https://wiki.blender.jp/index.php?action=history&feed=atom&title=Community%3AScience%2FBiology%2FStructuralBiology%2FBioBlenderCommunity:Science/Biology/StructuralBiology/BioBlender - 版の履歴2026-05-24T19:06:26Zこのウィキのこのページに関する変更履歴MediaWiki 1.31.0https://wiki.blender.jp/index.php?title=Community:Science/Biology/StructuralBiology/BioBlender&diff=109887&oldid=prevYamyam: 1版 をインポートしました2018-06-28T19:48:33Z<p>1版 をインポートしました</p>
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<td colspan="1" style="background-color: #fff; color: #222; text-align: center;">← 古い版</td>
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</td></tr></table>Yamyamhttps://wiki.blender.jp/index.php?title=Community:Science/Biology/StructuralBiology/BioBlender&diff=109886&oldid=prev2012年7月11日 (水) 09:47にwiki>Citrohan la vendettaによる2012-07-11T09:47:00Z<p></p>
<p><b>新規ページ</b></p><div>=BioBlender= <br />
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(page under construction, Nov. 2011)<br />
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BioBlender is made and maintained by SciVis, in Pisa Italy. The dedicated website, for specific comments, blogs, news tutorial etc, is http://www.bioblender.eu<br />
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BioBlender contains a set of functionalities aimed at two tasks in handling atomic data: elaboration of motion and surface visualization, using a specific visual code. For both tasks, the basis is a pdb file<br />
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The starting material is ALWAYS a pdb file (or a file written in .pdb format, with atoms, atoms type, their 3D coordinates all nicely formatted). <br />
The first thing to do is select it: in the field BioBlender Import type the 4 letter code of a pdb to be fetched from the Protein Data Bank, or the path to your file, or press the folder icon to open a file browser.<br />
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BioBlender reads the file and report its contents:<br />
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the number of chains, typically 1, (or more for a complex solved by X-ray), and called A, B, C or sometimes a more meaningful letter<br />
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the number of MODELS: 1 for X-ray and typically between 10 and 50 for NMR files.<br />
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{{Note|Note| if the file is not formatted according to the pdb specifications, BioBlender will not work}}<br />
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Before importing, select which models and their order, set the Number of frames that Blender will use to interpolate in the {{Shortcut/Keypress|Keyframe Interval}}, check the options necessary for your work, and press {{Shortcut/Keypress|Import PDB}} <br />
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If you imported more than one .pdb file, BioBlender will upload them, and directly interpolate each atom between the conformations. However, if the option {{Shortcut/Keypress|MakeBonds}} was checked, BioBlender can use the game engine and make a better interpolation, by pressing {{Shortcut/Keypress|Run in Game Engine}}.<br />
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By selecting {{Shortcut/Keypress|Collisions 1}}, Blender GE will calculate the movement considering:<br />
- The direction of the motion (linear, set in the IPO)<br />
- The collision factor<br />
- The rigid body joint, that allows only to rotate atoms along their bond axis<br />
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{{Note|Note| For movement of better quality set a long keyframe interval (100 frames or more)}}<br />
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By selecting {{Shortcut/Keypress|Collisions 2}}, all frames calculated by the GE will be recorded, look 200 frames downstream from the frame of your last conformation.<br />
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Now you have all atoms keyframed, and can use this data to: {{Shortcut/Keypress|Export}} data (set your preferences and the path to save the new pdb files), or use them for the visualization, using the BioBlender visual code.<br />
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For the MLP visualization choose a {{Shortcut/Keypress|Formula}}, set the {{Shortcut/Keypress|Grid Spacing}} (expressed in Å) and press {{Shortcut/Keypress|Show MLP on Surface}}. MLP is calculated in every point of a grid in the protein space and visualized on the surface of the protein as grey levels (light areas for hydrophobic and dark areas for hydrophilic).<br />
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{{Shortcut/Keypress|Contrast}} and {{Shortcut/Keypress|Brightness}} sliders can be used to enhance the visualization of MLP. Once the representation is satisfactory, press {{Shortcut/Keypress|Render MLP to Surface}}for a photo-realistic rendering and press {{Shortcut/Keypress|F12}} to render it.<br />
Our novel code for the representation of MLP is a range of optical features that goes from shiny-smooth surfaces for hydrophobic areas to dull-rough surfaces for hydrophilic ones.<br />
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For the EP visualization choose a {{Shortcut/Keypress|Formula}}, set the {{Shortcut/Keypress|Ion concentration}}, the {{Shortcut/Keypress|Grid Spacing}} (expressed in Å), the {{Shortcut/Keypress|Minimum Potential}} (the minimum value for which the field lines are calculated), the {{Shortcut/Keypress|n EP lines*eV/Ų}} (the number of field lines calculated<br />
for eV/Ų) and press {{Shortcut/Keypress|Show EP}}.<br />
EP is calculated using external programs and visualized as small particles flowing along the field lines (NURBS curves in Blender) from the positive to the negative end.<br />
If you want to change a setting and re-calculate EP, {{Shortcut/Keypress|Clear EP}} and follow the previous steps. <br />
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{{WikiTask/Inprogress|10|just started}} BioBlender wiki</div>wiki>Citrohan la vendetta