SilverbladeTE
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actually a huge break through if they can create this on a commercial scale!
normally microscopes can only see very large cells, and cannot ever see things as tiny as viruses
which means complex methods have to be done ot image tiny objects (like viruses for ME research), such as electron miscroscopes...expensive and they kill living cells so you can't examine them as they "do their thing" as it were.
http://www.bbc.co.uk/news/science-environment-12612209
normally microscopes can only see very large cells, and cannot ever see things as tiny as viruses
which means complex methods have to be done ot image tiny objects (like viruses for ME research), such as electron miscroscopes...expensive and they kill living cells so you can't examine them as they "do their thing" as it were.
http://www.bbc.co.uk/news/science-environment-12612209
Microscope with 50-nanometre resolution demonstratedBy Jason Palmer
Science and technology reporter, BBC News
The technique can see features significantly smaller than prior efforts
Science closes in on perfect lens
UK researchers have demonstrated the highest-resolution optical microscope ever - aided by tiny glass beads.
The microscope imaged objects down to just 50 billionths of a metre to yield a never-before-seen, direct glimpse into the "nanoscopic" world.
The team says the method could even be used to view individual viruses.
Their technique, reported in Nature Communications, makes use of "evanescent waves", emitted very near an object and usually lost altogether.
Instead, the beads gather the light and re-focus it, channeling it into a standard microscope, allowing researchers to see with their own eyes a level of detail that is normally restricted to indirect methods such as atomic force microscopy or scanning electron microscopy.
Using visible light - the kind that we can see - to look at objects of this size is, in a sense, breaking light's rules.
Normally, the smallest object that can be seen is set by a physical property known as the diffraction limit.
Light waves naturally and inevitably "spread out" in such a way as to limit the degree to which they can be focused - or, equivalently, the size of the object that can be imaged.
At the surfaces of objects, these evanescent waves are also produced.
As the name implies, evanescent waves fade quickly with distance. But crucially, they are not subject to the diffraction limit - so if they can be captured, they hold promise for far higher resolution than standard imaging methods can provide.
Going viral
"Previously, people including ourselves have been using microspheres for focusing light for fabrication purposes, so we can machine features smaller than the diffraction limit," explained Lin Li, of the University of Manchester's Laser Processing Research Centre.
"It just came to my mind that if we reverse it, we might be able to see small features as well, so that is the reason we carried out this piece of research," he told BBC News.
Professor Li and his colleagues used glass beads measuring between two and nine millionths of a metre across, placed on the surfaces of their samples.
The beads gather up and re-focus light that normally fades away within nanometres of the sample The beads collect the light transmitted through the samples, gathering up the evanescent waves and focusing them in such a way that a standard microscope lens could pick them up.
The team imaged minuscule features in various solid samples and even the nanometre-scale grooves in Blu-Ray discs to show that the approach's resolution beat all previous records for optical microscopy.
But Professor Li thinks the technique holds great promise for biological studies, for which the action at the nanoscale is difficult to see directly.
"The area we think will be of interest will be looking at cells, bacteria, and even viruses," he said.
"Using the current technology, it is very time consuming; for example, using fluorescence optical micoscopy, it takes two days to prepare one sample and the success rate of that preparation is 10 to 20%. That illustrates the potential gain by introducing a direct method of observing cells."
Ortwin Hess of Imperial College London said that "it's really quite fascinating and exciting to see these effects coming together".
"If you use the fact that you do generate those (evanescent waves) and focus them again, then you have a tight focal point that you wouldn't normally expect to have," he told BBC News.
"It's quite a nice phenomenon that they've absolutely exploited."