Difference between revisions of "Part:BBa K1317003:Experience"

m (Applications of BBa_K1317003)
m (Applications of BBa_K1317003)
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In order to obtain polymer wires, we carried out severeal tests by mixing the ELP with different solvants. The following results have been observed:
 
In order to obtain polymer wires, we carried out severeal tests by mixing the ELP with different solvants. The following results have been observed:
  
- Sodium Sulfate (Na2So4) at 320 g/L => cottony aspect of the fiber, the structure is not stable  
+
#* Sodium Sulfate (Na2So4) at 320 g/L => cottony aspect of the fiber, the structure is not stable  
  
- Diethyl ether (C2H5)2O => No reaction because the drop is trapped. This solvent is not miscible with the polymer
+
#* Diethyl ether (C2H5)2O => No reaction because the drop is trapped. This solvent is not miscible with the polymer
  
- Acetone (CH3COCH3) => Formation of a white ring
+
#* Acetone (CH3COCH3) => Formation of a white ring
  
- Heated Sodium Chloride (NaCl 5M) => Formation of a white cloud due to a lack of cohesiveness  
+
#* Heated Sodium Chloride (NaCl 5M) => Formation of a white cloud due to a lack of cohesiveness  
  
- Calcium Chloride (CaCl2 15%) => 1.25% alginate mixture with ELP40 at 10mg/mL were extruded in the calcium chloride solution: a white-colored fiber is obtained.
+
#* Calcium Chloride (CaCl2 15%) => 1.25% alginate mixture with ELP40 at 10mg/mL were extruded in the calcium chloride solution: a white-colored fiber is obtained.
  
 
This last trial has been performed with 0.75% alginate which seems to be the best experimental condition to get fibers from the ELP
 
This last trial has been performed with 0.75% alginate which seems to be the best experimental condition to get fibers from the ELP
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After getting the ELP40 fiber, it is necessary to wash it with hot water for extraction, the fiber could indeed dissolve at low temperature.
 
After getting the ELP40 fiber, it is necessary to wash it with hot water for extraction, the fiber could indeed dissolve at low temperature.
  
- Control remains transparent
+
#* Control remains transparent
  
- The aspect of the fiber changes at ambient temperature (from white to transparent)  
+
#* The aspect of the fiber changes at ambient temperature (from white to transparent)  
  
 
Thanks to the mixture alginate + ELP40 (10 mg/L), we could observe the formation of the polymer and it can be deduced that:
 
Thanks to the mixture alginate + ELP40 (10 mg/L), we could observe the formation of the polymer and it can be deduced that:
  
- In presence of salt, product is losing cohesiveness
+
#* In presence of salt, product is losing cohesiveness
  
- With contact of hot water, the product is contracting
+
#* With contact of hot water, the product is contracting
  
You can see the results on the phase transition on this video: https://www.youtube.com/watch?v=xoTQkoNoZu0
+
'''You can see the results on the phase transition on this video: https://www.youtube.com/watch?v=xoTQkoNoZu0'''
  
 
'''Wet-spinning and mechanical testing of fibers properties'''
 
'''Wet-spinning and mechanical testing of fibers properties'''

Revision as of 20:13, 7 October 2014

This experience page is provided so that any user may enter their experience using this part.
Please enter how you used this part and how it worked out.

Applications of BBa_K1317003

The protein ELP has been produced in BL21 strain of E.coli. After phase cycling purification it is possible to spin the protein into a wire, thanks to the wet-spinning method. The ELP can have different length regarding the number of copy of the gene. In these experiments, we used 40mer ELP (assemble of two gene copies).

Polymer formation trial:

Fiber obtained by extruding ELP/Alginate in calcium chloride

In order to obtain polymer wires, we carried out severeal tests by mixing the ELP with different solvants. The following results have been observed:

    • Sodium Sulfate (Na2So4) at 320 g/L => cottony aspect of the fiber, the structure is not stable
    • Diethyl ether (C2H5)2O => No reaction because the drop is trapped. This solvent is not miscible with the polymer
    • Acetone (CH3COCH3) => Formation of a white ring
    • Heated Sodium Chloride (NaCl 5M) => Formation of a white cloud due to a lack of cohesiveness
    • Calcium Chloride (CaCl2 15%) => 1.25% alginate mixture with ELP40 at 10mg/mL were extruded in the calcium chloride solution: a white-colored fiber is obtained.

This last trial has been performed with 0.75% alginate which seems to be the best experimental condition to get fibers from the ELP


Phase transition trial:

Phase transition of the ELP according to temperature

After getting the ELP40 fiber, it is necessary to wash it with hot water for extraction, the fiber could indeed dissolve at low temperature.

    • Control remains transparent
    • The aspect of the fiber changes at ambient temperature (from white to transparent)

Thanks to the mixture alginate + ELP40 (10 mg/L), we could observe the formation of the polymer and it can be deduced that:

    • In presence of salt, product is losing cohesiveness
    • With contact of hot water, the product is contracting

You can see the results on the phase transition on this video: https://www.youtube.com/watch?v=xoTQkoNoZu0

Wet-spinning and mechanical testing of fibers properties

The wet-spinning method has been used to create a wire out of the polymer.

TeamBdx2014 Wet spin.gif
Overview of the wet-sinning method


The mechanical traction machine

A traction machine allows to measure the resistance to rupture of a chosen material, in this case, the fiber obtained by wet-spinning. This experiment consists in placing a little stick of the material to be studied between the jaws of the traction machine. It will pull the stick until its rupture. The lenghtening and the applied force are recorded and then converted into distorsion and pressure data.

The mechanical testing allow us to state:

  1. For the alginate
    • The experiment done with the alginate is reproducible while using the same conditions, but the fiber ends by breaking.
    • Alginate breaks faster because the experiment is carried out at high temperature


  1. Comparison with carbon nanofibers
    • The elasticity is comparable with carbon nanofibers. Thus, ELP has characteristic properties of elasticity due to its polymeric nature.
    • The fibers are nevertheless fragile and break easily. Enhancing the resistance should be possible by using another part and fusing the proteins (BBa_K1317001, BBa_K1317002)


               2eme tests mecaniques le 25/09/2014

differents echantillons des ELP40 restants Echantillon 1.2 avec 2fois plus d’alginate  on ne remarque rien d’imporant il se casse vite 1.1 A  resiste plus longtemps avant de casser parcontre il y a une anomalie qui est du à la colle qui lui donne cet effet là 1.1 B  resultat aberant due aux differentes conditions de sechage ?!

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