| Yazarlar |
G. M. Saladino
The Royal Institute of Technology (KTH), Sweden |
|
N. I. Kilic
The Royal Institute of Technology (KTH), Sweden |
|
K. Shaker
The Royal Institute of Technology (KTH), Sweden |
|
Y. Li
The Royal Institute of Technology (KTH), Sweden |
|
B. Hamawandi
The Royal Institute of Technology (KTH), Sweden |
|
C. Vogt
The Royal Institute of Technology (KTH), Sweden |
|
B. Brodin
The Royal Institute of Technology (KTH), Sweden |
|
M. Svenda
The Royal Institute of Technology (KTH), Sweden |
|
I. Yazgan
Kastamonu University, Turkey |
|
H. M. Hertz
The Royal Institute of Technology (KTH), Sweden |
|
M. S. Toprak
The Royal Institute of Technology (KTH), Sweden |
| Özet |
| In recent years, the design and synthesis of bio-compatible coatings leading to hybrid nanoparticles (NPs) as the contrast agents have gained substantial relevance. Furthermore, the addition of several functionalities for bio-imaging applications represents a key step for non-invasive bio-diagnostics. In this context, we design and utilize hybrid nanostructures for X-ray fluorescence computed tomography (XFCT). The combination of a ceramic or metallic core–based on MoO2, Rh or Ru–with a protective shell allows the generation of bio-compatible nanohybrids for dual mode bio-imaging, where the core NPs constitute the X-ray fluorescence (XRF) contrast agents [1]–[3]. Core NPs are synthesized via polyol, hydrothermal or microwave-assisted hydrothermal methods, yielding uniform shape and high dispersibility in aqueous media. Different approaches have been pursued for the fabrication of a bio-compatible shell coating. A modified sol-gel based silica coating process, doped with a commercial fluorophore (Cy5.5), was developed and shown to be applicable to both ceramic and metallic NPs [4], forming core-shell NPs with both optical and X-ray fluorescence properties. Alternatively, carbon quantum dots (CQDs) were synthesized via citrate pyrolysis using microwave-assisted hydrothermal method, exhibiting uniform size distribution (1.6±0.4 nm) and excitation-independent emission (440 nm). Conjugation of these CQDs, via cross-linking, with Rh NPs led to excitation-independent hybrid NPs, with a red-shifted emission wavelength (520 nm), attributed to the reduction of pyrrolic nitrogen on CQDs [5]. These hybrid NPs exhibit improved in vitro biocompatibility in comparison with bare XRF contrast agents. Furthermore, the optical fluorescence–provided by Cy5.5 or CQDs–allows the localization of the NPs in the intracellular environment while the XRF signal from the core NPs is utilized for XFCT, in small animals, leading to both a microscopic and macroscopic bio-imaging contrast agent. |
| Anahtar Kelimeler |
| Bildiri Türü | Tebliğ/Bildiri |
| Bildiri Alt Türü | Tam Metin Olarak Yayımlanan Tebliğ (Uluslararası Kongre/Sempozyum) |
| Bildiri Niteliği | |
| Bildiri Dili | İngilizce |
| Kongre Adı | Proceedings of the International Conference of Theoretical and Applied Nanoscience and Nanotechnology |
| Kongre Tarihi | / |
| Basıldığı Ülke | |
| Basıldığı Şehir |
| Atıf Sayıları |
