Although nanotechnology has led to important advances in in vitro diagnostics, the development of nanosensors for in vivo molecular detection remains very challenging. Here, we demonstrated the proof‐of‐principle of in vivo detection of nucleic acid targets using a promising type of surface‐enhanced Raman scattering (SERS) nanosensor implanted in the skin of a large animal model (pig). The in vivo “smart tattoo” nanosensor used in this study employs the “inverse molecular sentinel” (iMS) detection scheme, which is a label-free homogeneous biosensing system based on a non-enzymatic DNA strand-displacement process and conformational change of stem-loop (hairpin) oligonucleotide probes upon target binding. In this study, plasmonics‐active nanostar was utilized as an efficient in vivo SERS sensing platform due to their tunable absorption bands in the near infrared region of the “tissue optical window. The results of this study illustrate the usefulness of SERS iMS nanosensors as an implantable skin‐based in vivo biosensing platform, providing a foundation for developments in continuous health status sensing, disease biomarker monitoring, and other clinical translation applications.
Surface-enhanced Raman scattering (SERS) spectroscopy can be a useful tool in regard to disease diagnosis and prevention. Advantage of SERS over conventional Raman spectroscopy is its significantly increased signal (up to factor of 106-108) which allows detection of trace amounts of substances in the sample. So far, this technique is successfully used for analysis of food, pieces of art and various biochemical/biomedical samples. In this work, we survey the possibility of applying SERS spectroscopy for detection of trace components in urinary deposits. Early discovery together with the identification of the exact chemical composition of urinary sediments could be crucial for taking appropriate preventive measures that inhibit kidney stone formation or growth processes. In this initial study, SERS spectra (excitation wavelength - 1064 nm) of main components of urinary deposits (calcium oxalate, uric acid, cystine, etc.) were recorded by using silver (Ag) colloid. Spectra of 10-3-10-5 M solutions were obtained. While no/small Raman signal was detected without the Ag colloid, characteristic peaks of the substances could be clearly separated in the SERS spectra. This suggests that even small amounts of the components could be detected and taken into account while determining the type of kidney stone forming in the urinary system. We found for the first time that trace amounts of components constituting urinary deposits could be detected by SERS spectroscopy. In the future study, the analysis of centrifuged urine samples will be carried out.
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