Evident

Waltham, MA 02453

COMPANY OVERVIEW

About Evident

Contact

48 Woerd Ave
Waltham, MA 02453
United States
https://www.evidentscientific.com
800-225-8330

More Info on Evident

At Evident, we are guided by the scientific spirit—innovation and exploration are at the heart of what we do. Committed to making people’s lives healthier, safer and more fulfilling, we support our customers with solutions that solve their challenges and advance their work; whether it’s researching medical breakthroughs, inspecting infrastructure, or exposing hidden toxins in consumer products.

Products

Fv3000
Fv3000
Fv3000
Fv3000
Fv3000
Microscopes

FLUOVIEW™ FV3000

The FLUOVIEW™ FV3000 series of confocal laser scanning microscopes meets some of the most difficult challenges in modern science. Featuring the high sensitivity and speed required...
Apx100 With Monitor
Apx100 With Monitor
Apx100 With Monitor
Apx100 With Monitor
Apx100 With Monitor
Microscopes

APEXVIEW™ APX100

The APEXVIEW™ APX100 all-in-one microscope makes it fast and simple to acquire expert-quality microscope images. Built with renowned Olympus optics, an intuitive user interface...
Ols5100
Ols5100
Ols5100
Ols5100
Ols5100
Microscopes

LEXT™ OLS5100 3D Laser Scanning Microscope

The LEXT™ OLS5100 3D Laser Scanning Microscope is a powerful tool for material analysis. With exceptional measurement accuracy and optical performance, this laser microscope is...
Product Dsx1000 Entry 01
Product Dsx1000 Entry 01
Product Dsx1000 Entry 01
Product Dsx1000 Entry 01
Product Dsx1000 Entry 01
Microscopes

DSX1000 Digital Microscope

The DSX1000 Digital Microscope is a powerful, fast, and reliable failure analysis tool. With guaranteed accuracy and repeatability, this microscope features a telecentric optical...
Product Szxar1 Overview01
Product Szxar1 Overview01
Product Szxar1 Overview01
Product Szxar1 Overview01
Product Szxar1 Overview01
Microscopes

SZX-AR1 Augmented Reality Microscope System

The SZX-AR1 Augmented Reality Microscope System microscope system overlays text and digital images over the field of view, making it easy to follow instructions, read notes, and...

Press Releases

Screen Shot 2023 05 10 At 3 02 04 Pm
Screen Shot 2023 05 10 At 3 02 04 Pm
Screen Shot 2023 05 10 At 3 02 04 Pm
Screen Shot 2023 05 10 At 3 02 04 Pm
Screen Shot 2023 05 10 At 3 02 04 Pm
Microscopes

OLYMPUS Makes it EVIDENT

Scientific Solutions business splits from global medtech company TOKYO, Japan (April 4, 2022)—Olympus Corporation (“Olympus”) announced the completion of the separation of its...

Articles

Detectors & Imaging

Digital microscope camera offers AI-based scene detection

The DP75 digital microscope camera captures images from brightfield to wide-wavelength fluorescence and near-infrared using a single camera.
Evident
Evident
Evident
Evident
Evident
Bio&Life Sciences

Whole-slide imaging system scans over 80 slides/hour

The SLIDEVIEW DX VS-M1 whole-slide imaging system is a digital pathology solution that delivers microscope-quality slide images onscreen.
FIGURE 1. The Olympus eyepoint height adjuster can be adjusted from 30 to 150 mm, allowing users of any height to operate the scope comfortably.
FIGURE 1. The Olympus eyepoint height adjuster can be adjusted from 30 to 150 mm, allowing users of any height to operate the scope comfortably.
FIGURE 1. The Olympus eyepoint height adjuster can be adjusted from 30 to 150 mm, allowing users of any height to operate the scope comfortably.
FIGURE 1. The Olympus eyepoint height adjuster can be adjusted from 30 to 150 mm, allowing users of any height to operate the scope comfortably.
FIGURE 1. The Olympus eyepoint height adjuster can be adjusted from 30 to 150 mm, allowing users of any height to operate the scope comfortably.
Detectors & Imaging

Integrating ergonomics is vital for routine microscopy

Incorporating proper ergonomics into your industrial microscope setup and routine helps to prevent injuries and increase productivity.
Photo 236540213 © Marek Uliasz | Dreamstime.com
Dreamstime Xl 236540213
Dreamstime Xl 236540213
Dreamstime Xl 236540213
Dreamstime Xl 236540213
Dreamstime Xl 236540213
Executive Forum

Photonics business roundup: February 2022

Business announcements were plentiful in February 2022 for the optics and photonics industry, spanning several application and product markets.
Olympus
Olympus
Olympus
Olympus
Olympus
Detectors & Imaging

Monochrome microscope camera features 400–1000 nm spectral range

The DP23M monochrome microscope camera features a backside-illuminated monochrome CMOS sensor with 2 × 2 binning.
FIGURE 1. Example of a complex and compact group of lenses inside an objective.
FIGURE 1. Example of a complex and compact group of lenses inside an objective.
FIGURE 1. Example of a complex and compact group of lenses inside an objective.
FIGURE 1. Example of a complex and compact group of lenses inside an objective.
FIGURE 1. Example of a complex and compact group of lenses inside an objective.
Detectors & Imaging

Lesser-known factors to consider during microscope system design

New objective lens technology delivers high levels of numerical aperture, chromatic aberration correction, and flatness at the same time for improved optical performance.
(Photo: ID 60933364 © Pichetw | Dreamstime.com)
Dreamstime M 60933364
Dreamstime M 60933364
Dreamstime M 60933364
Dreamstime M 60933364
Dreamstime M 60933364
Executive Forum

Boosting surgical endoscopy capabilities, Olympus acquires Quest Photonic Devices

Quest Photonic Devices’ multispectral imaging offerings will drive the growth of Olympus’ surgical endoscopy business.
FIGURE 1. The effect of laser wavelength on lateral resolution: A grating with 260-nm-wide lines imaged using a laser scanning confocal microscope with a 658 nm laser (a) and a grating with 120-nm-wide lines imaged using the Olympus LEXT OLS5000 laser scanning confocal microscope with a 405 nm laser (b) are shown.
FIGURE 1. The effect of laser wavelength on lateral resolution: A grating with 260-nm-wide lines imaged using a laser scanning confocal microscope with a 658 nm laser (a) and a grating with 120-nm-wide lines imaged using the Olympus LEXT OLS5000 laser scanning confocal microscope with a 405 nm laser (b) are shown.
FIGURE 1. The effect of laser wavelength on lateral resolution: A grating with 260-nm-wide lines imaged using a laser scanning confocal microscope with a 658 nm laser (a) and a grating with 120-nm-wide lines imaged using the Olympus LEXT OLS5000 laser scanning confocal microscope with a 405 nm laser (b) are shown.
FIGURE 1. The effect of laser wavelength on lateral resolution: A grating with 260-nm-wide lines imaged using a laser scanning confocal microscope with a 658 nm laser (a) and a grating with 120-nm-wide lines imaged using the Olympus LEXT OLS5000 laser scanning confocal microscope with a 405 nm laser (b) are shown.
FIGURE 1. The effect of laser wavelength on lateral resolution: A grating with 260-nm-wide lines imaged using a laser scanning confocal microscope with a 658 nm laser (a) and a grating with 120-nm-wide lines imaged using the Olympus LEXT OLS5000 laser scanning confocal microscope with a 405 nm laser (b) are shown.
Test & Measurement

Surface roughness measurement: Where to begin?

For industrial surface measurement, a laser scanning confocal microscope can provide high accuracy and the right roughness parameters for your application.
Olympus
Olympus
Olympus
Olympus
Olympus
Detectors & Imaging

Laser microscope uses two optical systems

The LEXT OLS5100 3D laser scanning microscope is designed for failure analysis and material engineering research with 0.12 µm lateral resolution.
Olympus Cropped
Olympus Cropped
Olympus Cropped
Olympus Cropped
Olympus Cropped
Detectors & Imaging

Olympus screening station provides fully automated image acquisition

The scanR high-content screen (HCS) station version 3.2 incorporates Olympus X Line objectives for improved chromatic aberration correction, image flatness, and resolution.

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Additional content from Evident

Photo 88499141 © Korn Vitthayanukarun | Dreamstime.com
Executive Forum

Photonics Business Moves: December 1, 2023

Here are the top four photonics business moves that made headlines during the week ending December 1, 2023.
FIGURE 1. Results from linear and nonlinear deconvolution are shown in these images depicting original objects before image acquisition, observed confocal image through microscope, and following deconvolution (left). The center panel depicts linear deconvolution with a Wiener filter, resulting in ringing artifacts observable in the beads and crossed filaments. Nonlinear deconvolution results (right) improve image quality, but may create data beyond the cut-off spatial frequency. Case 1 results show artifacting in connections between adjacent beads. When deconvolution parameters are carefully adjusted (as depicted in Case 2 column), good results can be achieved.
FIGURE 1. Results from linear and nonlinear deconvolution are shown in these images depicting original objects before image acquisition, observed confocal image through microscope, and following deconvolution (left). The center panel depicts linear deconvolution with a Wiener filter, resulting in ringing artifacts observable in the beads and crossed filaments. Nonlinear deconvolution results (right) improve image quality, but may create data beyond the cut-off spatial frequency. Case 1 results show artifacting in connections between adjacent beads. When deconvolution parameters are carefully adjusted (as depicted in Case 2 column), good results can be achieved.
FIGURE 1. Results from linear and nonlinear deconvolution are shown in these images depicting original objects before image acquisition, observed confocal image through microscope, and following deconvolution (left). The center panel depicts linear deconvolution with a Wiener filter, resulting in ringing artifacts observable in the beads and crossed filaments. Nonlinear deconvolution results (right) improve image quality, but may create data beyond the cut-off spatial frequency. Case 1 results show artifacting in connections between adjacent beads. When deconvolution parameters are carefully adjusted (as depicted in Case 2 column), good results can be achieved.
FIGURE 1. Results from linear and nonlinear deconvolution are shown in these images depicting original objects before image acquisition, observed confocal image through microscope, and following deconvolution (left). The center panel depicts linear deconvolution with a Wiener filter, resulting in ringing artifacts observable in the beads and crossed filaments. Nonlinear deconvolution results (right) improve image quality, but may create data beyond the cut-off spatial frequency. Case 1 results show artifacting in connections between adjacent beads. When deconvolution parameters are carefully adjusted (as depicted in Case 2 column), good results can be achieved.
FIGURE 1. Results from linear and nonlinear deconvolution are shown in these images depicting original objects before image acquisition, observed confocal image through microscope, and following deconvolution (left). The center panel depicts linear deconvolution with a Wiener filter, resulting in ringing artifacts observable in the beads and crossed filaments. Nonlinear deconvolution results (right) improve image quality, but may create data beyond the cut-off spatial frequency. Case 1 results show artifacting in connections between adjacent beads. When deconvolution parameters are carefully adjusted (as depicted in Case 2 column), good results can be achieved.
Optics

Microscopy/Image Processing: A deconvolution revolution for confocal image enhancement

A combination of advanced algorithms and improved hardware is driving the popularity of deconvolution for optical confocal microscopy.
(Image credit: Dan Houchin, Olympus America)
FIGURE 1. Superresolution techniques, enabled by software and hardware advances, highlight the most minute details and processes that define life; an example is this image depicting early embryonic development captured on the Olympus SpinSR superresolution microscope.
FIGURE 1. Superresolution techniques, enabled by software and hardware advances, highlight the most minute details and processes that define life; an example is this image depicting early embryonic development captured on the Olympus SpinSR superresolution microscope.
FIGURE 1. Superresolution techniques, enabled by software and hardware advances, highlight the most minute details and processes that define life; an example is this image depicting early embryonic development captured on the Olympus SpinSR superresolution microscope.
FIGURE 1. Superresolution techniques, enabled by software and hardware advances, highlight the most minute details and processes that define life; an example is this image depicting early embryonic development captured on the Olympus SpinSR superresolution microscope.
FIGURE 1. Superresolution techniques, enabled by software and hardware advances, highlight the most minute details and processes that define life; an example is this image depicting early embryonic development captured on the Olympus SpinSR superresolution microscope.
Detectors & Imaging

Advanced Imaging/Optical Design: Functional superresolution microscopy progresses

As technologies have progressed, certain types of superresolution optical imaging—so-called functional superresolution techniques—have become more user-friendly across a broad...
Content Dam Lfw En Articles Print Volume 54 Issue 05 Features Laser Focus World Announces 2018 Innovators Awards Leftcolumn Article Thumbnailimage File
Content Dam Lfw En Articles Print Volume 54 Issue 05 Features Laser Focus World Announces 2018 Innovators Awards Leftcolumn Article Thumbnailimage File
Content Dam Lfw En Articles Print Volume 54 Issue 05 Features Laser Focus World Announces 2018 Innovators Awards Leftcolumn Article Thumbnailimage File
Content Dam Lfw En Articles Print Volume 54 Issue 05 Features Laser Focus World Announces 2018 Innovators Awards Leftcolumn Article Thumbnailimage File
Content Dam Lfw En Articles Print Volume 54 Issue 05 Features Laser Focus World Announces 2018 Innovators Awards Leftcolumn Article Thumbnailimage File
Positioning, Support & Accessories

Laser Focus World announces 2018 Innovators Awards

For the first time, Laser Focus World has held its Innovators Awards program, which celebrates the disparate and innovative technologies, products, and systems found in the photonics...
1712 Lfw Pro 12
1712 Lfw Pro 12
1712 Lfw Pro 12
1712 Lfw Pro 12
1712 Lfw Pro 12
Test & Measurement

Confocal microscope from Olympus measures samples up to 210 mm in height

The LEXT OLS5000 3D laser confocal scanning microscope includes 4K scanning technology.
Courtesy of Olympus
These images were acquired using various Olympus IR objective lenses, a BX2M-IR upright compound microscope, an XM10-IR digital camera, and Olympus Stream software: 10x (a), 20x (b), 50x (c), and 100x (d).
These images were acquired using various Olympus IR objective lenses, a BX2M-IR upright compound microscope, an XM10-IR digital camera, and Olympus Stream software: 10x (a), 20x (b), 50x (c), and 100x (d).
These images were acquired using various Olympus IR objective lenses, a BX2M-IR upright compound microscope, an XM10-IR digital camera, and Olympus Stream software: 10x (a), 20x (b), 50x (c), and 100x (d).
These images were acquired using various Olympus IR objective lenses, a BX2M-IR upright compound microscope, an XM10-IR digital camera, and Olympus Stream software: 10x (a), 20x (b), 50x (c), and 100x (d).
These images were acquired using various Olympus IR objective lenses, a BX2M-IR upright compound microscope, an XM10-IR digital camera, and Olympus Stream software: 10x (a), 20x (b), 50x (c), and 100x (d).
Optics

Scientific Imaging: Near-IR microscopes image through silicon without damaging the finished product

Imaging through silicon with dedicated IR objective lenses enables nondestructive flip-chip analysis and other essential evaluations.
Olympus
Content Dam Lfw Online Articles 2017 11 Olympus
Content Dam Lfw Online Articles 2017 11 Olympus
Content Dam Lfw Online Articles 2017 11 Olympus
Content Dam Lfw Online Articles 2017 11 Olympus
Content Dam Lfw Online Articles 2017 11 Olympus
Detectors & Imaging

Olympus introduces smart glasses for use in the enterprise

The device uses "pupil division" to imitate a semitransparent viewing screen.
(Courtesy of BaySpec)
FIGURE 1. Confocal measurements of fossil feathers embedded in epoxy and amber show keratin, but no carotenoid (yellow) contributions in their Raman spectra.1 The measurements were done with a BaySpec Nomadic confocal microscope (bottom) at 1064 nm, one of the microscope's three Raman excitation wavelengths (the other two are 532 and 785 nm).
FIGURE 1. Confocal measurements of fossil feathers embedded in epoxy and amber show keratin, but no carotenoid (yellow) contributions in their Raman spectra.1 The measurements were done with a BaySpec Nomadic confocal microscope (bottom) at 1064 nm, one of the microscope's three Raman excitation wavelengths (the other two are 532 and 785 nm).
FIGURE 1. Confocal measurements of fossil feathers embedded in epoxy and amber show keratin, but no carotenoid (yellow) contributions in their Raman spectra.1 The measurements were done with a BaySpec Nomadic confocal microscope (bottom) at 1064 nm, one of the microscope's three Raman excitation wavelengths (the other two are 532 and 785 nm).
FIGURE 1. Confocal measurements of fossil feathers embedded in epoxy and amber show keratin, but no carotenoid (yellow) contributions in their Raman spectra.1 The measurements were done with a BaySpec Nomadic confocal microscope (bottom) at 1064 nm, one of the microscope's three Raman excitation wavelengths (the other two are 532 and 785 nm).
FIGURE 1. Confocal measurements of fossil feathers embedded in epoxy and amber show keratin, but no carotenoid (yellow) contributions in their Raman spectra.1 The measurements were done with a BaySpec Nomadic confocal microscope (bottom) at 1064 nm, one of the microscope's three Raman excitation wavelengths (the other two are 532 and 785 nm).
Test & Measurement

Photonics Products: Raman Spectrometers - Raman microscopes serve science and industry

When paired with a high-resolution microscope, Raman spectroscopy opens a world of knowledge for scientists, doctors, and industrial researchers.
1601 Lfw Pro Add 1
1601 Lfw Pro Add 1
1601 Lfw Pro Add 1
1601 Lfw Pro Add 1
1601 Lfw Pro Add 1
Test & Measurement

Digital microscope from Olympus includes 13.5x optical zoom

The DSX500 digital microscope observes, measures, and analyzes electronic components, circuit boards, construction materials, semiconductors, medical devices, and shielding components...
Content Dam Bow Online Articles 2015 December Olympus Ccsw Pict Web
Content Dam Bow Online Articles 2015 December Olympus Ccsw Pict Web
Content Dam Bow Online Articles 2015 December Olympus Ccsw Pict Web
Content Dam Bow Online Articles 2015 December Olympus Ccsw Pict Web
Content Dam Bow Online Articles 2015 December Olympus Ccsw Pict Web
Home

Cell counting software by Olympus

CKX-CCSW confluency check software automatically counts cells and measures cell confluency in a culture vessel.
1512 Lfw Pro 19
1512 Lfw Pro 19
1512 Lfw Pro 19
1512 Lfw Pro 19
1512 Lfw Pro 19
Detectors & Imaging

Focus compensation system from Olympus features rapid focus

The updated IX3-ZDC2 focus compensation system for inverted microscopes prevents focal drift over long periods.
Barbara G 720
Barbara G 720
Barbara G 720
Barbara G 720
Barbara G 720
BioOptics World View

Neuro15 exhibitors meet exacting demands: Part 2

Increasingly, neuroscientists are working with researchers in disciplines such as chemistry and physics. This trend has been noticed by exhibitors at the Society for Neuroscience...
Olympus Ckx53
Olympus Ckx53
Olympus Ckx53
Olympus Ckx53
Olympus Ckx53
Home

Inverted light microscope for cell culture by Olympus

The CKX53 inverted light microscope provides advanced imaging capabilities for cell culture checking and documentation.
(Courtesy of Dr. Simone Baltrusch, University of Rostock, Germany)
FIGURE 1. Investigating the pancreatic islet cells in mouse. The Olympus FV10i confocal microscope with 60x oil objective enables visualization of insulin-producing β-cells within regions of the pancreas called islets of Langerhans, including a section staining for insulin (red), with nuclei in cyan (a); and islet cells in culture, with insulin (green) and nuclei stained in blue (b).
FIGURE 1. Investigating the pancreatic islet cells in mouse. The Olympus FV10i confocal microscope with 60x oil objective enables visualization of insulin-producing β-cells within regions of the pancreas called islets of Langerhans, including a section staining for insulin (red), with nuclei in cyan (a); and islet cells in culture, with insulin (green) and nuclei stained in blue (b).
FIGURE 1. Investigating the pancreatic islet cells in mouse. The Olympus FV10i confocal microscope with 60x oil objective enables visualization of insulin-producing β-cells within regions of the pancreas called islets of Langerhans, including a section staining for insulin (red), with nuclei in cyan (a); and islet cells in culture, with insulin (green) and nuclei stained in blue (b).
FIGURE 1. Investigating the pancreatic islet cells in mouse. The Olympus FV10i confocal microscope with 60x oil objective enables visualization of insulin-producing β-cells within regions of the pancreas called islets of Langerhans, including a section staining for insulin (red), with nuclei in cyan (a); and islet cells in culture, with insulin (green) and nuclei stained in blue (b).
FIGURE 1. Investigating the pancreatic islet cells in mouse. The Olympus FV10i confocal microscope with 60x oil objective enables visualization of insulin-producing β-cells within regions of the pancreas called islets of Langerhans, including a section staining for insulin (red), with nuclei in cyan (a); and islet cells in culture, with insulin (green) and nuclei stained in blue (b).
Detectors & Imaging

Confocal Microscopy/Ophthalmology: Towards noninvasive detection of diabetic neuropathy

A new breed of compact confocal laser scanning microscopes is meeting everyday demands in life science research.
Cx23
Cx23
Cx23
Cx23
Cx23
Home

Microscope for education, training, and lab use by Olympus

The CX23 educational microscope is designed for medical students and in laboratory operations that take place in the field and in other nontraditional settings.
Content Dam Lfw Print Articles 2015 03 Nb Olympus Cd Height Map Fig Right Web
Content Dam Lfw Print Articles 2015 03 Nb Olympus Cd Height Map Fig Right Web
Content Dam Lfw Print Articles 2015 03 Nb Olympus Cd Height Map Fig Right Web
Content Dam Lfw Print Articles 2015 03 Nb Olympus Cd Height Map Fig Right Web
Content Dam Lfw Print Articles 2015 03 Nb Olympus Cd Height Map Fig Right Web
Detectors & Imaging

Olympus microscope recovers data from damaged optical media

The LEXT OLS4000 laser-scanning confocal microscope from Olympus can provide both visual and height maps of damaged CD and DVD optical media.
1501prod Olympus
1501prod Olympus
1501prod Olympus
1501prod Olympus
1501prod Olympus
Test & Measurement

Microscope from Olympus measures machined parts and electronics

The STM7 measuring microscope is an industrial microscope system that measures machined parts, semiconductors, and electronic components.
(Courtesy of Santa Barbara Imaging)
FIGURE 1. A compact single-objective microscope by Santa Barbara Imaging (a) finds use, for example, in microelectronics inspection (b).
FIGURE 1. A compact single-objective microscope by Santa Barbara Imaging (a) finds use, for example, in microelectronics inspection (b).
FIGURE 1. A compact single-objective microscope by Santa Barbara Imaging (a) finds use, for example, in microelectronics inspection (b).
FIGURE 1. A compact single-objective microscope by Santa Barbara Imaging (a) finds use, for example, in microelectronics inspection (b).
FIGURE 1. A compact single-objective microscope by Santa Barbara Imaging (a) finds use, for example, in microelectronics inspection (b).
Test & Measurement

Photonics Products: Microscopes: Industrial microscopes aid precision manufacturing

The fine tolerances required in many branches of modern industry naturally lead to the use of microscopes for inspection, assembly, and characterization.
NIGHTSEA's Stereo Microscope Fluorescence Adapter (SFA) system, shown with the Royal Blue setup, lets stereomicroscope owners add fluorescence capability with very little expense.
NIGHTSEA's Stereo Microscope Fluorescence Adapter (SFA) system, shown with the Royal Blue setup, lets stereomicroscope owners add fluorescence capability with very little expense.
NIGHTSEA's Stereo Microscope Fluorescence Adapter (SFA) system, shown with the Royal Blue setup, lets stereomicroscope owners add fluorescence capability with very little expense.
NIGHTSEA's Stereo Microscope Fluorescence Adapter (SFA) system, shown with the Royal Blue setup, lets stereomicroscope owners add fluorescence capability with very little expense.
NIGHTSEA's Stereo Microscope Fluorescence Adapter (SFA) system, shown with the Royal Blue setup, lets stereomicroscope owners add fluorescence capability with very little expense.
Microscopy

BIOIMAGING/MICROSCOPY/NEUROSCIENCE: Low cost and advanced imaging apply beyond Neuroscience audience

Low cost was a theme at the 2013 Society for Neuroscience annual meeting (November 9–13, San Diego, CA), as vendors demonstrated their responses to the effect of funding cuts ...
James Di Loreto, Smithsonian
The Olympus donation of 50 microscopes to the Smithsonian will help quench the public’s curiosity via the new Smithsonian Q?rius education center.
The Olympus donation of 50 microscopes to the Smithsonian will help quench the public’s curiosity via the new Smithsonian Q?rius education center.
The Olympus donation of 50 microscopes to the Smithsonian will help quench the public’s curiosity via the new Smithsonian Q?rius education center.
The Olympus donation of 50 microscopes to the Smithsonian will help quench the public’s curiosity via the new Smithsonian Q?rius education center.
The Olympus donation of 50 microscopes to the Smithsonian will help quench the public’s curiosity via the new Smithsonian Q?rius education center.
Research

Olympus donates 50 microscopes to Smithsonian Q?rius education center

Center Valley, PA--Olympus is supporting the 10,000 square-foot Q?rius (pronounced 'curious') experiential learning center at the Smithsonian with a donation of dozens of microscopes...
(Image courtesy of Olympus America)
FIGURE 1. An Olympus multiphoton microscope and a 4 mm SCALEVIEW-matched 25x objective created this image of 4 mm of depth through a SCALEVIEW-cleared mouse brain. The image was isosurface-rendered and blended in Imaris from Bitplane Scientific Software. The side panels show z-panels at 1 mm intervals.
FIGURE 1. An Olympus multiphoton microscope and a 4 mm SCALEVIEW-matched 25x objective created this image of 4 mm of depth through a SCALEVIEW-cleared mouse brain. The image was isosurface-rendered and blended in Imaris from Bitplane Scientific Software. The side panels show z-panels at 1 mm intervals.
FIGURE 1. An Olympus multiphoton microscope and a 4 mm SCALEVIEW-matched 25x objective created this image of 4 mm of depth through a SCALEVIEW-cleared mouse brain. The image was isosurface-rendered and blended in Imaris from Bitplane Scientific Software. The side panels show z-panels at 1 mm intervals.
FIGURE 1. An Olympus multiphoton microscope and a 4 mm SCALEVIEW-matched 25x objective created this image of 4 mm of depth through a SCALEVIEW-cleared mouse brain. The image was isosurface-rendered and blended in Imaris from Bitplane Scientific Software. The side panels show z-panels at 1 mm intervals.
FIGURE 1. An Olympus multiphoton microscope and a 4 mm SCALEVIEW-matched 25x objective created this image of 4 mm of depth through a SCALEVIEW-cleared mouse brain. The image was isosurface-rendered and blended in Imaris from Bitplane Scientific Software. The side panels show z-panels at 1 mm intervals.
Fluorescence

MICROSCOPY/DEEP TISSUE IMAGING: Deeper focus in microscopic bioimaging

Advanced clearing agents, optimized objectives, and innovative light sources allow deeper imaging inside specimens -- including living organisms.
(Image courtesy of Martin Microscope Company)
FIGURE 1. Scientists can create incredible images with high-definition (HD) systems, such as a HD camera and microscope adapter from Martin Microscope Company.
FIGURE 1. Scientists can create incredible images with high-definition (HD) systems, such as a HD camera and microscope adapter from Martin Microscope Company.
FIGURE 1. Scientists can create incredible images with high-definition (HD) systems, such as a HD camera and microscope adapter from Martin Microscope Company.
FIGURE 1. Scientists can create incredible images with high-definition (HD) systems, such as a HD camera and microscope adapter from Martin Microscope Company.
FIGURE 1. Scientists can create incredible images with high-definition (HD) systems, such as a HD camera and microscope adapter from Martin Microscope Company.
Microscopy

MICROSCOPY/ADVANCED BIOIMAGING: Life in HD: A new view of microscopic imaging

Advances in consumer video equipment are providing new options for life scientists: High-definition (HD) cameras and monitors improve resolution and facilitate image sharing.
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Fv1200jpg Opens To 10mb
Fv1200jpg Opens To 10mb
Fv1200jpg Opens To 10mb
Fv1200jpg Opens To 10mb
Fluorescence

Laser scanning confocal microscope system by Olympus

The FluoView FV1200 laser scanning confocal microscope system from Olympus for live cell and tissue imaging requires less laser power, resulting in low phototoxicity and photobleaching...
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Fluorescence

Olympus microscope objectives offering from Edmund Optics

Edmund Optics (Barrington, NJ) now offers four Olympus microscope objective families for bioimaging and microscopy applications. Plan Achromatic Objectives, available in 4, 10...
Biophotonics Tools

Teaching and routine microscope by Olympus

The CX22 series of microscopes from Olympus are designed for routine and educational microscopy.
Visiopharm Poster Screen
Visiopharm Poster Screen
Visiopharm Poster Screen
Visiopharm Poster Screen
Visiopharm Poster Screen
Cell Biology

Cell analysis software module by Olympus

Enabling quantitative cell analysis in cancer research, clinical research, and pathology, TissuemorphDP image analysis software from Olympus detects and classifies cell nuclei...
1122 Oeh29 Nov Dp73 Camera
1122 Oeh29 Nov Dp73 Camera
1122 Oeh29 Nov Dp73 Camera
1122 Oeh29 Nov Dp73 Camera
1122 Oeh29 Nov Dp73 Camera
Fluorescence

Digital cameras for microscopy from Olympus

The DP73 and DP73WDR digital cameras from Olympus provide a maximum resolution of 17.28 Mpixels for brightfield and fluorescence microscopy applications.
Olympus Integrated Technologies America 3DIR Metrology and Defect Review System
Olympus Integrated Technologies America 3DIR Metrology and Defect Review System
Olympus Integrated Technologies America 3DIR Metrology and Defect Review System
Olympus Integrated Technologies America 3DIR Metrology and Defect Review System
Olympus Integrated Technologies America 3DIR Metrology and Defect Review System
Test & Measurement

Olympus metrology and defect review system features laser scanning microscopy

A 3DIR Metrology and Defect Review System uses confocal IR laser scanning microscopy technology for measuring post-bond parameters of 3D stacked integrated circuits (3DS-ICs)....
1102 Oeh Count And Measure
1102 Oeh Count And Measure
1102 Oeh Count And Measure
1102 Oeh Count And Measure
1102 Oeh Count And Measure
Biophotonics Tools

Olympus microscopy software module for automated image analysis

The Count & Measure Solution module from Olympus (Center Valley, PA) for the cellSens Dimension software suite enables image analysis protocols by providing advanced object detection...
(Image courtesy of Dr. Igor Siwanowicz and Olympus America)
FIGURE 1. Dr. Igor Siwanowicz garnered First Prize for his image of a Daddy Longlegs taken using confocal microscopy. The sample was stained to visualize nuclei and F-actin, and shows not only the eyes' lenses (two large ovals), but also the retinas and optic nerves (trailing down at center back).
FIGURE 1. Dr. Igor Siwanowicz garnered First Prize for his image of a Daddy Longlegs taken using confocal microscopy. The sample was stained to visualize nuclei and F-actin, and shows not only the eyes' lenses (two large ovals), but also the retinas and optic nerves (trailing down at center back).
FIGURE 1. Dr. Igor Siwanowicz garnered First Prize for his image of a Daddy Longlegs taken using confocal microscopy. The sample was stained to visualize nuclei and F-actin, and shows not only the eyes' lenses (two large ovals), but also the retinas and optic nerves (trailing down at center back).
FIGURE 1. Dr. Igor Siwanowicz garnered First Prize for his image of a Daddy Longlegs taken using confocal microscopy. The sample was stained to visualize nuclei and F-actin, and shows not only the eyes' lenses (two large ovals), but also the retinas and optic nerves (trailing down at center back).
FIGURE 1. Dr. Igor Siwanowicz garnered First Prize for his image of a Daddy Longlegs taken using confocal microscopy. The sample was stained to visualize nuclei and F-actin, and shows not only the eyes' lenses (two large ovals), but also the retinas and optic nerves (trailing down at center back).
Cell Biology

Digital imaging competition brings bug-eyed splendor

The Olympus BioScapes competition has honored images and movies of human, plant and animal subjects as captured through light microscopes for the past eight years. Entries are...
Content Dam Etc Medialib New Lib Laser Focus World Online Articles 2011 02 50623
Content Dam Etc Medialib New Lib Laser Focus World Online Articles 2011 02 50623
Content Dam Etc Medialib New Lib Laser Focus World Online Articles 2011 02 50623
Content Dam Etc Medialib New Lib Laser Focus World Online Articles 2011 02 50623
Content Dam Etc Medialib New Lib Laser Focus World Online Articles 2011 02 50623
Test & Measurement

Olympus spectral reflectivity system eliminates need for backside coating

The USPM-RU III spectral reflectivity measurement system for optical manufacturing measures spherical, aspherical, flat, and other surfaces without any need for backside coating...
1072 Secondary Lg
1072 Secondary Lg
1072 Secondary Lg
1072 Secondary Lg
1072 Secondary Lg
Fluorescence

Olympus microscope series for clinical and research labs

The BX3 series of upright clinical and research microscopes from Olympus employs proprietary UIS2 optics manufactured from lead-free glass.
8 Lfw 26 Olympus
8 Lfw 26 Olympus
8 Lfw 26 Olympus
8 Lfw 26 Olympus
8 Lfw 26 Olympus
Optics

Microscope illuminator from Olympus for TIRF imaging

The Olympus cell^TIRF illuminator offers four individually controlled motorized laser inputs for simultaneousimage capture and instant setting and confirmation of the precise ...
A FLIM image of a cell with a GFP/RFP tandem construct. The red stripe is caused by acceptor photobleaching in this area that prevents an energy transfer-induced decrease in the fluorescence lifetime of the GFP.
A FLIM image of a cell with a GFP/RFP tandem construct. The red stripe is caused by acceptor photobleaching in this area that prevents an energy transfer-induced decrease in the fluorescence lifetime of the GFP.
A FLIM image of a cell with a GFP/RFP tandem construct. The red stripe is caused by acceptor photobleaching in this area that prevents an energy transfer-induced decrease in the fluorescence lifetime of the GFP.
A FLIM image of a cell with a GFP/RFP tandem construct. The red stripe is caused by acceptor photobleaching in this area that prevents an energy transfer-induced decrease in the fluorescence lifetime of the GFP.
A FLIM image of a cell with a GFP/RFP tandem construct. The red stripe is caused by acceptor photobleaching in this area that prevents an energy transfer-induced decrease in the fluorescence lifetime of the GFP.
Fluorescence

PicoQuant FLIM upgrade kit for Olympus two-photon confocal microscope

The Fluorescence Lifetime (FLIM) upgrade kit from PicoQuant (Berlin, Germany) is now also available for Olympus' FluoView FV1000MPE two-photon confocal microscope with non-descanned...
1003lfw18 Olympus
1003lfw18 Olympus
1003lfw18 Olympus
1003lfw18 Olympus
1003lfw18 Olympus
Test & Measurement

60X microscope objective from Olympus provides less than 0.2 microns chromatic aberration

The new Olympus 60X, NA 1.4 microscope objective is designed for use by cell biologists, neuroscientists, and others.