Engineering nanoparticle synthesis using microbial factories

Biologically engineered entities have enabled discoveries in the past decade and a half, spanning from novel routes for the syntheses of drugs and value‐added products to carbon capture. The precise cellular re‐programming has extended to the production of nanomaterials owing to their ever‐growing d...

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Bibliographic Details
Published in:Engineering biology 2017-06, Vol.1 (1), p.12-17
Main Authors: Pasula, Rupali Reddy, Lim, Sierin
Format: Article
Language:English
Subjects:
Algae
Ambient temperature
Bacteria
bio-inspired materials
biologically engineered entities
Cadmium
carbon capture
Cellular manufacture
cellular re-programming
Chemical synthesis
Copper
Cytochrome
downstream processing
drugs
E coli
eco-friendly approach
enzymes
fungi
Genetic engineering
Industrial applications
Industrial engineering
Manufacturing engineering
Metabolic engineering
Metabolic pathways
Metabolism
microbial factories
Microorganisms
nanobiotechnology
Nanocrystals
Nanomaterials
nanoparticle synthesis
Nanoparticles
Nanotechnology
Proteins
Quantum dots
Silver
Spectrum analysis
Stabilizers (agents)
value-added products
yeast
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Summary:Biologically engineered entities have enabled discoveries in the past decade and a half, spanning from novel routes for the syntheses of drugs and value‐added products to carbon capture. The precise cellular re‐programming has extended to the production of nanomaterials owing to their ever‐growing demand. The primary advantage of the biological nanoparticle synthesis is the eco‐friendly approach performed at ambient temperature and pressure, where the usage of harsh chemical stabilisers and capping agents is eliminated, providing ease of handling and downstream processing. Although the techniques hold great promise, many short comings hamper their scalability; thus, rendering them unsuitable for industrial applications. A fundamental understanding of the underlying mechanisms which involve various enzymes of different metabolic pathways is most crucial in surmounting these impending blocks leading to successfully engineered systems which can be tuned in accordance with the goals of specific applications. This mini review highlights the recent developments in nanoparticle synthesis that employ the use of microbial reaction vessels with specific emphasis on engineering of these biological entities such as bacteria, yeast, fungi and algae. Also presented are the challenges and future trends in this domain where novel and engineered approaches will be the most consequential.
ISSN:2398-6182
2398-6182
DOI:10.1049/enb.2017.0009