|
|
(One intermediate revision by one other user not shown) |
Line 48: |
Line 48: |
| <div class="text"> | | <div class="text"> |
| <b>Presented by DTU BioBuilders 2020</b> | | <b>Presented by DTU BioBuilders 2020</b> |
− | <p style="font-size:13px">Daniel Bavnhøj<sup>a</sup>, Peter Bing<sup>a</sup>, Clara Drachmann<sup>b</sup>, Martí M. Gómez<sup>b</sup>, Cecilia D. V. Graae<sup>a</sup>, Bira A. Khan<sup>a</sup>, Niels M. Knudsen<sup>a</sup>, Lucas Levassor<sup>a</sup>, Margrethe Mærsk-Møller<sup>b</sup>, Victoria V. Nissen<sup>a</sup>, Christine Pedersen<sup>a</sup>, Cecilie A. N. Thystrup<sup>b</sup>, Timian Rindal<sup>a</sup> </p> | + | <p style="font-size:13px">Daniel Bavnhøj<sup>a</sup>, Peter Bing<sup>a</sup>, Clara Drachmann<sup>b</sup>, Martí M. Gómez<sup>b</sup>, Cecilia D. V. Graae<sup>a</sup>, Bira A. Khan<sup>a</sup>, Niels MK<sup>a</sup>, Lucas Levassor<sup>a</sup>, Margrethe Mærsk-Møller<sup>b</sup>, Victoria V. Nissen<sup>a</sup>, Christine Pedersen<sup>a</sup>, Cecilie A. N. Thystrup<sup>b</sup>, Timian Rindal<sup>a</sup> </p> |
| <p style="font-size:10px"> <sup>a</sup>DTU Bioengineering, <sup>b</sup>DTU Health Tech, Technical University of Denmark </p> | | <p style="font-size:10px"> <sup>a</sup>DTU Bioengineering, <sup>b</sup>DTU Health Tech, Technical University of Denmark </p> |
| <br> | | <br> |
Line 154: |
Line 154: |
| <center><figure> <img style="width:80%" src="https://static.igem.org/mediawiki/2020/5/53/T--DTU-Denmark--Poster_imageana.png" class="center"><figcaption><p align="justify"><i> Showcase of our first model, Morphologizer. The model analyzes microscope images of mycelia, converts them into graph objects, and extracts morphological features of interest from the graph, such as the number of branches, branching angles, and hyphal curvature. </i></p></figcaption></figure></center> | | <center><figure> <img style="width:80%" src="https://static.igem.org/mediawiki/2020/5/53/T--DTU-Denmark--Poster_imageana.png" class="center"><figcaption><p align="justify"><i> Showcase of our first model, Morphologizer. The model analyzes microscope images of mycelia, converts them into graph objects, and extracts morphological features of interest from the graph, such as the number of branches, branching angles, and hyphal curvature. </i></p></figcaption></figure></center> |
| | | |
− | <center><figure> <img style="width:80%" src="https://static.igem.org/mediawiki/2020/0/06/T--DTU-Denmark--Poster_ATCC.gif" class="center"><figcaption><p align="justify"><i> Here, we demonstrate our final simulation of ATCC 1015 based on parameters obtained from both experimental measurements and microscopic image analysis. The substrate gradient is shown in green, i.e. the greener the higher substrate concentration and the mycelium is shown in purple with newer hyphal elements in lighter colors. </i></p></figcaption></figure></center> | + | <center><figure> <img style="width:80%" src="https://static.igem.org/mediawiki/2020/0/06/T--DTU-Denmark--Poster_ATCC.gif" class="center"><figcaption><p align="justify"><i>Showcase of our second model, Mycemulator. A stochastic simulation of background strain ATCC 1015 based on parameters obtained from both experimental measurements and microscopic image analysis. The substrate gradient is shown in green, i.e. the greener the higher substrate concentration and the mycelium is shown in purple with newer hyphal elements in lighter colors. </i></p></figcaption></figure></center> |
| </div> | | </div> |
| </div> | | </div> |