Concrete is a mixture of cement, water, sand and other aggregates in adequate proportions. Its high tensile strength and ability to withstand a vast range of environmental changes makes it the first choice for construction material. One of the major problems associated with concrete is its permeability because penetration of gases and/or liquids from the surrounding environment into the concrete, followed by physical and/or chemical reactions within its internal structure/s leads to irreversible damages. Although cement has autonomous capacity to heal, however cracks <0.2mm width can only self-heal. Biomineralization is one of the best ecofriendly techniques to tackle the problem of cracks in concrete structures. Biologically induced self-healing is beneficial in addressing all the drawbacks of concrete matrix. The most promising technology for producing crack resistant/highly self healing concrete in near future seems to be "BacillaFilla": genetically modified version of Bacillus subtilis, is a "custom -designed" bacteria to embed deep into the cracks in concrete where they produce a mix of calcium carbonate and a special bacteria glue that hardens to the same strength as of the surrounding concrete.
Biodegradation is the process by which chemicals both natural and xenobiotics are metabolized by microorganisms. Most naturally occurring chemical compounds are biodegradable while xenobiotic may be biodegradable, persistent or recalcitrant. Xenobiotic chemicals, because they are manmade and have developed recently, are present in the environment for comparatively shorter periods of time from its geological presence. This in turn means that the microbial communities present in these environments may not have evolved specific mechanisms for their degradation. Morpholine, a known xenobiotics micropollutant initially believes to be recalcitrant but later prove to be biodegradable by specific set of bacterium species most likely Mycobacterium and Pseudomonas sp in particular. However, the metabolic pathways involved in the successful biodegradation of morpholine stand challenging to establish because of its extreme water solubility and the lack of any chromophore group in morpholine which does not allow easy extraction process. Consequently, no tool for direct estimation of intermediates or metabolites of morpholine has been well reported and only indirect strategies have been developed like presence of microbial growth on intermediates, chemical/analytical assay for intermediate and ammonia measurements to elucidate the degradation pathway for zero pollution environment. In this present study degradation pathway has been ascertained by some selected bacterial isolate for their capacity to degrade morpholine. Based on the said analysis of culture filtrate, it has been revealed that the isolate namely Halobacillus utilizes glycolic route of the metabolic degradation pathway of morpholine and supports the fact that in presence of morpholine, one of two branches of morpholine biodegradation pathway namely ethanolamine and glycolate was was induced while the other branch was inhibited. Whatever the degradation pathway of morpholine exhibited by bacteria, ammonia is the end product of degradation which would be biochemically utilized by isolate.
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