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Evolution of Scientific Digital Imaging Technologies and their Applications

As important as an optical microscope system is to provide images with high resolution and contrast, digitizing the image seen through the eyepiece is equally important. This dramatically increases your ability to enhance features, extract information, and tell a meaningful story.

We have come a long way with respect to image capture, from photomicrography on a film to highly sensitive digital imaging that allows you to detect even single molecules. Digital imaging has allowed scientists to not only record their data, but also analyze it using new software technologies with artificial intelligence.

Digital cameras designed for life science have evolved considerably, and numerous technologies are available. From CCDs, to EMCCDs, to sCMOS, each technology has pros and cons and must be carefully chosen based on the application.

In this talk, Dr. Lin covers some critical facts about scientific digital cameras. He also discusses the evolution of these cameras, the solutions that Olympus offers, and how they are used in current advanced microscopy systems for various applications.

Presenter: Guo Lin, PhD
Manager, Product & Application, Olympus Signapore

Dr. Lin got his PhD back in 2010 in National University of Singapore working on biophysical research. From 2009 he joined Olympus as Technical and Application specialist taking care of laser based high end imaging system. In 2012, Lin decided to move back to China and taking a position with one of the leading scientific camera manufacturers Photometrics. There, he started as application specialist, later become regional sales manager and finally scientific sales manager for Asia Pacific. In 2021, Lin moved back to Singapore, joining Olympus Singapore as the manager for product and application. Lin has a long experience of various techniques on scientific digital imaging including various camera technologies.


Produits associés

Caméras numériques pour microscope

EM-CCD

Les caméras à CCD à multiplication d’électrons amplifient les signaux optiques sans augmenter le bruit. Elles peuvent prendre des images à grande vitesse d’échantillons de faible luminosité et fonctionnent bien pour l’imagerie de fluorescence de cellules vivantes avec une lumière d’excitation de faible intensité. Elles sont utilisées pour observer l’interaction des protéines dans une cellule et pour l’imagerie en temps réel.

  • Technologie CCD pour la détection de lumière ultrafaible
  • Plateforme de caméras scientifiques ultrasensibles spécialisées
  • Imagerie quantifiable et reproductible
Caméras numériques pour microscope

sCMOS

Les caméras CMOS scientifiques (sCMOS) sont optimisées pour l’imagerie de cellules vivantes grâce à un bruit réduit et une efficacité quantique améliorée par rapport aux caméras CMOS classiques. Parmi les caractéristiques des caméras sCMOS, on compte leur réponse extrêmement rapide, leurs larges gammes dynamiques, leur champ de vision étendu, leur haute résolution et leur capacité de gradation.

  • Lecture extrêmement rapide pour une grande vitesse
  • Conçues pour les applications exigeant une haute résolution
  • Images à rapport signal sur bruit élevé pour les applications d’imagerie de cellules vivantes

Evolution of Scientific Digital Imaging Technologies and their Applications

As important as an optical microscope system is to provide images with high resolution and contrast, digitizing the image seen through the eyepiece is equally important. This dramatically increases your ability to enhance features, extract information, and tell a meaningful story.

We have come a long way with respect to image capture, from photomicrography on a film to highly sensitive digital imaging that allows you to detect even single molecules. Digital imaging has allowed scientists to not only record their data, but also analyze it using new software technologies with artificial intelligence.

Digital cameras designed for life science have evolved considerably, and numerous technologies are available. From CCDs, to EMCCDs, to sCMOS, each technology has pros and cons and must be carefully chosen based on the application.

In this talk, Dr. Lin covers some critical facts about scientific digital cameras. He also discusses the evolution of these cameras, the solutions that Olympus offers, and how they are used in current advanced microscopy systems for various applications.

Presenter: Guo Lin, PhD
Manager, Product & Application, Olympus Signapore

Dr. Lin got his PhD back in 2010 in National University of Singapore working on biophysical research. From 2009 he joined Olympus as Technical and Application specialist taking care of laser based high end imaging system. In 2012, Lin decided to move back to China and taking a position with one of the leading scientific camera manufacturers Photometrics. There, he started as application specialist, later become regional sales manager and finally scientific sales manager for Asia Pacific. In 2021, Lin moved back to Singapore, joining Olympus Singapore as the manager for product and application. Lin has a long experience of various techniques on scientific digital imaging including various camera technologies.


Produits associés

Caméras numériques pour microscope

EM-CCD

Les caméras à CCD à multiplication d’électrons amplifient les signaux optiques sans augmenter le bruit. Elles peuvent prendre des images à grande vitesse d’échantillons de faible luminosité et fonctionnent bien pour l’imagerie de fluorescence de cellules vivantes avec une lumière d’excitation de faible intensité. Elles sont utilisées pour observer l’interaction des protéines dans une cellule et pour l’imagerie en temps réel.

  • Technologie CCD pour la détection de lumière ultrafaible
  • Plateforme de caméras scientifiques ultrasensibles spécialisées
  • Imagerie quantifiable et reproductible
Caméras numériques pour microscope

sCMOS

Les caméras CMOS scientifiques (sCMOS) sont optimisées pour l’imagerie de cellules vivantes grâce à un bruit réduit et une efficacité quantique améliorée par rapport aux caméras CMOS classiques. Parmi les caractéristiques des caméras sCMOS, on compte leur réponse extrêmement rapide, leurs larges gammes dynamiques, leur champ de vision étendu, leur haute résolution et leur capacité de gradation.

  • Lecture extrêmement rapide pour une grande vitesse
  • Conçues pour les applications exigeant une haute résolution
  • Images à rapport signal sur bruit élevé pour les applications d’imagerie de cellules vivantes
Experts
Lin Guo
Manager, Product and Application Life Science Department Scientific Solutions Business Division
Olympus Singapore

Lin got his PhD back in 2010 in National University of Singapore working on biophysical research. From 2009 he joined Olympus as Technical and Application specialist taking care of laser based high end imaging system. In 2012, Lin decided to move back to China and taking a position with one of the leading scientific camera manufacturers Photometrics. There, he started as application specialist, later become regional sales manager and finally scientific sales manager for Asia Pacific. In 2021, Lin moved back to Singapore, joining Olympus Singapore as the manager for product and application. Lin has a long experience of various techniques on scientific digital imaging including various camera technologies.

Evolution of Scientific Digital Imaging Technologies and their Applicationsnov. 21 2024
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