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• Zhu, J., Lines, B.M., Ganton, M.D., Kerr, M.A., Workentin, M.S., “Efficient synthesis of isoxazolidine tethered monolayer-protected gold nanoparticles (MPGNs) via 1,3-dipolar cycloadditions under high-pressure conditions”, Journal of Organic Chemistry, 73: 1099-1105, (2008).
• Karthikeyan, K., Perumal, P.T., Etti, S., Shanmugam, G., “Diastereoselective syntheses of pyrazolyl via 1,3-dipolar cycloaddition”, Tetrahedron, 63: 10581-10586, (2007).
• Dondas, H.A., Cummins, J.E., Grigg, R., Thornton, P.M., “X=Y–ZH Systems as potential 1,3- dipoles. Part 53: Sequential nucleophilic ring opening-1,3-dipolar cycloaddition reactions of Z-oxime anions with aziridines and dipolarophiles”, Tetrahedron, 57: 7951-7964, (2001).
• Casuscelli, F., Chiaccho, U., Rescifina, A., Romeo, R., Romeo, G., Tommasini, S., Uccella, N., “Ring-opening of isoxazolidine nucleus: competitive formation of α,β-enones and tetrahydro-1,3 oxazines”, Tetrahedron, 51: 2979-2990, (1995).
• Damodiran, M., Sivakumar, P.M., Senthil Kumar, R., Muralidharan, D., Kumar, B.V.N.P., Doble, M., Perumal, P.T., “Antibacterial activity, quantitative structure–activity relationship and diastereoselective synthesis of isoxazolidine derivatives via 1,3-dipolar cycloaddition of D-glucose derived nitrone with olefin”, Chemical Biology and Drug Design, 74: 494-506, (2009).
• Yin, Z., Zhang, J., Wu, J., Liu, C., Sioson, K., Devany, M., Hu, C., Zheng, S., “Double heteroMichael addition of N-substituted hydroxylamines to quinone monoketals: synthesis of bridged isoxazolidines”, Organic Letters,15: 3534-3537, (2013).
• Ali, A.S., Khan, J.H., Wazeer, M.I.M., “The regiochemistry and stereochemistry of 1,3-dipolar cycloaddition of cyclic nitrones”, Tetrahedron, 44: 5911-5920, (1998).
• Jäger, V., Müller, I., “Synthesis of amino sugars via isoxazolines: nitrile oxide-furan adducts as key intermediates in the isoxazoline route towards novel amino sugar derivatives”, Tetrahedron, 41: 3519-3528, (1985).
• Merino, P., Franco, S., Merchan, F.L., Tejero, T., “Asymmetric synthesis of an isoxazolidine nucleoside analog of thymine polyoxin C”, Tetrahedron Letters, 39:6411-6414, (1988).
• Nora, G.P., Miller, M.J., Möllmann, U., “The synthesis and in vitro testing of structurally novel antibiotics derived from acylnitroso Diels–Alder adducts”, Bioorganic and Medicinal Chemistry Letters, 16: 3966-3970, (2006).
• Litvinovskaya, R.P., Koval, N.V., Khripach, V.A., “Synthesis of modified vitamin D precursors”, Chemistry of Heterocyclic Compounds, 36: 190-194, (2000).
• Hanselmann, R., Zhou, J., Ma, P., Confalone, P.N., “Synthesis of cyclic and acyclic β-amino acids via chelation-controlled 1,3-dipolar cycloaddition”, Journal of Organic Chemistry, 68: 8739-8741, (2003).
• Chiacchio, U., Balestrieri, E., Macchi, B., Iannazzo, D., Piperino, A., Rescifina, A., Romeo, R., Saglimbeni, M., Sciortino, M.T., Valveri, V., Mastino, A., Romeo, G., “Synthesis of phosphonated carbocyclic 2’-oxa-3’-aza-nucleosides:  novel inhibitors of reverse transcriptase”, Journal of. Medicinal Chemistry, 48: 1389-1394, (2005).
• Palmer, G.C., Ordy, M.J., Simmons, R.D., Strand, J.C., Radov, L.A., Mullen, G.B., Kinsolving, C.R., St Giorgiev, V., Mitchell, J.T., Allen, S.D., “Selection of orally active antifungal agents from 3,5- substituted isoxazolidine derivatives based on acute efficacy-safety profiles”, Antimicrobial Agents and Chemotherapy, 33:895-905, (1989).
• Kumar, K.R.R., Mallesha, H., Basappa Rangappa, K.S., “Synthesis of novel isoxazolidine derivatives and studies for their antifungal properties”, European Journal of Medicinal Chemistry, 38: 613-619, (2003).
• Zhao, C., Casida, J.E., “Insect γ-aminobutyric acid receptors and isoxazoline insecticides: toxicological profiles relative to the binding sites of [3H]fluralaner, [3H]-4′-ethynyl-4-n-propylbicycloorthobenzoate, and [3H]avermectin”, Journal of Agricultural and Food Chemistry, 62: 1019-1024, (2014).
• Rakesh, D.S., Lee, R.B., Tangallapally, R.P., Lee, R.E., “Synthesis, optimization and structure– activity relationships of 3,5-disubstituted isoxazolines as new anti-tuberculosis agents”, European Journal of Medicinal Chemistry, 44: 460-472, (2009).
• Habeeb, A.G., Rao, P.P.N., Knaus, E.E., “Design and synthesis of 4,5-diphenyl-4- isoxazolines: novel inhibitors of cyclooxygenase-2 with analgesic and antiinflammatory activity”, Journal of Medicinal Chemistry, 44: 2921-2927, (2001).
• Mondal, P., Jana, S., Balaji, A., Ramakrishna, R., Kanthal, L.K,, “Synthesis of some new isoxazoline derivatives of chalconised indoline 2-one as a potential analgesic, antibacterial and anthelmintic agents”, Journal of Young Pharmacists, 4: 38-41, (2012).
• Pinto, D.J.P., Smallheer, J.M., Cheney, D.L., Knabb, R.M., Wexler, R.R., “Factor Xa inhibitors: Next-generation antithrombotic agents”, Journal of Medicinal Chemistry, 53: 6243-6274, (2010).
• Giofrè, S.V., Romeo, R., Carnovale, C., Mancuso, R., Cirmi, S., Navarra, M., Garozzo, A., Chiacchio, M.A., “Synthesis and biological properties of 5-(1h-1,2,3-triazol-4-yl) isoxazolidines: a new class of C-nucleosides”, Molecules, 20: 5260-5275, (2015).
• Büyükgüngör, O., Yavuz, S., Odabaşoğlu, M., Özkan, H., Pamir, Ö., Yıldırır, Y., “Dimethyl trans3-(4-bromophenyl)-2-methylisoxazolidine-4,5-dicarboxylate”, Acta Crystallographica, E65: o2207, (2009).
• Andrade, M., Barros, M.T., Pinto, R.C., “Exploiting microwave-assisted neat procedures: synthesis of N-aryl and N-alkylnitrones and their cycloaddition en route for isoxazolidines”, Tetrahedron,64: 10521-10530, (2008).
• Colacino, E., Nun, P., Colacino, F.M., Martinez, J., Lamaty, F., “Solvent-free synthesis of nitrones in a ball-mill”, Tetrahedron, 64: 5569-5576, (2008).
• Wagner, G., Garland, T., “Synthesis of 5-trichloromethyl-Δ 4 -1,2,4-oxadiazolines and their rearrangement into formamidine derivatives”, Tetrahedron Letters., 49: 3596-3599, (2008).
• Yijima, C., Tsujimoto, T., Suda, K., Yamauchi, M., “13C and 1H NMR of α-arylnitrones. Substituent effects on the α-position of α-(p-substituted phenyl)nitrones”, Bulletin of the Chemical Society of Japan, 59: 2165-2170, (1986).
• Odabaşıoğlu, M., Özkan, H., Yıldırır, Y., Büyükgüngör, O., “Dimethyl cis-2-methyl-3-p-tolylisoxazolidine-4,5-dicarboxylate”, Acta Crystallographica, E65: o806-o807, (2009).
• Wikler, M.A., Cockerill, F.R., Craig, W.A., Dudley, M.N., Eliopoulos, G.M., Hecht, D.W., Hindler, J.F., Ferraro, M.J., Swenson, J.M., Low, D.E., Sheehan, D.J., Tenover, F.C., Turnidge, J.D., Weinstein, M.P., Zimmer, B.L., “Methods for dilution antimicrobial susceptibility tests for bacteria that grow aerobically approved standard”, Clinical and Laboratory Standards Institute, 26: M7-A7, (2006).
• Wikler, M.A., Cockerill, F.R., Craig, W.A., Dudley, M.N., Eliopoulos, G.M., Hecht, D.W., Hindler, J.F., Ferraro, M.J., Swenson, J.M., Low, D.E., Sheehan, D.J., Tenover, F.C., Turnidge, J.D., Weinstein, M.P., Zimmer, B.L., “Reference method for broth dilution antifungal susceptibility testing of yeasts approved standard”, Clinical and Laboratory Standards Institute, 0(0): M27-A3, Replaces, 22(15): M27-A2, (2007).
• Iannazzo, D., Brunaccini, E., Giofre, S., Piperno, A., Romeo, G., Ronsisvalle, S., Chiacchio, M.A., Lanza, G., Chiacchio, U., “Competitive formation of β-enaminones and 3-amino-2(5H)-furanones from the isoxazolidine system: a combined synthetic and quantum chemical study”, European Journal of Organic Chemistry, 2010:5897-5905, (2010).
• Alavi Nikje, M.M., Bigdeli, M.A., Imanieh, H. A., “Facile and new method for the synthesis of αaryl-N-methylnitrones in solvent-free media using silica gel-NaOH”, Phosphorus, Sulfur, and Silicon and the Related Elements,179:1465-1468, (2004).
• Yavuz, S., Ozkan, H., Colak, N., Yildirir, Y., “Fast method for synthesis of alkyl and aryl-Nmethylnitrones”, Molecules,16:6677-83, (2011).
• Marvaniya, H.M., Modi, K.N., Sen, D.J., “Greener reactions under solvent free conditions”, International Journal of Drug Development and Research, 3:34-43, (2011).
• Zangade, S.B., Mokle, S.S., Shinde, A.T., Vibhute, Y.B., “An atom efficient, green synthesis of 2- pyrazoline derivatives under solvent-free conditions using grinding technique”, Green Chemistry Letters and Reviews, 6: 123-127, (2013).
• Singh, G., Sharma, A., Kaur, H., Ishar, M.P.S., “Chromanyl–isoxazolidines as antibacterial agents: synthesis, biological evaluation, quantitative structure activity relationship, and molecular docking studies”, Chemical Biology and Drug Design, 87: 213-223, (2016).
• Chacraborty, B., Samanta, A., Sharma, P.K., Singh, C., Kafley, S., Banerjee, A., Sinha, C., “One pot high yield synthesis of some novel isoxazolidine derivatives using N-methyl-α-chloro nitrone in water and their antibacterial activity”, Journal of Chemical and Pharmaceutical Research, 2: 727- 739, (2010).
• Chacraborty, B., Chhetri, M.S., Kafley, S., Samanta, A., “Synthesis and antibacterial activities of some novel isoxazolidine derivatives derived from N-phenyl-α-chloro nitrone in water”, Indian Journal of Chemistry, 49B: 209-215, (2010).
• Sadashiva, M.P., Mallesha, H., Karunakara Murthy, K., Rangappa, K.S., “Enhancement in antimicrobial activity of 2-(phenyl)-3-(2-butyl-4-chloro-1H-imidazolyl)-5-butylate isoxazolidine”, Bioorganic and Medicinal Chemistry Letters, 15: 1811-1814, (2005).
• Kumar, K.R.R., Mallesha, H., Rangappa, K.S., “The synthesis of novel isoxazolidine derivatives and their antifungal and antibacterial properties”, Archiv der Pharmazie-Pharmaceutical and Medicinal Chemistry, 336: 159-164, (2003).
• Kumar, K.R.R., Mallesha, H., Rangappa, K.S., “Synthesis and characterization of 5-substituted novel isoxazolidines derived from 1,3-dipolar cycloaddition of nitrones with olefins: studies of antibacterial and antifungal activities”, Synthetic Communications, 33: 1545-1555, (2003).
• Berthet, M., Cheviet, T., Dujardin, G., Parrot, I., Martinez, J., “Isoxazolidine: a privileged scaffold for organic and medicinal chemistry”, Chemical Reviews, 116: 15235-15283, (2016).
• Żelechohowski, K., Gołębiewski, W.M., “Synthesis and fungicidal activity of 2-diphenylmethyl 3- arylisoxazolidine-5-carboxamides”, Monatshefte für Chemie., 146: 1895-1905, (2015).