10.1007/s40097-022-00474-5

Therapeutic potential of C2N as targeted drug delivery system for fluorouracil and nitrosourea to treat cancer: a theoretical study

  • Faiza Ahsan1,
  • Muhammad Yar1,
  • Adnan Gulzar2,
  • Khurshid Ayub*1,
  1. Department of Chemistry, COMSATS University, Abbottabad, KPK, 22060, PK
  2. Biomolecular Dynamics, Institute of Physics, Albert Ludwigs University, Frieburg, 79104, DE

Published in Issue 24-02-2022

How to Cite

Ahsan, F., Yar, M., Gulzar, A., & Ayub, K. (2022). Therapeutic potential of C2N as targeted drug delivery system for fluorouracil and nitrosourea to treat cancer: a theoretical study. Journal of Nanostructure in Chemistry, 13(1 (February 2023). https://doi.org/10.1007/s40097-022-00474-5
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Abstract

Abstract Conventional drug delivery systems suffer from poor absorption and poor bioavailability at the target site due to either very weak or very strong adsorption of drug on the carrier. Porous 2D nanostructures can offer better drug delivery system provided the system chosen has suitable cavity with heteroatoms for reasonable interaction with drug molecules. C 2 N is a surface of choice in this regard; therefore, potential of C 2 N surface as drug delivery system for nitrosourea and fluorouracil (drugs) is explored here. Both nitrosourea and fluorouracil interacted with the electron rich central cavity of C 2 N. Different structural and electronic parameters show that both drugs have good adsorption on C 2 N surface and thus can be carried to the target easily. Values of interaction and basis set superposition error (BSSE) corrected energies are slightly higher for nitrosourea@C 2 N as compared to fluorouracil@C 2 N. While all other properties such as non-covalent interaction (NCI), symmetry-adapted perturbation theory (SAPT0), quantum theory of atoms in molecules (QTAIM), natural bond orbital (NBO), electron density difference (EDD) and frontier molecular orbital (FMO) analyses illustrate that C 2 N is better carrier for nitrosourea than fluorouracil. The off-loading of drug is explored through molecular dynamics simulations which reveal that slightly elevated temperature can cause off-loading of the drug at the target cancer cell, which usually have temperature higher than the normal cells. MD simulations reveal that atomic interactions between the drugs and C 2 N are destabilized at higher temperatures. Comparison of the loading and off-loading mechanism with other surfaces reported in the literature reveal that C 2 N is a better carrier for these drugs. Graphical abstract

Keywords

  • Drug delivery,
  • Antineoplastic drugs,
  • Nitrosourea,
  • Fluorouracil,
  • Carbon nitride nanosheet (C2N)

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