Results 41 to 50 of about 15,140 (295)

The application of deep eutectic solvent ionic liquids for environmentally-friendly dissolution and recovery of precious metals [PDF]

, 2016
publisher: Elsevier articletitle: The application of deep eutectic solvent ionic liquids for environmentally-friendly dissolution and recovery of precious metals journaltitle: Minerals Engineering articlelink: http://dx.doi.org/10.1016/j.mineng.2015.09 ...
Abbott, Abbott, Abbott, Abbott, Abbott, Ahmed Z.M. Al-Bassam, Andrew P. Abbott, Chapman, Christopher J. Stanley, Curtis, Daniel J. Smith, David A. Holwell, Dominy, Dong, Gawen R.T. Jenkin, Groen, Hill, Luczak, Robert C. Harris, Robert J. Chapman, Schouwstra, Smith, Spry, Vaughan, Wadsworth, Whitehead, Whitehead, Whitehead, Woodhouse, Zhang   +29 more
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Design of controlled release systems for THEDES - therapeutic deep eutectic solvents, using supercritical fluid technology [PDF]

, 2015
Deep eutectic solvents (DES) can be formed by bioactive compounds or pharmaceutical ingredients. A therapeutic DES (THEDES) based on ibuprofen, a non-steroidal anti-inflammatory drug (NSAID), and menthol was synthesized and its thermal behavior was ...
Aroso, Ivo Manuel Ascensão, Barreiros, Susana, Craveiro, Rita, Dionisio, Madalena, Duarte, Ana Rita C., Paiva, Alexandre, Reis, R. L., Rocha, Ângelo   +7 more
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Deep Eutectic Solvents for Pretreatment, Extraction, and Catalysis of Biomass and Food Waste

Molecules, 2019
Valorization of lignocellulosic biomass and food residues to obtain valuable chemicals is essential to the establishment of a sustainable and biobased economy in the modern world.
Payam Kalhor, Khashayar Ghandi
doaj   +1 more source

Deep Eutectic Solvents: The Organic Reaction Medium of the Century [PDF]

, 2016
This microreview summarizes the use of deep eutectic solvents (DESs) and related melts in organic synthesis. Solvents of this type combine the great advantages of other proposed environmentally benign alternative solvents, such as low toxicity, high ...
Abbott, Abbott, Abbott, Abbott, Abbott, Abbott, Abbott, Abo-Hamad, Amelio, Aparicio, Assanosi, Azizi, Azizi, Azizi, Azizi, Azizi, Azizi, Azizi, Azizi, Azizi, Azizi, Azizi, Azizi, Azizi, Azizi, Azizi, Azizi, Azizi, Bafti, Bakavoli, Beckman, Bednarz, Borse, Cao, Cardellini, Carriazo, Chahdoura, Chai, Chaskar, Chen, Chen, Constable, Cragg, Dai, Dai, Dai, Dai, Davey, De Oliveira Vigier, De Oliveira Vigier, De Santi, del Monte, Disale, Domínguez de María, Domínguez de María, Duan, Dupont, Durand, Díaz-Álvarez, Earle, Ferreira, Fischer, Francisco, Gambino, García, García-Verdugo, García-Álvarez, García-Álvarez, Gill, Gore, Gorke, Gu, Guajardo, Gupta, Hallet, Handy, Handy, Handy, Hari, Hawkins, Hayyan, Henderson, Hu, Hu, Ilgen, Ilgen, Imperato, Imperato, Imperato, Itoh, Jella, Jérôme, Karmakar, Kemeling, Keshavarzipour, Khandelwal, Krishnakumar, Kumar, Kus, Laird, Lavilla, Li, Li, Li, Li, Lindström, Liu, Liu, Liu, Lobo, Lobo, Lu, Macaev, Machida, Mahboub, Mallardo, Martins, Matsuda, Maugeri, Maugeri, Maugeri, Mobinikhaledi, Morales, More, Müller, Müller, Pace, Pal, Pandey, Patil, Pavia, Pawar, Pednekar, Pena-Pereira, Pena-Pereira, Peters, Phadtare, Phadtare, Pincock, Pérez, Pérez-Sánchez, Radošević, Rastogi, Reddy, Rodríguez-Álvarez, Ruß, Saberi, Sanap, Sanap, Santos, Sassone, Scholten, Serrano, Sheldon, Shuklov, Singh, Singh, Singh, Singh, Singh, Smith, Sonawane, Steinrück, Stepankova, Sunitha, Tanaka, Tang, Tang, Vidal, Vidal, Vidal, Wagle, Wang, Wang, Wang, Wang, Wang, Wang, Wasserscheid, Welton, Xia, Yadav, Yadav, Yadav, Yu, Zhang, Zhang, Zhang, Zhang, Zhang, Zhang, Zhao, Zhao   +192 more
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Production of electrospun fast-dissolving drug delivery systems with therapeutic eutectic systems encapsulated in gelatin [PDF]

, 2017
Fast-dissolving delivery systems (FDDS) have received increasing attention in the last years. Oral drug delivery is still the preferred route for the administration of pharmaceutical ingredients. Nevertheless, some patients, e.g.
A Pimenta, Alexandre Paiva, Ana Rita C. Duarte, ARC Duarte, BB Doyle, BD Ulery, C Yang, D Li, D-G Yu, DH Robinson, FL Lopez, Francisca Mano, G Tiwari, H Jukola, H-F Wen, IM Aroso, IM Aroso, Isabel Sá-Nogueira, J-M Jeon, JM Andrews, João Paulo Borges, JP Canejo, KY Lee, M Irfan, Marta Martins, P Sajkiewicz, PW Stott, Q Zhang, R Santos Dos, Rui L. Reis, S Koombhongse, S Ramakrishna, S Zhang, Susana Barreiros, V Parkash, VG Kadajji, Y Dai   +36 more
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Bio-renewable enantioselective aldol reaction in natural deep eutectic solvents [PDF]

, 2016
Among the deep eutectic solvents (DES), natural deep eutectic solvents (NADES) formed by D-glucose and racemic malic acid are suitable media to perform the enantioselective L-proline catalyzed intermolecular aldol reaction, creating simultaneously and ...
Berbegal, Lucía, Guillena, Gabriela, Martínez Flores, Regina, Ramón, Diego J.   +3 more
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Solubility and Solvation Properties of Pharmaceutically Active Ionic Liquid Benzocainium Ibuprofenate in Natural Deep Eutectic Solvent Menthol–Lauric Acid

Molecules, 2023
Due to their appealing physiochemical properties, particularly in the pharmaceutical industry, deep eutectic solvents (DESs) and ionic liquids (ILs) are utilized in various research fields and industries. The presented research analyzes the thermodynamic
Jovana Panić, Maksim Rapaić, Slobodan Gadžurić, Milan Vraneš   +3 more
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Deep Eutectic Solvents (DESs) and their applications [forthcoming] [PDF]

, 2014
Deep Eutectic Solvents (DESs) and Their ...
Abbott A., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abbott A. P., Abood H. M. A., Aidoudi F. H., Andrew P. Abbott, Avalos M., Azizi N., Azizi N., Azizi N., Azizi N., Azizi N., Bagh F. S. G., Ballantyne A., Biswas A., Bolkan S. A., Bonhote P., Bougouma M., Böck R., Carriazo D., Carvalho M. M., Chen F., Chen S., Chen S., Chen Z., Chen Z., Choi Y. H., Chu Q., Chung P. P., Clouthier C. M., Cojocaru P., Cooper E. R., Corma A., Corma A., Costa R., Cundy C. S., Davis M. E., De Vreese P., Deetlefs M., Diaz-Alvarez A. E., Dominguez de Maria P., Dong J.-Y., Drylie E. A., D’Agostino C., Emma L. Smith, Endres F., Endres F., Fannin A. A., Feng P., Ferreira E., Figueiedo M., Francisco M., Freyhardt C. C., Gambino M., Gambino M., Ge X., Gomez E., Gorke J., Gorke J. T., Graham A. K., Gu C., Gu C. D., Gu C. D., Gu C.-D., Guitierrez M. C., Gutierrez M., Gutierrez M. C., Gutierrez M. C., Gutierrez M. C., Haerens K., Haerens K., Haerens K., Hammons J. A., Handy S., Hao G. P., Hawkins I., Hayyan A., Hayyan M., Hayyan M., Hayyan M., Himeur F., Himeur F., Hsiu S. I., Hu S., Huang W., Huang Y., Hurley F. H., Jhang P.-C., Jhong H.-Ru., Kareem M. A., Karl S. Ryder, Konig U., Lanzinger G., Lawes S. D. A., Lee H., Lee Y. R., Leron R. B., Leron R. B., Leron R. B., Li C. P., Li L. M., Li S. Y., Li X., Li Y., Liao H.-G., Lin C. M., Lin I. J. B., Lin Y. F., Lin Y.-F., Lin Z., Lin Z., Lindberg D., Liu L., Liu L., Liu L., Liu L., Liu L., Liu W., Lloyd D., Lobo R. F., Lohmeier S. J., MacFarlane D. R., Malaquias J., Mamajanov I., Martins A. C., Maugeri Z., Meng Y., Michel A., Mondal D., Morales R. C., Morrison H. G., Mota-Morales J. D., Pandey A., Parnham E. R., Parnham E. R., Parnham E. R., Parnham E. R., Patil U. B., Patil U. B., Pawar P. M., Pednekar S., Phadtare S. B., Pollet B. G., Popescu A. M., Popescu A.-M. J., Ramesh S., Ramesh S., Rodrigues F., Ryder K. S., Salome S., Saravanan G., Sebastian P., Serrano M. C., Shahbaz K., Shahbaz K., Shahbaz K., Shahbaz K., Shahbaz K., Shahbaz K., Singh B., Singh B., Sitze M. S., Sitze M. S., Skopek M. A., Smith E. L., Smith E. L., Smith E. L., Smith E. L., Sonawane Y. A., Steichen M., Steichen M., Su W. C., Sun T., Taubert J., Taubert J., Taylor A. W., Vijayakumar J., Wang H., Wang H., Wang L., Wang L., Wang L., Wang S.-M., Wang S.-M., Wang S.-M., Wasserscheid P., Wei L., Wei L., Welton T., Wheatley P. S., Wilkes J. S., Wilkes J. S., Wilkes J. S., Xu W. G., Yang D. Z., Yang H., Yang H. Y., Yang J. Z., Yang J.-Z., Zdanowicz M., Zecchina A., Zein El Abedin S., Zhang F., Zhang J., Zhang Q. H., Zhao H., Zhao H., Zhao H., Zhao H., Zhao H., Zhu A., Zhu A. L.   +257 more
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Improving laccase thermostability with aqueous natural deep eutectic solvents

International Journal of Biological Macromolecules, 2020
The wide-spread use of laccases in industry is often limited due to the enzyme inactivation over time at conditions which exceeds the operating conditions of the enzymes, which are neutral pH and ambient temperatures (30-40 °C). Natural Deep Eutectic Solvents (NADESs) have attracted considerable attention as reaction media in biocatalysis due to their ...
Delorme, Astrid, Andanson, Jean-Michel, Verney, Vincent   +2 more
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Indirect assessment of the fusion properties of choline chloride from solid-liquid equilibria data [PDF]

, 2017
The temperature and enthalpy of fusion of choline chloride -[Ch]Cl- are not directly measurable since this compound decomposes upon melting. Yet, given the wide use of this compound in the preparation of deep eutectic solvents (DES), its thermophysical ...
Coutinho, João A.P., Fernandez, Luis, Ferreira, Olga, Martins, Mónia A.R., Ortega, Juan, Pinho, Simão, Silva, Liliana P.   +6 more
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