To pursue these studies, the Noma laboratory employs genomic technologies and single locus / live -
cell imaging technology along with molecular and chromatin biology and epigenetics.
Not exact matches
A veteran of digital
imaging technology, in 1999 he founded Quantitative Imaging Corp. (QImaging), a manufacturer of digital cameras for scientific and industrial uses — the kind, for example, that can detect microscopic, early - stage cancer
imaging technology, in 1999 he founded Quantitative
Imaging Corp. (QImaging), a manufacturer of digital cameras for scientific and industrial uses — the kind, for example, that can detect microscopic, early - stage cancer
Imaging Corp. (QImaging), a manufacturer of digital cameras for scientific and industrial uses — the kind, for example, that can detect microscopic, early - stage cancer
cells.
CAREstream America also distributes a large line of Aesthetic products ranging from water - jet assisted
technology, to ultrasound
imaging, to
cell counting and vascular access
imaging.
The latest in live -
cell microscopy — multiphoton
imaging, light - sheet techniques, and
technology borrowed from Raman spectroscopy — allow researchers to study living
cells in more detail with less effort.
Scientists at Barrow Neurological Institute have recently made discoveries about use of a new
technology for
imaging brain tumors in the operating room — a finding that could have important implications for identifying and locating invading
cells at the edge of a brain tumor.
At Actelion, employees are increasingly motivated by visualization
technologies, such as automated live -
cell imaging and high content screening, that offer new means to view and quantify cellular, even subcellular, processes.
Quantum dots, which have use in diverse applications such as medical
imaging, lighting, display
technologies, solar
cells, photocatalysts, renewable energy and optoelectronics, are typically expensive and complicated to manufacture.
To better determine the role of specific chemoattractants in type III hypersensitivity, lead author Yoshishige Miyabe, MD, PhD, a research fellow in Luster's lab, used multiphoton intravital microscopy — an
imaging technology pioneered for studies of immune
cell movements in living animals by CIID investigator and co-author Thorsten Mempel, MD, PhD — to follow in real time the development of IC - induced arthritis in a mouse model of rheumatoid arthritis.
Because SR - STORM gives full spectral and spatial information for each molecule, the
technology opens the door to high - resolution
imaging of multiple components and local chemical environments, such as pH variations, inside a
cell.
«After surgery, you always have microscopic
cells that spread,» he says, «and they hide throughout the brain, beyond the areas we can visualize by any kind of
imaging technology.
Through the new
imaging technology, researchers use fluorescent
imaging to locate proteins and other molecules in
cells and tissues.
The detection and
imaging of protein - protein interactions in live
cells just got a lot more colorful, thanks to a new
technology developed by University of Alberta chemist Dr. Robert E. Campbell and his team.
His work involves high - resolution
imaging of chick embryonic tissue slices to study the
cell - biological mechanisms driving neurogenesis in the spinal cord, for which Dr. Das played an instrumental role in pioneering new
imaging technology.
Building on traditional SIM
technology, the iSIM allows real - time, 3 - D super resolution
imaging of small, rapidly moving structures — such as individual blood
cells moving through a live zebrafish embryo.
Using sophisticated
imaging technology, they were then able to watch as the broken ends of the chromosomes were reattached correctly or incorrectly inside the
cells.
«Scientists design bacteria to reflect «sonar» signals for ultrasound
imaging: New
technology may one day allow doctors to image therapeutic bacterial
cells in patients.»
Employing the advanced
technology of the Institute's Cytometry,
Imaging and Histology centers, the researchers examined the relationship between megakaryocytes and hematopoietic stem
cells in mouse bone marrow.
Researchers from PSG College of
Technology, India have developed nano - contrast agents for magnetic resonance
imaging (MRI) as well as optical
imaging of cancer
cells.
Researchers in China have developed tiny nanocrystals that could be used in the next generation of medical
imaging technologies to light up cancer
cells.
CellSearch is used primarily to check the progress of cancer treatment, whereas U.C.L.A.'s
imaging technology could find cancerous
cells at an earlier stage, before they can form a new tumor.
His laboratory currently applies high throughput
imaging technologies to study trafficking between the endoplasmic reticulum and Golgi complex, and the internalization pathways taken by synthetic nanoparticles on exposure to
cells.
The researchers used two - photon calcium
imaging and patch - clamp electrophysiology, two sophisticated
technologies that allowed the researchers to record the signals from individual brain
cells.
Systems Biology and Genomics, including systems neurobiology, quantitative
cell biology, cellular dynamics, algorithms, methods and
technology development, data integration and visualization,
imaging, synthetic biology, deep learning applied to biology and human health, and single
cell biology.
They found that injecting into the carotid artery breast cancer
cells that express markers allowing them to enter the brain —
cells labelled with bioluminescent and fluorescent markers to enable tracking by
imaging technologies — resulted in the formation of many metastatic tumors throughout the brain, mimicking what is seen in advanced breast cancer patients.
Using state - of - the - art micro-computed tomography and digital
imaging technology applied to hundreds of fossil and recent molars, Ortiz and colleagues created virtual maps of the dental landscape of developing teeth to chart the precise location of embryonic signaling
cells from which molar cusps develop.
The injected
cells express markers that allow them to enter the brain and are labelled with bioluminescent and fluorescent markers to enable tracking by
imaging technologies.
IDMIT is an infrastructure for preclinical research in infectious diseases and immunology which is certified ISO9001 and which includes 1) A large animal facility with capacity to host NHP in BSL2 and BSL3 containment, 2) State - of - the - art laboratories for
cell biology, immunology, molecular biology, flow cytometry and mass cytometry (CyTof),
cell - sorting and confocal microscopy in BSL3 containment; 3) A biological resources centre with high storage capacity; 4) Highly innovative
technologies for in vivo
imaging of large animals in BSL2 and BSL3 containment, including a two - photon microscope, a PET - CT facility, and several optic based
technologies (fibered endo - microscopy, near infra - red
imaging).
We are also equipped with advanced
imaging system
technology offering non-invasive longitudinal monitoring of disease progression,
cell trafficking and gene expression patterns in relevant models using non-virulent mycobacteria tagged with bioluminescense genes.
diSPIM
technology enables rapid 3D
imaging of samples ranging from single
cells to small organisms over the course of hours to days.
We develop antibodies that may help us detect cancer
cells through highly sensitive medical
imaging technologies, as well as antibodies that directly trigger
cell - killing mechanisms in the tumour.
This research makes use of single - molecular fluorescence
imaging technology to visualize and analyze the behavior of exogenous DNA that were introduced into the
cell from outside.
But the development of new, high - resolution
imaging technology able to capture single
cells has finally enabled scientists to reliably chart noise at this level, and to study how it influences behavior.
Today, analyzing and editing genomes, proteomes and metabolomes has become a standard for many model systems;
imaging beyond the diffraction limit of light and new
technologies for studying protein structures provide insights deeper than ever before; the characterization of large populations of
cells or organisms brings unprecedented statistical power; and studying nearly all organisms of an ecosystems as a whole allows generating comprehensive models.
This significant speed difference combined with the superior sensitivity of high end CCDs has made spinning disk confocal a must have
technology for advanced live
cell imaging labs.
We employ a wide variety of state - of - the - art
technologies such as in vivo optical
imaging and high - throughput methods including
cell - based screening, genomics, and proteomics approaches.
The Bulte Lab has developed methods to label
cells magnetically using tiny superparamagnetic iron oxide nanoparticles in order to make them visible by magnetic resonance
imaging; this
technology has now been introduced in the clinic for several
cell therapy applications.
・ Use of single - molecular fluorescence
imaging technology to elucidate the fate of DNA introduced into a living
cell.
Cell biology has continued to expand ever since, extending its impact on clinical medicine and pharmacology while drawing on new
technologies in bioengineering, high - resolution
imaging, massive data handling, and genomic sequencing.
We've devised ways to test patients using new
imaging technologies to measure the health of their retinal ganglion
cells and of their fibers entering the optic nerve.
Topics covered include embryonic stem
cells, pluripotency, germline stem
cells, tissue - specific stem
cells, stem
cell differentiation, epigenetics, stem
cell genomics and systems biology, genome reprogramming, cancer stem
cells, stem
cell niches, stem -
cell - based disease models, nuclear transfer
technology, bioengineering, drug discovery, in vivo
imaging of stem
cells, therapeutic applications, regenerative medicine, clinical and translational insights, stem
cell research policies, ethical issues, and technical or resource - based innovations.
The overall goal of the
Cell Imaging Shared Resource is to supply VICC researchers with access to cutting edge
technology and expert technical support for microscopic observation and analysis of tissue and cellular anatomy and physiology related to cancer research.
The Metabolomics & Proteomics
Technology Unit will offer localizomics approaches based on MS
Imaging on tissue / organs slices (or on in - vitro
cell cultures), either in targeted MS (i.e. drug and metabolites distribution) or in untargeted high resolution (HR) MS (metabolite profiling).
To pursue these studies, we employ Hi - C and ChIA - PET genomic
technologies and single locus / live -
cell imaging approach.
By combining two state - of - the - art
imaging technologies, Howard Hughes Medical Institute Janelia Research Campus scientists, led by 2014 chemistry Nobel laureate physicist Eric Betzig, have imaged living
cells at unprecedented 3D detail and speed, the scientists report on April 19, 2018 in an open - access paper in the journal Science.
The Okyanos facility is fitted with a Class C operating theatre, a Philips bi-plane cardiac catheterization lab with advanced
imaging systems and offers leading
technologies for enzyme - derived
cell processing.
He has experience and knowledge in a variety of
technologies including various wireless
technologies (WCDMA, HSPA, LTE, CDMA2000, wireless modems, cellular Multi-media Messaging Service (MMS)-RRB-, vehicle navigation systems, digital and analog electronics, optics, LCD, and other display
technologies, magnetic resonance
imaging technology, digital image processing, nanotechnology, MEMS devices, photovoltaic
cells, hard disk drive
technology, semiconductor devices and processing, medical devices, computer software, motors and motor drives for electric vehicles and CNC machining centers.
«Our
technology will provide significantly higher forces and faster impact cycles than have previously been possible, and by building these tools onto microfluidic devices, we can leverage a host of other on - chip diagnostics and
imaging tools and can collect the
cells after testing for longer - term studies,» said Valentine.