Raman microscope

Oxford Instruments Asylum Research releases Cypher ES Atomic Force Microscope Package for Battery Research

Retrieved on: 
Wednesday, April 26, 2023
Nanotechnology, Batteries, Science, Research, Technology, Instrumental Asylum, NMR, Cypher, SEI, Raman microscope, Oxford Instruments, EC, EDL, AFM, EDS, Lithium, Microscope

Oxford Instruments Asylum Research today announces the release of its new atomic force microscope (AFM) package developed for battery research, the Cypher ES Battery Edition.

Key Points: 
  • Oxford Instruments Asylum Research today announces the release of its new atomic force microscope (AFM) package developed for battery research, the Cypher ES Battery Edition.
  • The configuration combines the ultra-high-performance Cypher ES AFM with an easy-to-use electrochemistry cell that enables a wide range of EC-AFM experiments.
  • “The Cypher ES Battery Edition is a versatile tool for optimizing battery performance and enabling nanoscale characterization of the electrode/electrolyte interface.
  • Oxford Instruments offers a full range of complementary tools for battery research, including energy dispersive X-ray spectroscopy (EDS), nuclear magnetic resonance (NMR), and Raman imaging technologies pioneered by WITec GmbH .

Kanazawa University research: Faster and less-invasive atomic force microscopy for visualizing biomolecular systems

Retrieved on: 
Friday, March 19, 2021
Scanning probe microscopy, Microscopy, Physical sciences, Chemistry, Intermolecular forces, Atomic force microscopy, Raman microscope

KANAZAWA, Japan, March 19, 2021 /PRNewswire/ --Researchers at Kanazawa University report in Review of Scientific Instruments a newly developed atomic force microscopy approach for imaging biological samples and processes.The method offers higher frame rates and less disturbance of samples.

Key Points: 
  • KANAZAWA, Japan, March 19, 2021 /PRNewswire/ --Researchers at Kanazawa University report in Review of Scientific Instruments a newly developed atomic force microscopy approach for imaging biological samples and processes.The method offers higher frame rates and less disturbance of samples.
  • Now, Shingo Fukuda and Toshio Ando from Nano Life Science Institute (WPI-NanoLSI), Kanazawa University have developed an alternative HS-AFM approach to increase the frame rate up to 30 frames per second.
  • (a) During retrace scanning, a DC offset signal (Aos
  • Faster high-speed atomic force microscopy for imaging of biomolecular processes, Rev.

Kanazawa University research: Faster and less-invasive atomic force microscopy for visualizing biomolecular systems

Retrieved on: 
Friday, March 19, 2021
Scanning probe microscopy, Microscopy, Physical sciences, Chemistry, Intermolecular forces, Atomic force microscopy, Raman microscope

KANAZAWA, Japan, March 19, 2021 /PRNewswire/ --Researchers at Kanazawa University report in Review of Scientific Instruments a newly developed atomic force microscopy approach for imaging biological samples and processes.The method offers higher frame rates and less disturbance of samples.

Key Points: 
  • KANAZAWA, Japan, March 19, 2021 /PRNewswire/ --Researchers at Kanazawa University report in Review of Scientific Instruments a newly developed atomic force microscopy approach for imaging biological samples and processes.The method offers higher frame rates and less disturbance of samples.
  • Now, Shingo Fukuda and Toshio Ando from Nano Life Science Institute (WPI-NanoLSI), Kanazawa University have developed an alternative HS-AFM approach to increase the frame rate up to 30 frames per second.
  • (a) During retrace scanning, a DC offset signal (Aos
  • Faster high-speed atomic force microscopy for imaging of biomolecular processes, Rev.

NanoString Launches Technology Access Program for the Spatial Molecular Imager (SMI) Platform and Showcases Spatially Resolved Transcriptomic Research at 2021 Advances in Genome Biology and Technology (AGBT) Conference

Retrieved on: 
Monday, March 1, 2021
Biotechnology, Health, Genetics, Science, Research, Cancer screening, NanoString Technologies, Microscopes, Raman microscope

Researchers interested in participating in NanoStrings Technology Access Program should contact the company at [email protected] .

Key Points: 
  • Researchers interested in participating in NanoStrings Technology Access Program should contact the company at [email protected] .
  • The SMI platform provides highly sensitive, high-resolution imaging of hundreds to thousands of RNAs or proteins directly from single cells within morphologically intact tissue samples.
  • Together, the GeoMx DSP and Spatial Molecular Imager platform span the continuum of spatial biology applications and will serve the needs of both discovery and translational researchers.
  • NanoString, NanoString Technologies, the NanoString logo, GeoMx, and nCounter are trademarks or registered trademarks of NanoString Technologies, Inc. in various jurisdictions.

Kanazawa University research: High-speed atomic force microscopy takes on intrinsically disordered proteins

Retrieved on: 
Friday, December 4, 2020
Science and technology, Microscopes, Laboratory techniques, Scanning probe microscopy, Protein structure, Antonie van Leeuwenhoek, Microscopy, Scanning tunneling microscope, Atomic force microscopy, Raman microscope, Intrinsically disordered proteins, Nanotechnology

KANAZAWA, Japan, Dec. 4, 2020 /PRNewswire/ -- Kanazawa University's pioneering high-speed atomic force microscope technology has now shed light on the structure and dynamics of some of life's most ubiquitous and inscrutable molecules intrinsically disordered proteins.

Key Points: 
  • KANAZAWA, Japan, Dec. 4, 2020 /PRNewswire/ -- Kanazawa University's pioneering high-speed atomic force microscope technology has now shed light on the structure and dynamics of some of life's most ubiquitous and inscrutable molecules intrinsically disordered proteins.
  • Now researchers at Kanazawa University in Japan have shown that their home-grown high-speed atomic force microscopy technology can provide information not just on the structures of these proteins but also their dynamics.
  • Atomic force microscopy was developed in the 1980s and brought the atomic scale resolution achieved by scanning tunnelling microscopy (which won the 1986 Nobel Prize for Physics) to non-conducting samples.
  • Structural and dynamics analysis of intrinsically disordered proteins by high-speed atomic force microscopy, Nature Nanotechnology (2020)
    Figure 1.

Kanazawa University research: High-speed atomic force microscopy takes on intrinsically disordered proteins

Retrieved on: 
Friday, December 4, 2020
Science and technology, Microscopes, Laboratory techniques, Scanning probe microscopy, Protein structure, Antonie van Leeuwenhoek, Microscopy, Scanning tunneling microscope, Atomic force microscopy, Raman microscope, Intrinsically disordered proteins, Nanotechnology

KANAZAWA, Japan, Dec. 4, 2020 /PRNewswire/ -- Kanazawa University's pioneering high-speed atomic force microscope technology has now shed light on the structure and dynamics of some of life's most ubiquitous and inscrutable molecules intrinsically disordered proteins.

Key Points: 
  • KANAZAWA, Japan, Dec. 4, 2020 /PRNewswire/ -- Kanazawa University's pioneering high-speed atomic force microscope technology has now shed light on the structure and dynamics of some of life's most ubiquitous and inscrutable molecules intrinsically disordered proteins.
  • Now researchers at Kanazawa University in Japan have shown that their home-grown high-speed atomic force microscopy technology can provide information not just on the structures of these proteins but also their dynamics.
  • Atomic force microscopy was developed in the 1980s and brought the atomic scale resolution achieved by scanning tunnelling microscopy (which won the 1986 Nobel Prize for Physics) to non-conducting samples.
  • Structural and dynamics analysis of intrinsically disordered proteins by high-speed atomic force microscopy, Nature Nanotechnology (2020)
    Figure 1.

Microscope Software Market worth $1,021 million by 2025 - Exclusive Report by MarketsandMarkets™

Retrieved on: 
Wednesday, October 28, 2020
Microscopes, Science and technology, Laboratory techniques, Optics, Optical microscope, MicroScope, Electron microscope, Raman microscope, Digital microscope, Confocal microscopy

Based on the type of microscope, the market is segmented into optical microscopes, electron microscopes, Raman microscopes, and other microscopes.

Key Points: 
  • Based on the type of microscope, the market is segmented into optical microscopes, electron microscopes, Raman microscopes, and other microscopes.
  • Also, the low cost of optical microscope software is contributing to the growth of this market segment.
  • The healthcare industry accounted for the largest share of the market, by application, in 2019
    The microscope software available in the market are based on five major applicationssemiconductors, healthcare, automotive, aerospace, and other industries.
  • The healthcare industry segment is expected to dominate the microscope software market in 2019.

Microscope Software Market worth $1,021 million by 2025 - Exclusive Report by MarketsandMarkets™

Retrieved on: 
Wednesday, October 28, 2020
Microscopes, Science and technology, Laboratory techniques, Optics, Optical microscope, MicroScope, Electron microscope, Raman microscope, Digital microscope, Confocal microscopy

Based on the type of microscope, the market is segmented into optical microscopes, electron microscopes, Raman microscopes, and other microscopes.

Key Points: 
  • Based on the type of microscope, the market is segmented into optical microscopes, electron microscopes, Raman microscopes, and other microscopes.
  • Also, the low cost of optical microscope software is contributing to the growth of this market segment.
  • The healthcare industry accounted for the largest share of the market, by application, in 2019
    The microscope software available in the market are based on five major applicationssemiconductors, healthcare, automotive, aerospace, and other industries.
  • The healthcare industry segment is expected to dominate the microscope software market in 2019.

Imaging system from Molecular Devices helps Recursion produce the largest publicly available set of human cellular morphological data for COVID-19 therapeutic research

Retrieved on: 
Thursday, June 25, 2020
Microscopes, Raman microscope, Raman scattering, Molecular Devices, Imaging, Optics, Microscopy, Medical imaging

The images and data were acquired using the ImageXpress Micro Confocal High-Content Imaging System from Molecular Devices, LLC.

Key Points: 
  • The images and data were acquired using the ImageXpress Micro Confocal High-Content Imaging System from Molecular Devices, LLC.
  • Named RxRx19 , the dataset from Recursion is an important contribution to a growing body of scientific data in the fight against COVID-19.
  • "We commend Recursion for their leadership around RxRx19, empowering researchers with the statistically relevant data to advance our understanding of COVID-19 cellular responses and drug discovery.
  • Molecular Devices continues to lead the cellular imaging community towards new discoveries utilizing a comprehensive portfolio of powerful yet easy-to-use high-content imaging systems.

Agilent Introduces New Handheld Raw Material ID System for Pharmaceutical Manufacturers

Retrieved on: 
Tuesday, March 31, 2020
Software, Biotechnology, Pharmaceutical, Other Manufacturing, Health, Consumer electronics, Technology, Manufacturing, Raman scattering, Companies, Agilent Technologies, Hewlett-Packard, Raman microscope, California, Science and technology in the United States

The new Agilent Vaya Raman raw material identity verification system is a handheld instrument that accelerates quality control testing in the pharmaceutical and biopharmaceutical industries.

Key Points: 
  • The new Agilent Vaya Raman raw material identity verification system is a handheld instrument that accelerates quality control testing in the pharmaceutical and biopharmaceutical industries.
  • Vaya verifies raw material identity through unopened transparent and non-transparent packaging, testing more containers for the same cost by reducing the need for sampling.
  • Incoming goods can be tested quickly in the warehouse on receipt, reducing operator time and sample-handling booth usage.
  • Improving the speed and efficiency of raw material testing has a major impact on pharma and biopharma manufacturing, said Paul Loeffen, Agilent vice president and general manager of the companys Molecular Spectroscopy Division.