α-Cellulose Fibers of Paper-Waste Origin Surface-Modified with Fe3O4 and Thiolated-Chitosan for Efficacious Immobilization of Laccase

Abstract

The utilization of waste-paper-biomass for extraction of important α-cellulose biopolymer, and modification of extracted α-cellulose for application in enzyme immobilization can be extremely vital for green circular bio-economy. Thus, in this study, α-cellulose fibers were super-magnetized (Fe₃O₄), grafted with chitosan (CTNs), and thiol (-SH) modified for laccase immobilization. The developed material was characterized by high-resolution transmission electron microscopy (HR-TEM), HR-TEM energy dispersive X-ray spectroscopy (HR-TEM-EDS), X-ray diffraction (XRD), vibrating sample magnetometer (VSM), X-ray photoelectron spectroscopy (XPS), and Fourier transform infrared spectroscopy (FT-IR) analyses. Laccase immobilized on α-Cellulose-Fe₃O₄-CTNs (α-Cellulose-Fe₃O₄-CTNs-Laccase) gave significant activity recovery (99.16%) and laccase loading potential (169.36 mg/g). The α-Cellulose-Fe₃O₄-CTNs-Laccase displayed excellent stabilities for temperature, pH, and storage time. The α-Cellulose-Fe₃O₄-CTNs-Laccase applied in repeated cycles shown remarkable consistency of activity retention for 10 cycles. After the 10th cycle, α-Cellulose-Fe₃O₄-CTNs possessed 80.65% relative activity. Furthermore, α-Cellulose-Fe₃O₄-CTNs-Laccase shown excellent degradation of pharmaceutical contaminant sulfamethoxazole (SMX). The SMX degradation by α-Cellulose-Fe₃O₄-CTNs-Laccase was found optimum at incubation time (20 h), pH (3), temperatures (30 °C), and shaking conditions (200 rpm). Finally, α-Cellulose-Fe₃O₄-CTNs-Laccase gave repeated degradation of SMX. Thus, this study presents a novel, waste-derived, highly capable, and super-magnetic nanocomposite for enzyme immobilization applications.

Keywords: chitosan; laccase immobilization; super-magnetic; waste-paper-biomass; α-Cellulose.

Figure 1

Schematic presentation of a chemical scheme for laccase immobilization on α-Cellulose-Fe₃O₄-CTNs-SH and its environmental application.

Figure 2

High-resolution transmission electron microscopy (HR-TEM) image of (A) α-Cellulose-Fe₃O₄-CTNs-SH, (B) Zoomed view of the α-Cellulose-Fe₃O₄-CTNs-SH HR-TEM image, (C) high-angle annular dark-field imaging (HAADF) analysis of the α-Cellulose-Fe₃O₄-CTNs-SH, HR-TEM HAADF elemental mapping (D) carbon (C), (E) oxygen (O), (F) nitrogen (N), (G) iron (Fe), and (I) sulfur (S), and (J) HR-TEM EDS profile of the α-Cellulose-Fe₃O₄-CTNs-SH.

Figure 3

XRD analysis of the α-Cellulose-Fe₃O₄-CTNs-SH.

Figure 4

Vibrating sample magnetometer (VSM) analysis of the α-Cellulose-Fe₃O₄-CTNs-SH.

Figure 5

(A) XPS analysis of the α-Cellulose-Fe₃O₄-CTNs-SH-Laccase, and (B) high-resolution Fe 2p XPS spectrum of α-Cellulose-Fe₃O₄-CTNs-SH-Laccase.

Figure 6

FT-IR analysis of the α-Cellulose-Fe₃O₄-CTN-SH and α-Cellulose-Fe₃O₄-CTN-SH-Laccase.

Figure 7

Laccase loading pattern on α-Cellulose-Fe₃O₄-CTNs-SH, and laccase activity recovery by α-Cellulose-Fe₃O₄-CTNs-SH-Laccase.

Figure 8

(A) Temperature stability of free and α-Cellulose-Fe₃O₄-CTNs-SH-Laccase carried out at 60 °C for 180 min time, (B) pH stability study of free and α-Cellulose-Fe₃O₄-CTNs-SH-Laccase carried out at pH 1–9 for 1 h incubation time, (C) storage stability study of free and α-Cellulose-Fe₃O₄-CTNs-SH-Laccase carried out at 4 °C and for 30 days, and (D) reusability study of the α-Cellulose-Fe₃O₄-CTNs-SH-Laccase in 10 cycles.

Figure 9

Effect of time (A), pH (B), temperatures (C), and shaking conditions (D) on SMX degradation by the α-Cellulose-Fe₃O₄-CTNs-SH-Laccase.

Figure 10

The repeated cycle degradation of SMX by α-Cellulose-Fe₃O₄-CTNs-SH-Laccase.