In another demonstration of the ripple effect created by a single, RPB - supported investigation, researchers, using
a new microscopy technique focused on eye tissues damaged by scarring in diabetic patients, have...
«Revolutionary
new microscopy technology provided thru Park Systems AFM (Atomic Force Microscopy) and new innovations in chemical and material research indicates that there is a defined opportunity to use the advances in chemistry, materials, and nanoscience to make valuable industry process updates.»
Scientists have developed and implemented
a new microscopy method that allows resolution of three - dimensional structures to 10 - 20 nm throughout entire cells, in samples up to 10 microns thick.
In addition, they hope to take the spatial recognition experiments to the next level using
a new microscopy technology that could show simultaneous activity in both subclasses of pyramidal cells in a freely moving mouse.
Amazingly,
a new microscopy technique described in the journal Science on Friday makes those deep dives possible, and there are gorgeous videos to prove it.
«Using
new microscopy techniques, we could show that the receptor of a well known growth factor, EGF, plays an important role in tight junction barrier formation in the epidermis.
Powerful
new microscopy techniques enable researchers to observe the whole process in living cells, with bright fluorescent tags highlighting the chromosomes and other cellular components.
«We offer PRISM as
a new microscopy tool and anticipate that it will be rapidly used in the life science community to expand the scope for 3D high - speed imaging for biological investigations,» says Theo Lasser.
After the formal announcement, Sven Lidin, chair of the Nobel Chemistry Committee, explained the importance of
the new microscopy in chemistry.
The team has named
the new microscopy platform PRISM, for Phase Retrieval Instrument with Super-resolution Microscopy.
To find answers, Columbia researchers developed
a new microscopy technique that allows for the direct tracking of fatty acids after they've been absorbed into living cells.
It's not reruns of «The Jetsons,» but researchers working at the National Institute of Standards and Technology (NIST) have developed
a new microscopy technique that uses a process similar to how an old tube television produces a picture — cathodoluminescence — to image nanoscale features.
The discovery was made through a University of Cambridge collaboration between the Sainsbury Laboratory Cambridge University microscopy facility and Cambridge University Botanic Garden, as part of an ongoing research project that is probing the inner workings of plants in the Garden using
new microscopy technologies.
Much like in an old tube television where a beam of electrons moves over a phosphor screen to create images,
the new microscopy technique works by scanning a beam of electrons over a sample that has been coated with specially engineered quantum dots.
Besides devising unique ways to analyze conventional cell images, researchers are also using
new microscopy techniques to better define cell shapes.
Live cells are highly sensitive to their surroundings, so
the new microscopy strategy — which replaces glass slides with blocks of collagen — could help reveal more natural behaviors.
NSF provides state - of - the - art imaging tools to academic labs; supports efforts to develop
new microscopy techniques; and funds training for young scientists and engineers in the field.
At that point,
new microscopy technology and the germ theory of disease had revolutionized medicine.
Using a relatively
new microscopy technique called atom probe tomography, their work produced the first - ever three - dimensional maps showing the positions of atoms critical in the decay process.
Not exact matches
«SUNY Poly is thrilled that a worldwide leader in atomic force
microscopy is selecting the campus for its
newest location, and we warmly welcome Park Systems as we look forward to working closely to advance research capabilities in this important area,» SUNY Poly Interim President Bahgat Sammakia said.
For the current study, working in the CU Cancer Center Advanced Light
Microscopy Core, co-authors Dominik Stitch, PhD, and Radu Moldovan, PhD, implemented a
new technique known intravital multiphoton in vivo
microscopy that enabled the team to watch fluorescent - tagged liposomes in real - time after injection.
This
new development paves the way for a
new field of dynamical study in the position dependence of atomic vibration in small particles, and is also likely to benefit the catalytical study of particles.Richard Aveyard, Postdoctoral Research Associate in the Department of Physics at York, said: «Our work highlights the valuable contribution that computational simulations can have in the field of electron
microscopy: the more details we can put into our simulations, the more details we can extract from experiments.»
Biophysicist Hyungsik Lim at Hunter College, City University of
New York, uses third harmonic generation (THG)
microscopy to image myelin — the «insulation» around nerve «wires» — in live cultures and tissues without adding any labels.
These
new, non-invasive tools — representing significant advances related to positron emission tomography (PET), 3 - D
microscopy and the use of magnetic fields and nanoparticles to remotely control targeted cells...
In doing so, the researchers have demonstrated that they can still push ahead into
new fields using atomic force
microscopy, which was developed exactly 30 years ago.
TOUGH STUFF A
new wood - compacting process crushes the gaps between cell walls in natural wood (porous structure seen in the scanning electron
microscopy image, left), making the densified wood (right) as strong as steel.
Room - temperature investigations apply several techniques (polarization
microscopy, single - molecule imaging, emission time dependence, energy transfer, lifetime studies, and the like) to a growing array of biophysical problems where
new insight may be gained from direct observations of hidden static and dynamic inhomogeneity.
The
new 3 - D structure, which was obtained using X-ray crystallography and electron
microscopy, revealed that the outer surface of the Zika NS1 protein has substantially different electrical - charge properties than those of other flaviviruses — indicating it may interact differently with the members of an infected person's immune system.
«For developing cryo - electron
microscopy for the high - resolution structure determination of biomolecules in solution,» the Royal Swedish Academy of Sciences awarded the Chemistry Prize to Jacques Dubochet of the University of Lausanne in Switzerland, Joachim Frank of Columbia University in
New York City, and Richard Henderson of the MRC Laboratory of Molecular Biology in Cambridge, England.
«We applied a
new technique called X-ray fluorescence
microscopy — it looks at elemental composition,» said Marshall.
Now a research team led by Dr. Peter Baum and Dr. Yuya Morimoto at LMU Munich and the Max Planck Institute for Quantum Optics (MPQ) has developed a
new mode of electron
microscopy, which enables one to observe this fundamental interaction in real time and real space.
A transmission electron
microscopy image of the
new material SAM2X5 - 630 shows the metallic compound's disorganized inner structure, usually a hallmark of glass.
«What's
new is the application of [force
microscopy] to the nanomechanical properties of biological structure,» says Sergei Magonov, a staff scientist at Digital Instruments, a company that makes force microscopes.
The polymer that absorbs wetness in a diaper is now a critical element of a
new imaging approach called expansion
microscopy.
«This is a
new type of imaging, combining single - molecule spectral measurement with super-resolution
microscopy.»
A
new nanopatterning technique combines the advantages of near - field
microscopy with photolithography.
«When shallow defects align, diamonds shine for unprecedented quantum sensitivity: Researchers demonstrate a
new way to produce high - density clusters of aligned quantum sensors in diamond just nanometers from the surface, offering submolecular sensitivity to
microscopy like never before.»
«
New X-Ray
microscopy technique images nanoscale workings of rechargeable batteries: Method could help researchers improve battery performance.»
«Major innovation in molecular imaging delivers spatial and spectral info simultaneously: Combines spectroscopy with super-resolution
microscopy, enabling
new ways to examine cell structures.»
Researchers at Columbia University have reported a
new approach to visualize glucose uptake activity in single living cells by light
microscopy with minimum disturbance.
The researchers have also been able to couple their
new meso - level imaging technique with extremely detailed electron
microscopy.
The
new method combines two types of
microscopy.
A
new support for biological specimens improves the resolution that can be achieved by electron
microscopy.
It also utilizes
new techniques that allow three - dimensional analysis of fluorescent embryonic skeletons, using advanced spin - disc confocal
microscopy and software.
Researchers of Karlsruhe Institute of Technology (KIT) have developed a
new fluorescence
microscopy method: STEDD (Stimulation Emission Double Depletion) nanoscopy produces images of highest resolution with suppressed background.
«It's opened up the horizons of
microscopy to
new techniques, especially in the biological sciences.»
The
new technique, dubbed photoactivated localization
microscopy, currently has a resolution similar to that of electron
microscopy.
«
New quantum dot technique combines best of optical and electron
microscopy.»
This
new technique was made possible by the development in recent years of single - molecule
microscopy, which enables scientists to peer into the nano - world by turning the fluorescence of individual molecules on and off.
The breakthrough came with a
new imaging technique, dual - resonance - frequency - enhanced electrostatic force
microscopy (DREEM), which was developed by University of North Carolina at Chapel Hill chemist and co-author Dorothy Erie, former UNC and NC State postdoctoral researchers Dong Wu and Parminder Kaur, and was featured earlier this year in Molecular Cell.