Abstract
The rapid development of upconversion nanoparticles (UCNPs) has been facing with a great challenge: intense emission, fast scanning, and deep imaging require high-power light irradiation with minimized heating effect (the intrinsic 975-nm excitation of Yb(3+)-sensitized UCNPs have overheating problem). By shifting the excitation peak from 975 nm to 795 nm, Nd(3+)-Yb(3+) cascade sensitized upconversion nanoparticles (Nd-UCNPs) with minimized heating effect were reported as the new generation UCNPs. For the first time, within two optically modeled applications in vitro and in vivo, the damage outcomes under long time high power laser excitation were solidly calculated, complementing the damage-free study of Nd-UCNPs. The higher resolution (20% improvement) and five times faster scanning microscopy were successfully performed using Nd-UCNPs under safety laser power level. The computational results showed the Nd(3+)-Yb(3+) energy transfer efficiency would not compromise the deep imaging ability, and the red (650-nm) emission is worth to be enhanced for deep tissue imaging.
Highlights
Lanthanide-doped upconversion nanoparticles (UCNPs) can absorb multiple near infrared photons via intermediate energy states and convert into one short wavelength photon [1, 2]
The 100% surviving cells and tissue after long-term 795-nm-irradiation have clearly proved that Nd-UCNPs enabled the damage-free imaging in vitro and in vivo with high power laser irradiation
The experimental results exhibited that high safety power excited Nd-UCNPs enable five times faster scanning microscopy in damage-free microscopy imaging
Summary
Lanthanide-doped upconversion nanoparticles (UCNPs) can absorb multiple near infrared photons via intermediate energy states and convert into one short wavelength photon [1, 2]. #227211 - $15.00 USD Received 4 Dec 2014; revised 27 Jan 2015; accepted 6 Feb 2015; published 18 Feb 2015 light irradiation [3,4,5]. Due to these advantages, UCNPs have been widely employed in bioimaging, diffusion optical tomography, bio-sensing and photodynamic therapy [6,7,8,9,10]. One way to suppress the heating effect is decreasing the excitation power by enhancing the quantum yield (QY). Various chemical optimizations were reported [14, 15], and recently the significant enhancement by a factor of 70 was achieved by high excitation irradiance combined with high activator concentration [16]
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