Olive mill wastewater valorisation through phenolic compounds adsorption in a continuous flow column

Frascari, Dario; Bacca, Aurora Esther Molina; Zama, Fabiana; Bertin, Lorenzo; Fava, Fabio; Pinelli, Davide

doi:10.1016/j.cej.2015.07.048

Cited by 87 publications

(84 citation statements)

References 56 publications

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“…Consequently, in the last few years, a myriad of sources have been investigated to supply the growing market of natural antioxidants: olive mill wastewaters [7][8][9], apple pomace [10],…”

Section: Introductionmentioning

confidence: 99%

Sequential pressure-driven membrane operations to recover and fractionate polyphenols and polysaccharides from second racking wine lees

Giacobbo

Bernardes

Pinho

2017

Separation and Purification Technology

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“…Consequently, in the last few years, a myriad of sources have been investigated to supply the growing market of natural antioxidants: olive mill wastewaters [7][8][9], apple pomace [10],…”

Section: Introductionmentioning

confidence: 99%

Sequential pressure-driven membrane operations to recover and fractionate polyphenols and polysaccharides from second racking wine lees

Giacobbo

Bernardes

Pinho

2017

Separation and Purification Technology

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“…This phase is dedicated to the development and adaptation of technologies for WW treatment and water efficiency in agriculture to the local context of the 3 MACs. To maximize the impact of MADFORWATER, 4 water categories are taken into consideration: Municipal WW (MWW), which represents 82%–92% of the total WW produced; only 50% of MWW produced is currently treated in the target MACs. Textile WW (TWW), a relevant type of industrial WW in the 3 MACs (textile production provides 6% of GDP in Egypt, 7% in Morocco and Tunisia). Agro‐industrial WWs, in particular olive mill WW (OMWW) and fruit and vegetable packaging WW (FVPWW), due to their quantitative and qualitative relevance in all 3 MACs and to the lack of cost‐effective, industrial‐scale processes for their treatment (Frascari et al ). Drainage canal water (DCW) of the Nile Delta (Egypt), a mixture of freshwater from the Nile river and water from irrigation drains, with minor contributions from untreated or partially treated municipal and industrial WWs; DCW is extensively used for irrigation (11 × 10 9 m 3 /y; FAO 2017). …”

Section: The Madforwater Strategy To Enhance Wastewater Treatment Wamentioning

confidence: 99%

Integrated technological and management solutions for wastewater treatment and efficient agricultural reuse in Egypt, Morocco, and Tunisia

Frascari

Zanaroli

Motaleb

et al. 2018

Integr Envir Assess & Manag

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Mediterranean-African countries (MACs) face a major water crisis. The annual renewable water resources are close to the 500 m /capita threshold of absolute water scarcity, and water withdrawals exceed total renewable water resources by 30%. Such a low water availability curbs economic development in agriculture, which accounts for 86% of freshwater consumption. The analysis of the current situation of wastewater treatment, irrigation, and water management in MACs and of the research projects targeted to these countries indicates the need for 1) an enhanced capacity to analyze water stress, 2) the development of water management strategies capable of including wastewater reuse, and 3) development of locally adapted water treatment and irrigation technologies. This analysis shaped the MADFORWATER project (www.madforwater.eu), whose goal is to develop a set of integrated technological and management solutions to enhance wastewater treatment, wastewater reuse for irrigation, and water efficiency in agriculture in Egypt, Morocco, and Tunisia. MADFORWATER develops and adapts technologies for the production of irrigation-quality water from drainage canals and municipal, agro-industrial, and industrial wastewaters and technologies for water efficiency and reuse in agriculture, initially validated at laboratory scale, to 3 hydrological basins in the selected MACs. Selected technologies will be further adapted and validated in 4 demonstration plants of integrated wastewater treatment and reuse. Integrated strategies for wastewater treatment and reuse targeted to the selected basins are developed, and guidelines for the development of integrated water management strategies in other basins of the 3 target MACs will be produced. The social and technical suitability of the developed technologies and nontechnological tools in relation to the local context is evaluated with the participation of MAC stakeholders and partners. Guidelines on economic instruments and policies for the effective implementation of the proposed water management solutions in the target MACs will be developed. Integr Environ Assess Manag 2018;14:447-462. © 2018 The Authors. Integrated Environmental Assessment and Management published by Wiley Periodicals, Inc. on behalf of Society of Environmental Toxicology & Chemistry (SETAC).

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“…Thus, the adsorption process is preferred because it is a low-cost separation technique, applicable for industrial scale processes, with high adsorption capacities, possible recovery of the adsorbed molecules and easy regeneration (Abdelkreem, 2013;Kammerer et al, 2011;Soto et al, 2011). Resins have been applied for the adsorption of phenolic compounds and hydroxytyrosol from olive oil mill wastewater (Agalias et al, 2007;Frascari et al, 2016;Petrotos et al, 2016Petrotos et al, , 2013, hydroxytyrosol and tyrosol from fermentation brine wastewater (Ferrer-Poloniom et al, 2016), spinacetin and patuletin from spinach leaves (Aehle et al, 2004), polyphenols from kiwifruit juice (Gao et al, 2013), limonin and naringin from orange juice (Ribeiro et al, 2002), hesperidin from orange peel (Di Mauro et al, 1999), anthocyanins from roselle (Chang et al, 2012), narirutin from a water-extract of Citrus unshiu peels (Kim et al, 2007), genistein and apigenin from extracts of pigeon pea roots (Liu et al, 2010), anthocyanins and hydroxycinnamates from orange juice (Scordino et al, 2005), chlorogenic acid and apigenin-7-O-glucoside from artichoke wastewaters (Conidi et al, 2015), catechin, epicatechin, epicatechin gallate, epigallocatechin gallate and caffeine from green tea (Jin et al, 2015; MARK 2016), catechins and theaflavins from black tea (Monsanto et al, 2015). The study of plant extracts is complex due to the interactions of other plant constituents, which could has an impact on phenolic binding (Bretag et al, 2009;Kammerer et al, 2010).…”

Section: Introductionmentioning

confidence: 99%

Recovery of phenols from autohydrolysis liquors of barley husks: Kinetic and equilibrium studies

Conde

Moure

Domı́nguez

2017

Industrial Crops and Products

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Olive mill wastewater valorisation through phenolic compounds adsorption in a continuous flow column

Cited by 87 publications

References 56 publications

Sequential pressure-driven membrane operations to recover and fractionate polyphenols and polysaccharides from second racking wine lees

Sequential pressure-driven membrane operations to recover and fractionate polyphenols and polysaccharides from second racking wine lees

Integrated technological and management solutions for wastewater treatment and efficient agricultural reuse in Egypt, Morocco, and Tunisia

Recovery of phenols from autohydrolysis liquors of barley husks: Kinetic and equilibrium studies

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