000 | 03642cam a22003255i 4500 | ||
---|---|---|---|
020 | _a9789811086663 | ||
082 | 0 | 4 | _a630 PRA |
245 | 0 | 0 |
_aFungal Nanobionics: _cedited by Ram Prasad, Vivek Kumar, Manoj Kumar, Shanquan Wang. _b Principles and Applications / |
250 | _a1st ed. 2018. | ||
260 |
_aSingapore: _bSpringer; _c2018. |
||
300 | _a1 online resource (XVIII, 316 pages 50 illustrations, 38 illustrations in color.) | ||
505 | 0 | _aNanobiocomposites: Synthesis and Environmental Applications -- Medical and Cosmetic Applications of Fungal Nanotechnology: Production, Characterization and Bioactivity -- Fungal Nanoparticles: A Novel Tool for a Green Biotechnology? -- Application of Nanotechnology in Mycoremediation: Current Status and Future Prospects -- Fungal Nanotechnology: A New Approach Toward Efficient Biotechnology Application -- Advances in Biomedical Application of Chitosan and its Functionalized Nano-derivatives -- Biosynthesis of Metal Nanoparticles via Fungal Dead Biomass in Industrial Bioremediation Process -- Nanofabrication of Myconanoparticles: A Future Prospect -- In vitro Secondary Metabolite Production Through Fungal Elicitation: An Approach for Sustainability -- Metal and Metal Oxide Mycogenic Nanoparticles and Their Application as Antimicrobial and Antibiofilm Agents -- Applications of Fungal Nanobiotechnology in Drug Development -- Mycosynthesized Nanoparticles: Role in Food Processing Industries. | |
520 | _aFungal nanobionics has great prospects for developing new products with industrial, agriculture, medicine and consumer applications in a wide range of sectors. The fields of chemical engineering, agri-food, biochemical, pharmaceuticals, diagnostics and medical device development all employ fungal products, with fungal nanomaterials currently used in a wide range of applications, ranging from drug development to food industry and agricultural sector. The fungal agents emerge as an environmentally friendly, clean, non-toxic agent for the biogenic metal nanoparticles and employs both intracellular and extracellular methods. The simplicity of scaling up and downstream processing and the presence of fungal mycelia affording an increased surface area provide key advantages. In addition, the larger spectrum of synthesized nanoparticle morphologies and the substantially faster biosynthesis rate in cell-free filtrate (due to the higher amount of proteins secreted in fungi) make this a particularly enticing route. Understanding the diversity of fungi in assorted ecosystems, as well as their interactions with other microorganisms, animals and plants, is essential to underpin real and innovative technological developments and the applications of metal nanoparticles in many disciplines including agriculture, catalysis, and biomedical biosensors. Importantly, biogenic fungal nanoparticles show significant synergistic characteristics when combined with antibiotics and fungicides to offer substantially greater resistance to microbial growth and applications in nanomedicine ranging from topical ointments and bandages for wound healing to coated stents. | ||
650 | 0 | _aAgriculture. | |
650 | 0 | _aBiotechnology. | |
650 | 0 | _aEnvironmental engineering. | |
650 | 0 | _aMycology. | |
650 | 0 | _aNanotechnology. | |
650 | 0 | _aSustainable development. | |
650 | 1 | 4 | _aAgriculture. |
650 | 2 | 4 | _aEnvironmental Engineering/Biotechnology. |
650 | 2 | 4 | _aMycology. |
650 | 2 | 4 | _aNanotechnology. |
650 | 2 | 4 | _aSustainable Development. |
700 | 1 | _aKumar, Manoj. | |
700 | 1 | _aKumar, Vivek. | |
700 | 1 | _aPrasad, Ram. | |
700 | 1 | _aWang, Shanquan. | |
942 | _cBK | ||
999 |
_c255687 _d255687 |