Potential Environmental and Health Impacts of High Land Application of Cheese Whey

Ghaly, A. E.; Mahmoud, N. S.; Rushton, D.G.; Arab, F.

doi:10.3844/ajabssp.2007.106.117

Cited by 19 publications

(2 citation statements)

References 34 publications

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“…This could result in the soil's Fe and Mn becoming soluble, potentially contaminating groundwater sources. According to Ghaly et al (2007), each millimeter (103/ha) of whey applied to the soil reportedly adds approximately 400-600 kg of total salt per hectare, causing elevated soil salinity and diminished crop yields. The atmosphere is also exposed to hazardous toxic gases derived from DI, such as nitrogen oxide, sulfur oxides, and carbon dioxide (Alkorta et al, 2017).…”

Section: Dairy Effluent-related Environmental Problemsmentioning

confidence: 99%

Innovative applications of whey protein for sustainable dairy industry: Environmental and technological perspectives—A comprehensive review

El‐Aidie,

Khalifa

2024

Comp Rev Food Sci Food Safe

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Industrial waste management is critical to maintaining environmental sustainability. The dairy industry (DI), as one of the major consumers of freshwater, generates substantial whey dairy effluent, which is notably rich in organic matter and thus a significant pollutant. The effluent represents environmental risks due to its high biological and chemical oxygen demands. Today, stringent government regulations, environmental laws, and heightened consumer health awareness are compelling industries to responsibly manage and reuse whey waste. Therefore, this study investigates sustainable solutions for efficiently utilizing DI waste. Employing a systematic review approach, the research reveals that innovative technologies enable the creation of renewable, high‐quality, value‐added food products from dairy byproducts. These innovations offer promising sustainable waste management strategies for the dairy sector, aligning with economic interests. The main objectives of the study deal with, (a) assessing the environmental impact of dairy sector waste, (b) exploring the multifaceted nutritional and health benefits inherent in cheese whey, and (c) investigating diverse biotechnological approaches to fashion value‐added, eco‐friendly dairy whey‐based products for potential integration into various food products, and thus fostering economic sustainability. Finally, the implications of this work span theoretical considerations, practical applications, and outline future research pathways crucial for advancing the sustainable management of dairy waste.

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Section: Dairy Effluent-related Environmental Problemsmentioning

confidence: 99%

Innovative applications of whey protein for sustainable dairy industry: Environmental and technological perspectives—A comprehensive review

El‐Aidie,

Khalifa

2024

Comp Rev Food Sci Food Safe

View full text Add to dashboard Cite

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“…High butanol yields have been reported when using this substrate [24], [32] and it is available in relatively large quantities [33]- [35]. Around 50 % of this residue is dumped into sewage systems or directly into water bodies, therefore it can have a negative effect on the environment [34]- [36]. So, using it for fermentation processes has some additional benefits like reduction of environmental pollution.…”

Section: Evaluation Of Waste Substrates For Fermentationmentioning

confidence: 99%

In Search of the Best Technological Solutions for Optimal Biobutanol Production: A Multi-Criteria Analysis Approach

Berzina,

Mika,

Spalvins

2023

Environmental and Climate Technologies

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Rising energy demands and the environmental impact of fossil fuel combustion have promoted a growing interest in alternative fuel sources. Biobutanol is a promising biofuel that can be used as a partial or complete substitute for petrol in unmodified internal combustion engines. It can be produced through a microbiological process called ABE fermentation. Currently, its production is uncompetitive in the market, but researchers are still working on solutions to improve the technology. This paper used a multi-criteria decision analysis method to evaluate different alternatives for biobutanol production: microorganism strain, agro-industrial waste substrate as process feedstock, bioreactor type and extraction method. It was determined that C. beijerinckii and C. saccharoperbutylacetonicum have great potential for being used for efficient biobutanol production. Cheese whey is a promising residue for being used in the fermentation medium. Other residues evaluated in the paper gained similar results as being “close to ideal”. Fed-batch with immobilized cells was chosen as the most promising fermentation method. It showed the greatest prospects as an optimal way to produce butanol. And, finally, adsorption and liquid-liquid extraction methods were identified as the most promising for ABE product extraction in comparison to others. Identified combinations of optimal solutions for microorganisms, fermentation methods, substrates and extraction techniques should be further evaluated in the laboratory setting.

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Valorization of whey using a biorefinery

Sebastián-Nicolas

González-Olivares

Vázquez‐Rodríguez

et al. 2020

Biofuels Bioprod Bioref

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In Mexico, whey is discarded into drains without treatment, which represents an environmental problem. It is known that whey is a mixture of nutrients that increase biochemical demand (BOD) and chemical oxygen demand (COD), exceeding the limits established by national and international standards. Some uses of whey have been proposed to reduce the negative impact it produces on the environment. Some of these uses are the production of high‐value raw materials, separation of macromolecules of industrial interest, and the generation of energy, among others. The integral use of waste under a biorefinery scheme represents a viable alternative for the use of this waste. In this way, the chemical composition of the waste can be used to recover compounds with high added value. The main objective of this review is to propose a dairy whey biorefinery to use components of commercial interest. This biorefinery process involves three stages: the first is the separation of lactoferrin using a polyacrylamide matrix (PAM) impregnated with copper; the second is lactic fermentation using the residue resulting from the separation of lactoferrin, from which lactic acid, hydrolyzed proteins, and probiotics will be obtained. Finally, in the third stage, the residue from the previous stage can be used to generate biogas. © 2020 Society of Chemical Industry and John Wiley & Sons, Ltd

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Potential Environmental and Health Impacts of High Land Application of Cheese Whey

Cited by 19 publications

References 34 publications

Innovative applications of whey protein for sustainable dairy industry: Environmental and technological perspectives—A comprehensive review

Innovative applications of whey protein for sustainable dairy industry: Environmental and technological perspectives—A comprehensive review

In Search of the Best Technological Solutions for Optimal Biobutanol Production: A Multi-Criteria Analysis Approach

Valorization of whey using a biorefinery

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