The microscope allows students to connect iPad or iOS devices directly to the device using the free AirMicroPro app.
A digital USB
microscope allows you to display images on a projector screen, so all students can see the same image simultaneously.
This highly sensitive
microscope allows scientists to obtain much sharper three - dimensional images, even in very low light.
The new stimulated Raman scattering (SRS)
microscope allows us to see the edges of a tumor in a few seconds instead of waiting the 30 - 45 minutes it usually takes for a frozen tumor section to be developed.
A new
microscope allows three - dimensional imaging of living systems at very high resolution in real time.
The first
microscope allows researchers to obtain fast moving images at double the spatial resolution of a conventional microscope.
«Super-resolution
microscope allows visualization of the mechanism that maintains cell polarity: The key is to repeatedly establish temporary polarity.»
A camera attached to
a microscope allowed the researchers to record the tumors invading the artificial blood vessel.
A high - resolution
microscope allowed the neuroscientists to direct the light beam directly to a specific dendrite.
Modern
microscopes allow us to acquire high quality images of large fields of view.
State - of - the - art light - sheet and confocal
microscopes allow recording of entire embryos in 3D and over time (3D + t) for many hours.
Inverted
microscopes allow the imaging of live cells in culture acquiring either still photos or time - lapse movies.
High - powered
microscopes allowed visitors to see small objects and organisms at high magnification.
This positions the cilia within the 200 - nanometer reach of the total internal reflection fluorescence
microscope allowing for the imaging of individual proteins as they move inside the cilia.
Microscopes allow us to see structures that are otherwise invisible to the human eye.
Haber proceeds to discuss how tools like a Geiger counter and
a microscope allow us to explore things that are unnoticeable to the human eye.
Not exact matches
Electron
microscope photography
allows the demonstration of a good versus poor coating, which would not be revealed in an assay.
less physical league so he'll adjust quicker while regaining his fitness, and also he'll not be under the
microscope of the British media n fans so he'll be
allowed to focus on his football.
A modern
microscope that adds a smartphone adapter which
allows teenagers to take photos and videos of the tiniest objects.
Like a biologist's
microscope or a geographer's GPS, assistive technologies
allow scientists to extend their capabilities.
We have our first electron
microscope working now and, while we are waiting for a second instrument to arrive in 18 months, we are developing and debugging the
microscope, looking at samples for «friends and family,» and organising the process of
allowing more general access.
The
microscope's nanometer resolution will
allow researchers to track particles floating in colloidal solutions (for example, nanoscale beads floating in a sample of paint) using equipment that is at least a tenth of the cost of an electron
microscope.
Only with this experimental set - up is it possible to measure the tiny forces between
microscope tip and noble gas atom, as a pure metal surface would
allow the noble gas atoms to slide around.
Juan Carlos Cuevas at the Autonomous University of Madrid in Spain and his colleagues modified a scanning tunnelling
microscope — which
allows the manipulation and imaging of atoms — to trap a ring of benzene between the probing tip of the
microscope and a flat gold surface.
«I think of a
microscope as something that
allows you to image things on the micron scale,» he said.
Veeraraghavan said SAVI leans on work by the California Institute of Technology and the University of California, Berkeley, which developed the Fourier ptychography technique that
allows microscopes to resolve images beyond the physical limitations of their optics.
The biopsies were thinly sliced and stained with a dye called Congo red that
allowed the researchers to view the protein clumps in the layers of skin or within the sweat glands and pilomotor muscles (those that cause goose bumps) under the
microscope.
That structure is three dimensional, and beginning in the 1970s Frank developed a mathematical image - processing method that
allowed a computer to merge several two - dimensional electron
microscope images into a sharp 3 - D picture.
Physicists from Ludwig - Maximilians - Universitaet (LMU) in Munich have developed an attosecond electron
microscope that
allows them to visualize the dispersion of light in time and space, and observe the motions of electrons in atoms.
It was around this time — in 1671, specifically — that Anton van Leeuwenhoek, a Dutch fabric merchant in Delft, developed a new but far less ornate
microscope with smaller, simpler and, ironically, better optics that
allowed much higher magnification without the distortion of the more complicated, expensive instruments.
Some
microscopes aren't just a window to a world invisible to the naked eye — they
allow scientists to probe a bumpy molecular landscape by feel.
Zebrafish embryos have transparent brains, which
allowed Peri and her team to track the microglia in real time under the
microscope.
Using scanning tunnelling
microscopes, scientists at TU Vienna have now been able to image the catalytic behaviour of platinum sitting on iron - oxide, which
allowed them to explain the process on an atomic scale.
A powerful X-ray tomography scanner
allowed the researchers to image particularly thick sections of the brains of mice, which afforded them views into intact neural areas much larger than are customary in
microscope imaging.
Konradt used Penn Vet's multi-photon
microscope, which
allows them to peer deep into living tissues without damaging them, to try to witness the parasite's invasion in action.
That
microscope had a split screen that
allowed Goddard to compare bullets or cartridge cases, the metal cases a gun ejects after firing a bullet, side by side.
The technique is «very important,» he says, because it will extend the capabilities of conventional electron
microscopes and should
allow «atom - by - atom magnetic analysis in the near future.»
The technique
allows more information to be harvested from fluid, tissue and other samples, but not everyone has access to an optical
microscope that can use fluorescence.
For example, the wide - field multi-view
microscope clearly resolved the spherical protein shell present when Bacillus subtilis forms a spore and also
allowed the researchers to observe the dynamics of organelles inside cells.
Key to the researchers» efforts to track oxytocin at work in individual brain cells was use of an antibody developed at NYU Langone that specifically binds to oxytocin - receptor proteins on each neuron,
allowing the cells to be seen with a
microscope.
The increased speed at which the new dual
microscope can image the cells
allows for clearer images of even very fast moving viruses.
They examined the structure and proteins in the clam's tiny eyes using a powerful
microscope and concluded that its vision is likely too poor to
allow it to observe displays by other clams.
Better yet, the fluorescent signal persists for hours after the communication event,
allowing researchers to study the brain's activity after the fact, under a
microscope.
When viewed under a
microscope, details like internal muscle structure were visible,
allowing the team to calculate the range of movement of the limbs.
«This
allowed us to examine the interactions of the florescent integrase under the light
microscope both in vitro in a single HIV virion as well as in a human cell infected with it.»
This added flexibility
allows us to collect information faster and
allows our
microscope to work in near - native conditions in fluid like those found in the cell, yielding more realistic results.»
A US - Chinese team of nanotechnologists used a specially outfitted transmission electron
microscope to capture the footage,
allowing the effect of electrical charging on nanostructures to be seen in action for the first time.
An automated
microscope takes images every 20 minutes at multiple locations in the microfluidic device, and multiple devices at once,
allowing for the tracking of dozens of cells in one experiment.
In 2013, a team led by Gradinaru together with Karl Deisseroth of Stanford University in California reported a method that strips away fats and other molecules to make intact brain tissue transparent,
allowing thick sections to be imaged with a light
microscope (see «See - through brains clarify connections»).
The key technologies that enabled this finding included a molecular sensor that the group developed to track activity of TrkB, and
microscopes that
allowed them to visualize a single spine in the area of living mouse brain tissue, all in real time.