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2. Electrochemical and theoretical investigations of the role of the appended base on the reduction of protons by [Fe2(CO)4(κ2-PNP(R)(μ-S(CH2)3S] (PNP(R) ={Ph2PCH2}2NR, R=Me, Ph)

Author

Lounissi, S, Capon, JF, Matoussi, F, Mahfoudhi, S, Petillon, FY, Schollhammer, P, Talarmin, J., ZAMPELLA, GIUSEPPE, DE GIOIA, LUCA, Lounissi, S, Zampella, G, Capon, J, DE GIOIA, L, Matoussi, F, Mahfoudhi, S, Petillon, F, Schollhammer, P, and Talarmin, J

Subjects
CHIM/03 - CHIMICA GENERALE E INORGANICA, Iron-Sulfur Proteins, Binding Sites, Magnetic Resonance Spectroscopy, appended base, Molecular Structure, Nitrogen, Molecular Mimicry, Electrochemical Techniques, density functional calculation, Crystallography, X-Ray, Ligands, Catalysis, Kinetics, electrochemistry, Hydrogenase, Models, Chemical, Quantum Theory, Thermodynamics, Ferrous Compounds, hydrogenase model, Protons, Oxidation-Reduction, Hydrogen
Abstract

The behavior of [Fe(2)(CO)(4)(κ(2)-PNP(R))(μ-pdt)] (PNP(R) =(Ph(2)PCH(2))(2)NR, R=Me (1), Ph (2); pdt=S(CH(2))(3)S) in the presence of acids is investigated experimentally and theoretically (using density functional theory) in order to determine the mechanisms of the proton reduction steps supported by these complexes, and to assess the role of the PNP(R) appended base in these processes for different redox states of the metal centers. The nature of the R substituent of the nitrogen base does not substantially affect the course of the protonation of the neutral complex by CF(3)SO(3)H or CH(3)SO(3)H; the cation with a bridging hydride ligand, 1 μH(+) (R=Me) or 2 μH(+) (R=Ph) is obtained rapidly. Only 1 μH(+) can be protonated at the nitrogen atom of the PNP chelate by HBF(4)·Et(2)O or CF(3)SO(3)H, which results in a positive shift of the proton reduction by approximately 0.15 V. The theoretical study demonstrates that in this process, dihydrogen can be released from a η(2)-H(2) species in the Fe(I)Fe(II) state. When R=Ph, the bridging hydride cation 2 μH(+) cannot be protonated at the amine function by HBF(4)·Et(2)O or CF(3)SO(3)H, and protonation at the N atom of the one-electron reduced analogue is also less favored than that of a S atom of the partially de-coordinated dithiolate bridge. In this situation, proton reduction occurs at the potential of the bridging hydride cation, 2 μH(+). The rate constants of the overall proton reduction processes are small for both complexes 1 and 2 (k(obs) ≈4-7 s(-1)) because of the slow intramolecular proton migration and H(2) release steps identified by the theoretical study.

Published
2012

3. Electrochemical and Theoretical Investigations of the Role of the Appended Base on the Reduction of Protons by [Fe-2(CO)(4)(kappa(2)-PNPR)(mu-S(CH2)(3)S] (PNPR={Ph2PCH2}(2)NR, R=Me, Ph)

Author

Lounissi, S, Zampella, G, Capon, J, DE GIOIA, L, Matoussi, F, Mahfoudhi, S, Petillon, F, Schollhammer, P, Talarmin, J, Capon, JF, Petillon, FY, Talarmin, J., ZAMPELLA, GIUSEPPE, DE GIOIA, LUCA, Lounissi, S, Zampella, G, Capon, J, DE GIOIA, L, Matoussi, F, Mahfoudhi, S, Petillon, F, Schollhammer, P, Talarmin, J, Capon, JF, Petillon, FY, Talarmin, J., ZAMPELLA, GIUSEPPE, and DE GIOIA, LUCA

Abstract

The behavior of [Fe2(CO)4(?2-PNPR)(mu-pdt)] (PNPR=(Ph2PCH2)2NR, R=Me (1), Ph (2); pdt=S(CH2)3S) in the presence of acids is investigated experimentally and theoretically (using density functional theory) in order to determine the mechanisms of the proton reduction steps supported by these complexes, and to assess the role of the PNPR appended base in these processes for different redox states of the metal centers. The nature of the R substituent of the nitrogen base does not substantially affect the course of the protonation of the neutral complex by CF3SO3H or CH3SO3H; the cation with a bridging hydride ligand, 1?mu H+ (R=Me) or 2?mu H+ (R=Ph) is obtained rapidly. Only 1?mu H+ can be protonated at the nitrogen atom of the PNP chelate by HBF4 center dot Et2O or CF3SO3H, which results in a positive shift of the proton reduction by approximately 0.15 V. The theoretical study demonstrates that in this process, dihydrogen can be released from a ?2-H2 species in the FeIFeII state. When R=Ph, the bridging hydride cation 2?mu H+ cannot be protonated at the amine function by HBF4 center dot Et2O or CF3SO3H, and protonation at the N atom of the one-electron reduced analogue is also less favored than that of a S atom of the partially de-coordinated dithiolate bridge. In this situation, proton reduction occurs at the potential of the bridging hydride cation, 2?mu H+. The rate constants of the overall proton reduction processes are small for both complexes 1 and 2 (kobs approximate to 47 s-1) because of the slow intramolecular proton migration and H2 release steps identified by the theoretical study.

Published
2012

6. Abstracts of the 40th National Congress of Medicine Tunis, 19-20 October 2017

Author

Abdallah, M., Abdelaziz, A., Abdelaziz, O., Abdelhedi, N., Abdelkbir, A., Abdelkefi, M., Abdelmoula, L., Abdennacir, S., Abdennadher, M., Abidi, H., Abir Hakiri, A., Abou El Makarim, S., Abouda, M., Achour, W., Aichaouia, C., Aissa, A., Aissa, Y., Aissi, W., Ajroudi, M., Allouche, E., Aloui, H., Aloui, D., Amdouni, F., Ammar, Y., Ammara, Y., Ammari, S., Ammous, A., Amous, A., Amri, A., Amri, M., Amri, R., Annabi, H., Antit, S., Aouadi, S., Arfaoui, A., Assadi, A., Attia, L., Attia, M., Ayadi, I., Ayadi Dahmane, I., Ayari, A., Azzabi, S., Azzouz, H., B Mefteh, N., B Salah, C., Baccar, H., Bachali, A., Bahlouli, M., Bahri, G., Baïli, H., Bani, M., Bani, W., Bani, M. A., Bassalah, E., Bawandi, R., Bayar, M., Bchir, N., Bechraoui, R., Béji, M., Beji, R., Bel Haj Yahia, D., Belakhel, S., Belfkih, H., Belgacem, O., Belgacem, N., Belhadj, A., Beltaief, N., Ben Abbes, M., Ben Abdelaziz, A., Ben Ahmed, I., Ben Aissia, N., Ben Ali, M., Ben Ammar, H., Ben Ammou, B., Ben Amor, A., Ben Amor, M., Benatta, M., Ben Ayed, N., Ben Ayoub, W., Ben Charrada, N., Ben Cheikh, M., Ben Dahmen, F., Ben Dhia, M., Ben Fadhel, S., Ben Farhat, L., Ben Fredj Ismail, F., Ben Hamida, E., Ben Hamida Nouaili, E., Ben Hammamia, M., Ben Hamouda, A., Ben Hassine, L., Ben Hassouna, A., Ben Hasssen, A., Ben Hlima, M., Ben Kaab, B., Ben Mami, N., Ben Mbarka, F., Ben Mefteh, N., Ben Kahla, N., Ben Mrad, M., Ben Mustapha, N., Ben Nacer, M., Ben Neticha, K., Ben Othmen, E., Ben Rhouma, S., Ben Rhouma, M., Ben Saadi, S., Ben Safta, A., Ben Safta, Z., Ben Salah, C., Ben Salah, N., Ben Sassi, S., Ben Sassi, J., Ben Tekaya, S., Ben Temime, R., Ben Tkhayat, A., Ben Tmim, R., Ben Yahmed, Y., Ben Youssef, S., Ben Atta, M., Ben Salah, M., Berrahal, I., Besbes, G., Bezdah, L., Bezzine, A., Bokal, Z., Borsali, R., Bouasker, I., Boubaker, J., Bouchekoua, M., Bouden, F., Boudiche, S., Boukhris, I., Bouomrani, S., Bouraoui, S., Bourgou, S., Boussabeh, E., Bouzaidi, K., Chaker, K., Chaker, L., Chaker, A., Chaker, F., Chaouech, N., Charfi, M., Charfi, M. R., Charfi, F., Chatti, L., Chebbi, F., Chebbi, W., Cheikh, R., Cheikhrouhou, S., Chekir, J., Chelbi, E., Chelly, I., Chelly, B., Chemakh, M., Chenik, S., Cheour, M., Cherif, E., Cherif, Y., Cherif, W., Cherni, R., Chetoui, A., Chihaoui, M., Chiraz Aichaouia, C., Dabousii, S., Daghfous, A., Daib, A., Daib, N., Damak, R., Daoud, N., Daoud, Z., Daoued, N., Debbabi, H., Demni, W., Denguir, R., Derbel, S., Derbel, B., Dghaies, S., Dhaouadi, S., Dhilel, I., Dimassi, K., Dougaz, A., Dougaz, W., Douik, H., Douik El Gharbi, L., Dziri, C., El Aoud, S., El Hechmi, Z., El Heni, A., Elaoud, S., Elfeleh, E., Ellini, S., Ellouz, F., Elmoez Ben, O., Ennaifer, R., Ennaifer, S., Essid, M., Fadhloun, N., Farhat, M., Fekih, M., Fourati, M., Fteriche, F., G Hali, O., Galai, S., Gara, S., Garali, G., Garbouge, W., Garbouj, W., Ghali, O., Ghali, F., Gharbi, E., Gharbi, R., Ghariani, W., Gharsalli, H., Ghaya Jmii, G., Ghédira, F., Ghédira, A., Ghédira, H., Ghériani, A., Gouta, E. L., Guemira, F., Guermazi, E., Guesmi, A., Hachem, J., Haddad, A., Hakim, K., Hakiri, A., Hamdi, S., Hamed, W., Hamrouni, S., Hamza, M., Haouet, S., Hariz, A., Hendaoui, L., Hfaidh, M., Hriz, H., Hsairi, M., Ichaoui, H., Issaoui, D., Jaafoura, H., Jazi, R., Jazia, R., Jelassi, H., Jerraya, H., Jlassi, H., Jmii, G., Jouini, M., Kâaniche, M., Kacem, M., Kadhraoui, M., Kalai, M., Kallel, K., Kammoun, O., Karoui, M., Karouia, S., Karrou, M., Kchaou, A., Kchaw, R., Kchir, N., Kchir, H., Kechaou, I., Kerrou, M., Khaled, S., Khalfallah, N., Khalfallah, M., Khalfallah, R., Khamassi, K., Kharrat, M., Khelifa, E., Khelil, M., Khelil, A., Khessairi, N., Khezami, M. A., Khouni, H., Kooli, C., Korbsi, B., Koubaa, M. A., Ksantini, R., Ksentini, A., Ksibi, I., Ksibi, J., Kwas, H., Laabidi, A., Labidi, A., Ladhari, N., Lafrem, R., Lahiani, R., Lajmi, M., Lakhal, J., Laribi, M., Lassoued, N., Lassoued, K., Letaif, F., Limaïem, F., Maalej, S., Maamouri, N., Maaoui, R., Maâtallah, H., Maazaoui, S., Maghrebi, H., Mahfoudhi, S., Mahjoubi, Y., Mahjoubi, S., Mahmoud, I., Makhlouf, T., Makni, A., Mamou, S., Mannoubi, S., Maoui, A., Marghli, A., Marrakchi, Z., Marrakchi, J., Marzougui, S., Marzouk, I., Mathlouthi, N., Mbarek, K., Mbarek, M., Meddeb, S., azza mediouni, Mechergui, N., Mejri, I., Menjour, M. B., Messaoudi, Y., Mestiri, T., Methnani, A., Mezghani, I., Meziou, O., Mezlini, A., Mhamdi, S., Mighri, M., Miled, S., Miri, I., Mlayeh, D., Moatemri, Z., Mokaddem, W., Mokni, M., Mouhli, N., Mourali, M. S., Mrabet, A., Mrad, F., Mrouki, M., Msaad, H., Msakni, A., Msolli, S., Mtimet, S., Mzabi, S., Mzoughi, Z., Naffeti, E., Najjar, S., Nakhli, A., Nechi, S., Neffati, E., Neji, H., Nouira, Y., Nouira, R., Omar, S., Ouali, S., Ouannes, Y., Ouarda, F., Ouechtati, W., Ouertani, J., Ouertani, H., Oueslati, A., Oueslati, J., Oueslati, I., Rabai, B., Rahali, H., Rbia, E., Rebai, W., Regaïeg, N., Rejeb, O., Rhaiem, W., Rhimi, H., Riahi, I., Ridha, R., Robbena, L., Rouached, L., Rouis, S., Safer, M., Saffar, K., Sahli, H., Sahraoui, G., Saidane, O., Sakka, D., Salah, H., Sallami, S., Salouage, I., Samet, A., Sammoud, K., Sassi Mahfoudh, A., Sayadi, C., Sayhi, A., Sebri, T., Sedki, Y., Sellami, A., Serghini, M., Sghaier, I., Skouri, W., Slama, I., Slimane, H., Slimani, O., Souhail, O., Souhir, S., Souissi, A., Souissi, R., Taboubi, A., Talbi, G., Tbini, M., Tborbi, A., Tekaya, R., Temessek, H., Thameur, M., Touati, A., Touinsi, H., Tounsi, A., Tounsia, H., Trabelsi, S., Triki, A., Triki, M., Turki, J., Turki, K., Twinsi, H., Walha, Y., Wali, J., Yacoub, H., Yangui, F., Yazidi, M., Youssef, I., Zaier, A., Zainine, R., Zakhama, L., Zalila, H., Zargouni, H., Zehani, A., Zeineb, Z., Zemni, I., Zghal, M., Ziadi, J., Zid, Z., Znagui, I., Zoghlami, C., Zouaoui, C., Zouari, B., Zouiten, L., and Zribi, H.

7. Simultaneous determination of oxacillin and cloxacillin in plasma and CSF using turbulent flow liquid chromatography coupled to high-resolution mass spectrometry: Application in therapeutic drug monitoring.

Author

Mahfoudhi S, Mory C, Le Ven J, Coudore F, El Helali N, Safta F, and Le Monnier A

Subjects
Humans, Drug Monitoring methods, Reproducibility of Results, Anti-Bacterial Agents, Chromatography, Liquid methods, Tandem Mass Spectrometry methods, Chromatography, High Pressure Liquid methods, Cloxacillin analysis, Oxacillin
Abstract

Cloxacillin and oxacillin are group M penicillins. The therapeutic monitoring of plasma concentrations of these antibiotics and those of their hydroxymethylated metabolites is of great clinical interest, especially in the choice of an adequate dosage allowing an effective treatment while limiting the occurrence of undesirable effects and the development of bacterial resistance. In this context, we conducted this work aiming at developing and validating a method allowing the determination of cloxacillin and oxacillin as well as the identification of their active metabolites in different biological matrices (CSF and plasma) using turbulent flow liquid chromatography coupled to high-resolution mass spectrometry. To do this, we carried out several optimisation tests. Subsequently, we validated our method according to the latest bioanalytical validation recommendations of the European Medicines Agency. The validation results showed that our method is specific and sensitive. We obtained good linearity in the range 0.5 to 100 µg/mL with correlation coefficients above 0.995. The lower limit of quantification was 0.5 µg/mL for each analyte. The method was found to be accurate with repeatability and reproducibility coefficients of variation below 15 %. Our method is also accurate with bias values below 15 %. Recovery values ranged from 87 % to 95 %. Finally, we were able to apply our method to the therapeutic monitoring of the analysed molecules and to identify their active metabolites. Our results suggest that LC-MS shows superiority in the therapeutic monitoring of these antibiotics due to the superiority of specificity shown by this method. This assay method can be routinely used for the daily plasma assays of patients treated with these antibiotics in the context of therapeutic monitoring., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2023 Elsevier B.V. All rights reserved.)

Published
2024
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8. Green complexation for heavy metals removal from wastewater by Keggin-polyoxometalates enhanced ultrafiltration.

Author

Kahloul M, Mahfoudhi S, Ounifi I, Elabed B, Amor TB, and Hafiane A

Subjects
Anions, Cadmium, Chelating Agents, Copper, Polyelectrolytes, Sodium Chloride, Wastewater, Metals, Heavy, Ultrafiltration methods
Abstract

The presence of heavy metals in wastewater has become a serious issue and a global concern for the environment and public health with rapid progress of modern textile industry. To minimize the health risks of heavy metals their complexation to a chelating agent constitute a promising process using membrane separation. We highlight for the first time the use of Keggin type-polyoxometalates (PW 12 ) as complexing agent to eliminate heavy metals from synthetic textile wastewater. Indeed, filtration experiments were performed through the ultrafiltration organic regenerated cellulose membrane (3KDa). Effects of pressure (1-2.5 bar), PW 12 concentration (10-50 mg·L -1 ), salt concentration (10 -4 -2 M) and pH value (2-12) on cadmium (Cd) and copper (Cu) removal were regularly explored. Experimental data showed that the addition of PW 12 improves metal removal efficiency (up to 90%). The addition of NaCl salt significantly decreases the metals retention to 42%. The retention drop is probably due to the competition between Na+ and metals on complexation same negative sites of the PW 12 and to the electric double-layer compressing. 2 4 full factorial design has been used to evaluate the most influencing parameters. The results obtained revealed that the maximum metal retention was 99% for both Cd and Cu.

Published
2022
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9. Abstracts of the 40th National Congress of Medicine Tunis, 19-20 October 2017.

Author

Abdallah M, Abdelaziz A, Abdelaziz O, Abdelhedi N, Abdelkbir A, Abdelkefi M, Abdelmoula L, Abdennacir S, Abdennadher M, Abidi H, Abir Hakiri A, Abou El Makarim S, Abouda M, Achour W, Aichaouia C, Aissa A, Aissa Y, Aissi W, Ajroudi M, Allouche E, Aloui H, Aloui D, Amdouni F, Ammar Y, Ammara Y, Ammari S, Ammous A, Amous A, Amri A, Amri M, Amri R, Annabi H, Antit S, Aouadi S, Arfaoui A, Assadi A, Attia L, Attia M, Attia L, Ayadi I, Ayadi Dahmane I, Ayari A, Azzabi S, Azzouz H, B Mefteh N, B Salah C, Baccar H, Bachali A, Bahlouli M, Bahri G, Baïli H, Bani M, Bani W, Bani MA, Bassalah E, Bawandi R, Bayar M, Bchir N, Bechraoui R, Béji M, Beji R, Bel Haj Yahia D, Belakhel S, Belfkih H, Belgacem O, Belgacem N, Belhadj A, Beltaief N, Beltaief N, Ben Abbes M, Ben Abdelaziz A, Ben Ahmed I, Ben Aissia N, Ben Ali M, Ben Ammar H, Ben Ammou B, Ben Amor A, Ben Amor M, Benatta M, Ben Ayed N, Ben Ayoub W, Ben Charrada N, Ben Cheikh M, Ben Dahmen F, Ben Dhia M, Ben Fadhel S, Ben Farhat L, Ben Fredj Ismail F, Ben Hamida E, Ben Hamida Nouaili E, Ben Hammamia M, Ben Hamouda A, Ben Hassine L, Ben Hassouna A, Ben Hasssen A, Ben Hlima M, Ben Kaab B, Ben Mami N, Ben Mbarka F, Ben Mefteh N, Ben Kahla N, Ben Mrad M, Ben Mustapha N, Ben Nacer M, Ben Neticha K, Ben Othmen E, Ben Rhouma S, Ben Rhouma M, Ben Saadi S, Ben Safta A, Ben Safta Z, Ben Salah C, Ben Salah N, Ben Sassi S, Ben Sassi J, Ben Tekaya S, Ben Temime R, Ben Tkhayat A, Ben Tmim R, Ben Yahmed Y, Ben Youssef S, Ben Ali M, Ben Atta M, Ben Safta Z, Ben Salah M, Berrahal I, Besbes G, Bezdah L, Bezzine A, Bezzine A, Bokal Z, Borsali R, Bouasker I, Boubaker J, Bouchekoua M, Bouden F, Boudiche S, Boukhris I, Bouomrani S, Bouraoui S, Bouraoui S, Bourgou S, Boussabeh E, Bouzaidi K, Chaker K, Chaker L, Chaker A, Chaker F, Chaouech N, Charfi M, Charfi MR, Charfi F, Chatti L, Chebbi F, Chebbi W, Cheikh R, Cheikhrouhou S, Chekir J, Chelbi E, Chelly I, Chelly B, Chemakh M, Chenik S, Cheour M, Cheour M, Cherif E, Cherif Y, Cherif W, Cherni R, Chetoui A, Chihaoui M, Chiraz Aichaouia C, Dabousii S, Daghfous A, Daib A, Daib N, Damak R, Daoud N, Daoud Z, Daoued N, Debbabi H, Demni W, Denguir R, Derbel S, Derbel B, Dghaies S, Dhaouadi S, Dhilel I, Dimassi K, Dougaz A, Dougaz W, Douik H, Douik El Gharbi L, Dziri C, El Aoud S, El Hechmi Z, El Heni A, ELaoud S, Elfeleh E, Ellini S, Ellouz F, Elmoez Ben O, Ennaifer R, Ennaifer S, Essid M, Fadhloun N, Farhat M, Fekih M, Fourati M, Fteriche F, G Hali O, Galai S, Gara S, Garali G, Garbouge W, Garbouj W, Ghali O, Ghali F, Gharbi E, Gharbi R, Ghariani W, Gharsalli H, Ghaya Jmii G, Ghédira F, Ghédira A, Ghédira H, Ghériani A, Gouta EL, Guemira F, Guermazi E, Guesmi A, Hachem J, Haddad A, Hakim K, Hakiri A, Hamdi S, Hamed W, Hamrouni S, Hamza M, Haouet S, Hariz A, Hendaoui L, Hfaidh M, Hriz H, Hsairi M, Ichaoui H, Issaoui D, Jaafoura H, Jazi R, Jazia R, Jelassi H, Jerraya H, Jlassi H, Jmii G, Jouini M, Kâaniche M, Kacem M, Kadhraoui M, Kalai M, Kallel K, Kammoun O, Karoui M, Karouia S, Karrou M, Kchaou A, Kchaw R, Kchir N, Kchir H, Kechaou I, Kerrou M, Khaled S, Khalfallah N, Khalfallah M, Khalfallah R, Khamassi K, Kharrat M, Khelifa E, Khelil M, Khelil A, Khessairi N, Khezami MA, Khouni H, Kooli C, Korbsi B, Koubaa MA, Ksantini R, Ksentini A, Ksibi I, Ksibi J, Kwas H, Laabidi A, Labidi A, Ladhari N, Lafrem R, Lahiani R, Lajmi M, Lakhal J, Laribi M, Lassoued N, Lassoued K, Letaif F, Limaïem F, Maalej S, Maamouri N, Maaoui R, Maâtallah H, Maazaoui S, Maghrebi H, Mahfoudhi S, Mahjoubi Y, Mahjoubi S, Mahmoud I, Makhlouf T, Makni A, Mamou S, Mannoubi S, Maoui A, Marghli A, Marrakchi Z, Marrakchi J, Marzougui S, Marzouk I, Mathlouthi N, Mbarek K, Mbarek M, Meddeb S, Mediouni A, Mechergui N, Mejri I, Menjour MB, Messaoudi Y, Mestiri T, Methnani A, Mezghani I, Meziou O, Mezlini A, Mhamdi S, Mighri M, Miled S, Miri I, Mlayeh D, Moatemri Z, Mokaddem W, Mokni M, Mouhli N, Mourali MS, Mrabet A, Mrad F, Mrouki M, Msaad H, Msakni A, Msolli S, Mtimet S, Mzabi S, Mzoughi Z, Naffeti E, Najjar S, Nakhli A, Nechi S, Neffati E, Neji H, Nouira Y, Nouira R, Omar S, Ouali S, Ouannes Y, Ouarda F, Ouechtati W, Ouertani J, Ouertani J, Ouertani H, Oueslati A, Oueslati J, Oueslati I, Oueslati A, Rabai B, Rahali H, Rbia E, Rebai W, Regaïeg N, Rejeb O, Rhaiem W, Rhimi H, Riahi I, Ridha R, Robbena L, Rouached L, Rouis S, Safer M, Saffar K, Sahli H, Sahraoui G, Saidane O, Sakka D, Salah H, Sallami S, Salouage I, Samet A, Sammoud K, Sassi Mahfoudh A, Sayadi C, Sayhi A, Sebri T, Sedki Y, Sellami A, Serghini M, Sghaier I, Skouri W, Skouri W, Slama I, Slimane H, Slimani O, Souhail O, Souhir S, Souissi A, Souissi R, Taboubi A, Talbi G, Tbini M, Tborbi A, Tekaya R, Temessek H, Thameur M, Touati A, Touinsi H, Tounsi A, Tounsia H, Trabelsi S, Trabelsi S, Triki A, Triki M, Turki J, Turki K, Twinsi H, Walha Y, Wali J, Yacoub H, Yangui F, Yazidi M, Youssef I, Zaier A, Zainine R, Zakhama L, Zalila H, Zargouni H, Zehani A, Zeineb Z, Zemni I, Zghal M, Ziadi J, Zid Z, Znagui I, Zoghlami C, Zouaoui C, Zouari B, Zouiten L, and Zribi H

Published
2017

10. Biophysical properties of cationic lipophosphoramidates: Vesicle morphology, bilayer hydration and dynamics.

Author

Loizeau D, Jurkiewicz P, Aydogan G, Philimonenko AA, Mahfoudhi S, Hozák P, Maroto A, Couthon-Gourvès H, Jaffrès PA, Deschamps L, Giamarchi P, and Hof M

Subjects
Cations, Fluorescence Polarization, Microscopy, Electron, Transmission methods, Water chemistry, Lipid Bilayers chemistry, Organophosphorus Compounds chemistry
Abstract

Cationic lipids are used to deliver genetic material to living cells. Their proper biophysical characterization is needed in order to design and control this process. In the present work we characterize some properties of recently synthetized cationic lipophosphoramidates. The studied compounds share the same structure of their hydrophobic backbone, but differ in their hydrophilic cationic headgroup, which is formed by a trimethylammonium, a trimethylarsonium or a dicationic moiety. Dynamic light scattering and cryo-transmission electron microscopy proves that the studied lipophosphoramidates create stable unilamellar vesicles. Fluorescence of polarity probe, Laurdan, analyzed using time-dependent fluorescence shift method (TDFS) and generalized polarization (GP) gives important information about the phase, hydration and dynamics of the lipophosphoramidate bilayers. While all of the compounds produced lipid bilayers that were sufficiently fluid for their potential application in gene therapy, their polarity/hydration and mobility was lower than for the standard cationic lipid - DOTAP. Mixing cationic lipophosphoramidates with DOPC helps to reduce this difference. The structure of the cationic headgroup has an important and complex influence on bilayer hydration and mobility. Both TDFS and GP methods are suitable for the characterization of cationic amphiphiles and can be used for screening of the newly synthesized compounds., (Copyright © 2015 Elsevier B.V. All rights reserved.)

Published
2015
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11. Physicochemical properties of cationic lipophosphoramidates with an arsonium head group and various lipid chains: A structure-activity approach.

Author

Loizeau D, Le Gall T, Mahfoudhi S, Berchel M, Maroto A, Yaouanc JJ, Jaffrès PA, Lehn P, Deschamps L, Montier T, and Giamarchi P

Subjects
Amides metabolism, Cations metabolism, Cell Line, DNA chemistry, DNA genetics, Humans, Liposomes metabolism, Lung cytology, Membrane Fusion, Nucleic Acid Conformation, Phospholipids metabolism, Phosphoric Acids metabolism, Plasmids chemistry, Plasmids genetics, Transfection, Amides chemistry, Cations chemistry, DNA administration & dosage, Liposomes chemistry, Phospholipids chemistry, Phosphoric Acids chemistry, Plasmids administration & dosage
Abstract

We studied the physicochemical properties of some cationic lipophosphoramidates used as gene vectors in an attempt to better understand the link between the nature of the hydrophobic chain and both physico-chemical properties and transfection efficiency. These compounds have an arsonium head group and various chain lengths and unsaturation numbers. The synthesis of cationic phospholipids with oleic (Guenin et al., 2000 [1]; Floch et al., 2000 [2]) or linoleic (Fraix et al., 2011 [3]; Le Gall et al., 2010 [4]) chains has already been reported by our group and their efficiency as gene carriers has been demonstrated. Four new compounds were synthesized which incorporated either C14:0, C18:0, C20:4 or C20:5 chains. The membrane fluidity was studied by fluorescence anisotropy measurements. The fusion of liposomes and lipoplexes with membrane models was studied by Förster Resonant Energy Transfer. Finally, DNA condensation was studied and the lipoplexes were tested in vitro to quantify their transfection efficiency. From the results obtained on these cationic lipophosphoramidates series, we show that aliphatic chain length and unsaturation number have an important influence on liposomes physicochemical properties and transfection efficiency. However there is no direct link between fluidity and fusion efficiency or between fluidity and DNA condensation. Nevertheless, it seems that for best transfection efficiency the compounds need to combine the properties of fluidity, fusion efficiency and DNA condensation efficiency. This was the case for the C18:1 and C18:2 compounds., (Copyright © 2012 Elsevier B.V. All rights reserved.)

Published
2013
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