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<h2 class="h1 text-white mb-3">CAPOEIRA</h2> | <h2 class="h1 text-white mb-3">CAPOEIRA</h2> | ||
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<span class="btn-inner--text">Learn more about our project</span> | <span class="btn-inner--text">Learn more about our project</span> | ||
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“CAPOEIRA”, named after the Brazilian self-defense martial-art, exploits the potential of synthetic biology to develop a personalized, cost-effective, and rapid production scheme for cancer vaccine and point-of-care relapse surveillance. | “CAPOEIRA”, named after the Brazilian self-defense martial-art, exploits the potential of synthetic biology to develop a personalized, cost-effective, and rapid production scheme for cancer vaccine and point-of-care relapse surveillance. | ||
First, a bioinformatic pipeline integrating state-of-the-art tools identifies our targets: melanoma neoantigens, the fingerprints of cancer cells. Next, cell-free protein expression rapidly synthesizes a library of encapsulin protein nanocompartments | First, a bioinformatic pipeline integrating state-of-the-art tools identifies our targets: melanoma neoantigens, the fingerprints of cancer cells. Next, cell-free protein expression rapidly synthesizes a library of encapsulin protein nanocompartments | ||
− | presenting the various neoantigen epitopes. This encapsulin vaccine activates dendritic cells which trigger T- | + | presenting the various neoantigen epitopes. This encapsulin vaccine activates dendritic cells which trigger a T-cell attack on the neoantigen-bearing cancer cells. Nevertheless, we don’t underestimate a defeated villain! To detect potential |
relapse, we combine techniques including dumbbell probes, rolling circle amplification, isothermal amplification, and CRISPR-Cas12a to detect circulating tumor miRNA and DNA. Ultimately, CAPOEIRA trains the immune system to fight back! | relapse, we combine techniques including dumbbell probes, rolling circle amplification, isothermal amplification, and CRISPR-Cas12a to detect circulating tumor miRNA and DNA. Ultimately, CAPOEIRA trains the immune system to fight back! | ||
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<h2 class="text-center"><font size="+2">Dendritic cell Activation</font></h2> | <h2 class="text-center"><font size="+2">Dendritic cell Activation</font></h2> | ||
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− | <font size="+2">This encapsulin vaccine activates dendritic cells which trigger T-cell | + | <font size="+2">This encapsulin vaccine activates dendritic cells which trigger a T-cell attack on the neoantigen bearing cancer cells</font> |
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+ | <section class="slice slice-xl bg-cover bg-size--cover" style="background-image: url('https://static.igem.org/mediawiki/2018/4/4f/T--EPFL--TeamPage.jpeg'); background-position: center top;"> | ||
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+ | <h2 class="heading h1 text-white"> </br> </br> </br> Won: <span>Gold Medal</span></br> Nominated for: <span>Best Therapeutic Project</span> and <span>Best Software</br></ul></ui></h2> | ||
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+ | <a href="https://2018.igem.org/Team:EPFL/Awards" class="btn btn-white btn-primary btn-circle px-5">Our Awards!</a> | ||
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Latest revision as of 00:21, 8 December 2018
CAPOEIRA
CAncer PersOnalized Encapsulin Immunotherapy and Relapse Assay
Learn more about our projectWhat is CAPOEIRA ?
While Melanoma remains the deadliest form of skin cancer, immunotherapy approaches can harness our immune system to defeat it! Yet, current immuno-treatments suffer from high costs, limited accessibility, and poor specificity. Our project “CAPOEIRA”, named after the Brazilian self-defense martial-art, exploits the potential of synthetic biology to develop a personalized, cost-effective, and rapid production scheme for cancer vaccine and point-of-care relapse surveillance. First, a bioinformatic pipeline integrating state-of-the-art tools identifies our targets: melanoma neoantigens, the fingerprints of cancer cells. Next, cell-free protein expression rapidly synthesizes a library of encapsulin protein nanocompartments presenting the various neoantigen epitopes. This encapsulin vaccine activates dendritic cells which trigger a T-cell attack on the neoantigen-bearing cancer cells. Nevertheless, we don’t underestimate a defeated villain! To detect potential relapse, we combine techniques including dumbbell probes, rolling circle amplification, isothermal amplification, and CRISPR-Cas12a to detect circulating tumor miRNA and DNA. Ultimately, CAPOEIRA trains the immune system to fight back!
This is CAPOEIRA
Bioinformatics
First, a bioinformatic pipeline integrating state-of-the-art tools identifies our target: melonoma neoantigens, the fingerprints of cancer cells
Vaccine
Next, cell-free protein expression rapidly synthesizes a library of encapsulin protein nanocompartments presenting the various neoantigen epitopes
Dendritic cell Activation
This encapsulin vaccine activates dendritic cells which trigger a T-cell attack on the neoantigen bearing cancer cells
Follow-up
Nevertheless, we don't underestimate a defeated villain! To detect potential relapse we use techniques like CRISPR-Cas12a to detect circulationg tumor miRNA and DNA
Won: Gold Medal Nominated for: Best Therapeutic Project and Best Software