Abstract
Applications of terahertz time-domain spectroscopy (THz-TDS) in the fields of chemistry and biomedicine have recently received increased attention. Specifically, THz-TDS is particularly effective for the identification of alkaloid molecules, because it can distinguish the vibration types of base molecules in the THz band and provide a direct characteristic spectrum for the configuration and conformation of biomolecules. However, when THz-TDS technology is used to identify alkaloid molecules, most of them are concentrated in the 0.1–3.0 THz band, limiting the amount of information that can be obtained. In this work, a wide-spectrum THz-TDS system was independently built to explore the absorption spectra of uracil and its 5-substituents in the range of 1.3–6.0 THz. We found that, in the THz band, uracil and its 5-substituents have similar absorption peaks near 4.9 and 3.3 THz, while the 5-substituents have an additional absorption peak in the range of 1.5–2.5 THz. This absorption peak is red-shifted as the relative atomic mass of the 5-substituted atoms increases. Gaussian software was adopted to calculate the absorption spectra of the samples. The simulation conclusions were in good agreement with the experimental results, revealing that the vibration of the base molecule at low frequencies can be attributed to the inter-molecular vibration. This work demonstrates that THz-TDS technology can be used to accurately identify biomolecules with similar molecular structures, reflecting the importance of molecular structure in biological activity.
Highlights
The terahertz (THz) band consists of electromagnetic waves located between infrared waves and microwaves on the electromagnetic spectrum
In the molecular structure of biological samples, changes in substituents and differences in relative atomic mass have a large impact on their properties and functions
In order to confirm the conjecture about the experimental results, the Gaussian 09w software package was used to explain the weak interaction of the samples in the THz region [22]
Summary
The terahertz (THz) band consists of electromagnetic waves located between infrared waves and microwaves on the electromagnetic spectrum. The low-frequency resonance absorption of biological macromolecules in the THz range has received more and more attention in recent years. For biological macromolecules (e.g., nucleic acids, proteins, carbohydrates, and lipids), the absorption frequencies corresponding to the inter-/intra-molecular weak interaction forces (e.g., hydrogen bond, Van der Waals force, and so on) and the lattice vibrations are distributed in the THz frequency range [9,10,11,12,13,14]. The unique characteristics of THz technology have been applied in biomedical research [18,19,20,21,22,23,24], and the connection between low-frequency vibration modes and molecular structure makes the spectroscopy of biomolecules quite interesting
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