How to cite this paper
Abdeen, M., Hamed, M., Aleem, A., Nassar, I & El-Sayed, I. (2021). A comparative study of metal-catalyzed three-component synthesis of α-aminophosphonates.Current Chemistry Letters, 10(3), 221-234.
Refrences
1 Arribat M., Cavelier F., and R´emond E. (2020) Phosphorus-containing amino acids with a P–C bond in the side chain or a P–O, P–S or P–N bond: from synthesis to applications. RSC Adv.,10 (11) 6678-6724.
2 Mucha A., Kafarski P., Berlicki Ł. (2011) Remarkable potential of the α-aminophosphonat /phosphinate structural motif in medicinal chemistry. J. Med. Chem., 54 (17) 5955-5980.
3 Elsherbiny D. A., Abdelgawad A. M., El-Naggar M. E., El-Sherbiny R. A., El-Rafie M. H., El-Sayed I. E. T. (2020) Synthesis, antimicrobial activity, and sustainable release of novel α-aminophosphonate derivatives loaded Carrageenan Cryogel. International. Journal of Biological Macromolecules., 163 96-107.
4 Xiao L. X., Li K., Shi D. Q. (2008) A Convenient Synthesis and Herbicidal Activity of N-phosphonoalkylpyrazolo [4, 3-e] [1, 2, 4]-triazolo [1, 5-d] pyrimidines. Phosphorus, Sulfur Silicon Relat. Elem, 183 (12) 3156-3165.
5 Boshta N. M., Elgamal E. A., & El-Sayed I. E. (2018) Bioactive amide and α-aminophosphonate inhibitors for methicillin-resistant Staphylococcus aureus (MRSA). Monatshefte für Chemie-Chemical Monthly., 149 (12) 2349-2358.
6 Hamed M. A., El Gokha A. A., Ahmed A. F. A., Elsayed M. S. A. E., Tarabee R., Megeed A. E. S. A., El Sayed I. E. T. (2015) Synthesis and Antimicrobial Activity of Novel α-Aminophosphonates Bearing Pyrazoloquinoxaline Moiety. Int. J. Pharm. Sci. Rev. Res., 34 205-213.
7 Ouf N. H., Hamed M. A., El Sayed I., Sakeran M. I. (2014) Anti-cancer, Anti-inflammatory, Cytotoxic and Biochemical Activities of a Novel Phosphonotripeptide Synthesized from Formyl Pyrazolofuran using TUBU as Condensing Agent. Journal of Advances in Chemistry., 6 (3) 1093-1102
8 Sebeka A. A. H., Osman A. M., El Sayed I. E. T., El Bahanasawy M., Tantawy M. A. (2017) Synthesis and antiproliferative activity of novel neocryptolepine-hydrazides hybrids. Journal of Applied Pharmaceutical Science., 7 (10) 009-015.
9 Xu Y., Yan K., Song B., Xu G., Yang S., Xue W., Chen Z. (2006) Synthesis and antiviral bioactivities of α-aminophosphonates containing alkoxyethyl moieties. Molecules, 11 (9) 666-676.
10 Joossens J., Van der Veken P., Surpateanu G., Lambeir A. M., El-Sayed I., Ali O. M., Haemers A. (2006) Diphenyl phosphonate inhibitors for the urokinase-type plasminogen activator: Optimization of the P4 position. J. Med. Chem., 49 (19) 5785-5793.
11 Joossens J., Ali O. M., El-Sayed I., Surpateanu G., Van der Veken P., Lambeir A. M., Haemers A. (2007) Small, potent, and selective diaryl phosphonate inhibitors for urokinase-type plasminogen activator with in vivo antimetastatic properties. J. Med. Chem., 50 (26) 6638-6646.
12 Ahmed A. A., Awad H. M., El-Sayed I. E. T., & El Gokha A. A. (2020) Synthesis and antiproliferative activity of new hybrids bearing neocryptolepine, acridine and α-aminophosphonate scaffolds. Journal of the Iranian Chemical Society., 17 (5) 1211-1221.
13 El-Boraey H. A. L., El-Gokha A. A. A., El-Sayed I. E. T.,Azzam M. A. (2015) Transition metal complexes of α-aminophosphonates Part I: synthesis, spectroscopic characterization, and in vitro anticancer activity of copper (II) complexes of α-aminophosphonates. Med. Chem. Res., 24 (5) 2142-2153.
14 Azzam M. A., El-Boraey H. A. L., El-Sayed I. E. T. (2020) Transition metal complexes of α-aminophosphonates part II: Synthesis, spectroscopic characterization, and in vitro anticancer activity of copper (II) complexes of α-aminophosphonates. Phosphorus, Sulfur Silicon Relat. Elem., 195 (4) 339-347.
15 Imam E. A., El-Sayed I. E. T., Mahfouz M. G., Tolba A. A., Akashi T., Galhoum A. A., Guibal E. (2018) Synthesis of α-aminophosphonate functionalized chitosan sorbents: effect of methyl vs phenyl group on uranium sorption. Chemical Engineering Journal., 352 (15) 1022-1034.
16 Mahmoud M. E., Adel S. E., ElSayed I. E. (2020) Development of titanium oxide-bound-α-aminophosphonate nanocomposite for adsorptive removal of lead and copper from aqueous solution. Water Resources and Industry., 23 100126.
17 Galhoum A. A., Eisa W. H., El-Sayed I. E. T., Tolba A. A., Shalaby Z. M., Mohamady S. I., Guibal E. (2020) A new route for manufacturing poly (aminophosphonic)-functionalized poly (glycidyl methacrylate)-magnetic nanocomposite-Application to uranium sorption from ore leachate. Environmental Pollution, 264 114797.
18 (a)Hou J. T., Gao J. W., Zhang Z. H. (2011) NbCl5: an efficient catalyst for one‐pot synthesis of α‐aminophosphonates under solvent‐free conditions. Appl. Organometal. Chem., 25 (1) 47-53. (b) Gao G., Chen M. N., Mo L. P., Zhang Z. H. (2019) Catalyst free one-pot synthesis of α-aminophosphonates in aqueous ethyl lactate. Phosphorus, Sulfur Silicon Relat. Elem., 194 (4-6) 528-532
19 Sun G. Y., Hou J. T., Dou J. J., Lu J., Hou Y. J., Xue T., Zhang Z. H. (2010) Xanthan Sulfuric Acid as an Efficient Biodegradable and Recyclable Catalyst for the One‐Pot Synthesis of α‐Amino Phosphonates. J. Chin. Chem. Soc, 57 (6) 1315-1320.
20 Van der Veken P., El Sayed I., Joossens J., Stevens C. V., Augustyns K., Haemers A. (2005) Lewis acid catalyzed synthesis of N-protected diphenyl 1-aminoalkylphosphonates. Synthesis, 2005 (04) 634-638.
21 Abu‐Dief A. M., Nassar I. F., Elsayed W. H. (2016) Magnetic NiFe2O4 nanoparticles: efficient, heterogeneous and reusable catalyst for synthesis of acetylferrocene chalcones and their anti‐tumour activity. Appl. Organometal. Chem., 30 (11) 917-923.
22 Mollashahi E., Gholami H., Kangani M., Lashkari M., Maghsoodlou M. T. (2015) A Quick and Clean Procedure for Synthesis of α‐Aminophosphonates in Aqueous Media. Heteroatom Chemistry, 26 (5) 322-328.
23 Sayed I. E., Kosy S. M. E., Magied M. A., Hamed M. A., Gokha A. A. A., & Sattar M. A. (2011) One-pot synthesis of novel α-aminophosphonate derivatives containing a pyrazole moiety. Journal of American Science., 7(9) 604-608.
24 Wu M., Liu R., & Wan D. (2013) Convenient One‐Pot Synthesis of α‐Amino Phosphonates in Water Using p‐Toluenesulfonic Acid as Catalyst for the Kabachnik–Fields Reaction. Heteroatom Chemistry., 24 (2) 110-115.
2 Mucha A., Kafarski P., Berlicki Ł. (2011) Remarkable potential of the α-aminophosphonat /phosphinate structural motif in medicinal chemistry. J. Med. Chem., 54 (17) 5955-5980.
3 Elsherbiny D. A., Abdelgawad A. M., El-Naggar M. E., El-Sherbiny R. A., El-Rafie M. H., El-Sayed I. E. T. (2020) Synthesis, antimicrobial activity, and sustainable release of novel α-aminophosphonate derivatives loaded Carrageenan Cryogel. International. Journal of Biological Macromolecules., 163 96-107.
4 Xiao L. X., Li K., Shi D. Q. (2008) A Convenient Synthesis and Herbicidal Activity of N-phosphonoalkylpyrazolo [4, 3-e] [1, 2, 4]-triazolo [1, 5-d] pyrimidines. Phosphorus, Sulfur Silicon Relat. Elem, 183 (12) 3156-3165.
5 Boshta N. M., Elgamal E. A., & El-Sayed I. E. (2018) Bioactive amide and α-aminophosphonate inhibitors for methicillin-resistant Staphylococcus aureus (MRSA). Monatshefte für Chemie-Chemical Monthly., 149 (12) 2349-2358.
6 Hamed M. A., El Gokha A. A., Ahmed A. F. A., Elsayed M. S. A. E., Tarabee R., Megeed A. E. S. A., El Sayed I. E. T. (2015) Synthesis and Antimicrobial Activity of Novel α-Aminophosphonates Bearing Pyrazoloquinoxaline Moiety. Int. J. Pharm. Sci. Rev. Res., 34 205-213.
7 Ouf N. H., Hamed M. A., El Sayed I., Sakeran M. I. (2014) Anti-cancer, Anti-inflammatory, Cytotoxic and Biochemical Activities of a Novel Phosphonotripeptide Synthesized from Formyl Pyrazolofuran using TUBU as Condensing Agent. Journal of Advances in Chemistry., 6 (3) 1093-1102
8 Sebeka A. A. H., Osman A. M., El Sayed I. E. T., El Bahanasawy M., Tantawy M. A. (2017) Synthesis and antiproliferative activity of novel neocryptolepine-hydrazides hybrids. Journal of Applied Pharmaceutical Science., 7 (10) 009-015.
9 Xu Y., Yan K., Song B., Xu G., Yang S., Xue W., Chen Z. (2006) Synthesis and antiviral bioactivities of α-aminophosphonates containing alkoxyethyl moieties. Molecules, 11 (9) 666-676.
10 Joossens J., Van der Veken P., Surpateanu G., Lambeir A. M., El-Sayed I., Ali O. M., Haemers A. (2006) Diphenyl phosphonate inhibitors for the urokinase-type plasminogen activator: Optimization of the P4 position. J. Med. Chem., 49 (19) 5785-5793.
11 Joossens J., Ali O. M., El-Sayed I., Surpateanu G., Van der Veken P., Lambeir A. M., Haemers A. (2007) Small, potent, and selective diaryl phosphonate inhibitors for urokinase-type plasminogen activator with in vivo antimetastatic properties. J. Med. Chem., 50 (26) 6638-6646.
12 Ahmed A. A., Awad H. M., El-Sayed I. E. T., & El Gokha A. A. (2020) Synthesis and antiproliferative activity of new hybrids bearing neocryptolepine, acridine and α-aminophosphonate scaffolds. Journal of the Iranian Chemical Society., 17 (5) 1211-1221.
13 El-Boraey H. A. L., El-Gokha A. A. A., El-Sayed I. E. T.,Azzam M. A. (2015) Transition metal complexes of α-aminophosphonates Part I: synthesis, spectroscopic characterization, and in vitro anticancer activity of copper (II) complexes of α-aminophosphonates. Med. Chem. Res., 24 (5) 2142-2153.
14 Azzam M. A., El-Boraey H. A. L., El-Sayed I. E. T. (2020) Transition metal complexes of α-aminophosphonates part II: Synthesis, spectroscopic characterization, and in vitro anticancer activity of copper (II) complexes of α-aminophosphonates. Phosphorus, Sulfur Silicon Relat. Elem., 195 (4) 339-347.
15 Imam E. A., El-Sayed I. E. T., Mahfouz M. G., Tolba A. A., Akashi T., Galhoum A. A., Guibal E. (2018) Synthesis of α-aminophosphonate functionalized chitosan sorbents: effect of methyl vs phenyl group on uranium sorption. Chemical Engineering Journal., 352 (15) 1022-1034.
16 Mahmoud M. E., Adel S. E., ElSayed I. E. (2020) Development of titanium oxide-bound-α-aminophosphonate nanocomposite for adsorptive removal of lead and copper from aqueous solution. Water Resources and Industry., 23 100126.
17 Galhoum A. A., Eisa W. H., El-Sayed I. E. T., Tolba A. A., Shalaby Z. M., Mohamady S. I., Guibal E. (2020) A new route for manufacturing poly (aminophosphonic)-functionalized poly (glycidyl methacrylate)-magnetic nanocomposite-Application to uranium sorption from ore leachate. Environmental Pollution, 264 114797.
18 (a)Hou J. T., Gao J. W., Zhang Z. H. (2011) NbCl5: an efficient catalyst for one‐pot synthesis of α‐aminophosphonates under solvent‐free conditions. Appl. Organometal. Chem., 25 (1) 47-53. (b) Gao G., Chen M. N., Mo L. P., Zhang Z. H. (2019) Catalyst free one-pot synthesis of α-aminophosphonates in aqueous ethyl lactate. Phosphorus, Sulfur Silicon Relat. Elem., 194 (4-6) 528-532
19 Sun G. Y., Hou J. T., Dou J. J., Lu J., Hou Y. J., Xue T., Zhang Z. H. (2010) Xanthan Sulfuric Acid as an Efficient Biodegradable and Recyclable Catalyst for the One‐Pot Synthesis of α‐Amino Phosphonates. J. Chin. Chem. Soc, 57 (6) 1315-1320.
20 Van der Veken P., El Sayed I., Joossens J., Stevens C. V., Augustyns K., Haemers A. (2005) Lewis acid catalyzed synthesis of N-protected diphenyl 1-aminoalkylphosphonates. Synthesis, 2005 (04) 634-638.
21 Abu‐Dief A. M., Nassar I. F., Elsayed W. H. (2016) Magnetic NiFe2O4 nanoparticles: efficient, heterogeneous and reusable catalyst for synthesis of acetylferrocene chalcones and their anti‐tumour activity. Appl. Organometal. Chem., 30 (11) 917-923.
22 Mollashahi E., Gholami H., Kangani M., Lashkari M., Maghsoodlou M. T. (2015) A Quick and Clean Procedure for Synthesis of α‐Aminophosphonates in Aqueous Media. Heteroatom Chemistry, 26 (5) 322-328.
23 Sayed I. E., Kosy S. M. E., Magied M. A., Hamed M. A., Gokha A. A. A., & Sattar M. A. (2011) One-pot synthesis of novel α-aminophosphonate derivatives containing a pyrazole moiety. Journal of American Science., 7(9) 604-608.
24 Wu M., Liu R., & Wan D. (2013) Convenient One‐Pot Synthesis of α‐Amino Phosphonates in Water Using p‐Toluenesulfonic Acid as Catalyst for the Kabachnik–Fields Reaction. Heteroatom Chemistry., 24 (2) 110-115.