Abstract
Nanodiamonds have been studied for several biomedical applications due to their inherent biocompatibility and low cytotoxicity. Recent investigations have shown perspectives in using fluorescent nanodiamonds as nanothermometers because of their optical properties’ dependence on temperature. Easy and accurate localized temperature sensing is essential in a wide variety of scientific fields. Our work demonstrated how the fluorescence spectrum of high-pressure high-temperature fluorescent nanodiamonds of three different sizes: 35 nm, 70 nm and 100 nm, changes with temperature within an important biological temperature range (25 °C to 60 °C). Taking advantage of this phenomenon, we obtained nanothermic scales (NS) from the zero phonon lines (ZPL) of the NV0 and NV− colour centres. In particular, the 100 nm-sized features the more intense fluorescence spectra whose linear dependence with temperature achieved 0.98 R2 data representation values for both NV0 and NV−. This model predicts temperature for all used nanodiamonds with sensitivities ranging from 5.73% °C−1 to 6.994% °C−1 (NV0) and from 4.14% °C−1 to 6.475% °C−1 (NV−). Furthermore, the non-cytotoxic interaction with HeLa cells tested in our study enables the potential use of fluorescence nanodiamonds to measure temperatures in similar nano and microcellular aqueous environments with a simple spectroscopic setup.
Highlights
A large number of nanoparticles are currently being considered for biomedical applications, such as imaging, diagnostics and drug delivery
The overall fluorescence intensity of the fluorescent nanodiamonds used for this work decreases as temperature rises within the range of biologically relevant temperatures (25 ◦ C to 60 ◦ C)
We demonstrated how this fluorescence intensity mostly follows a linear dependence with the local nanodiamond temperature
Summary
A large number of nanoparticles are currently being considered for biomedical applications, such as imaging, diagnostics and drug delivery. Nanodiamonds receive special attention within the range of nanocarbon materials due to their outstanding physical and chemical features [5,6] This versatile material exhibits low cytotoxicity at the cellular level [7,8] and is considered the most biocompatible of all carbon-containing derivatives [9,10]. Further studies show that under the typical 532 nm excitation wavelength, the probabilities of finding the NV centre in the NV− and NV0 configurations are 70% and 30%, respectively [28,30] These optical properties make fluorescent nanodiamonds a suitable probe for bioimaging and thermic sensing applications in cellular environments [31,32]. Sci. 2021, 11, 4065 bioimage of HeLa cells at RT was obtained, opening a new perspective of using FNDs as nanothermometers in living cellular environments for thermal imaging and diagnosis aid
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