Difference between revisions of "Arsenic Prototype 4.0"

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(Testing the Electronics)
(Laser Cutting the Inner Pieces)
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==Step by Step Buildling==
==Step by Step Buildling==
===Laser Cutting the Inner Pieces===
===Laser Cutting the Inner Scaffold Pieces===
at chez [http://hackuarium.strikingly.com/ hackuarium] neighboring @make space of [http://www.univercite.ch/ univercité] - laser cutter model: Keyland KQG-1060 120W CO2 laser cutter
at chez [http://hackuarium.strikingly.com/ hackuarium] neighboring @make space of [http://www.univercite.ch/ univercité] - laser cutter model: Keyland KQG-1060 120W CO2 laser cutter

Revision as of 19:54, 5 January 2016


The Arsenic prototype v4.0 is the Winter School 2016 kit version of prototype 3.0.

The basis of the prototype remains the same - the bioreporter, a GMO bacteria expressing eGFP (Green Fluorescent Protein) is incubated with a water sample, where the fluorescence is detected optically and can be quantified in order to measure the concentration of Arsenic in the water

  • A vial containing the water sample we want to test is positioned on a socket through which a fluorescent excitation LED (blue 488nm for eGFP) passes.
  • GFP absorbs this blue light (λ=475 nm) and emits green light (λ=504 nm) which is detected by a photosensor on which the light is concentrated with the help of two lenses that avoid loss of intensity
  • A long-pass filter allow only the signal eGFP fluorescence to reach the photosensor

Moreover, a red LED was added to measure the transmittance, which can be converted into turbidity. The measurement of turbidity will allow us to normalize our results.

  • A red LED is placed in-line with the photosensor

We use an arduino to take the measurements, and we have a liquid crystal display (LCD) to read out the numbers.
With these measures, compared against a standard curve of water containing known arsenic concentrations, one can determine the concentration of arsenic in the sample and so know if the water is drinkable or not.

In summary, the most current version consists of:

   lasercut chassis
   blue LED for eGFP fluorescence excitation at 90 degrees from detector
   red LED for transmittance measurements in line with detector
   vial holder matching the vial approved by the Swiss authorities
   light to frequency detector
   a filter to block excitation light
   LCD screen read out
   based on the arduino


You can find the bill of materials here:

Step by Step Buildling

Laser Cutting the Inner Scaffold Pieces

at chez hackuarium neighboring @make space of univercité - laser cutter model: Keyland KQG-1060 120W CO2 laser cutter

Cutting Parameters for Material: HDF (MDF)
mode speed power scan mode interval
Groove LED (fluo) scan 50 (100) 35 x_unilat 0.1
3mm board cut 15 100
Text and Logo scan 250 (100) 25 x_unilat 0.3
Groove Lens scan 50 12 x_unilat 0.1
2mm board cut 35 100


Assembling the Electronics

There are four PCBs for:

  1. Blue LED (for the eGFP excitation)
  2. LCD screen
  3. Red LED (for the transmittance)
  4. Light to frequency meter (to detect the light)

Each of the PCBs except the LCD screen PCB are fixed onto the lasercut fiber boards using M3 screws.

Soldering and Mounting

Blue LED

Blue LED PCB and parts.png

Soldering the pieces:

Blue LED 10.jpg
10. ready for mounting

Now mounting onto the particle board:

LCD screen

This LCD screen / arduino shield will connect to the blue LED PCB with a ribbon cable
LCD PCB and parts.png

Soldering the pieces:

LCD 09.jpg
9. done soldering


Red LED PCB and parts.png

light to frequency meter

LFD PCB and parts.png

Final Assembly

Finally, the Red LED and light to frequency meter will be plugged into the Blue LED board with connectors.
Final assembly 1.JPG

Then the LCD screen is plugged into the Blue LED board with a ribbon cable.
Final assembly 2.JPG

The LCD screen board is ready to be mounted on the arduino.

We are now ready to test it out.

Testing the Electronics

Uploading the arduino code

Reading the measurements

Transmittance and absorbance

Making the Outer Housing

What we have built so far leaves the samples exposed to ambient light. So we need to make outer housing that can mount the LCD screen, house the battery, enclose the rig inside, and have easy access to put the samples in and out while keeping the light and optics dark.

Links other References