Today I attended a meeting dedicated to nanobiology (another recent buzzword). One of the speakers, prof. Daniel Morse from UC Santa Barbara, talked about synthesis of nanostructures using silicatein. Silicatein is an enzyme extracted from marine glass sponges, that catalyzes synthesis of silica. Sponges use it to build their glass skeleton. Synthesis of glass occurs at low temperature and at neutral pH - not an easy task for human engineer! But, in experiments, metaloorganic compounds are used as silicatein substrates. Thus, it is possible to create complex patterned nanostructures. Can you imagine? Perhaps soon we will employ internal mechanisms of sponges or radiolarians to create structures that are not only beautiful, but also useful. Catalysts, sensors, microelectronics. What a wicked idea - but very cool!
Pictured are sponge spicules found in a sample of radiolarian ooze:
10x objective, darkfield
Sponge spicules and nanotechnology
Moderators: MacroMike, nzmacro, Ken Ramos, twebster, S. Alden
Hi Piotr
That's very interesting! You must've had a good time. Do you think the next step is to also synthesize the organic structure that controls the system? Did they cover how these micro structures would perform their tasks? Also, did you collect the Radiolarian sample yourself? I'm thinking about ordering a sample from Ward's Scientific.
http://www.wardsci.com/product.asp?pn=IG0002734
Thanks
Frez
That's very interesting! You must've had a good time. Do you think the next step is to also synthesize the organic structure that controls the system? Did they cover how these micro structures would perform their tasks? Also, did you collect the Radiolarian sample yourself? I'm thinking about ordering a sample from Ward's Scientific.
http://www.wardsci.com/product.asp?pn=IG0002734
Thanks
Frez
I'm sorry, Frez, for my late answer.
The Ward Science sample is very nice and I have it, too. This particular slide comes from a small set of Pacific Ocean radiolaria slides that I borrowed from the Scripps Institute of Oceanography. I contacted them some time ago and they were very friendly.
The organic structures are already there! The 3D structure of the protein is known and it is extremely interesting to make modifications in the protein in order to change properties of the product compounds. But, in fact, industry doesn't like organic structures when it comes to 'pure' applications, such as microelectronics. So they are trying to learn from nautre and re-create the protein mechanisms with inorganic compounds and nanotechnology... very cool.
The Ward Science sample is very nice and I have it, too. This particular slide comes from a small set of Pacific Ocean radiolaria slides that I borrowed from the Scripps Institute of Oceanography. I contacted them some time ago and they were very friendly.
The organic structures are already there! The 3D structure of the protein is known and it is extremely interesting to make modifications in the protein in order to change properties of the product compounds. But, in fact, industry doesn't like organic structures when it comes to 'pure' applications, such as microelectronics. So they are trying to learn from nautre and re-create the protein mechanisms with inorganic compounds and nanotechnology... very cool.
Piotr