Visible and NIR upconverting Er3+-Yb3+ luminescent nanorattles and other hybrid PMO‐inorganic structures for in vivo nanothermometry
- Author
- Anna Kaczmarek (UGent) , Markus Suta, Hannes Rijckaert (UGent) , Anatolii Abalymov, Isabel Van Driessche (UGent) , Andre Skirtach (UGent) , Andries Meijerink and Pascal Van Der Voort (UGent)
- Organization
- Abstract
- Lanthanide-doped luminescent nanoparticles are an appealing system for nanothermometry with biomedical applications due to their sensitivity, reliability, and minimal invasive thermal sensing properties. Here, four unique hybrid organic-inorganic materials prepared by combining beta-NaGdF4 and PMOs (periodic mesoporous organosilica) or mSiO(2) (mesoporous silica) are proposed. PMO/mSiO(2) materials are excellent candidates for biological/biomedical applications as they show high biocompatibility with the human body. On the other hand, the beta-NaGdF4 matrix is an excellent host for doping lanthanide ions, even at very low concentrations with yet very efficient luminescence properties. A new type of Er3+-Yb3+ upconversion luminescence nanothermometers operating both in the visible and near infrared regime is proposed. Both spectral ranges permit promising thermometry performance even in aqueous environment. It is additionally confirmed that these hybrid materials are non-toxic to cells, which makes them very promising candidates for real biomedical thermometry applications. In several of these materials, the presence of additional voids leaves space for future theranostic or combined thermometry and drug delivery applications in the hybrid nanostructures.
- Keywords
- Electrochemistry, Electronic, Optical and Magnetic Materials, General Chemical Engineering, Condensed Matter Physics, Biomaterials, hybrid materials, lanthanide luminescence, periodic mesoporous organosilicas, physiological sensing, ratiometric thermometers, ORGANIC FRAMEWORK, LANTHANIDE, NANOPARTICLES, THERMOMETERS, NONCONTACT, DESIGN
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Citation
Please use this url to cite or link to this publication: http://hdl.handle.net/1854/LU-8664896
- MLA
- Kaczmarek, Anna, et al. “Visible and NIR Upconverting Er3+-Yb3+ Luminescent Nanorattles and Other Hybrid PMO‐inorganic Structures for in Vivo Nanothermometry.” ADVANCED FUNCTIONAL MATERIALS, vol. 30, no. 32, 2020, doi:10.1002/adfm.202003101.
- APA
- Kaczmarek, A., Suta, M., Rijckaert, H., Abalymov, A., Van Driessche, I., Skirtach, A., … Van Der Voort, P. (2020). Visible and NIR upconverting Er3+-Yb3+ luminescent nanorattles and other hybrid PMO‐inorganic structures for in vivo nanothermometry. ADVANCED FUNCTIONAL MATERIALS, 30(32). https://doi.org/10.1002/adfm.202003101
- Chicago author-date
- Kaczmarek, Anna, Markus Suta, Hannes Rijckaert, Anatolii Abalymov, Isabel Van Driessche, Andre Skirtach, Andries Meijerink, and Pascal Van Der Voort. 2020. “Visible and NIR Upconverting Er3+-Yb3+ Luminescent Nanorattles and Other Hybrid PMO‐inorganic Structures for in Vivo Nanothermometry.” ADVANCED FUNCTIONAL MATERIALS 30 (32). https://doi.org/10.1002/adfm.202003101.
- Chicago author-date (all authors)
- Kaczmarek, Anna, Markus Suta, Hannes Rijckaert, Anatolii Abalymov, Isabel Van Driessche, Andre Skirtach, Andries Meijerink, and Pascal Van Der Voort. 2020. “Visible and NIR Upconverting Er3+-Yb3+ Luminescent Nanorattles and Other Hybrid PMO‐inorganic Structures for in Vivo Nanothermometry.” ADVANCED FUNCTIONAL MATERIALS 30 (32). doi:10.1002/adfm.202003101.
- Vancouver
- 1.Kaczmarek A, Suta M, Rijckaert H, Abalymov A, Van Driessche I, Skirtach A, et al. Visible and NIR upconverting Er3+-Yb3+ luminescent nanorattles and other hybrid PMO‐inorganic structures for in vivo nanothermometry. ADVANCED FUNCTIONAL MATERIALS. 2020;30(32).
- IEEE
- [1]A. Kaczmarek et al., “Visible and NIR upconverting Er3+-Yb3+ luminescent nanorattles and other hybrid PMO‐inorganic structures for in vivo nanothermometry,” ADVANCED FUNCTIONAL MATERIALS, vol. 30, no. 32, 2020.
@article{8664896, abstract = {{Lanthanide-doped luminescent nanoparticles are an appealing system for nanothermometry with biomedical applications due to their sensitivity, reliability, and minimal invasive thermal sensing properties. Here, four unique hybrid organic-inorganic materials prepared by combining beta-NaGdF4 and PMOs (periodic mesoporous organosilica) or mSiO(2) (mesoporous silica) are proposed. PMO/mSiO(2) materials are excellent candidates for biological/biomedical applications as they show high biocompatibility with the human body. On the other hand, the beta-NaGdF4 matrix is an excellent host for doping lanthanide ions, even at very low concentrations with yet very efficient luminescence properties. A new type of Er3+-Yb3+ upconversion luminescence nanothermometers operating both in the visible and near infrared regime is proposed. Both spectral ranges permit promising thermometry performance even in aqueous environment. It is additionally confirmed that these hybrid materials are non-toxic to cells, which makes them very promising candidates for real biomedical thermometry applications. In several of these materials, the presence of additional voids leaves space for future theranostic or combined thermometry and drug delivery applications in the hybrid nanostructures.}}, articleno = {{2003101}}, author = {{Kaczmarek, Anna and Suta, Markus and Rijckaert, Hannes and Abalymov, Anatolii and Van Driessche, Isabel and Skirtach, Andre and Meijerink, Andries and Van Der Voort, Pascal}}, issn = {{1616-301X}}, journal = {{ADVANCED FUNCTIONAL MATERIALS}}, keywords = {{Electrochemistry,Electronic,Optical and Magnetic Materials,General Chemical Engineering,Condensed Matter Physics,Biomaterials,hybrid materials,lanthanide luminescence,periodic mesoporous organosilicas,physiological sensing,ratiometric thermometers,ORGANIC FRAMEWORK,LANTHANIDE,NANOPARTICLES,THERMOMETERS,NONCONTACT,DESIGN}}, language = {{eng}}, number = {{32}}, pages = {{11}}, title = {{Visible and NIR upconverting Er3+-Yb3+ luminescent nanorattles and other hybrid PMO‐inorganic structures for in vivo nanothermometry}}, url = {{http://doi.org/10.1002/adfm.202003101}}, volume = {{30}}, year = {{2020}}, }
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