387
Volume 5, Issue 10: Special Issue
(EJAR)
ISSN: 2181-2020
MPHAPP
THE 6TH INTERNATIONAL SCIENTIFIC AND PRACTICAL
CONFERENCE
“
MODERN PHARMACEUTICS: ACTUAL
PROBLEMS AND PROSPECTS
”
TASHKENT, OCTOBER 17, 2025
in-academy.uz
MULTISCALE THEORETICAL INVESTIGATION OF HEAVY METAL AND
ORGANIC POLLUTANT SORPTION ON FUNCTIONALIZED CELLULOSE
DERIVATIVES
Nurgaliev I.N.
1
Marasulov M.B.
1
Abilkasimov A.B.
2
1
Institute of polymer chemistry and physics, Tashkent, Uzbekistan
2
Kimyo International University, Tashkent, Uzbekistan
e-mail: ilnarvodnik@gmail.com, polymer@academy.uz,
phone: (71)-241-85-94, (91)-136-40-04
https://doi.org/10.5281/zenodo.17339326
Relevance:
Water contamination by heavy metals (Pb²⁺, Cd²⁺, Ni²⁺), metalloid ions (As(III),
As(V), Cr(VI)), and persistent organic pollutants (phenolic derivatives, pharmaceutical residues,
dyes) remains a major environmental concern worldwide. Conventional water treatment methods are
often insufficient to achieve both high efficiency and selectivity. In this context, biopolymeric
sorbents based on modified cellulose offer significant advantages due to their biocompatibility,
availability, and ease of functionalization. Dialdehyde cellulose grafted with thiosemicarbazide
(DAC@TCH) and its thiol-functionalized derivative (DAC@TCH–SH) are particularly promising
candidates for the selective binding of toxic metal ions and organic pollutants.
Objective:
The present study aims to provide a comprehensive theoretical investigation of the
sorption properties of DAC@TCH and DAC@TCH–SH toward heavy metals, oxyanions of arsenic
and chromium, and representative organic pollutants using density functional theory (DFT), quantum
theory of atoms in molecules (QTAIM), molecular orbital analysis, and molecular docking.
Materials and Methods:
All structures were optimized, and binding energies were calculated
at the ωB97X-D/def2-TZVP level with the SMD solvation model for water. Counterpoise corrections
were applied to account for basis set superposition error (BSSE), and thermodynamic corrections
(ΔG298) were included. Donor–acceptor interactions were examined by Natural Bond Orbital (NBO)
analysis. The spatial distribution of the electron density and bond critical points were analyzed via
QTAIM. Electronic properties, including HOMO–LUMO gaps and projected density of states
(PDOS), were employed to discuss the nature of the interactions. Molecular docking was performed
to evaluate the antimicrobial potential of the sorbent–pollutant complexes against bacterial proteins
of Escherichia coli and Staphylococcus aureus.
Results:
DFT calculations revealed that Pb²⁺ and Cd²⁺ exhibit the strongest interactions with
DAC@TCH–SH, with significantly enhanced binding due to S-donor coordination. Nitrogen and
oxygen donors provided weaker stabilization, consistent with HSAB principles. For oxyanions As(V)
and Cr(VI), sorption was dominated by hydrogen-bonding networks involving NH and OH groups,
with little effect of thiol modification. Organic pollutants displayed variable behavior: tetracycline
and methylene blue showed strong binding through a combination of hydrogen bonding, π–π
stacking, and electrostatics, while bisphenol A and 4-nitrophenol bound moderately. QTAIM
confirmed partial covalency in Pb–S bonds (ρ(r) ≈ 0.08 a.u.) and closed-shell characteristics of
hydrogen-bond interactions with oxyanions. Molecular docking suggested that sorbent–pollutant
complexes could interact with bacterial proteins, highlighting a potential antimicrobial synergy.
Conclusions:
This study demonstrates that thiol functionalization markedly enhances the
sorption performance of cellulose-based adsorbents toward soft heavy metals (Pb²⁺, Cd²⁺), while
maintaining high activity against oxyanions and organic pollutants. DAC@TCH–SH exhibits dual
388
Volume 5, Issue 10: Special Issue
(EJAR)
ISSN: 2181-2020
MPHAPP
THE 6TH INTERNATIONAL SCIENTIFIC AND PRACTICAL
CONFERENCE
“
MODERN PHARMACEUTICS: ACTUAL
PROBLEMS AND PROSPECTS
”
TASHKENT, OCTOBER 17, 2025
in-academy.uz
functionality, serving both as an effective sorbent and as a potential antimicrobial agent. The obtained
results provide theoretical guidance for the rational design of multifunctional biopolymer-based
materials for water purification and environmental protection.
