Line 85: | Line 85: | ||
<h5>About us</h5> | <h5>About us</h5> | ||
<ul id="footer-item"> | <ul id="footer-item"> | ||
− | <li><a style="font-size:16px | + | <li><a style="font-size:16px;" href="mailto:dtubiobuilders@gmail.com">dtubiobuilders@gmail.com</a></li> |
<li><i class="fa fa-map-marker"></i><a style="font-size: 16px;list-style-type: none;" href="https://www.google.dk/maps/@55.7854419,12.5196676,16z"> Anker Engelunds Vej 1 Bygning 101A, 2800 Kgs. Lyngby, Denmark</a></li> | <li><i class="fa fa-map-marker"></i><a style="font-size: 16px;list-style-type: none;" href="https://www.google.dk/maps/@55.7854419,12.5196676,16z"> Anker Engelunds Vej 1 Bygning 101A, 2800 Kgs. Lyngby, Denmark</a></li> | ||
Revision as of 10:50, 23 September 2018
Building Mycotextures
The DTU biobuilders are looking forward to enter iGEM once again! This year, we are working to develop a toolbox so properties of fungi can be manipulated and exploited to build fungal materials.
Project Description
For millennia humans have known the value of fungi whether it be the yeast we cultivate for bread, beer and wine, or the mushrooms that serve both as a source of nutrition and natural medicinal compounds. However, the fungi we find on the forest floor are only the fruit of a much larger fungal organism, which stays unseen as a complex network of fungal mycelia that stretches far and wide underground.
Briefly summarised, composite fungal biomaterials are generally rapidly generated, renewable, biodegradable, naturally fire resistant, non-polluting and can be produced from the waste of other industries, be it spent grain from a brewery or discarded furniture from Ikea. For this reason, fungal biomaterials can come to play a significant role in fulfilling the demand for new sustainable materials. Frontrunner companies such as Ecovative and Mycoworks are currently exploring the potential use of fungal mycelia to make insulation materials, foams, fibreboards, bricks and even fungal leather.
Our project will focus on exploring how synthetic biology can advance the field of fungal biomaterials by targeting genes relevant to the morphology and physical properties of the mycelium. For one, we aim to promote the expression of chitin (what insects shells are made of) in the fungus Pleurotus ostreatus to make its mycelium stronger. Furthermore, due to interest from our collaborators at NASA, we also aim introduce the biosynthetic pathway for melanin such that we can produce UV-resistant biomaterials, which will be important in the context of extraterrestrial construction materials.
Contact us on: dtubiobuilders@gmail.com.