Difference between revisions of "Team:IIT Kanpur/idea"

Line 39: Line 39:
 
BL21(DE3) strain using alkyl sulfatase protein (SdsA1) derived from Pseudomonas sp.
 
BL21(DE3) strain using alkyl sulfatase protein (SdsA1) derived from Pseudomonas sp.
 
ATCC 19151 where it is has been shown to be responsible for degrading SDS into
 
ATCC 19151 where it is has been shown to be responsible for degrading SDS into
1-dodecanol.<br>
+
1-dodecanol.<br><br>
 
We plan to achieve this in three steps:<br>
 
We plan to achieve this in three steps:<br>
 
● Extracellular release of SdsA1 by E.coli BL21(DE3) via attachment of N-terminal
 
● Extracellular release of SdsA1 by E.coli BL21(DE3) via attachment of N-terminal
Line 46: Line 46:
 
production of 1-dodecanol within the water sample.<br>
 
production of 1-dodecanol within the water sample.<br>
 
● Separation and purification of 1-dodecanol from the sample. <br>
 
● Separation and purification of 1-dodecanol from the sample. <br>
 
 
 
 
 
Application in water conservation<br>
 
 
 
Applications in Industry<br>
 
 
❖ Uses of 1-Dodecanol in Industries<br>
 
In 1993, the European demand of dodecanol, saturated 12-carbon fatty alcohol was around
 
60 thousand tons per year. Dodecanol can be obtained from palm kernel or coconut oil fatty
 
acids and methyl esters by hydrogenation. In cosmetics, dodecanol can be used as an
 
emollient. <br>
 
An exhaustible ingredient, 1-Dodecanol is found to have its uses in a lot of products such as
 
in steel cleaning and furnishing care products. It is also used as a drag reducing agents for
 
pipelining for petroleum extraction. Many laundry and dishwashing products like SDS are
 
made using it. Fatty alcohols like dodecanol are used particularly in bottle washing and
 
metal cleaning products. It also finds use in synthetic detergents, lube additives,
 
pharmaceuticals, cosmetics, rubber, textiles, perfumes, and as a flavoring agent. For use
 
in other industries like textiles, leather, plastics, pharmaceuticals and paper, dodecanol
 
imparts properties such as that of a leveling agent, bacteriostatic, water evaporation
 
retardant, coupling agent, plasticizer and anti-corrosion agent.<br>
 
Our strategy focuses on generating dodecanol from only contaminated water from various
 
industrial and household sources. The major benefits of our product will be-<br>
 
● Extracted from waste-water, thus recycling and reducing waste.<br>
 
● The synthetic biological procedure as a manufacturing tool, reducing the cost of the project.
 
The major benefit of our project would be the high-quality production of 1-dodecanol as compared to
 
those produced in industry use which is around 65 percent pure only. Our goal is to extract
 
1-dodecanol from the bio-renewable process rather than affecting the biodiversity. Our project
 
has potential applications in encouraging water conservation by making recycling of
 
contaminated water into an economically productive activity by the generation of 1-dodecanol.
 
This has both an environmental impact as well as economic value.
 
 
</p>
 
</p>
 
</html>
 
</html>
 
{{Template:IIT_Kanpur/Footer}}
 
{{Template:IIT_Kanpur/Footer}}

Revision as of 16:09, 17 October 2018

Our Idea

Our aim is to extract 1-dodecanol(C12H26O) via in vitro degradation of Sodium Dodecyl Sulphate (SDS) from contaminated water. This would be done in Escherichia coli(E.coli) BL21(DE3) strain using alkyl sulfatase protein (SdsA1) derived from Pseudomonas sp. ATCC 19151 where it is has been shown to be responsible for degrading SDS into 1-dodecanol.

We plan to achieve this in three steps:
● Extracellular release of SdsA1 by E.coli BL21(DE3) via attachment of N-terminal secretion signal sequence pelB or OmpT.
● This is followed by the action of alkyl sulfatase(SdsA1) on SDS resulting in the production of 1-dodecanol within the water sample.
● Separation and purification of 1-dodecanol from the sample.