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authors |
Neves, CMSS; Sousa, RDS; Pereira, MM; Freire, MG; Coutinho, JAP |
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nationality |
International |
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journal |
BIOCHEMICAL ENGINEERING JOURNAL |
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author keywords |
Aqueous biphasic systems; Partition; Extraction; Ionic liquids; Adjuvants; Biomolecules |
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keywords |
BIPHASIC SYSTEMS; EXTRACTION CAPABILITY; CONTROLLED PH; PURIFICATION; SEPARATION; BOOST |
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abstract |
Ionic liquids (ILs) as adjuvants in polymer-salt aqueous two-phase systems (ATPS) have been used to improve the extraction of biomolecules. However, the impact of Its as adjuvants on the partition of biomolecules is still poorly understood. Previous works mostly focused on ATPS based on strong salting-out agents, which may mask the IL effect. In this work, ATPS formed by polyethylene glycol (PEG 400) and a weak salting-out salt ((NH4)(2)SO4) with a wide number of Its as adjuvants (chloride-based combined with cholinium, imidazolium, pyrrolidinium, piperidinium, tetralkylammonium and tetralkylphosphonium cations) were investigated. The respective phase diagrams were determined, and the systems extraction performance for a wide range of biomolecules (phenolic compounds, alkaloids and amino acids) was investigated. The results obtained show that ILs as adjuvants in polymer-salt ATPS modulate the partition of biomolecules. In particular, more hydrophobic ILs significantly enhance the partition of more hydrophobic biomolecules to the PEG-rich phase (where the IL is enriched). Furthermore, the intensity of the IL effect is more pronounced when using weak salting-out agents. A linear correlation between the biomolecules and the Its partition coefficients, and with the biomolecules octanol-water partition coefficients, was found. In most ATPS formed by polymers and salts using ILs as adjuvants, the biomolecules partition is driven by the Its partition and by the difference in hydrophobicity between the coexisting phases. |
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publisher |
ELSEVIER |
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issn |
1369-703X |
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isbn |
1873-295X |
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year published |
2019 |
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volume |
141 |
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beginning page |
239 |
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ending page |
246 |
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digital object identifier (doi) |
10.1016/j.bej.2018.10.022 |
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web of science category |
Biotechnology & Applied Microbiology; Engineering, Chemical |
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subject category |
Biotechnology & Applied Microbiology; Engineering |
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unique article identifier |
WOS:000453623900026
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