Scientific Reports (Dec 2023)

In silico investigation on sensing of tyramine by boron and silicon doped C60 fullerenes

  • S. Pattanaik,
  • A. K. Vishwkarma,
  • T. Yadav,
  • E. Shakerzadeh,
  • D. Sahu,
  • S. Chakroborty,
  • P. K. Tripathi,
  • E. A. Zereffa,
  • J. Malviya,
  • A. Barik,
  • S. K. Sarankar,
  • P. Sharma,
  • V. J. Upadhye,
  • S. Wagadre

DOI
https://doi.org/10.1038/s41598-023-49414-5
Journal volume & issue
Vol. 13, no. 1
pp. 1 – 9

Abstract

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Abstract The present communication deals with the adsorption of tyramine neurotransmitter over the surface of pristine, Boron (B) and Silicon (Si) doped fullerenes. Density functional theory (DFT) calculations have been used to investigate tyramine adsorption on the surface of fullerenes in terms of stability, shape, work function, electronic characteristics, and density of state spectra. The most favourable adsorption configurations for tyramine have been computed to have adsorption energies of − 1.486, − 30.889, and − 31.166 kcal/mol, respectively whereas for the rest three configurations, it has been computed to be − 0.991, − 6.999, and − 8.796 kcal/mol, respectively. The band gaps for all six configurations are computed to be 2.68, 2.67, 2.06, 2.17, 2.07, and 2.14 eV, respectively. The band gap of pristine, B and Si doped fullerenes shows changes in their band gaps after adsorption of tyramine neurotransmitters. However, the change in band gaps reveals more in B doped fullerene rather than pristine and Si doped fullerenes. The change in band gaps of B and Si doped fullerenes leads a change in the electrical conductivity which helps to detect tyramine. Furthermore, natural bond orbital (NBO) computations demonstrated a net charge transfer of 0.006, 0.394, and 0.257e from tynamine to pristine, B and Si doped fullerenes.