures (β-sheet and α-helix). With improved jet breakup at higher θPGX ratios, protein exposure to the solvent is increased, resulting in rearrangements of proteins to more compact configurations with increased protein hydrophobicity. To assess the potential of the PGX technology for commercial applications to produce whey protein concentrates, ultrafiltration and spray drying were introduced as reference methods in the second study. To evaluate the versatility of the PGX technology, a second type of whey feedstock was also introduced. The results demonstrated that the PGX technology was comparable to a one-step ultrafiltration process in terms of protein concentration. Whey protein concentration up to 4.4x was achievable utilizing sweet whey, while only 2.7x protein concentration was possible with acid whey feedstocks. Lactose reduction ranged from 25-50% with more effective reduction in sweet matrices compared to acid matrices. This indicated that while it is possible to concentrate whey proteins from various whey feedstocks, obtaining high protein content products from acid whey was more challenging compared to sweet whey due to the high level of ash content and lower amounts of protein in the feed material. Overall, these research findings are significant in the continued application of the PGX technology for the development of value-added ingredients for nutraceutical applications.

Published
2024

8. Techno-economic and Environmental Evaluation of Cheesemaking Waste Valorization Through Process Simulation Using SuperPro Designer.

Author

Gómez, James A., Sánchez, Óscar J., and Correa, Leonardo F.

Abstract

Purpose: The objective of this work was to perform a techno-economic and environmental assessment of several technological alternatives for production of whey syrups and protein concentrate (WPC) via process simulation under two scenarios: Stand-alone process and process attached to a cheese production plant. Methods: Information related to different industrial dairy processes (parameters, variables and diagrams) was consulted and gathered. A base case and three alternative technological configurations for production of whey syrups and WPC were designed. SuperPro Designer was employed as the process simulation tool and for the techno-economic assessment of the technological configurations, and WARGUI software was used for their environmental evaluation. A combined techno-economic and environmental indicator was calculated to identify the best alternative. Results: The alternative involving the production of WPC, glucose syrup, and glucose and fructose syrup had the best economic indicators (net present value of $3,381,000 and $16,354,000 for the stand-alone and attached processes, respectively). This alternative had a Potential Environmental Impact of 14,510 PEI/kg products for both scenarios. Water recovery from different waste streams was simulated, managing to reuse 322,338,477 kg water/year. Conclusions: The implementation of a process for producing whey syrups and WPC attached to a cheese production facility has the potential to generate a significant profitability for the dairy industries in a middle-income country like Colombia. Simulation techniques employed are a powerful supporting tool when making decisions in investment projects for valorization of waste from the food industry in order to find the most appropriate process configuration. [ABSTRACT FROM AUTHOR]

Published
2020
Full Text
View/download PDF

9. Simple utilization of lactic acid whey in dairy processing

Author

Csanádi J., Szász G., and H-Bara O.

Subjects
whey utilization, sour cream, ultrafiltration, Food processing and manufacture, TP368-456
Abstract

The use of ultra-filtered lactic acid whey retentate was investigated for the making of sour cream. The utilization of lactic acid whey is limited due to its special properties, so the logical utilization way is to use it in fermented products. First, we concentrated lactic acid whey collected from cottage cheese making by ultrafiltration (UF), then UF Whey Retentate (UFWR) was added (by 2, 5, and 10%) into fat standardized cream for sour cream making. We investigated the texture and sensory properties of the sour cream samples compared with the industrial products. Generally, we can state that the use of small portion of UF whey retentate did not result noticeable changes and did not reduce the sensory value of sour creams. Higher UF whey retentate addition improved some texture properties of experimental samples, but the summarized evaluation of UFWR addition was not unequivocal. Control samples showed better results. Based on our results, the sample, which contained 5% UF whey retentate, had good texture and acceptable sensory properties. Furthermore, more than 5% UF lactic acid whey retentate (coming from our own ultrafiltration process) resulted remarkably worse sensory properties than the other samples. Further investigation is needed to find the optimal composition and sensory properties of UFWR. Furthermore, we have to perform technological investigation to reach a higher concentration factor using pre-treatment of whey and to avoid the precipitation of whey proteins during the high temperature pasteurization of cream, cream mixed with UFWR or diafiltered whey retentate. We guess that the use of one-stage diafiltration would already decrease the unfavourable sensory properties of lactic acid whey retentate.

Published
2016
Full Text
View/download PDF

10. Comparative Study of Whey Utilization in India, New Zealand, and Australia- Identifying Untapped Potential and Means of Utilization.

Author

Das, Monami and Ghosh, Sadhan Kumar

Abstract

Whey, a major by-product of cheese and dairy industry has a high BOD and COD content due to the presence of lactose (4.5-5% w/v), making it highly polluting. Whey was previously treated as waste surplus, but presence of proteins and bioactive compounds makes it economically valuable, emerging as a resource for extraction of valuable compounds as well as feedstock for fermentation into ethanol. This process abates the pollution risks of whey surcharge while providing economic benefits in return. However this bioconversion of whey to ethanol is not practiced widely. The study investigates whey ethanol production or lack of it, in three countries- India, Australia, and New Zealand. While whey in New Zealand is mostly converted into ethanol, most of Australia's whey surplus is converted to secondary products aimed at exports. In India, however, due to lack of consolidated central structure for the dairy industry, supply chain of whey and it is use and disposal is undocumented and unregulated. Thus a comparative study of whey utilization by these countries, identifying the potential for effective, efficient and economical whey utilization is devised. [ABSTRACT FROM AUTHOR]

Published
2016

12. Ethanol Production from Whey by Kluyveromyces marxianus in Batch Fermentation System: Kinetics Parameters Estimation

Author

Dessy Ariyanti and Hadiyanto Hadiyanto

Subjects
ethanol, fermentation kinetics, kluyveromycess marxianus, lactose, whey utilization, Chemical engineering, TP155-156
Abstract

Whey is the liquid remaining after milk has been curdled and strained. It is a by-product of the manufacture of cheese or casein and has several commercial uses. In environmental point of view, whey is kind of waste which has high pollution level due to it’s contain high organic compound with BOD and COD value 50 and 80 g/L respectively. On the other side, whey also contain an amount of lactose (4.5%-5%); lactose can be used as carbon source and raw material for producing ethanol via fermentation using yeast strain Kluyveromyces marxianus. The objective of this research is to investigate the ethanol production kinetics from crude whey through fermentation using Kluyveromyces marxianus and to predict the model kinetics parameter. The yeast was able to metabolize most of the lactose within 16 h to give 8.64 g/L ethanol, 4.43 g/L biomass, and remain the 3.122 g/L residual lactose. From the results presented it also can be concluded that common kinetic model for microbial growth, substrate consumption, and product formation is a good alternative to describe an experimental batch fermentation of Kluyveromyces marxianus grown on a medium composed of whey. The model was found to be capable of reflecting all batch culture phases to a certain degree of accuracy, giving the parameter value: μmax, Ks, YX/S, α, β : 0.32, 10.52, 0.095, 1.52, and 0.11 respectively.© 2013 by Authors, Published by BCREC Group. This is an open access article under the CC BY-SA License (https://creativecommons.org/licenses/by-sa/4.0)

Published
2013
Full Text
View/download PDF

13. Dairy wastewater utilization: separation of whey proteins in membrane and chromatographic processes.

Author

Lech, Magdalena, Niesobska, Anita, and Trusek-Holownia, Anna

Subjects
WHEY proteins, DAIRY industry, PROTEIN fractionation, ULTRAFILTRATION, AFFINITY chromatography, ION exchange chromatography
Abstract

Dairies are obligated to utilize whey after cheese production. From an environmental protection point of view, the high content of lactose and proteins in post-production wastes, like whey, is harmful for the environment. From another point of view, whey is a source of very valuable, active proteins, particularly lactoferrin and serum albumin. Their modulatory potential is exhibited in their pure form and improves after partial, controlled hydrolysis. Unfortunately, the fractionation of this multicomponent medium is not an easy task. The paper describes an integrated process of fractionation of whey proteins. After the first step of treatment based on membrane techniques, the concentrated, most valuable whey proteins were subjected to a few steps of chromatographic separation. The separation properties of the ultrafiltration membranes were unexpected. The typical cut-off boundary was shifted in the direction of components having a lower molecular weight. After laboratory-scale testing, a concept for an industrial-scale process for the isolation of the most valuable whey proteins with purities of nearly 100% was elaborated. [ABSTRACT FROM PUBLISHER]

Published
2016
Full Text
View/download PDF

14. Bebida com adição de soro de leite e fibra alimentar prebiótica Drink with the addition of whey and prebiotic dietary fiber

Author

Mirela Guedes Bosi, Bruna Magnago Bernabé, Suzana Maria Della Lucia, and Consuelo Domenici Roberto

Subjects
aproveitamento de soro, aceitação sensorial, inulina, whey utilization, sensory acceptance, inulin, Agriculture (General), S1-972
Abstract

O objetivo deste trabalho foi avaliar a aceitação sensorial de bebida não fermentada, com adição de inulina e polpa de acerola. Seis formulações foram desenvolvidas, com adição de 0, 20, 40, 60, 80 e 100% de soro. O pH do soro foi 6,59, e a acidez de 0,103% de ácido lático. Utilizou-se a escala hedônica de nove pontos no teste de aceitação. As médias hedônicas das amostras com 0, 20 e 40% de soro não diferiram significativamente e variaram entre 6 e 8 pontos. As bebidas desenvolvidas com até 60% de soro são alternativas interessantes para o aproveitamento desse subproduto em laticínios.The objective of this work was to evaluate the sensorial acceptance of non‑fermented drink with addition of inulin and acerola pulp. Six beverage formulations were developed with addition of 0, 20, 40, 60, 80, and 100% whey. Whey pH was 6.59, and its acidity was 0.103% lactic acid. A nine‑point hedonic scale was used for the acceptance test. Hedonic means of samples with 0, 20, and 40% whey did not differ significantly and varied between 6 and 8. Developed beverages with up to 60% whey are good alternatives for harnessing this byproduct in milk companies.

Published
2013

15. Izraba odpadne kisle sirotke za gojenje laktobacilov s probiotičnim potencialom

Author

Žohar, Tjaša and Bogovič Matijašić, Bojana

Subjects
lactobacilli, probiotic bacteria, whey utilization, kisla sirotka, mikrobiološke metode, bioprocess, microbiological methods, uporaba sirotke, bioproces, yeast extract, bioreaktor, bioreactor, udc:637.344:602.4:579.864, kvasni ekstrakt, laktobacili, probiotične bakterije, by-product, stranski produkt, acid whey
Abstract

Kisla sirotka je tekoč stranski produkt, ki nastane pri fermentaciji ali kisli koagulaciji mleka z dodatkom organske ali anorganske kisline. V primerjavi z obdelavo sladke sirotke je predelava kisle sirotke veliko zahtevnejša, predvsem zaradi večje vsebnosti mlečne kisline, ki otežuje proces sušenja. Kisla sirotka je zato pogosteje obravnavana kot odpadek in predstavlja ekološko obremenitev oziroma strošek za proizvajalca. Namen magistrskega dela je bil raziskati uporabnost kisle sirotke, ki nastane pri industrijski izdelavi skute, za gojenje bakterij s probiotičnim potencialom. V manjšem merilu smo najprej pokazali, da so bili vsi izbrani sevi sposobni rasti v gojišču iz kisle sirotke. Obogatitev kisle sirotke s kvasnim ekstraktom in/ali mešanico mineralov je izboljšala rast sevov Lactiplantibacillus plantarum in seva Lacticaseibacillus rhamnosus IM239, ni pa vplivala na rast seva Lactobacillus paragasseri IM105. V večjem merilu smo nato z gojenjem v bioreaktorju pokazali, da je bil izplen živih bakterij boljši, če tekom fermentacije vrednosti pH nismo uravnavali. Ugotovili smo tudi, da so testirane bakterije, odvzete na začetku stacionarne faze rasti, bolje preživele liofiliziranje, če smo jim tekom gojenja uravnavali vrednost pH na 6,5, medtem ko pri kulturah, odvzetih po 24-ih urah, vpliv vrednosti pH ni bil tako izrazit. Z raziskavo smo tako potrdili potencial kisle sirotke za industrijsko gojenje mlečnokislinskih bakterij. Acid whey is a liquid fraction that remains after the fermentation of milk or the addition of organic or mineral acids to milk. The processing of acid whey is much more challenging than the processing of sweet whey, mainly because of the higher lactic acid content, which obstructs the drying process. Acid whey is, therefore, more often considered as waste, and as such as an ecological burden for the environment and an unwanted cost for the manufacturer. The purpose of this study was to investigate the possibility of using acid whey as a culture medium for probiotic bacteria. The acid whey used was the by-product of an industrial-sized production of cottage cheese. We first showed on a smaller scale that the chosen bacterial strains were able to grow in an acid whey medium. The addition of yeast extract and/or a mixture of minerals improved the growth of the Lactiplantibacillus plantarum strains and the Lacticaseibacillus rhamnosus IM239 strain, but it did not affect the growth of the Lactobacillus paragasseri IM105 strain. Then we showed on a larger scale that the yield of live bacteria was higher if the pH value was not regulated during the fermentation in a bioreactor. We also showed that the bacteria samples collected at the beginning of the stationary growth phase had a higher survival rate during freeze-drying if their pH value was adjusted to 6,5 during the fermentation. However, in the samples collected after 24 hours the pH value had a smaller effect on the survival rate during freeze-drying. With the study we thus confirmed that acid whey can be used as a growth medium for the cultivation of lactic acid bacteria.

Published
2021

16. Cottage cheese whey as an ingredient of cottage cheese dressing mixes.

Author

Monsoor, M A, Farooq, K, and Haque, Z U

Subjects
*COTTAGE cheese, *WHEY products, *CHEESEMAKING
Abstract

The objective of this study was to formulate and develop a good quality cottage cheese dressing using acid whey as the main ingredient. Up to 72% of cottage cheese whey was used in the dressing mixes. The percentage of fat (4.10–5.05%) and total solids (19.41–20.24%) approached the desired level and was within the legal limits for regular cottage cheese. Sensory evaluation scores for flavour, body/texture and appearance were not adversely affected by the use of acid whey. The sensory evaluation scores for all four products made with whey- or skimmed milk-based dressings were higher than the commercial control. [ABSTRACT FROM AUTHOR]

Published
2003
Full Text
View/download PDF

17. Whey Utilization: Sustainable Uses and Environmental Approach.

Author

Zandona E, Blažić M, and Režek Jambrak A

Abstract

The dairy industry produces large amounts of whey as a by- or co-product, which has led to considerable environmental problems due to its high organic matter content. Over the past decades, possibilities of more environmentally and economically efficient whey utilisation have been studied, primarily to convert unwanted end products into a valuable raw material. Sustainable whey management is mostly oriented to biotechnological and food applications for the development of value-added products such as whey powders, whey proteins, functional food and beverages, edible films and coatings, lactic acid and other biochemicals, bioplastic, biofuels and similar valuable bioproducts. This paper provides an overview of the sustainable utilization of whey and its constituents, considering new refining approaches and integrated processes to convert whey, or lactose and whey proteins to high value-added whey-based products., Competing Interests: CONFLICT OF INTEREST The authors declare that there is no conflict of interest.

Published
2021
Full Text
View/download PDF

18. Bebida com adição de soro de leite e fibra alimentar prebiótica

Author

Bosi, Mirela Guedes, Bernabé, Bruna Magnago, Della Lucia, Suzana Maria, and Roberto, Consuelo Domenici

Subjects
aceitação sensorial, whey utilization, inulin, sensory acceptance, aproveitamento de soro, inulina
Abstract

O objetivo deste trabalho foi avaliar a aceitação sensorial de bebida não fermentada, com adição de inulina e polpa de acerola. Seis formulações foram desenvolvidas, com adição de 0, 20, 40, 60, 80 e 100% de soro. O pH do soro foi 6,59, e a acidez de 0,103% de ácido lático. Utilizou-se a escala hedônica de nove pontos no teste de aceitação. As médias hedônicas das amostras com 0, 20 e 40% de soro não diferiram significativamente e variaram entre 6 e 8 pontos. As bebidas desenvolvidas com até 60% de soro são alternativas interessantes para o aproveitamento desse subproduto em laticínios. The objective of this work was to evaluate the sensorial acceptance of non‑fermented drink with addition of inulin and acerola pulp. Six beverage formulations were developed with addition of 0, 20, 40, 60, 80, and 100% whey. Whey pH was 6.59, and its acidity was 0.103% lactic acid. A nine‑point hedonic scale was used for the acceptance test. Hedonic means of samples with 0, 20, and 40% whey did not differ significantly and varied between 6 and 8. Developed beverages with up to 60% whey are good alternatives for harnessing this byproduct in milk companies.

Published
2013

Catalog

Books, media, physical & digital resources
See catalog results