Difference between revisions of "Team:Aix-Marseille/Integrated Practices/Process"

(Quantities of DHOB per µg of platinum)
(Siderophore mediated recovery)
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'''This step consist in spreading a ''Thiobacillus'' solution on the ashes then recollecting the produced leachate. This step could be also realised not with ''Thiobacillus'' but with chemicals solutions.'''
 
'''This step consist in spreading a ''Thiobacillus'' solution on the ashes then recollecting the produced leachate. This step could be also realised not with ''Thiobacillus'' but with chemicals solutions.'''
  
==Siderophore mediated recovery==
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==Siderophore mediated leaching==
  
Once the platinum is leached, we need to recover it. If leaching (by biological or chemical methods) is clearly recommended to improves solubilization of metals, it does not improves the concentrations. As we worked with synthetic biology, we decided to use what it is commonly employed by cells to catch metals, i.e. siderophore. Siderophores are well known to catch iron most of all but some of them have an affinity with others metals as platinum. So in our process, we planned to work with such a siderophore, called  [[Team:Aix-Marseille/Integrated_Practices/Process#Glossary|Desferrioxamine B]]. This one is already employed to recover platinum in mines, and have shown high capacity to recover platinum from ores <ref>Bau and al., 2015 http://dx.doi.org.gate1.inist.fr/10.1016/j.hydromet.2015.01.002</ref>.  
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Even if almost 30 % of platinum has been leached by the drop of pH we need to improve the proportion of leached platinum. As we worked with synthetic biology, we decided to use what it is commonly employed by cells to catch metals, i.e. siderophore. Siderophores are well known to catch iron most of all but some of them have an affinity with others metals as platinum. So in our process, we planned to work with such a siderophore, called  [[Team:Aix-Marseille/Integrated_Practices/Process#Glossary|Desferrioxamine B]]. This one is already employed to leach platinum in mines, and have shown high capacity to leach platinum from ores <ref>Bau and al., 2015 http://dx.doi.org.gate1.inist.fr/10.1016/j.hydromet.2015.01.002</ref>.  
  
Recovery yields with [[Team:Aix-Marseille/Integrated_Practices/Process#Glossary|DFHOB]] can reach '''78%''' of the total platinum if both of these conditions are fully respected: a lowering pH level leaching step should be performed, as well as a alcanization of medium (until a pH range between 8 and 9)  just before addition of siderophore. The last step devoted to rise up the pH level will be realized using a standard buffer, e.g. a Tris buffer.   
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Leaching yields with [[Team:Aix-Marseille/Integrated_Practices/Process#Glossary|DFHOB]] can reach '''78%''' of the total platinum if both of these conditions are fully respected: a lowering pH level leaching step should be performed, as well as a alcanization of medium (until a pH range between 8 and 9)  just before addition of siderophore. The last step devoted to rise up the pH level will be realized using a standard buffer, e.g. a Tris buffer.   
  
 
So where is the innovation in this step? Firstly, in our case, [[Team:Aix-Marseille/Integrated_Practices/Process#Glossary|DFHOB]] won't be applied on the same materials where is commonly used, in our cases not ores but a leachate of ashes. Basically the main difference will be the metal concentration.
 
So where is the innovation in this step? Firstly, in our case, [[Team:Aix-Marseille/Integrated_Practices/Process#Glossary|DFHOB]] won't be applied on the same materials where is commonly used, in our cases not ores but a leachate of ashes. Basically the main difference will be the metal concentration.
 
Secondly, [[Team:Aix-Marseille/Integrated_Practices/Process#Glossary|DFHOB]] is usually synthesized chemically, we'll rather produce it in high amounts with bacteria. Indeed, [[Team:Aix-Marseille/Description#Overview|operon]] of the Desferrioxamine B biosynthesis  from ''Streptomyces coelicolor'' will be cloned into a E. coli bacteria strains in order to produce it, hence lowering the costs of required basic matter as production by bacteria needs especially an appropriate medium and good growth conditions.
 
Secondly, [[Team:Aix-Marseille/Integrated_Practices/Process#Glossary|DFHOB]] is usually synthesized chemically, we'll rather produce it in high amounts with bacteria. Indeed, [[Team:Aix-Marseille/Description#Overview|operon]] of the Desferrioxamine B biosynthesis  from ''Streptomyces coelicolor'' will be cloned into a E. coli bacteria strains in order to produce it, hence lowering the costs of required basic matter as production by bacteria needs especially an appropriate medium and good growth conditions.
[[Team:Aix-Marseille/Integrated_Practices/Process#Glossary|DFHOB]] is a derivative of diamines moelcule and therefore its  [[Team:Aix-Marseille/Experiments|Biosynthesis]] start with a amino acid, lysine. Lysine is quite expansive, and as we are aware about the cost of our process we decided to use a cheap source of lysine the [[Team:Aix-Marseille/Integrated_Practices/Process#Glossary|corn steep liquor]]. Such a lysine source is already in use in industry since it's cheap, amino acid provided, produced in industrial amounts and well known as a excellent source of nitrogen in growth media. So in this step we hope we could produce [[Team:Aix-Marseille/Integrated_Practices/Process#Glossary|DFHOB]] in high quantities with a affordable cost.  
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[[Team:Aix-Marseille/Integrated_Practices/Process#Glossary|DFHOB]] is a derivative of diamines moelcule and therefore its  [[Team:Aix-Marseille/Experiments|Biosynthesis]] start with an amino acid, lysine. Lysine is quite expansive, and as we are aware about the cost of our process we decided to use a cheap source of lysine the [[Team:Aix-Marseille/Integrated_Practices/Process#Glossary|corn steep liquor]]. Such a lysine source is already in use in industry since it's cheap, amino acid provided, produced in industrial amounts and well known as a excellent source of nitrogen in growth media. So in this step we hope we could produce [[Team:Aix-Marseille/Integrated_Practices/Process#Glossary|DFHOB]] in high quantities with a affordable cost. Moreover, DFHOB production has been repoted with corn steep ATICLE
  
Following previous uses of [[Team:Aix-Marseille/Integrated_Practices/Process#Glossary|DFHOB]], '''78% of platinum''' can be recovered with 3mM [[Team:Aix-Marseille/Integrated_Practices/Process#Glossary|DFHOB]] solution on 100g at 5ppm platinum concentrated ore. That allow us to estimate that in order to reach a 78% yield (max yield obtained) we 'll need to add approximately '''3mg of DFHOB per µg of platinum''' (see [[Team:Aix-Marseille/Integrated_Practices/Process#Quantities_of_DHOB_per_.C2.B5g_of_platinum|Raw calculations]]). Of course this number a based on leaching on ore sample, so maybe we can expect higher yields for the ashes are probably easier to leach than the ore.
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Following previous uses of [[Team:Aix-Marseille/Integrated_Practices/Process#Glossary|DFHOB]], '''78% of platinum''' can be leached with 3mM [[Team:Aix-Marseille/Integrated_Practices/Process#Glossary|DFHOB]] solution on 100g at 5ppm platinum concentrated ore. That allow us to estimate that in order to reach a 78% yield (max yield obtained) we 'll need to add approximately '''3mg of DFHOB per µg of platinum''' (see [[Team:Aix-Marseille/Integrated_Practices/Process#Quantities_of_DHOB_per_.C2.B5g_of_platinum|Raw calculations]]). Of course this number a based on leaching on ore sample, so maybe we can expect higher yields for the ashes are probably easier to leach than the ore.
  
 
CALCULS POUR 1G COMBIEN PRODUIT UNE ECOLI DE DFHOB,,???
 
CALCULS POUR 1G COMBIEN PRODUIT UNE ECOLI DE DFHOB,,???

Revision as of 19:42, 21 September 2016