MediaWiki API result
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{
"batchcomplete": "",
"continue": {
"gapcontinue": "SensNC_2018",
"continue": "gapcontinue||"
},
"query": {
"pages": {
"35": {
"pageid": 35,
"ns": 0,
"title": "Sandbox",
"revisions": [
{
"contentformat": "text/x-wiki",
"contentmodel": "wikitext",
"*": "[[File:sandbox.jpg|200px|thumb|right|Logo of Team Sanbox]]\n\n\n== Team Sandbox 2018 ==\n\n\nTeam Sandbox is a team competing in Sensus 2018, its university is the TU Eindhoven. For Sensus 2018, Team Sandbox investigated the possibilities for creating a biosensor which is able to measure the concentration of [[Vancomycin]]. The full TRD can be found [https://digital.sensus.org/storage/264/Team-Results-Document---AUC.pdf via this link]\n\n== Method ==\n\nSpectrophotometry (Light absorbtion). Vanomycin has the property that it absorbs photons of a specific wavelength, the strength of the absorbtion is the dependant on the concentration. By looking at the transmission for a specific wavelenght of light the concentration of Vanomycin can be determined.\n\n==Molecular Recognition ==\n\nThe detection method is based on the absorbance properties that vancomycin possesses. \n\n== Physical Transduction ==\n\nUV light (280 nm) was immited on a quartz cuvette. The light that is not absorbed passes through an optical filter (bandpass filter with center wavelength 300 nm) which then falls on a sicilone detector.\n\n== Cartridge ==\n\nTo plasma spiked with vancomycin, trichloroacetic acid (TCA) is added. The mixture is then centrifuged at 15000 rpm for 3 mins to separated proteins from plasma. Then, the supernatant is seperated from the precipitated proteins, and diluted to 1:10 volume ratio.\n\n== Reader Instrument ==\n\nNo information is given\n\n== Prizes==\n\nPublic Inspiation Award"
}
]
},
"42": {
"pageid": 42,
"ns": 0,
"title": "SensImperial 2018",
"revisions": [
{
"contentformat": "text/x-wiki",
"contentmodel": "wikitext",
"*": "[[File:Imperial.png|200px|thumb|right|Logo of Imperial College of London]]\n\n\n== SensImperial 2018 ==\n\n\nSensImperial is a team competing in Sensus 2018, its university is the Imperial College of London. For Sensus 2018, Team SensImperial investigated the possibilities for creating a biosensor which is able to measure the concentration of [[Vancomycin]]. The full TRD can be found [https://digital.sensus.org/storage/258/Team-Results-Document---SensImperial.pdf via this link]\n\n== Method ==\n\nCompetitive Lateral Flow Assay\n\n==Molecular Recognition ==\n\nThe detection method uses a large complex with a gold nanoparticle at the centre and vancomyocin and biotin on the outside, which have a bright red colour. When vancomyocin is present, this large complex is displaced from its original position on an vancomyocin antibody and binds to a line of streptavidin. This change in colour intensity signals the amount of vancomyocin in the serum\n\n== Physical Transduction ==\n\nThe change in colour is detected by an app running a neural network, which is taught to detect the change in colour and convert it into a particular concentration of vancomyocin. \n\n== Cartridge ==\n\nThe plasma is pipetted onto the membrane, which then travels up the membrane, where it picks up the large complex and encounters the two lines of antibodies and streptavidin.\n\n== Reader Instrument ==\n\nThe reader is the mobile phone with the app, where the concentration is measured and saved"
}
]
}
}
}
}