Nanochitin and Nanochitosan: Chitin Nanostructure Engineering with Multiscale Properties for Biomedical and Environmental Applications

Lee, Changhon; Hào, Lâm Tấn; Park, Jeyoung; Oh, Dongyeop X.; Hwang, Dong Soo

doi:10.1002/adma.202203325

Cited by 63 publications

(26 citation statements)

References 335 publications

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“…In the transition from fossil-based resources to renewables, biobased nanomaterials are pursued as one of the most promising alternatives to address these challenges. Cellulose nanomaterials (CNMs) are by far the most researched plant-based nanomaterial, − followed by lignin nanoparticles (LNPs). , Other renewable nanomaterials include chitin and chitosan, − starch, , and hemicelluloses, − but these have, to date, attracted less attention. Biobased nanomaterials combine the possibilities of nanotechnology with the typical advantages of renewables, like abundance, biodegradability, recyclability, biocompatibility, and low production costs.…”

Section: Introductionmentioning

confidence: 99%

Biobased Nanomaterials─The Role of Interfacial Interactions for Advanced Materials

et al. 2023

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This review presents recent advances regarding biomass-based nanomaterials, focusing on their surface interactions. Plant biomass-based nanoparticles, like nanocellulose and lignin from industry side streams, hold great potential for the development of lightweight, functional, biodegradable, or recyclable material solutions for a sustainable circular bioeconomy. However, to obtain optimal properties of the nanoparticles and materials made thereof, it is crucial to control the interactions both during particle production and in applications. Herein we focus on the current understanding of these interactions. Solvent interactions during particle formation and production, as well as interactions with water, polymers, cells and other components in applications, are addressed. We concentrate on cellulose and lignin nanomaterials and their combination. We demonstrate how the surface chemistry of the nanomaterials affects these interactions and how excellent performance is only achieved when the interactions are controlled. We furthermore introduce suitable methods for probing interactions with nanomaterials, describe their advantages and challenges, and introduce some less commonly used methods and discuss their possible applications to gain a deeper understanding of the interfacial chemistry of biobased nanomaterials. Finally, some gaps in current understanding and interesting emerging research lines are identified.

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Section: Introductionmentioning

confidence: 99%

Biobased Nanomaterials─The Role of Interfacial Interactions for Advanced Materials

et al. 2023

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“…Following cellulose, chitin is the second most abundant naturally occurring polymer on earth. Owing to the biodegradability and high tensile strength, chitin derivatives have been found in diverse applications, such as tissue engineering, drug carriers, cosmetics, wound dressing, and recently pickering emulsion. − However, to make functional materials from chitin, a challenge is to find effective and environmentally friendly ways to dissolve it in solution, , and once dissolved, another challenge is to achieve controlled fabrication. , Thus, a detailed understanding of chitin’s self-assembly mechanism is important.…”

Section: Introductionmentioning

confidence: 99%

“…Chitin is a homopolymer composed of β-(1–4)-linked N -acetylglucosamine units. Native chitin is a semicrystalline fibril material consisting of crystalline (microfibers) and amorphous regions, where the crystal is composed of a 2–5 nm thick fibril made up of 18–25 chains . Chitin’s crystalline structures have been studied by numerous groups using electron microscopy and X-ray diffraction for over 50 years, which revealed three (α, β, and γ) polymorphic forms depending on the natural sources (Figure a,b). − The most abundant allomorph is α-chitin, which contains antiparallel chains in the crystalline structure and can be found in hard shells of various crustaceans and cell walls of select fungi (Figure a).…”

Section: Introductionmentioning

confidence: 99%

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Mechanism of the Temperature-Dependent Self-Assembly and Polymorphism of Chitin

Romany,

Payne,

Shen

2023

Chem. Mater.

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Chitin is the second most abundant natural biopolymer. Its crystalline structures have been extensively studied. However, the mechanism of chitin’s self-assembly is unknown. Here, we applied all-atom molecular dynamics to study chitin’s self-assembly process at different temperatures. Strikingly, at 278 K, an amorphous aggregate was formed, whereas at 300 K single-sheet and at 323 K both single-sheet and multisheet nanofibril regions were formed. The nanofibrils contain antiparallel, parallel, or mixed orientation chains, with antiparallel being slightly preferred, recapitulating chitin’s polymorphism observed in nature. The inverse temperature dependence is consistent with a recent experiment conducted in the aqueous KOH/urea solution. The analysis suggested that the multisheet nanofibrils are assembled by stacking the single nanofibril sheets, which are formed through two types of pathways in which hydrophobic collapse either precedes or is concomitant with the increasing number of interchain hydrogen bonds and solvent expulsion. Furthermore, the antiparallel and parallel chains are mediated by different interchain hydrogen bonds. The analysis also suggested that the inverse temperature dependence may be attributed to the hydrophobic effect reminiscent of the low critical solution temperature phase behavior. The present study provides a rich, atomic-level view of chitin’s polymorphic self-assembly process, paving the way for the rational design of chitin-derived novel materials.

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“…Nevertheless, compared with various renewable resources, chitin has the characteristics of abundant reserves, biodegradability, film-forming properties, nontoxicity, biocompatibility, and biochemical availability. Therefore, chitin is very attractive as a raw material for the preparation of bioplastics. − …”

Section: Introductionmentioning

confidence: 99%

Sustainable, High-Performance, and Biodegradable Plastics Made from Chitin

Zhou

Lin

et al. 2022

ACS Appl. Mater. Interfaces

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A high-performance biodegradable plastic was made from a chitin KOH/urea solution. The solution was transferred into a hydrogel by cross-linking using epichlorohydrin and ethanol immersion, and a chitin bioplastic was finally prepared by drying in a mold at 40 °C. The solution concentration positively impacts viscosity, crystallinity, and smoothness. A 4% chitin bioplastic exhibits high barrier properties, flame retardancy, high-temperature resistance, mechanical properties (tensile strength up to 107.1 MPa), and soil degradation properties. The chitin bioplastic can be completely degraded by microorganisms in 7 weeks. In addition, biosafety tests suggest that chitin is safe for cells and crops (wheat and mung beans). The chitin bioplastic was further applied to containers, straws, cups, and photoprotection, and it was found that the water resistance and transparency were comparable to those of commercial polypropylene plastics. Due to the excellent performance, safety, and sustainability of the chitin bioplastic, it is expected to become a good substitute for conventional fossil fuel-based plastics.

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Nanochitin and Nanochitosan: Chitin Nanostructure Engineering with Multiscale Properties for Biomedical and Environmental Applications

Cited by 63 publications

References 335 publications

Biobased Nanomaterials─The Role of Interfacial Interactions for Advanced Materials

Biobased Nanomaterials─The Role of Interfacial Interactions for Advanced Materials

Mechanism of the Temperature-Dependent Self-Assembly and Polymorphism of Chitin

Sustainable, High-Performance, and Biodegradable Plastics Made from Chitin

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