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ZEISS実験用顕微鏡とルーチンワークのためのソリューション

実験用ルーチン顕微鏡

ZEISSの実験用顕微鏡やソリューションのメリットを、ルーチンワークでご実感ください。

人間工学的に設計された顕微鏡を用いて、皆様の知識とメソッドを効率的にご活用ください。

コストパフォーマンスを最大限に生かした、堅固で使い易い顕微鏡はルーチンワークをスピードアップさせます。

  • 顕微鏡を使って細胞や体液を検査
  • 多くは1度に数時間を要するヒト、植物、または動物サンプルを準備、操作または記録
  • 血球の量、種類、特徴を評価
  • 操作が簡単で優れた光学性能を発揮する、便利で効率的な顕微鏡システム
  • ZEISS顕微鏡は人間工学的に設計されており、あらゆる作業手順に適応

Select your Field of Application

Clinical Laboratory

Analyze Blood, Urine or Tissues to Identify Diseases

Academic Laboratory

Sample Preparation, Cell Culture, and Quality Control in Research and University Laboratories

Food Analysis

Identify Ingredients, Additives and Undesirable Substances

Assisted Reproductive Technology

In Vitro Fertilization and Reproductive Medicine

Forensic Science

Get Physical Evidence in Forensic Science

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Tutorials

Basic concepts in microscopy
Through various sections, learn more about the principles of microscopy and get detailed advice and comments on how to use the different methods with your microscope. For instance, start with the concepts of image formation, numerical aperture and the Köhler illumination.

How the Microscope Forms Images

Optical microscopes belong to a class of instruments that are said to be diffraction limited, meaning that resolution is determined in part by the number of diffraction orders created by the specimen that can be successfully captured by the objective and imaged by the optical system.

Basic Microscopy

Köhler Illumination

Illumination of the specimen is the most important variable in achieving high-quality images in microscopy and critical photomicrography. Köhler illumination was first introduced in 1893 by August Köhler of the Carl Zeiss corporation as a method of providing the optimum specimen illumination.

Achieving High-Quality Images

Numerical Aperture and Resolution

The numerical aperture of a microscope objective is the measure of its ability to gather light and to resolve fine specimen detail while working at a fixed object (or specimen) distance. Resolution is determined by the number of diffracted wavefront orders captured by the objective.

Resolve Fine Specimen Detail

Basic Staining Methods in Laboratory Routine

Most of the cells and microorganisms you are observing with your light microscope are poor of color and contrast. To enhance the contrast and color of interesting features you can apply different stains (dyes).

Papanicolaou (PAP) stain