, 6-ANS) CANS: concentration of 2-anilino-6-naphthalenesulfonate (2,6-ANS) Vbuffer: volume of buffer An initial 2 mM solution of the guest molecule (2,6-ANS) was prepared in a mixture of methanol (30%) and a buffer solution, CCD: concentration of cyclodextrin VCD: volume of cyclodextrin VANS: volume of 2-anilino-6-naphthalenesulfonate

, Schéma 16 : synthèse assistée de substrat supporté sur liquide ionique 41 _______________________________ 33

, Schéma 17 : les réactions de Diels-Alder et de clivage du support _____________________________________ 34

, Schéma, vol.18

, Schéma 19 : oxydation des alcools catalysée par LI supporté sur silice et TEMPO supporté _________________ 36

, Schéma 20 : oxydation des alcools catalysée par LI supporté sur silice _________________________________ 37

, synthèse des carbonates cycliques à partir des IL-CNT ____________________________________ 38, vol.21

, Schéma 22 : matériau cellulosique à base de chlorure de méthylimidazolium ___________________________ 38

, Schéma 23 : cycloaddition de CO 2 avec différents époxydes catalysée par

, Schéma 24 : a) réaction de redistribution dans le cas du PCL ; b) réaction de rétrocession dans le cas du PCL __ 47

, Schéma 25 : mécanisme de la POC par voie cationique _____________________________________________ 48

, POC du 1,5-dioxépan-2-one via un catalyseur cationique _________________________________ 48, Schéma, vol.26

, POC d'un ester cyclique inférieur ou égal à 4 chainons par initiation anionique. Ouverture du monomère par 1) clivage de la liaison acyl-oxygène et 2) clivage des liaisons, Schéma, vol.27

, Schéma 28 : mécanisme de la polymérisation par ouverture du cycle __________________________________ 50

, Schéma 29 : mécanisme de la POC par coordination-insertion des lactones _____________________________ 52

, Schéma 30 : synthèse de différents types de copolymère à bloc ______________________________________ 52

, structure des différentes formes stéréométriques du monomère lactide : ____________________ 57, vol.32

, Schéma 33 : méthodes de synthèse du PLA 95 ______________________________________________________ 58

, Schéma 34 : représentation de la tacticité du PLA _________________________________________________ 59

, Schéma 35 : les grandes catégories de polymères classifiés selon leur tacticité __________________________ 60

, synthèse des liquides ioniques, vol.37, pp.7-9

, Schéma 38 : échange en position 2 du cation imidazolium avec le deutérium 44 __________________________ 72

, Schéma 39 : mode d'activation proposé pour la POC catalysée par un sel d'imidazolium __________________ 77

, POC du rac-lactide par les liquides ioniques chiraux 12 et 13 ______________________________ 80, vol.41

, POC du D, L-lactide avec le liquide ionique 13 __________________________________________ 89, vol.43

, Schéma 44 : mode d'activation proposé pour le POC catalysé par un LIC 12 _____________________________ 89

, Schéma 45 : mécanisme de racémisation lors de la polymérisation anionique ___________________________ 91

, Schéma 46 : les mécanismes de la POC proposés en présence de SnOct 2 _______________________________ 92

, Schéma 47 : préparation d'alcoxydes d'étain (IV) __________________________________________________ 93

, Schéma 48 : période d'induction pour défaire les agrégats des alcoxydes métalliques_____________________ 96

, Schéma 49 : halogénures de triorganoétain supportés sur polymère solide _____________________________ 99

, POC de l'?-caprolactone catalysée par le C 11 SnCl 3 ______________________________________ 100, Schéma, vol.50

, Schéma 51 : formation de l'halogénure d'organoétain _____________________________________________ 101

, Schéma 52 : monoalkylétains activés par une source de fluorure ____________________________________ 102

, POC de l'?-CL en utilisant le catalyseur organostannique ________________________________ 104, Schéma, vol.53

, Schéma 54 : polymérisation du lactide avec le tétra(phényléthynyl) d'étain ____________________________ 105

, Schéma 55 : voie de synthèse 1 _______________________________________________________________ 106

, Schéma, vol.56, p.107

, Schéma 57 : voie de synthèse 2 _______________________________________________________________ 108

, Schéma 58 : rétrosynthèse du dérivé à base d'étain supporté sur liquide ionique ________________________ 109

, Schéma 59 : synthèse de l'organostannique 26 ___________________________________________________ 109

, Schéma 60 : réactifs d'étain supportés par un liquide ionique 27 _____________________________________ 109

, Schéma 62 : conversion in situ du catalyseur trichloré en alcoolate d'étain ____________________________ 112

, POC de l'?-CL avec le butyltrichloroétain comme catalyseur ______________________________ 112, Schéma, vol.63

, Schéma 64 : formation de l'alcoolate d'étain in situ lors de la POC de l'?-CL ____________________________ 115

, Schéma 65 : mécanisme de la POC de l'?-CL par coordination-insertion en utilisant l'organostannane supporté sur LI 6 comme catalyseur et l'isopropanol comme cocatalyseur _____________________________________ 117

, Schéma 66 : minéralisation des échantillons polymère avant analyse ICP ______________________________ 121

, Schéma 67: formation de complexe d'inclusion de type hôte

, Schéma 68 : synthèse de la bêta-cyclodextrine 2 _________________________________________________ 134

, Schéma 69 : préparation de la ?-CD-Ts via la voie, vol.1, pp.203-135

, Schéma 70 : voies de synthèse de la TRIME?-CD-NH 2 5 et de la ?-CD-NH 2 6 _____________________________ 136

, synthèse du liquide ionique, vol.71, p.147

, Schéma 72 : synthèse du liquide ionique 10 par voie micro-onde _____________________________________ 148

, Schéma 73 : formation d'une liaison amide entre le liquide ionique 9 et la TRIME?-NH 2 5 _________________ 149

, Schéma 75 : couplage peptidique entre le liquide ionique 10 et la ?-CD(OH)-NH 2 6 ______________________ 150

, Schéma 76 : immobilisation du complexe CD-LI 11a sur un polymère chargé (PSS) par dialyse _____________ 151

, Schéma 77 : métathèse de la ?-CD modifiée 13 sur le PSS __________________________________________ 154

, Schéma 78 : formation d'un complexe d'inclusion entre la 2

, Schéma 79 : dispositif de purification des eaux usées avec le complexe CD-LI + PSS -_______________________ 176

I. L. Librando and E. C. Creencia, Procedia Chemistry, vol.16, pp.299-305, 2015.

M. Deetlefs, K. R. Seddon, and G. Chemistry, , vol.5, pp.181-186, 2003.

A. Abbott, Chemical Society Reviews, vol.22, pp.435-440, 1993.

H. Olivier-bourbigou, L. Magna, and D. Morvan, Applied Catalysis A: General, vol.373, pp.1-56, 2010.

L. Magna, Y. Chauvin, G. P. Niccolai, and J. Basset, Organometallics, vol.22, pp.4418-4425, 2003.

H. Nasrallah, S. Germain, P. Queval, C. Bouvier, M. Mauduit et al.,

. Schulz, Journal of Molecular Catalysis A: Chemical, vol.425, pp.136-146, 2016.

A. K. Burrell, R. E. Sesto, S. N. Baker, T. M. Mccleskey, and G. A. Baker, Green Chemistry, vol.9, pp.449-454, 2007.

C. Chiappe, Monatshefte für Chemie -Chemical Monthly, vol.138, pp.1035-1043, 2007.

H. Taher and S. Al-zuhair, Biofuels, Bioproducts and Biorefining, vol.11, pp.168-194, 2017.

W. Ogihara, N. Suzuki, N. Nakamura, and H. Ohno, Polym. J, vol.38, pp.117-121, 2006.

C. Zhong, Y. Deng, W. Hu, J. Qiao, L. Zhang et al., Chemical Society Reviews, vol.44, pp.7484-7539, 2015.

E. Frackowiak, G. Lota, and J. Pernak, Applied physics letters, vol.86, p.164104, 2005.

J. D. Holbrey and K. R. Seddon, Journal of the Chemical Society, pp.2133-2140, 1999.

F. Endres and S. Z. El-abedin, Physical Chemistry Chemical Physics, vol.8, pp.2101-2116, 2006.

K. Marsh, J. Boxall, and R. Lichtenthaler, Fluid Phase Equilibria, vol.219, pp.93-98, 2004.

L. Sun, O. Morales-collazo, H. Xia, and J. F. Brennecke, The Journal of Physical Chemistry B, vol.120, pp.5767-5776, 2016.

P. Wasserscheid, R. V. Hal, and A. Bosmann, Green Chemistry, vol.4, pp.400-404, 2002.

J. G. Huddleston, A. E. Visser, W. M. Reichert, H. D. Willauer, G. A. Broker et al., Green chemistry, vol.3, pp.156-164, 2001.

T. Welton, F. Endres, S. Z. Abedin, M. Antonietti, B. Smarsly et al., Ionic Liquids in Synthesis, pp.569-617, 2008.

D. Coleman and N. Gathergood, Chemical Society Reviews, vol.39, pp.600-637, 2010.

D. Zhao, Y. Liao, and Z. Zhang, Clean-soil, air, water, vol.35, pp.42-48, 2007.

S. Tang, G. A. Baker, and H. Zhao, Chemical Society Reviews, vol.41, pp.4030-4066, 2012.

Y. Deng, P. Besse-hoggan, M. Sancelme, A. Delort, P. Husson et al., Journal of Hazardous Materials, vol.198, pp.165-174, 2011.

N. V. Plechkova and K. R. Seddon, Chemical Society Reviews, vol.37, pp.123-150, 2008.

T. Tooming, T. Thomberg, L. Siinor, K. Tõnurist, A. Jänes et al., Journal of The Electrochemical Society, vol.161, pp.222-227, 2014.

P. Simon and Y. Gogotsi, Nature materials, vol.7, pp.845-854, 2008.

S. Zhang, N. Sun, X. He, X. Lu, and X. Zhang, Journal of physical and chemical reference data, vol.35, pp.1475-1517, 2006.

M. Ishikawa, T. Sugimoto, M. Kikuta, E. Ishiko, and M. Kono, Journal of power sources, vol.162, pp.658-662, 2006.

A. B. Mcewen, S. F. Mcdevitt, and V. R. Koch, Journal of The Electrochemical Society, vol.144, pp.84-86, 1997.

V. Ruiz, T. Huynh, S. Sivakkumar, and A. Pandolfo, , vol.2, pp.5591-5598, 2012.

A. C. Cole, J. L. Jensen, I. Ntai, K. L. Tran, K. J. Weaver et al., Journal of the American Chemical Society, vol.124, pp.5962-5963, 2002.

K. Endo and R. H. Grubbs, Dalton Transactions, vol.45, pp.3627-3634, 2016.

P. ?led?, M. Mauduit, and K. Grela, Chemical Society Reviews, vol.37, pp.2433-2442, 2008.

P. Nehra, B. Khungar, K. Pericherla, S. Sivasubramanian, and A. Kumar, Green Chemistry, vol.16, pp.4266-4271, 2014.

W. Shieh, R. Shekhar, T. Blacklock, and A. Tedesco, Synthetic communications, vol.32, pp.1059-1067, 2002.

P. Pham, J. Vitz, C. Chamignon, A. Martel, and S. Legoupy, European Journal of Organic Chemistry, pp.3249-3257, 2009.

N. Louaisil, P. D. Pham, F. Boeda, D. Faye, A. S. Castanet et al., European Journal of Organic Chemistry, pp.143-149, 2011.

G. Kerric, E. L. Grognec, F. Zammattio, M. Paris, and J. Quintard, Journal of Organometallic Chemistry, vol.695, pp.103-110, 2010.

A. R. Muci and S. L. Buchwald, Cross-Coupling Reactions, pp.131-209, 2002.

X. He and T. H. Chan, Tetrahedron, vol.62, pp.3389-3394, 2006.

R. Ratti, Advances in Chemistry, p.16, 2014.

S. T. Handy and M. Okello, Tetrahedron letters, vol.44, pp.8399-8402, 2003.

W. Miao and T. H. Chan, Organic letters, vol.5, pp.5003-5005, 2003.

B. Karimi, D. Elhamifar, J. H. Clark, and A. J. Hunt, Chemistry-A European Journal, vol.16, pp.8047-8053, 2010.

M. Jin, A. Taher, H. Kang, M. Choi, and R. Ryoo, Green Chemistry, vol.11, pp.309-313, 2009.

H. Zhao, Y. Wang, and R. Wang, Chemical Communications, vol.50, pp.10871-10874, 2014.

T. Kang, Q. Feng, and M. Luo, Synlett, pp.2305-2308, 2005.

A. Taher, J. Kim, J. Jung, W. Ahn, and M. Jin, , pp.2477-2482, 2009.

H. A. Beejapur, V. Campisciano, F. Giacalone, and M. Gruttadauria, Advanced Synthesis & Catalysis, vol.357, pp.51-58, 2015.

H. A. Beejapur, F. Giacalone, R. Noto, P. Franchi, M. Lucarini et al., ChemCatChem, issue.5, pp.2991-2999, 2013.

L. Han, H. Li, S. Choi, M. Park, S. Lee et al., Applied Catalysis A: General, vol.429, pp.67-72, 2012.

Q. Chen, C. Peng, H. Xie, Z. Zhao, and M. Bao, , vol.5, pp.44598-44603, 2015.

P. Saini, M. Arora, and M. N. Kumar, Advanced Drug Delivery Reviews, vol.107, pp.47-59, 2016.

B. D. Ulery, L. S. Nair, and C. T. Laurencin, Journal of polymer science Part B: polymer physics, vol.49, pp.832-864, 2011.

E. Frazza and E. Schmitt, Journal of Biomedical Materials Research Part A, vol.5, pp.43-58, 1971.

C. G. Pitt, F. Chasalow, Y. Hibionada, D. Klimas, and A. Schindler, Journal of Applied Polymer Science, vol.26, pp.3779-3787, 1981.

G. Pitt, M. Gratzl, G. Kimmel, J. Surles, and A. Sohindler, Biomaterials, vol.2, pp.215-220, 1981.

B. Laycock, M. Nikoli?, J. M. Colwell, E. Gauthier, P. Halley et al., Progress in Polymer Science, vol.71, pp.144-189, 2017.

R. J. Müller and B. Online,

J. Heller, R. Sparer, and G. Zentner, Drugs and the pharmaceutical sciences, vol.45, pp.121-161, 1990.

V. Siracusa, P. Rocculi, S. Romani, M. , and D. Rosa, Trends in Food Science & Technology, vol.19, pp.634-643, 2008.

A. C. Albertsson and M. Eklund, Journal of applied polymer science, vol.57, pp.87-103, 1995.

S. Doppalapudi, A. Jain, W. Khan, and A. J. Domb, Polymers for Advanced Technologies, vol.25, pp.427-435, 2014.

V. Tserki, P. Matzinos, E. Pavlidou, D. Vachliotis, and C. Panayiotou, Polymer degradation and stability, vol.91, pp.367-376, 2006.

S. Slomkowski, S. Penczek, and A. Duda, Polymers for Advanced Technologies, vol.25, pp.436-447, 2014.

I. Vroman and L. Tighzert, , 2009.

H. N. Rabetafika, M. Paquot, P. Dubois, and . Biotechnologie, , vol.10, pp.185-196, 2006.

M. Labet and W. Thielemans, Chemical Society Reviews, vol.38, pp.3484-3504, 2009.

V. Bergeot, , vol.1, 2002.

A. Albertsson and I. K. Varma, Biomacromolecules, vol.4, pp.1466-1486, 2003.

A. Duda, S. Penczek, and B. Online, , 2005.

V. H. Cherdron, H. Ohse, and F. Korte, Macromolecular Chemistry and Physics, vol.56, pp.179-186, 1962.

Z. Jedli?ski, W. Wa?ach, P. Kurcok, and G. Y. Adamus, Die Makromolekulare Chemie, vol.192, pp.2051-2057, 1991.

A. Hofman, S. Slomkowski, and S. Penczek, Die Makromolekulare Chemie, vol.188, pp.2027-2040, 1987.

Z. Jedlinski, P. Kurcok, and M. Kowalczuk, Macromolecules, vol.18, pp.2679-2683, 1985.

A. Hofman, S. S?omkowski, and S. Penczek, Macromolecular Chemistry and Physics, vol.185, pp.91-101, 1984.

H. R. Kricheldorf and I. Kreiser-saunders, Die Makromolekulare Chemie, vol.191, pp.1057-1066, 1990.

A. Kowalski, A. Duda, and S. Penczek, Macromolecular rapid communications, vol.19, pp.567-572, 1998.

Y. A. Piskun, I. V. Vasilenko, K. V. Zaitsev, Y. F. Oprunenko, and S. V. Kostjuk, Macromolecular Chemistry and Physics, p.218, 2017.

Y. Kim, G. K. Jnaneshwara, and J. G. Verkade, Inorganic chemistry, vol.42, pp.1437-1447, 2003.

M. Pastusiak, P. Dobrzynski, J. Kasperczyk, M. Sobota, B. Kaczmarczyk et al., Polymer International, 2017.

P. Dobrzynski, Polymer, vol.48, pp.2263-2279, 2007.

A. Löfgren, A. Albertsson, P. Dubois, and R. Jérôme, Journal of Macromolecular Science, Part C: Polymer Reviews, vol.35, pp.379-418, 1995.

P. Dubois, R. Jér?me, and P. Teyssie, , 1991.

J. C. Middleton and A. J. Tipton, Biomaterials, vol.21, pp.2335-2346, 2000.

M. Kalmi, M. Lahcini, P. Castro, O. Lehtonen, A. Belfkira et al., Journal of Polymer Science Part A: Polymer Chemistry, vol.42, pp.1901-1911, 2004.

M. Lahcini, P. M. Castro, M. Kalmi, M. Leskelä, and T. Repo, Organometallics, vol.23, pp.4547-4549, 2004.

S. P. Dubey, H. Abhyankar, V. Marchante, J. Brighton, and K. Blackburn, , 2016.

P. J. Dijkstra, H. Du, and J. Feijen, Polymer Chemistry, vol.2, pp.520-527, 2011.

S. J. Moravek, J. M. Messman, and R. F. Storey, Journal of Polymer Science Part A: Polymer Chemistry, vol.47, pp.797-803, 2009.

S. Farah, D. G. Anderson, and R. Langer, Advanced Drug Delivery Reviews, vol.107, pp.367-392, 2016.

A. Kuznetsov, A. Beloded, A. Derunets, V. Grosheva, L. Vakar et al., Clean Technologies and Environmental Policy, vol.19, pp.869-882, 2017.

S. Jacobsen and H. Fritz, Polymer Engineering & Science, vol.39, pp.1303-1310, 1999.

A. Mukhopadhyay, , 2009.

B. Gupta, N. Revagade, and J. Hilborn, Progress in polymer science, vol.32, pp.455-482, 2007.

H. Tsuji, Encyclopedia of Polymeric Nanomaterials, pp.1692-1702, 2015.

F. Prévot, , 2015.

K. Hamad, M. Kaseem, H. Yang, F. Deri, and Y. Ko, Express Polymer Letters, p.9, 2015.

J. R. Dorgan, H. Lehermeier, and M. Mang, Journal of Polymers and the Environment, vol.8, pp.1-9, 2000.

J. Lunt and A. L. Shafer, Journal of Coated Fabrics, vol.29, pp.191-205, 2000.

L. Avérous, Monomers, polymers and composites from renewable resources, p.1, 2008.

D. Garlotta, Journal of Polymers and the Environment, vol.9, pp.63-84, 2001.

K. Perepelkin, Fibre Chemistry, vol.34, pp.85-100, 2002.

R. Auras and P. , , 2010.

P. I. Dalko and L. Moisan, Angewandte Chemie International Edition, vol.40, pp.3726-3748, 2001.

A. Taheri, B. Lai, C. Cheng, and Y. Gu, Green Chemistry, vol.17, pp.812-816, 2015.

P. R. Schreiner, Chemical Society Reviews, vol.32, pp.289-296, 2003.

A. Aggarwal, N. L. Lancaster, A. R. Sethi, and T. Welton, Green Chemistry, vol.4, pp.517-520, 2002.

L. Crowhurst, P. R. Mawdsley, J. M. Perez-arlandis, P. A. Salter, and T. Welton, Physical Chemistry Chemical Physics, vol.5, pp.2790-2794, 2003.

A. R. Gholap, K. Venkatesan, T. Daniel, R. Lahoti, and K. Srinivasan, Green Chemistry, vol.5, pp.693-696, 2003.

E. Reyes, U. Uria, J. L. Vicario, and L. Carrillo, The Catalytic, Enantioselective Michael Reaction, 2016.

D. Enders, O. Niemeier, and A. Henseler, Chem. Rev, vol.107, pp.5606-5655, 2007.

G. W. Nyce, J. A. Lamboy, E. F. Connor, R. M. Waymouth, and J. L. Hedrick, Organic letters, vol.4, pp.3587-3590, 2002.

A. Kaoukabi, F. Guillen, H. Qayouh, A. Bouyahya, S. Balieu et al., Industrial Crops and Products, vol.72, pp.16-23, 2015.

A. Sarkar, S. R. Roy, and A. K. Chakraborti, Chemical Communications, vol.47, pp.4538-4540, 2011.

A. Nafchi, M. Moradpour, M. Saeidi, and A. K. Alias, , vol.65, pp.61-72, 2013.

O. Persenaire, M. Alexandre, P. Degée, and P. Dubois, Biomacromolecules, vol.2, pp.288-294, 2001.

C. J. Bradaric, A. Downard, C. Kennedy, A. J. Robertson, and Y. Zhou, Green Chemistry, vol.5, pp.143-152, 2003.

N. Kumar and R. Jain, Journal of Heterocyclic Chemistry, vol.49, pp.370-374, 2012.

M. C. Galan, K. Jouvin, and D. Alvarez-dorta, Carbohydrate research, vol.345, pp.45-49, 2010.

M. G. Freire, C. M. Neves, I. M. Marrucho, J. A. Coutinho, and A. M. Fernandes, The Journal of Physical Chemistry A, vol.114, pp.3744-3749, 2009.

A. V. Plakhotnyk, L. Ernst, and R. Schmutzler, Journal of Fluorine Chemistry, vol.126, pp.27-31, 2005.

T. L. Amyes, S. T. Diver, J. P. Richard, F. M. Rivas, and K. Toth, Journal of the American Chemical Society, vol.126, pp.4366-4374, 2004.

S. T. Handy and M. Okello, The Journal of organic chemistry, vol.70, pp.1915-1918, 2005.

C. Decker and K. Moussa, European Polymer Journal, vol.26, pp.393-401, 1990.

J. Dupont, Journal of the Brazilian Chemical Society, vol.15, pp.341-350, 2004.

N. Zhu, J. Ling, K. Xiao, and Z. Shen, Acta Polymerica Sinica, vol.8, p.22, 2009.

R. Lungwitz and S. Spange, New Journal of Chemistry, vol.32, pp.392-394, 2008.

C. D. Campbell, C. Concellón, and A. D. Smith, Tetrahedron: Asymmetry, vol.22, pp.797-811, 2011.

M. Jalabert, C. Fraschini, and R. E. Prud'homme, Journal of Polymer Science Part A: Polymer Chemistry, vol.45, pp.1944-1955, 2007.

M. T. Zell, B. E. Padden, A. J. Paterick, K. A. Thakur, R. T. Kean et al., Macromolecules, vol.35, pp.7700-7707, 2002.

M. Bero, J. Kasperczyk, and Z. J. Jedlinski, Macromolecular Chemistry and Physics, vol.191, pp.2287-2296, 1990.

F. Drouin, , 2010.

M. Bero, B. Czapla, P. Dobrzy?ski, H. Janeczek, and J. Kasperczyk, Macromolecular Chemistry and Physics, pp.911-916, 0200.

H. Du, A. H. Velders, P. J. Dijkstra, J. Sun, Z. Zhong et al., Chemistry-A European Journal, vol.15, pp.9836-9845, 2009.

H. R. Kricheldorf and S. Rost, Biomacromolecules, vol.6, pp.1345-1352, 2005.

C. Robert, T. E. Schmid, V. Richard, P. Haquette, S. K. Raman et al., Journal of the American Chemical Society, vol.139, pp.6217-6225, 2017.

H. R. Kricheldorf, M. Berl, and N. Scharnagl, Macromolecules, vol.21, pp.286-293, 1988.

A. Kowalski, A. Duda, and S. Penczek, Macromolecules, vol.33, pp.7359-7370, 2000.

A. Kowalski, A. Duda, and S. Penczek, Macromolecules, vol.33, pp.689-695, 2000.

H. R. Kricheldorf, I. Kreiser-saunders, and C. Boettcher, , vol.36, pp.1253-1259, 1995.

H. Kricheldorf and I. Kreiser-saunders, Polymer, vol.41, pp.3957-3963, 2000.

H. R. Kricheldorf, C. Boettcher, and K. Tönnes, Polymer, vol.33, pp.2817-2824, 1992.

K. M. Stridsberg, M. Ryner, and A. Albertsson, Degradable aliphatic polyesters, pp.41-65, 2002.

S. J. Mclain and N. E. Drysdale, Journal, 1991.

C. Bakewell, A. J. White, N. J. Long, and C. K. Williams, Angewandte Chemie International Edition, vol.53, pp.9226-9230, 2014.

Y. Yu, D. Yuan, Y. Wang, and Y. Yao, Journal of Organometallic Chemistry, vol.819, pp.37-45, 2016.

A. Amgoune, C. M. Thomas, and J. F. Carpentier, Macromolecular rapid communications, vol.28, pp.693-697, 2007.

C. Robert, T. E. Schmid, V. Richard, P. Haquette, S. K. Raman et al., J Am Chem Soc, vol.139, pp.6217-6225, 2017.

P. Dubois, N. Ropson, R. Jérôme, and P. Teyssié, Macromolecules, vol.29, pp.1965-1975, 1996.

G. Montaudo, M. S. Montaudo, C. Puglisi, F. Samperi, N. Spassky et al., Macromolecules, vol.29, pp.6461-6465, 1996.

A. Duda, Macromolecules, vol.29, pp.1399-1406, 1996.

G. Schwach, J. Coudane, R. Engel, and M. Vert, Polymer bulletin, vol.37, pp.771-776, 1996.

G. Schwach, J. Coudane, R. Engel, and M. Vert, Biomaterials, vol.23, pp.993-1002, 2002.

K. Fent, Critical reviews in toxicology, vol.26, pp.3-117, 1996.

H. Harino, M. Ohji, G. Wattayakorn, K. Adulyanukosol, T. Arai et al., Archives of environmental contamination and toxicology, vol.53, pp.119-125, 2007.

J. Strand, M. M. Larsen, and C. Lockyer, Science of the Total Environment, vol.350, pp.59-71, 2005.

K. Kannan, K. Senthilkumar, and J. P. Giesy, Environmental science & technology, vol.33, pp.1776-1779, 1999.

W. H. Organization, , 1980.

E. L. Grognec, J. Chrétien, F. Zammattio, and J. Quintard, Chemical reviews, vol.115, pp.10207-10260, 2015.

C. D. Stefano, C. Foti, A. Gianguzza, F. Marrone, and S. Sammartano, Applied organometallic chemistry, vol.13, pp.805-811, 1999.

C. Alzieu, J. Sanjuan, J. Deltreil, and M. Borel, Marine pollution bulletin, vol.17, pp.494-498, 1986.

V. Delgado-filho, P. Lopes, P. Podratz, and J. Graceli, Brazilian Journal of Medical and Biological Research, vol.44, pp.958-965, 2011.

G. Shi, D. Chen, G. Zhai, M. S. Chen, Q. C. Cui et al., Environmental health perspectives, vol.117, p.379, 2009.

S. Osada, J. Nishikawa, T. Nakanishi, K. Tanaka, and T. Nishihara, Toxicology letters, vol.155, pp.329-335, 2005.

A. Herve, A. L. Rodriguez, and E. Fouquet, The Journal of organic chemistry, vol.70, pp.1953-1956, 2005.

J. Chrétien, F. Zammattio, E. L. Grognec, M. Paris, B. Cahingt et al., The Journal of organic chemistry, vol.70, pp.2870-2873, 2005.

K. Poelmans, V. Pinoie, I. Verbruggen, M. Biesemans, G. Deshayes et al., Organometallics, vol.27, pp.1841-1849, 2008.

D. Milstein and J. Stille, Journal of the American Chemical Society, vol.100, pp.3636-3638, 1978.

J. Leibner and J. Jacobus, The Journal of Organic Chemistry, vol.44, pp.449-450, 1979.

B. S. Edelson, B. M. Stoltz, and E. Corey, Tetrahedron letters, vol.40, pp.6729-6730, 1999.

W. J. Scott and J. Stille, Journal of the American Chemical Society, vol.108, pp.3033-3040, 1986.

M. J. Earle and K. R. Seddon, Pure and applied chemistry, vol.72, pp.1391-1398, 2000.

P. Wasserscheid and W. Keim, Angewandte Chemie International Edition, vol.39, pp.3772-3789, 2000.

K. Goossens, K. Lava, C. W. Bielawski, and K. Binnemans, Chemical reviews, vol.116, pp.4643-4807, 2016.

R. D. Rogers and K. R. Seddon, Science, vol.302, pp.792-793, 2003.

P. Jaumier, B. Jousscaume, M. Lahcini, F. Ribot, and C. Sanchez, Chemical Communications, pp.369-370, 1998.

G. Vilaça, K. Barathieu, B. Jousseaume, T. Toupance, and H. Allouchi, Organometallics, vol.22, pp.4584-4592, 2003.

A. Shiryaev, V. Kochergin, A. Polivanov, T. Slyusarenko, A. Kisin et al., , p.9, 1978.

J. Vitz, D. H. Mac, and S. Legoupy, Green Chemistry, vol.9, pp.431-433, 2007.

Z. Hu, B. Liu, Z. Zhang, and L. Chen, Industrial crops and products, vol.50, pp.264-269, 2013.

J. P. Hallett and T. Welton, Chemical Reviews, vol.111, pp.3508-3576, 2011.

H. Y. Chen, H. J. Fang, Y. J. Chen, S. C. Hsu, Y. C. Lai et al., Journal of Polymer Science Part A: Polymer Chemistry, vol.50, pp.3286-3294, 2012.

S. Chen, S. Zhang, X. Liu, J. Wang, J. Wang et al., Physical Chemistry Chemical Physics, vol.16, pp.5893-5906, 2014.

J. Lafarge, , 2012.

S. V. Kurkov and T. Loftsson, International journal of pharmaceutics, vol.453, pp.167-180, 2013.

W. Tang and S. C. Ng, Journal of separation science, vol.31, pp.3246-3256, 2008.

J. Szejtli, Pure and Applied Chemistry, vol.76, pp.1825-1845, 2004.

H. Dodziuk, Cyclodextrins and their complexes: chemistry, analytical methods, applications, 2006.

J. Szejtli, Chemical reviews, vol.98, pp.1743-1754, 1998.

B. Cheirsilp and J. Rakmai, Biol, vol.2, pp.1-6, 2016.

S. He, X. Sun, and H. Zhang, Journal of Molecular Structure, vol.1107, pp.182-188, 2016.

N. Mourtzis, K. Eliadou, and K. Yannakopoulou, Supramolecular Chemistry, vol.16, pp.587-593, 2004.

K. Harata, Bulletin of the Chemical Society of Japan, vol.49, pp.1493-1501, 1976.

A. , Cyclodextrine Materials, Phtochemstry Photophysics and photobiology, p.15, 2006.

G. Wenz, Angewandte Chemie International Edition, vol.33, pp.803-822, 1994.

S. Soni and A. , Journal of Solution Chemistry, vol.45, pp.665-674, 2016.

M. ?ezanka, European Journal of Organic Chemistry, pp.5322-5334, 2016.

E. Gaidamauskas, E. Norkus, E. Butkus, D. C. Crans, and G. Grincien?, Carbohydrate research, vol.344, pp.250-254, 2009.

F. Sallas and R. Darcy, European Journal of Organic Chemistry, pp.957-969, 2008.

L. Jicsinszky, M. Caporaso, K. Tuza, K. Martina, E. Gaudino et al., ACS Sustainable Chemistry & Engineering, vol.4, pp.919-929, 2016.

J. Defaye, J. G. Fernández, and C. O. Mellet, Annales Pharmaceutiques Fran?aises, vol.65, pp.33-49, 2007.

S. Moutard, B. Perly, P. Godé, G. Demailly, and F. Djedaïni-pilard, Journal of inclusion phenomena and macrocyclic chemistry, vol.44, pp.317-322, 2002.

W. Tang and S. Ng, Nature Protocols, vol.3, p.691, 2008.

N. Mofaddel, S. Fourmentin, F. Guillen, D. Landy, and G. Gouhier, Analytical and bioanalytical chemistry, vol.408, pp.8211-8220, 2016.

X. Qin and X. Zhu, Analytical Letters, vol.49, pp.189-199, 2016.

A. Cao, H. Ai, Y. Ding, C. Dai, and J. Fei, Sensors and Actuators B: Chemical, vol.155, pp.632-638, 2011.

Z. Zhou, X. Li, X. Chen, and X. Hao, Analytica chimica acta, vol.678, pp.208-214, 2010.

M. Raoov, S. Mohamad, and M. R. Abas, Journal of hazardous materials, vol.263, pp.501-516, 2013.

M. Raoov, S. Mohamad, M. R. Abas, and H. Surikumaran, Talanta, vol.130, pp.155-163, 2014.

G. Feng, W. Ping, X. X. Qin, J. Liu, and X. Zhu, Food analytical methods, vol.8, pp.2315-2320, 2015.

N. Zhou, R. Sang, and X. Zhu, Food Analytical Methods, vol.7, pp.1256-1262, 2014.

C. Zhou, J. Deng, G. Shi, and T. Zhou, Electrophoresis, vol.38, pp.1060-1067, 2017.

X. Yu, Y. Chen, L. Chang, L. Zhou, F. Tang et al., Sensors and Actuators B: Chemical, vol.186, pp.648-656, 2013.

C. Amiel, C. Galant, and L. Auvray, Trends in Colloid and Interface Science XVII, pp.44-46, 2004.

A. Berthod, L. He, and D. W. Armstrong, Chromatographia, vol.53, pp.63-68, 2001.

J. Ding, T. Welton, and D. W. Armstrong, Analytical Chemistry, vol.76, pp.6819-6822, 2004.

T. Malefetse, B. Mamba, R. Krause, M. Mahlambi, and W. Sa, , vol.35, pp.729-734, 2009.

S. Chen, X. Qin, W. Gu, and X. Zhu, Talanta, vol.161, pp.325-332, 2016.

W. Ping, H. Xu, and X. Zhu, Biochem. Anal. Biochem, vol.2, pp.1-5, 2013.

N. Zhou and X. Zhu, Journal of Pharmaceutical Analysis, vol.4, pp.242-249, 2014.

X. Qin and X. Zhu, , vol.29, pp.205-214, 2017.

P. Qi, Z. Lin, J. Li, C. Wang, W. Meng et al., Food chemistry, vol.164, pp.98-103, 2014.

F. L. Rasdi, S. Mohamad, N. S. Manan, and H. R. Nodeh, , vol.6, pp.100186-100194, 2016.

F. Galán-cano, M. Del-carmen-alcudia-león, R. Lucena, S. Cárdenas, and M. Valcárcel, Journal of Chromatography A, vol.1300, pp.134-140, 2013.

K. Krupczy?ska and B. Buszewski, Journal, 2004.

H. Claessens, TrAC Trends in Analytical Chemistry, vol.20, pp.563-583, 2001.

R. Singh, N. Bharti, J. Madan, and S. Hiremath, J. Pharm. Sci. Technol, vol.2, pp.171-183, 2010.

C. Kessler, J. Ng, K. Valdez, H. Xie, and B. Geiger, Journal of hospital medicine, vol.6, pp.136-140, 2011.

Y. H. Kim, C. Sachse, M. L. Machala, C. May, L. Müller-meskamp et al., Advanced Functional Materials, vol.21, pp.1076-1081, 2011.

H. M. Wang and L. X. Song, Journal, vol.36, pp.596-597, 2007.

A. Favrelle, G. Gouhier, F. Guillen, C. Martin, N. Mofaddel et al., Journal, vol.119, pp.12921-12930, 2015.

K. Taguchi, Journal of the American Chemical Society, vol.108, pp.2705-2709, 1986.

C. G. Da-rosa, C. D. Borges, R. C. Zambiazi, M. R. Nunes, E. V. Benvenutti et al., Industrial Crops and Products, vol.46, pp.138-146, 2013.

S. Chelli, M. Majdoub, M. Jouini, S. Aeiyach, F. Maurel et al., Journal of physical organic chemistry, vol.20, pp.30-43, 2007.

L. Yang, S. Wang, S. Zhou, F. Zhao, Q. Chang et al., Journal, vol.76, pp.1136-1145, 2017.

B. D. Wagner and S. J. Fitzpatrick, Journal of inclusion phenomena and macrocyclic chemistry, vol.38, pp.467-478, 2000.

G. Gao, Y. Li, W. Wang, D. Zhong, S. Wang et al., Journal of Photochemistry and Photobiology B: Biology, vol.145, pp.60-65, 2015.

V. N. Uversky, S. Winter, and G. Löber, Biochimica et Biophysica Acta (BBA)-Protein Structure and Molecular Enzymology, vol.1388, pp.133-142, 1998.

E. Bismuto, I. Sirangelo, and G. Irace, Biophysical chemistry, vol.44, pp.83-90, 1992.

D. Sarkar, D. Ghosh, P. Das, and N. Chattopadhyay, The Journal of Physical Chemistry B, vol.114, pp.12541-12548, 2010.

U. Pfeifer-fukumura, H. Misawa, H. Fukumura, and H. Masuhara, Chemistry letters, vol.23, pp.1589-1592, 1994.

L. W. Städe, T. T. Nielsen, L. Duroux, R. Wimmer, K. Shimizu et al., Beilstein journal of organic chemistry, issue.11, p.514, 2015.

F. V. Bright, G. C. Catena, and J. Huang, Journal of the American Chemical Society, vol.112, pp.1343-1346, 1990.