Your search keyword '"González-Mancebo, Daniel"' showing total 9 results

1. Sodium lanthanide tungstate-based nanoparticles as bimodal contrast agents for in vivo high-field MRI and CT imaging.

Author

Gómez-González, Elisabet, Caro, Carlos, Núñez, Nuria O., González-Mancebo, Daniel, Urbano-Gámez, Jesús D., García-Martín, Maria L., and Ocaña, Manuel

Abstract

Research on high-field magnetic resonance imaging (HF-MRI) has been increased in recent years, aiming to improve diagnosis accuracy by increasing the signal-to-noise ratio and hence image quality. Conventional contrast agents (CAs) have important limitations for HF-MRI, with the consequent need for the development of new CAs. Among them, the most promising alternatives are those based on Dy3+ or Ho3+ compounds. Notably, the high atomic number of lanthanide cations would bestow a high capability for X-ray attenuation to such Dy or Ho-based compounds, which would also allow them to be employed as CAs for X-ray computed tomography (CT). In this work, we have prepared uniform NaDy(WO4)2 and NaHo(WO4)2 nanoparticles (NPs), which were dispersible under conditions that mimic the physiological media and were nontoxic for cells, meeting the main requirements for their use in vivo. Both NPs exhibited satisfactory magnetic relaxivities at 9.4 T, thus making them a promising alternative to clinical CAs for HF-MRI. Furthermore, after their intravenous administration in tumor-bearing mice, both NPs exhibited significant accumulation inside the tumor at 24 h, attributable to passive targeting by the enhanced permeability and retention (EPR) effect. Therefore, our NPs are suitable for the detection of tumors through HF-MRI. Finally, NaDy(WO4)2 NPs showed a superior X-ray attenuation capability than iohexol (commercial CT CA), which, along with their high r2 value, makes them suitable as the dual-probe for both HF-MRI and CT imaging, as demonstrated by in vivo experiments conducted using healthy mice. [ABSTRACT FROM AUTHOR]

Published

2024

2. Europium doped-double sodium bismuth molybdate nanoparticles as contrast agents for luminescence bioimaging and X-ray computed tomography.

Author

Calderón-Olvera, Roxana M., Núñez, Nuria O., González-Mancebo, Daniel, Monje-Moreno, Jose M., Muñoz-Rui, Manuel J., Gómez-González, Elisabet, Arroyo, Encarnación, Torres-Herrero, Beatriz, de la Fuente, Jesús M., and Ocaña, Manuel

Published

2023

3. Revealing the substitution mechanism in Eu3+:CaMoO4 and Eu3+,Na+:CaMoO4 phosphors

Author

Becerro Nieto, Ana Isabel, Allix, Mathieu, Laguna Moreno, Mariano, González Mancebo, Daniel, Genevois, Cecile, Caballero Martínez, Alfonso, Lozano Suárez, Juan Gabriel, Núñez Álvarez, Nuria Ofelia, Ocaña Jurado, Manuel, Universidad de Sevilla. Departamento de Química Inorgánica, Consejo Superior de Investigaciones Científicas (CSIC), and European Research Council (ERC)

Abstract

Eu3+-Doped calcium molybdate is an excellent phosphor for lighting and display devices due to the very intense pure red emission after UV excitation. It has been reported in the literature that the CaMoO4 unit cell volume expands after Eu3+ doping, in spite of the smaller Eu3+ ionic radius compared with Ca2+. Likewise, several studies found that the emission intensity of the phosphor could be improved by codoping with alkaline ions like Li+, Na+ or K+. None of these studies correlated the apparent volume expansion and luminescence enhancement with the crystal structural details. This paper analyses the aliovalent substitution mechanism and crystal structure of Eu3+:CaMoO4 and Eu3+,Na+:CaMoO4 phosphors using complementary techniques like Raman spectroscopy, EXAFS and SPD. We found that the substitution mechanism was different for both systems, with Ca site vacancies forming in the Eu3+:CaMoO4 phosphors and leading to Ca13xEu2x&xMoO4 compositions, while the Eu3+,Na+:CaMoO4 phosphors formed Ca12xEuxNaxMoO4. SPD showed that the cell volume expansion observed with increasing Eu3+ content is related to the increase of the Mo–O bond distance due to the higher electronegativity of Eu3+ compared with Ca2+. Finally, it was shown that the luminescence properties, i.e. lifetime values and quantum yields (the latter reported here for the first time), do not depend on the presence of monovalent ions in the crystal structure but, exclusively, on the Eu3+ content of the phosphor. The integral and detailed analysis of the materials presented in this paper, ranging from crystal structure to luminescent properties including elemental composition, allows a full picture of the structure–property relationships that had never been addressed before for CaMoO4-based phopshors Consejo Superior de Investigaciones Científicas de España (CSIC)-PIC2016FR1 y PIE201460E005 Consejo Europeo de Investigación (ERC)-Horizonte 2020/NANOPHOM 715832

Published

2018

4. Revealing the substitution mechanism in Eu3+:CaMoO4 and Eu3+,Na+:CaMoO4 phosphors

Author

Universidad de Sevilla. Departamento de Química Inorgánica, Consejo Superior de Investigaciones Científicas (CSIC), European Research Council (ERC), Becerro Nieto, Ana Isabel, Allix, Mathieu, Laguna Moreno, Mariano, González Mancebo, Daniel, Genevois, Cecile, Caballero Martínez, Alfonso, Lozano Suárez, Juan Gabriel, Núñez Álvarez, Nuria Ofelia, Ocaña Jurado, Manuel, Universidad de Sevilla. Departamento de Química Inorgánica, Consejo Superior de Investigaciones Científicas (CSIC), European Research Council (ERC), Becerro Nieto, Ana Isabel, Allix, Mathieu, Laguna Moreno, Mariano, González Mancebo, Daniel, Genevois, Cecile, Caballero Martínez, Alfonso, Lozano Suárez, Juan Gabriel, Núñez Álvarez, Nuria Ofelia, and Ocaña Jurado, Manuel

Abstract

Eu3+-Doped calcium molybdate is an excellent phosphor for lighting and display devices due to the very intense pure red emission after UV excitation. It has been reported in the literature that the CaMoO4 unit cell volume expands after Eu3+ doping, in spite of the smaller Eu3+ ionic radius compared with Ca2+. Likewise, several studies found that the emission intensity of the phosphor could be improved by codoping with alkaline ions like Li+, Na+ or K+. None of these studies correlated the apparent volume expansion and luminescence enhancement with the crystal structural details. This paper analyses the aliovalent substitution mechanism and crystal structure of Eu3+:CaMoO4 and Eu3+,Na+:CaMoO4 phosphors using complementary techniques like Raman spectroscopy, EXAFS and SPD. We found that the substitution mechanism was different for both systems, with Ca site vacancies forming in the Eu3+:CaMoO4 phosphors and leading to Ca13xEu2x&xMoO4 compositions, while the Eu3+,Na+:CaMoO4 phosphors formed Ca12xEuxNaxMoO4. SPD showed that the cell volume expansion observed with increasing Eu3+ content is related to the increase of the Mo–O bond distance due to the higher electronegativity of Eu3+ compared with Ca2+. Finally, it was shown that the luminescence properties, i.e. lifetime values and quantum yields (the latter reported here for the first time), do not depend on the presence of monovalent ions in the crystal structure but, exclusively, on the Eu3+ content of the phosphor. The integral and detailed analysis of the materials presented in this paper, ranging from crystal structure to luminescent properties including elemental composition, allows a full picture of the structure–property relationships that had never been addressed before for CaMoO4-based phopshors

Published

2018

5. Revealing the substitution mechanism in Eu3+:CaMoO4 and Eu3+,Na+:CaMoO4 phosphors.

Author

Becerro, Ana Isabel, Allix, Mathieu, Laguna, Mariano, González-Mancebo, Daniel, Genevois, Cecile, Caballero, Alfonso, Lozano, Gabriel, Náñez, Nuria O., and Ocaña, Manuel

Abstract

Eu3+-Doped calcium molybdate is an excellent phosphor for lighting and display devices due to the very intense pure red emission after UV excitation. It has been reported in the literature that the CaMoO4 unit cell volume expands after Eu3+ doping, in spite of the smaller Eu3+ ionic radius compared with Ca2+. Likewise, several studies found that the emission intensity of the phosphor could be improved by codoping with alkaline ions like Li+, Na+ or K+. None of these studies correlated the apparent volume expansion and luminescence enhancement with the crystal structural details. This paper analyses the aliovalent substitution mechanism and crystal structure of Eu3+:CaMoO4 and Eu3+,Na+:CaMoO4 phosphors using complementary techniques like Raman spectroscopy, EXAFS and SPD. We found that the substitution mechanism was different for both systems, with Ca site vacancies forming in the Eu3+:CaMoO4 phosphors and leading to Ca1−3xEu2x□xMoO4 compositions, while the Eu3+,Na+:CaMoO4 phosphors formed Ca1−2xEuxNaxMoO4. SPD showed that the cell volume expansion observed with increasing Eu3+ content is related to the increase of the Mo–O bond distance due to the higher electronegativity of Eu3+ compared with Ca2+. Finally, it was shown that the luminescence properties, i.e. lifetime values and quantum yields (the latter reported here for the first time), do not depend on the presence of monovalent ions in the crystal structure but, exclusively, on the Eu3+ content of the phosphor. The integral and detailed analysis of the materials presented in this paper, ranging from crystal structure to luminescent properties including elemental composition, allows a full picture of the structure–property relationships that had never been addressed before for CaMoO4-based phopshors. [ABSTRACT FROM AUTHOR]

Published

2018

6. Structural, optical and X-ray attenuation properties of Tb3+:BaxCe1−xF3−x (x = 0.18–0.48) nanospheres synthesized in polyol medium.

Author

González-Mancebo, Daniel, Becerro, Ana Isabel, Genevois, Cécile, Allix, Mathieu, Corral, Ariadna, Parrado-Gallego, Angel, and Ocaña, Manuel

Subjects

*POLYOLS, *TERBIUM, *ETHYLENE glycol

Abstract

Uniform Ba0.18Ce0.82F2.82 nanospheres have been obtained after aging a solution of barium and cerium nitrates and sodium tetrafluoroborate in a mixture of ethylene glycol and water at 120 °C for 20 hours. The diameter of the spheres could be tailored from 65 nm to 80 nm by varying the NaBF4 concentration while maintaining their colloidal stability in aqueous suspension. Increasing the aging temperature led to a phase transformation from hexagonal to cubic symmetry and to a concomitant increase of the Ba/Ce ratio, which reached a value close to the nominal one (50/50) at 240 °C. The same method was successful in obtaining Tb3+-doped nanospheres with homogeneous cation distribution and the same morphological features as the undoped material. An intense green emission was observed after the excitation of the Tb3+-doped samples through the Ce3+–Tb3+ energy transfer (ET) band. The ET efficiency increased with increasing Tb content, the maximum emission being observed for the 10% Tb-doped nanospheres. Aqueous suspensions of the latter sample showed excellent X-ray attenuation values that were superior to those of an iodine-based clinically approved contrast agent. Their fluorescence and X-ray attenuation properties make this material a potential dual bioprobe for luminescence bioimaging and X-ray computed tomography. [ABSTRACT FROM AUTHOR]

Published

2018

7. Crystal structure, NIR luminescence and X-ray computed tomography of Nd3+:Ba0.3Lu0.7F2.7 nanospheres.

Author

González-Mancebo, Daniel, Becerro, Ana Isabel, Cantelar, Eugenio, Cussó, Fernando, Briat, Arnaud, Boyer, Damien, and Ocaña, Manuel

Subjects

*CRYSTAL structure, *LUMINESCENCE, *TOMOGRAPHY

Abstract

Uniform, hydrophilic 50 nm diameter Nd3+-doped Ba0.3Lu0.7F2.7 nanospheres are synthesized at 120 °C using a singular one-pot method based on the use of ethylene glycol as solvent, in the absence of any additive. The composition and crystal structure of the undoped material are analyzed in detail using ICP and XRD, which reveals a BaF2 cubic crystal structure that is able to incorporate 70 mol% of Lu ions. This finding contrasts with the reported phase diagram of the system, where the maximum solubility is around 30 mol% Lu. XRD proves as well that the Ba0.3Lu0.7F2.7 structure is able to incorporate Nd3+ ions up to, at least 10 mol%, without altering the uniform particles morphology. The Nd-doped particles exhibit near-infrared luminescence when excited at 810 nm. The maximum emission intensity with the minimum concentration quenching effect is obtained at 1.5% Nd doping level. X-ray computed tomography experiments are carried out on powder samples of the latter composition. The sample significantly absorbs X-ray photons, thus demonstrating that the Nd3+-doped Ba0.3Lu0.7F2.7 nanospheres are good candidates as contrast agents in computed tomography. [ABSTRACT FROM AUTHOR]

Published

2017

8. Structural, optical and X-ray attenuation properties of Tb 3+ :Ba x Ce 1-x F 3-x (x = 0.18-0.48) nanospheres synthesized in polyol medium.

Author

González-Mancebo D, Becerro AI, Genevois C, Allix M, Corral A, Parrado-Gallego A, and Ocaña M

Abstract

Uniform Ba0.18Ce0.82F2.82 nanospheres have been obtained after aging a solution of barium and cerium nitrates and sodium tetrafluoroborate in a mixture of ethylene glycol and water at 120 °C for 20 hours. The diameter of the spheres could be tailored from 65 nm to 80 nm by varying the NaBF4 concentration while maintaining their colloidal stability in aqueous suspension. Increasing the aging temperature led to a phase transformation from hexagonal to cubic symmetry and to a concomitant increase of the Ba/Ce ratio, which reached a value close to the nominal one (50/50) at 240 °C. The same method was successful in obtaining Tb3+-doped nanospheres with homogeneous cation distribution and the same morphological features as the undoped material. An intense green emission was observed after the excitation of the Tb3+-doped samples through the Ce3+-Tb3+ energy transfer (ET) band. The ET efficiency increased with increasing Tb content, the maximum emission being observed for the 10% Tb-doped nanospheres. Aqueous suspensions of the latter sample showed excellent X-ray attenuation values that were superior to those of an iodine-based clinically approved contrast agent. Their fluorescence and X-ray attenuation properties make this material a potential dual bioprobe for luminescence bioimaging and X-ray computed tomography.

Published

2018

9. Crystal structure, NIR luminescence and X-ray computed tomography of Nd 3+ :Ba 0.3 Lu 0.7 F 2.7 nanospheres.

Author

González-Mancebo D, Becerro AI, Cantelar E, Cussó F, Briat A, Boyer D, and Ocaña M

Abstract

Uniform, hydrophilic 50 nm diameter Nd 3+ -doped Ba 0.3 Lu 0.7 F 2.7 nanospheres are synthesized at 120 °C using a singular one-pot method based on the use of ethylene glycol as solvent, in the absence of any additive. The composition and crystal structure of the undoped material are analyzed in detail using ICP and XRD, which reveals a BaF 2 cubic crystal structure that is able to incorporate 70 mol% of Lu ions. This finding contrasts with the reported phase diagram of the system, where the maximum solubility is around 30 mol% Lu. XRD proves as well that the Ba 0.3 Lu 0.7 F 2.7 structure is able to incorporate Nd 3+ ions up to, at least 10 mol%, without altering the uniform particles morphology. The Nd-doped particles exhibit near-infrared luminescence when excited at 810 nm. The maximum emission intensity with the minimum concentration quenching effect is obtained at 1.5% Nd doping level. X-ray computed tomography experiments are carried out on powder samples of the latter composition. The sample significantly absorbs X-ray photons, thus demonstrating that the Nd 3+ -doped Ba 0.3 Lu 0.7 F 2.7 nanospheres are good candidates as contrast agents in computed tomography.

Published

2017