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=Photos, Algorithms and Art=
=Photos and Art=
=Tools and Demonstrations=
=Algorithms, Tools and Demonstrations=
=About=
=About=
The Bangham Lab is part of the [http://www.uea.ac.uk/cmp/research/cmpbio UEA D’Arcy Thompson Centre] for computational biology.
The Bangham Lab is part of the [http://www.uea.ac.uk/cmp/research/cmpbio| <span style="color:DarkSlateGray;">UEA D’Arcy Thompson Centre<!span>] for computational biology and collaborates closely with [[http://rico-coen.jic.ac.uk/index.php/Main_Page|<span style="color:DarkSlateGray;">the Coen Lab, John Innes Centre</span>]]
--[[User:AndrewBangham|Andrew]] 09:50, 4 May 2011 (UTC)
--[[User:AndrewBangham|Andrew]] 09:50, 4 May 2011 (UTC)

Revision as of 10:04, 4 May 2011

The Bangham Lab

Computational Biology

The aim is to understand how patterns of gene activity in biological organs influence the developing shape.

<sgallery width="140" height="200" showarrows="false" showcarousel="false" showinfopane="false" timed="true" delay="2000"> LabelledCropped_GPT_Snapdragon_2010-000250-0001.png LabelledCropped_GPT_Snapdragon_2010-000340-0001.png LabelledCropped_GPT_Snapdragon_2010-000490-0001.png LabelledCropped_GPT_Snapdragon_2010-000570-0002.png LabelledCropped_GPT_Snapdragon_2010-000570-0003.png LabelledCropped_GPT_Snapdragon_2010-000570-0004.png LabelledCropped_GPT_Snapdragon_2010-000570-0005.png LabelledCropped_GPT_Snapdragon_2010-000570-0007.png LabelledCropped_GPT_Snapdragon_2010-000570-0006.png LabelledCropped_GPT_Snapdragon_2010-000570-0001.png </sgallery>

More Snapdragon model

Genes and growing shapes

  • Observed: patterns of gene activity regulate tissue growth.
  • Hypothesis: gene activity independently regulates direction of growth.
  • Formalised in the Growing Polarised Tissue Framework (cite).
  • Implemented in GFtbox (cite) for developing ideas on growth and form.
    • Start with a sheet of tissue (the canvas) with observed, or hypothetical patterns of growth factor activity.
    • Grow the canvas in 3D under constraints of tissue continuity
    • Compare with observed data quantitatively

Downloads and more details on GFtbox

<sgallery width="140" height="200" showarrows="false" showcarousel="false" showinfopane="false" timed="true" delay="3000"> LabelledCropped GPT Snapdragon 2010-000570-0003 double.png LabelledCropped GPT Snapdragon 2010-000570-0002 triple.png LabelledCropped GPT Snapdragon 2010-000570-0001-Wildtype.png </sgallery>

More on testing models

<sgallery width="140" height="200" showarrows="false" showcarousel="false" showinfopane="false" timed="true" delay="1500"> Arabidopsis_Leaf_ATH8bbg.png Antirrhinum flower small1.jpg Antirrhinum flower small2.jpg Antirrhinum flower small3.jpg Anthers1.jpg MacroOPTIris1.jpg </sgallery>

More on visualising 3D

Working with 3D volume images

  • Three dimensional (3D) volume images are key to understanding the development of shape.
  • Produced by
    • CT X-ray scanners, MRI and PET.
    • Confocal microscopy and OPT (cite) used with fluorescent probes that monitor biological gene activity.
    • Huge amounts of data potentially make viewing slow, but...
  • Implemented VolViewer (cite) which exploits powerful graphics processors.
  • Works with BioformatsConverter to read open and proprietary file formats
Downloads and more details on VolViewer

<sgallery width="140" height="200" showarrows="false" showcarousel="false" showinfopane="false" timed="true" delay="4000"> Arabidopsis_Leaf_ATH8bbg.png </sgallery>

More on 3D measurement

Photos and Art

Algorithms, Tools and Demonstrations

About

The Bangham Lab is part of the UEA D’Arcy Thompson Centre<!span> for computational biology and collaborates closely with [the Coen Lab, John Innes Centre] --Andrew 09:50, 4 May 2011 (UTC)