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Revision as of 06:39, 19 October 2016
console.js:26
Week 4: June 8 2016
Wednesday, 6/8
Members Present: Kat, Hamed, Alex, Cathy, Dk, Tam
LAB:
Morning:
- Prepared LB broth to be autoclaved.
Afternoon:
- Autoclaved LB.
- Prepared SOC to be autoclaved.
TO DO:
For the next day:
LAB TEAM:
- Autoclave SOC
- Obtain DH10b from Kevin
- Redesign parts to make them IDT-compatible
LAB MANAGERS:
Purchase label maker
Label everything in the lab
Purchase stationery - sharpies, pens, whiteboard markers, baskets to organise these in drawers
Label MSDS files alphabetically
Ask Susie for ethanol burner for WB403
Gmail correspondence:
- Contact GE Health Life Sciences with regards to legitimacy of Heparin columns and syringe.
Meetings/Notes:
I-Tasser Updates:
Job ID: S277386 - GolS flag tag
Flag-tag appears to show no change in the metal ion binding pocket size. However it is uncertain as to whether it still retains a high level of affinity for Au ions or other ions. Given the residues are retained, GolS Flag-tag may not change its metal ion binding affinity.
Possibilities with 3D Printing of Proteins:
GolS and its variants can be 3D-printed for better visualization and depiction. Using PyMol, MeshLab and Makerbot Desktop to allow for 3D printing of our proteins. This allows for a better visualization of the protein.
Currently, attempts to convert proteins .pdb file to .x3g (3D printer friendly file).
Concerns for HiTrap Heparin Column:
GE Health Life Sciences provides general protocols for HiTrap Heparin Column usage with syringe. The HiTrap Heparin provider also includes instruction for other procedures.
Notes from meeting with Professor Vladimiros Papangelakis:
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Rare earth metals exist in very dilute amounts - 50 to 300 ppm
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High demand in industries (cellphones, etc) and high intensity magnets for electronic devices, space exploration, hybrid cars, basically high intensity magnetic field for a small compact instrument
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Biosensor not useful for commodity metals
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Useful application for rare earth metals
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Toxic - cyanide high selectivity to bind with gold and form ionic entities that are highly soluble; mix gold with NaCN and blow air + agitate to solubilise gold
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To avoid unwanted toxicity - alkaline pH (~9) to prevent formation of gaseous HCN which is volatile, use NaOH or limestone, then contain CN in liquid phase and alkaline for maximum safety
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Once gold is extracted, remaining cyanide decomposes under UV (solar) radiation and naturally occuring bacteria chew on cyanide to form CO2 and ammonia
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Chemical destruction by strong oxidants or mixture of sulphur dioxide and oxygen (industrial)
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Less efficient than cyanide method - chloride ion + air (always need an oxidant) and a ligand (CN- the best, Cl- 2nd best), more effective at high temperature but no guarantee that it will take out ALL the gold
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Gold chloride + HCl and stays soluble as long as there are no organics otherwise it will decompose because gold likes to exist in metallic form, not ionic form
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Slow leaching makes bigger gold NPs
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Keep ionic metal solutions at slightly acidic conditions or highly alkaline conditions - U shaped solubility curve vs pH
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Working with synthetic solutions is fine, but real world applications?
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Gold prospector needs to leach out the metal from the soil in order for the sensor to work as intended (Part 2, Part 1 is proof of concept of paper working) Cd, Hg, Arsenic, Selenium are toxic
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Heavy rare earths are the useful ones >18 atomic number; they all have extremely similar chemical properties, important if we can discover proteins that are sensitive and selective to rare earth metals
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Check concept: test on standard rare earth element (lanthanum) which is cheap too
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If it works on lanthanum, it would work in general. then we can test against other rare earth chlorides (better because soluble in mildly acidic conditions)
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He can give us some lanthanum
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Gold exists in 1 and 3 valence, in nature they exist in 3, other rare earths only exist in 3
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Maybe achieve selectivity at a different valence state?
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He's very encouraging :)
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Is okay with contacting him for further info, help with solution preparation