Nanomaterials Derived from Fungal Sources—Is It the New Hype?

Nawawi, Mohd; Jones, Mitchell P.; Murphy, Richard J.; Lee, Koon‐Yang; Kontturi, Eero; Bismarck, Alexander

doi:10.1021/acs.biomac.9b01141

Cited by 73 publications

(54 citation statements)

References 282 publications

(434 reference statements)

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“…Crustacean chitin typically binds with sclerotized proteins and minerals and contains minimal residual protein. Such a difference makes the isolation procedure for fungal chitin nanofibers very simple, requiring just brief mechanical agitation in a kitchen blender after a mild alkaline treatment to remove proteins (Fazli Wan Nawawi et al, 2019;Nawawi et al, 2020). However, the glucan associates with fungal chitin can occur in quantities exceeding the chitin content itself (Hackman, 1960; (Haneef et al, 2017).…”

Section: Chitinmentioning

confidence: 99%

“…In recent years, mycelium gains more interest in academics and commerce studies because of its low energy consumption in growth, zero-byproduct, and broad potential application (Holt et al, 2012;Pelletier et al, 2013;Jones et al, 2017;Nawawi et al, 2020) (Figure 1). Mycelium is the vegetative part of a fungus, consisting of a network of fine white filaments of 1-30 μm in diameter, which spreads out from a single spore into every corner of the substrate (Fricker et al, 2007;Islam et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

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Material Function of Mycelium-Based Bio-Composite: A Review

2021

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Mycelium-based bio-composite materials have been invented and widely applied to different areas, including construction, manufacturing, agriculture, and biomedical. As the vegetative part of a fungus, mycelium has the unique capability to utilize agricultural crop waste (e.g., sugarcane bagasse, rice husks, cotton stalks, straw, and stover) as substrates for the growth of its network, which integrates the wastes from pieces to continuous composites without energy input or generating extra waste. Their low-cost and environmentally friendly features attract interest in their research and commercialization. For example, mycelium-based foam and sandwich composites have been actively developed for construction structures. It can be used as synthetic planar materials (e.g., plastic films and sheets), larger low-density objects (e.g., synthetic foams and plastics), and semi-structural materials (e.g., paneling, flooring, furniture, decking). It is shown that the material function of these composites can be further tuned by controlling the species of fungus, the growing conditions, and the post-growth processing method to meet a specific mechanical requirement in applications (e.g., structural support, acoustic and thermal insulation). Moreover, mycelium can be used to produce chitin and chitosan, which have been applied to clinical trials for wound healing, showing the potential for biomedical applications. Given the strong potential and multiple advantages of such a material, we are interested in studying it in-depth and reviewing the current progress of its related study in this review paper.

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Section: Chitinmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Material Function of Mycelium-Based Bio-Composite: A Review

2021

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“…Fungal β-glucans, such as lentinan from L. edodes (shiitake), schizophyllan from S. commune (split gill), zymosan from S. cereviase (baker's yeast), pleuran from P. ostreatus (oyster), and ganoderan from G. lucidum (reishii), have also been extensively studied due to the human immune system's ability to recognize them, promoting immune stimulation, antibacterial, antitumor, anticancer, and antioxidant properties [92][93][94][95]. These findings, coupled with the varying chitin, chitosan, and polysaccharide profiles of the over 5.1 million species of fungi in existence [96] and recent advances in fungal material technology [7,14,17,[97][98][99][100][101], suggest that fungi-derived wound treatments warrant further investigation. In particular, the native chitin-β-glucan composite architecture of fungal chitin could be utilized to achieve scaffolds exceeding the mechanical performance of crustacean chitin [17] and novel antibacterial properties resulting from composite dressings incorporating naturally generated complexes of fungal chitin, chitosan, β-glucans, and exopolysaccharides could pave the way for new low-cost, natural, and mass-producible dressing technologies.…”

Section: Of 23mentioning

confidence: 99%

Crab vs. Mushroom: A Review of Crustacean and Fungal Chitin in Wound Treatment

et al. 2020

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Chitin and its derivative chitosan are popular constituents in wound-treatment technologies due to their nanoscale fibrous morphology and attractive biomedical properties that accelerate healing and reduce scarring. These abundant natural polymers found in arthropod exoskeletons and fungal cell walls affect almost every phase of the healing process, acting as hemostatic and antibacterial agents that also support cell proliferation and attachment. However, key differences exist in the structure, properties, processing, and associated polymers of fungal and arthropod chitin, affecting their respective application to wound treatment. High purity crustacean-derived chitin and chitosan have been widely investigated for wound-treatment applications, with research incorporating chemically modified chitosan derivatives and advanced nanocomposite dressings utilizing biocompatible additives, such as natural polysaccharides, mineral clays, and metal nanoparticles used to achieve excellent mechanical and biomedical properties. Conversely, fungi-derived chitin is covalently decorated with -glucan and has received less research interest despite its mass production potential, simple extraction process, variations in chitin and associated polymer content, and the established healing properties of fungal exopolysaccharides. This review investigates the proven biomedical properties of both fungal- and crustacean-derived chitin and chitosan, their healing mechanisms, and their potential to advance modern wound-treatment methods through further research and practical application.

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“…The attention has been focused also on membranes based on chitosan blended with other biomacromolecules such as alginate, cellulose, collagen, gelatin, keratin, sericin, and soy protein [6]. Chitin-related materials from fungal sources with focus on nanocomposites and nanopapers have been suggested as greener alternative to synthetic polymers [7]. Fungal chitin-glucan nanopapers have manufactured from chitin nanofibrils, which is a native composite material (chitin-glucan) combining the strength of chitin and the toughness of glucan.…”

Section: Introductionmentioning

confidence: 99%

Characterization of Novel Biopolymer Blend Mycocel from Plant Cellulose and Fungal Fibers

et al. 2021

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In this study unique blended biopolymer mycocel from naturally derived biomass was developed. Softwood Kraft (KF) or hemp (HF) cellulose fibers were mixed with fungal fibers (FF) in different ratios and the obtained materials were characterized regarding microstructure, air permeability, mechanical properties, and virus filtration efficiency. The fibers from screened Basidiomycota fungi Ganoderma applanatum (Ga), Fomes fomentarius (Ff), Agaricus bisporus (Ab), and Trametes versicolor (Tv) were applicable for blending with cellulose fibers. Fungi with trimitic hyphal system (Ga, Ff) in combinations with KF formed a microporous membrane with increased air permeability (>8820 mL/min) and limited mechanical strength (tensile index 9–14 Nm/g). HF combination with trimitic fungal hyphae formed a dense fibrillary net with low air permeability (77–115 mL/min) and higher strength 31–36 Nm/g. The hyphal bundles of monomitic fibers of Tv mycelium and Ab stipes made a tight structure with KF with increased strength (26–43 Nm/g) and limited air permeability (14–1630 mL/min). The blends KF FF (Ga) and KF FF (Tv) revealed relatively high virus filtration capacity: the log10 virus titer reduction values (LRV) corresponded to 4.54 LRV and 2.12 LRV, respectively. Mycocel biopolymers are biodegradable and have potential to be used in water microfiltration, food packaging, and virus filtration membranes.

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Nanomaterials Derived from Fungal Sources—Is It the New Hype?

Cited by 73 publications

References 282 publications

Material Function of Mycelium-Based Bio-Composite: A Review

Material Function of Mycelium-Based Bio-Composite: A Review

Crab vs. Mushroom: A Review of Crustacean and Fungal Chitin in Wound Treatment

Characterization of Novel Biopolymer Blend Mycocel from Plant Cellulose and Fungal Fibers

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