In vitro
cancer cell imaging and therapy using transferrin - conjugated gold nanoparticles.
Not exact matches
That company is pioneering medical uses for carbon molecules called nanospheres, such as attacking
cancer cells and dramatically improving magnetic - resonance -
imaging contrasts.
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.
To surmount this hurdle, Dr. Hodgson and his colleagues in the Gruss Lipper Biophotonics Center at Einstein devised a new fluorescent protein biosensor that, combined with live -
cell imaging, revealed exactly when and where Rac1 is activated inside
cancer cells.
When Conklin joined his lab, he had no experience in his PI's core area of
cancer research, but he brought valuable expertise in
cell imaging techniques.
The gold - iron oxide core - shell nanorods may be useful in
cancer therapy, with MRI
imaging enabled by the iron oxide shell, and local heating created by the photothermal effect on the gold nanorod core killing
cancer cells.
To overcome these problems, Min and his team developed a new modality to visualize glucose uptake activity inside single
cells based on stimulated Raman scattering (SRS)
imaging, and demonstrated its use in live
cancer cells, tumor xenograft tissues, primary neurons and mouse brain tissues.
In a study presented in the featured clinical investigation article of the November issue of The Journal of Nuclear Medicine, they used 18F - fluorodeoxyglucose (FDG) PET / CT
imaging to show that the amount of
cell - free tumor DNA circulating in the bloodstream correlates with tumor metabolism (linked to
cancer aggressiveness), not tumor burden (amount of
cancer in the body).
Diagnosing
cancer today usually involves various
imaging techniques, examining tissue samples under a microscope, or testing
cells for proteins or genetic material.
«We showed with this technique that we can detect very tiny tumors of just a few hundred
cells,» Lu said, adding that the study pushed
imaging boundaries, revealing smaller
cancers than can be detected with current clinical
imaging modalities.
I also think that the next revolution in science might be new
imaging techniques to observe our
cells and molecules in real time within the entire body during infections or
cancer or even while we watch our favorite movie star on video in our doctor's office.
Through laser
imaging at speeds up to 3,000 frames per second, a computer can capture images from all angles and reconstruct a model of all
cells in the given sample, testing for all types of
cancer in a matter of minutes.
To diagnose the
cancer cells, various
imaging modalities are being used.
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.
«We can tell through high - speed
imaging that
cancer cells tend to be larger than white or red blood
cells.
By engineering red blood
cells to have «sticky» proteins on their surface, a team of researchers has given the
cells the ability to carry anything from drugs to treat immune disorders or
cancer to radioactive molecules used in
imaging of blood vessels.
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.
For years researchers have been developing molecular
imaging techniques that visualize hormonally active breast
cancer cells — specifically those testing positive for human epidermal growth factor receptor 2 (HER2).
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.
The High Resolution Electron Microscopy Facility (HREMF) provides a resource to the scientific community at MD Anderson for high resolution
imaging of
cells, tissues, organs or polymers containing
cancer agents.
His research interests include medicinal chemistry, nanotechnology, drug delivery,
cell trafficking and molecular
imaging for theranostic applications in
cancer and Alzheimer's disease (AD).
To answer this question, a study presented at the AACR Annual Meeting 2018 used real - time, single -
cell imaging to make movies of live
cancer cells.
For leadership and pioneering contributions in the field of biophotonics, comprising the diverse use of label - free native fluorescence, Raman spectroscopy, and optical
imaging for
cancer detection in tissues and
cells.
Breast
cancer cell movement:
imaging invadopodia by TIRF and IRM microscopy.
Atkinson explains, «Alex's video, «Killing
Cancer,» has some of the most advanced — and most exciting —
cell imaging in the world.
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.
We focus on squamous tissues, the skin epidermis and the lining of the oesophagus, using transgenic models, novel sequencing approaches, live
imaging and single
cell analysis to uncover key steps in
cancer development, with aim of developing rational interventions to decrease
cancer risk.
Correlative nanomechanical profiling with super-resolution F - actin
imaging reveals novel insights into mechanisms of cisplatin resistance in ovarian
cancer cells Sharma S, Santiskulvong C, Bentolila, L A, Rao J, Dorigo O and Gimzewski J K 2012 Nanomedicine: Nanotechnology, Biology, and Medicine 8 757 - 766
Foreign researchers honored as the 31st KIA laureates include: Prof. Eric Vivier (France) for his research on harnessing innate immunity against
cancer; Prof. Jianfang Wang (Hong Kong, China) for his research on Colloidal Plasmonic Metal Nanocrystals; Prof. Majed Chergui (Switzerland) for his research on unravelling the fundamentals of solar; Prof. Katharina Gaus (Australia) for her research on Single molecule
imaging of T
cell receptor signaling; and Prof. Dr. Burkhard Büdel (Germany) for his research on Role of lichens and cyanobacteria in biological soil crusts.
With key strengths in advanced medical
imaging,
cell biology, genomics, immunology and stem
cell biology, our scientists and their skilled staff conduct research on some of the most debilitating diseases of our time: heart disease and stroke, Alzheimer's,
cancer, organ failure, diabetes and many others.
Embryonic stem
cells, Adult stem
cells, Reprogramming to pluripotency and lineage conversion, Directed differentiation, Germ
cells, Genetic and epigenetic mechanisms, Stem
cells in development, Stem
cell niche,
Cancer stem
cells, Disease modeling and drug screening, Stem
cell therapy, Clinical studies in regenerative medicine, Tissue engineering and biomaterials,
Imaging and diagnostics, Stem
cell products, manufacturing, and quality control, Ethical, legal, and social issues Read Journal
Decreased metastasis by ABL - deficient breast
cancer cells was accompanied by a significant reduction in the extent of hindlimb osteolytic lesions, as determined by x-ray and micro — computed tomography (μCT)
imaging (Fig. 2, I and J).
The 1833 and SCP28 breast
cancer cells were engineered to express reporters with luciferase and green fluorescent protein to monitor metastatic progression by bioluminescence
imaging (Fig. 2A).
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 method, called «theranostic»
imaging, targets potent drug therapies directly and only to
cancer cells while also tracking and monitoring the journey.
By
imaging cancer cells in vivo, we are studying how
cells migrate in and interact with complex environments in the living animal (Fig 2C).
This article describes methods for preparation and
imaging of 3D
cancer cell cultures, either as single
cells or spheroids.
Multiplexed
Imaging Here the goal is to add spatial resolution to cytometry - data in order to understand, in a tissue, WHERE immune and
cancer cells interact We design, develop and apply methods for multiplexed visualization of protein and RNA molecules in tissue sections.
I am a Morgridge Postdoctoral Fellow working jointly with Kevin Eliceiri, Morgridge Institute for Research and LOCI; Patricia Keely,
Cell and Regenerative Biology; and Sean Fain, Medical Physics; in multiscale
imaging — including fluorescence lifetime
imaging microscopy and magnetic resonance
imaging of tumor metabolic signatures — to predict
cancer metastasis.
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.
«Theranostics» Simultaneously Kill and Image Prostate
Cancer Cells Experimenting with human prostate cancer cells and mice, cancer - imaging experts developed a method for finding and killing malignant cells while sparing healthy
Cancer Cells Experimenting with human prostate cancer cells and mice, cancer - imaging experts developed a method for finding and killing malignant cells while sparing healthy
Cells Experimenting with human prostate
cancer cells and mice, cancer - imaging experts developed a method for finding and killing malignant cells while sparing healthy
cancer cells and mice, cancer - imaging experts developed a method for finding and killing malignant cells while sparing healthy
cells and mice,
cancer - imaging experts developed a method for finding and killing malignant cells while sparing healthy
cancer -
imaging experts developed a method for finding and killing malignant
cells while sparing healthy
cells while sparing healthy ones.
The optical contrast (measured as a ratio of the fluorescent image amplitudes for C4 - 2B to HS - 5) of fluorescent
imaging for
cancer versus stromal
cells was 2.3 (Figure 7B, D).
I am also developing various
imaging and molecular sequencing methods for tracking genes, molecules, and
cells to understand how
cancer cells arise and evolve.
Up to 40 investigators will eventually be part of this new program, including teams looking at experimental therapeutics,
cancer stem
cells, molecular
imaging and genomics.
Using
imaging techniques, the
cell signaling pathway can be investigated in detail to target areas that could prevent
cancer from developing.
We support 10 major research thematic areas including — immunotherapy, stem
cells, genomics, epigenetics, diagnostics, proteomics and computational biology,
cancer imaging, drug development, supportive care and other key areas.