Comparative Utilization of Dead and Live Fungal Biomass for the Removal of Heavy Metal: A Concise Review

Ayele, Abate; Haile, Setegn; Alemu, Digafe; Kamaraj, M.

doi:10.1155/2021/5588111

Cited by 58 publications

(31 citation statements)

References 54 publications

(95 reference statements)

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“…It has been used as the production of dietary supplements or nutraceuticals such as antitumor, antimetastatic, antioxidant, anti-inflammatory, insecticidal, and antimicrobial. Gradually, utilization of mycelium was translated into mycoremediation since the 1980s [ 52 – 54 ]. Beyond bioremediation and medicinal application, nowadays mycelium is applied in biomaterial production such as biocement, bioblock, and bioenzyme.…”

Section: Literature Reviewmentioning

confidence: 99%

“…The length of the incubation period affects the quality of the composite materials. The density of fungal-based composites increased as the incubation period increased from 195 kg/m 3 to 280 kg/m 3 [ 52 ]. That might be due to the fact that the voids between the fibers are filled as the mycelium continues to grow and the substrate is bonded more strongly together which in turn increases the density [ 28 ].…”

Section: Mechanismsmentioning

confidence: 99%

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Mycelium-Based Composite: The Future Sustainable Biomaterial

Alemu

Tafesse

Mondal

2022

International Journal of Biomaterials

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Because of the alarming rate of human population growth, technological improvement should be needed to save the environment from pollution. The practice of business as usual on material production is not creating a circular economy. The circular economy refers to an economic model whose objective is to produce goods and services sustainably, by limiting the consumption and waste of resources (raw materials, water, and energy). Fungal-based composites are the recently implemented technology that fulfills the concept of the circular economy. It is made with the complex of fungi mycelium and organic substrates by using fungal mycelium as natural adhesive materials. The quality of the composite depends on both types of fungi and substrate. To ensure the physicochemical property of the fabricated composite, mycelium morphology, bimolecular content, density, compressive strength, thermal stability, and hydrophobicity were determined. This composite is proven to be used for different applications such as packaging, architectural designs, walls, and insulation. It also has unique features in terms of low cost, low emission, and recyclable.

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Section: Literature Reviewmentioning

confidence: 99%

Section: Mechanismsmentioning

confidence: 99%

Mycelium-Based Composite: The Future Sustainable Biomaterial

Alemu

Tafesse

Mondal

2022

International Journal of Biomaterials

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“…The biomass (algae, bacteria, yeast, and fungi) can be used as living cells, offering the possibility of removing larger amounts of pollutants, since it has the enzymatic facility that allows it to either transform or degrade the pollutant (considered as food source for living cells/microorganism), but the biosorption process depends on the cell metabolism and requires specific conditions compatible with living cells (nutrient supply, temperature and pH in a certain domain, oxygen supply for aerobic cells, etc.) and can be stored for very limited periods of time [20,22,23]. The non-living biomass is used in the simpler and less expensive treatment processes, thus the biosorbent can be utilized for more than one cycle (taking into account the pollutant concentration), and no cell disruption occurs as long as the working conditions are not extreme.…”

Section: Biosorptionmentioning

confidence: 99%

“…There are different immobilization techniques that can be applied for biosorbents, with microbial cells being bonded either on the surface or within a polymer matrix: adsorption, covalent bonding, cross-linking, encapsulation, and entrapment in a matrix (Figure 2) [6,22,[24][25][26]. [23,27].…”

Section: Biosorptionmentioning

confidence: 99%

“…An extremely important step in the immobilization process is the selection of a suitable support (it can be natural-gelatin, agar, gum, sodium alginate, calcium alginate, dextran, fats and fatty acids, starch, chitosan, sucrose, and wax, or synthetic-acrylic polymer and copolymers, and semi-synthetic-cellulose acetate, cellulose nitrate, ethylcellulose and hydroxypropylcellulose, methylcellulose, sodium carboxymethylcellulose, hydrogenated fat, and myristic alcohol), since it needs to fulfill several characteristics, presented in Table 2 [6,[22][23][24][25]. The choice of a support is very important for the efficiency of immobilization and the stability of final biosorbent.…”

Section: Polymer Support For Immobilization Of Microbial Biomass To Obtain Biosorbentsmentioning

confidence: 99%

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Polysaccharides as Support for Microbial Biomass-Based Adsorbents with Applications in Removal of Heavy Metals and Dyes

2021

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The use of biosorbents for the decontamination of industrial effluent (e.g., wastewater treatment) by retaining non-biodegradable pollutants (antibiotics, dyes, and heavy metals) has been investigated in order to develop inexpensive and effective techniques. The exacerbated water pollution crisis is a huge threat to the global economy, especially in association with the rapid development of industry; thus, the sustainable reuse of different treated water resources has become a worldwide necessity. This review investigates the use of different natural (living and non-living) microbial biomass types containing polysaccharides, proteins, and lipids (natural polymers) as biosorbents in free and immobilized forms. Microbial biomass immobilization performed by using polymeric support (i.e., polysaccharides) would ensure the production of efficient biosorbents, with good mechanical resistance and easy separation ability, utilized in different effluents’ depollution. Biomass-based biosorbents, due to their outstanding biosorption abilities and good efficiency for effluent treatment (concentrated or diluted solutions of residuals/contaminants), need to be used in industrial environmental applications, to improve environmental sustainability of the economic activities. This review presents the most recent advances related the main polymers such as polysaccharides and microbial cells used for biosorbents production; a detailed analysis of the biosorption capability of algal, bacterial and fungal biomass; as well as a series of specific applications for retaining metal ions and organic dyes. Even if biosorption offers many advantages, the complexity of operation increased by the presence of multiple pollutants in real wastewater combined with insufficient knowledge on desorption and regeneration capacity of biosorbents (mostly used in laboratory scale) requires more large-scale biosorption experiments in order to adequately choose a type of biomass but also a polymeric support for an efficient treatment process.

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Exploring the Application and Prospects of Synthetic Biology in Engineered Living Materials

Wang,

Hu,

et al. 2023

Advanced Materials

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At the intersection of synthetic biology and materials science, engineered living materials (ELMs) exhibit unprecedented potential. Possessing unique “living” attributes, ELMs represent a significant paradigm shift in material design, showcasing self‐organization, self‐repair, adaptability, and evolvability, surpassing conventional synthetic materials. This review focuses on reviewing the applications of ELMs derived from bacteria, fungi, and plants in environmental remediation, eco‐friendly architecture, and sustainable energy. The review provides a comprehensive overview of the latest research progress and emerging design strategies for ELMs in various application fields from the perspectives of synthetic biology and materials science. In addition, the review provides valuable references for the design of novel ELMs, extending the potential applications of future ELMs. The investigation into the synergistic application possibilities amongst different species of ELMs offers beneficial reference information for researchers and practitioners in this field. Finally, future trends and development challenges of synthetic biology for ELMs in the coming years are discussed in detail.This article is protected by copyright. All rights reserved

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Comparative Utilization of Dead and Live Fungal Biomass for the Removal of Heavy Metal: A Concise Review

Cited by 58 publications

References 54 publications

Mycelium-Based Composite: The Future Sustainable Biomaterial

Mycelium-Based Composite: The Future Sustainable Biomaterial

Polysaccharides as Support for Microbial Biomass-Based Adsorbents with Applications in Removal of Heavy Metals and Dyes

Exploring the Application and Prospects of Synthetic Biology in Engineered Living Materials

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