HIGHLY POROUS HYBRID COMPOSITE HYDROGELS BASED ON CELLULOSE AND 1,10-PHENANTHROCYANINE OF Zn(II): SYNTHESIS AND CHARACTERIZATION WITH WAXS, FTIR, 13C CP/MAS NMR AND SEM

Михаилиди, А. М.; Saprykina, Natalia; Мокеев, М. В.; Zinchenko, A. V.; Kotelnikova, N. E.

doi:10.35812/cellulosechemtechnol.2020.54.85

Cited by 4 publications

(25 citation statements)

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“…A higher concentration of trisodium citrate facilitated the rapid stabilization of smaller-sized Au nanoparticles, while a lower concentration led to larger Au nanoparticles due to aggregation. Silver nanoparticle sizes ranged from 20 to 260 nm (Figure 2e), showing a more uniform size distribution for gold nanoparticles compared to silver nanoparticles [46]. It was demonstrated that cellulose hydrogels that contained from 0.30 to 5.66 wt.% of Ag or Au nanoparticles revealed antimicrobial activity against Gram-positive (Staphylococcus aureus) and Gram-negative (Escherichia coli) bacteria (Figure 2c) [24,46,47].…”

Section: Medical Applicationmentioning

confidence: 97%

Cellulose-Based Metallogels—Part 3: Multifunctional Materials

Mikhailidi,

Ungureanu,

Belosinschi

et al. 2023

Gels

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The incorporation of the metal phase into cellulose hydrogels, resulting in the formation of metallogels, greatly expands their application potential by introducing new functionalities and improving their performance in various fields. The unique antiviral, antibacterial, antifungal, and anticancer properties of metal and metal oxide nanoparticles (Ag, Au, Cu, CuxOy, ZnO, Al2O3, TiO2, etc.), coupled with the biocompatibility of cellulose, allow the development of composite hydrogels with multifunctional therapeutic potential. These materials can serve as efficient carriers for controlled drug delivery, targeting specific cells or pathogens, as well as for the design of artificial tissues or wound and burn dressings. Cellulose-based metallogels can be used in the food packaging industry to provide biodegradable and biocidal materials to extend the shelf life of the goods. Metal and bimetallic nanoparticles (Au, Cu, Ni, AuAg, and AuPt) can catalyze chemical reactions, enabling composite cellulose hydrogels to be used as efficient catalysts in organic synthesis. In addition, metal-loaded hydrogels (with ZnO, TiO2, Ag, and Fe3O4 nanoparticles) can exhibit enhanced adsorption capacities for pollutants, such as dyes, heavy metal ions, and pharmaceuticals, making them valuable materials for water purification and environmental remediation. Magnetic properties imparted to metallogels by iron oxides (Fe2O3 and Fe3O4) simplify the wastewater treatment process, making it more cost-effective and environmentally friendly. The conductivity of metallogels due to Ag, TiO2, ZnO, and Al2O3 is useful for the design of various sensors. The integration of metal nanoparticles also allows the development of responsive materials, where changes in metal properties can be exploited for stimuli-responsive applications, such as controlled release systems. Overall, the introduction of metal phases augments the functionality of cellulose hydrogels, expanding their versatility for diverse applications across a broad spectrum of industries not envisaged during the initial research stages.

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Section: Medical Applicationmentioning

confidence: 97%

Cellulose-Based Metallogels—Part 3: Multifunctional Materials

Mikhailidi,

Ungureanu,

Belosinschi

et al. 2023

Gels

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“…The proportion of hydrogel volume occupied by the pores (porosity) is calculated according to the following equation: P t = 1 − m 0 · P −1 · L −1 · ρ − 1 , where m 0 is the weight of the dried hydrogel, g, P is a square of the surface of the hydrogel, cm 2 , L is the thickness of the hydrogel, cm, and ρ is the density of cellulose ( ρ = 1.561 g∙cm −3 ) [ 71 ].…”

Section: Physical Propertiesmentioning

confidence: 99%

“…Introduction of a metal phase into the hydrogel decreases the average pore size; for instance, after the formation of the metallogel with Zn(II) organic complex, the porosity of the composite hydrogels fell to 95.8% and 94.8% compared with those of the flax and deciduous hydrogels listed in Table 1 , row 3 [ 71 ]. It was also mentioned in the same study that the surface of the hydrogels was loose, and the inner structure of the hydrogels was composed of randomly distributed pores that formed a cellular honeycomb-like structure.…”

Section: Physical Propertiesmentioning

confidence: 99%

“…It was also mentioned in the same study that the surface of the hydrogels was loose, and the inner structure of the hydrogels was composed of randomly distributed pores that formed a cellular honeycomb-like structure. As a result, the metallogels retained great amounts of water [ 71 ].…”

Section: Physical Propertiesmentioning

confidence: 99%

“…The additional crystallization occurred during the formation of the composite hydrogel with Zn(II) organic-complex [ 71 ]; however, the authors admit the possibility of the change in crystallinity not by the immobilization of 1,10-phencyanine Zn(II) but due to the eventual crystallization of the complex itself in the matrix of the hydrogel. Oppositely, the decrease of the initial cellulosic material’s crystallinity index after introducing Ag particles was reported in [ 61 ].…”

Section: Chemical Propertiesmentioning

confidence: 99%

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Cellulose-Based Metallogels—Part 2: Physico-Chemical Properties and Biological Stability

Mikhailidi,

Volf,

Belosinschi

et al. 2023

Gels

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Metallogels represent a class of composite materials in which a metal can be a part of the gel network as a coordinated ion, act as a cross-linker, or be incorporated as metal nanoparticles in the gel matrix. Cellulose is a natural polymer that has a set of beneficial ecological, economic, and other properties that make it sustainable: wide availability, renewability of raw materials, low-cost, biocompatibility, and biodegradability. That is why metallogels based on cellulose hydrogels and additionally enriched with new properties delivered by metals offer exciting opportunities for advanced biomaterials. Cellulosic metallogels can be either transparent or opaque, which is determined by the nature of the raw materials for the hydrogel and the metal content in the metallogel. They also exhibit a variety of colors depending on the type of metal or its compounds. Due to the introduction of metals, the mechanical strength, thermal stability, and swelling ability of cellulosic materials are improved; however, in certain conditions, metal nanoparticles can deteriorate these characteristics. The embedding of metal into the hydrogel generally does not alter the supramolecular structure of the cellulose matrix, but the crystallinity index changes after decoration with metal particles. Metallogels containing silver (0), gold (0), and Zn(II) reveal antimicrobial and antiviral properties; in some cases, promotion of cell activity and proliferation are reported. The pore system of cellulose-based metallogels allows for a prolonged biocidal effect. Thus, the incorporation of metals into cellulose-based gels introduces unique properties and functionalities of this material.

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Utilization of Pineapple Peel Waste/ZnO Nanoparticles Reinforcement for Cellulose-Based Nanocomposite Membrane and Its Characteristics

Yanuhar,

Suryanto,

Aminnudin

et al. 2024

J Polym Environ

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Bacterial cellulose (BC) is a natural substance produced by microorganisms and offers numerous bene ts. It can be produced by utilizing biomass waste which is abundantly available through the fermentation process. This study investigates the utilization of pineapple peel waste for bacterial cellulose synthesis and observes their properties as nanocomposites membrane after the addition of ZnO nanoparticles (ZnO-NPs). The experimental methods were conducted by synthesizing BC using pineapple peel extract using fermentation process. Subsequently, BNC was synthesized using a high-pressure homogenizer, and ZnO-NPs nanoparticles were added as reinforcement at concentrations of 2.5 wt.%, 5.0 wt.%, and 7.5wt.%. The mixture was sonicated and subsequently dried in an oven at 60°C for 20 h. BNC/ZnO-NPs membranes were characterized using XRD, FTIR, tensile test, BET, antibacterial test, and SEM analysis. The results indicate that the membrane structure of BNC/ZnO-NPs nanocomposite has peaks at diffraction angles of 14.4°, 15.2°, 16.9°, 22.8°, 31.6°, 34.1°, and 36.8°. The addition of ZnO-NPs affects the crystallite size and pore diameter of the membrane. It enhances the crystalline index of BNC by 81.37% at 2.5wt.% ZnO-NPs but reduces the membrane strength. The surface morphology of nanocomposite shows agglomeration with increasing ZnO-NPs content. Membrane BNC/ZnO-NPs show antibacterial activity against S.aureus.

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HIGHLY POROUS HYBRID COMPOSITE HYDROGELS BASED ON CELLULOSE AND 1,10-PHENANTHROCYANINE OF Zn(II): SYNTHESIS AND CHARACTERIZATION WITH WAXS, FTIR, 13C CP/MAS NMR AND SEM

Cited by 4 publications

References 0 publications

Cellulose-Based Metallogels—Part 3: Multifunctional Materials

Cellulose-Based Metallogels—Part 3: Multifunctional Materials

Cellulose-Based Metallogels—Part 2: Physico-Chemical Properties and Biological Stability

Utilization of Pineapple Peel Waste/ZnO Nanoparticles Reinforcement for Cellulose-Based Nanocomposite Membrane and Its Characteristics

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