Quantitative fluorescence microscopy

V. E. Centonze; A. Takahashi; E. Casanova; B. Herman

doi:10.1179/his.2000.23.3.229

Quantitative fluorescence microscopy

V. E. Centonze, A. Takahashi, E. Casanova, B. Herman

Biomedical Engineering

Research output: Contribution to journal › Article › peer-review

7 Scopus citations

Abstract

Quantitative fluorescence microscopy has exploited the principle that the excitation wavelengths of biological molecules is always lower than their emission wavelengths. This has enabled scientists to visualize biological structures and their functions. The addition of immunofluorescence techniques allowed the specificity of antibody-hapten bonds and naturally occurring ligands to be used to generate specific probes. New filter designs made it possible to simultaneously detect multiple fluorophores with even greater specificity. These, however, were only qualitative observations. The latest developments in engineered probes and microscopy methods such as radiometric imaging, fluorescence resonance energy transfer imaging, and fluorescence lifetime imaging have permitted quantitative measurements. This review examines the latest in quantification techniques and their applications.

Original language	English (US)
Pages (from-to)	229-234
Number of pages	6
Journal	Journal of Histotechnology
Volume	23
Issue number	3
DOIs	https://doi.org/10.1179/his.2000.23.3.229
State	Published - 2000

Keywords

Emission wavelengths
Excitation wavelengths
FLIM
FRET

Access

10.1179/his.2000.23.3.229

OpenUrl availability

Full text

Cite this

@article{bffd78a44e314571a8ca3a39d3b3d427,

title = "Quantitative fluorescence microscopy",

abstract = "Quantitative fluorescence microscopy has exploited the principle that the excitation wavelengths of biological molecules is always lower than their emission wavelengths. This has enabled scientists to visualize biological structures and their functions. The addition of immunofluorescence techniques allowed the specificity of antibody-hapten bonds and naturally occurring ligands to be used to generate specific probes. New filter designs made it possible to simultaneously detect multiple fluorophores with even greater specificity. These, however, were only qualitative observations. The latest developments in engineered probes and microscopy methods such as radiometric imaging, fluorescence resonance energy transfer imaging, and fluorescence lifetime imaging have permitted quantitative measurements. This review examines the latest in quantification techniques and their applications.",

keywords = "Emission wavelengths, Excitation wavelengths, FLIM, FRET",

author = "Centonze, {V. E.} and A. Takahashi and E. Casanova and B. Herman",

year = "2000",

doi = "10.1179/his.2000.23.3.229",

language = "English (US)",

volume = "23",

pages = "229--234",

journal = "Journal of Histotechnology",

issn = "0147-8885",

publisher = "Maney Publishing",

number = "3",

}

TY - JOUR

T1 - Quantitative fluorescence microscopy

AU - Centonze, V. E.

AU - Takahashi, A.

AU - Casanova, E.

AU - Herman, B.

PY - 2000

Y1 - 2000

N2 - Quantitative fluorescence microscopy has exploited the principle that the excitation wavelengths of biological molecules is always lower than their emission wavelengths. This has enabled scientists to visualize biological structures and their functions. The addition of immunofluorescence techniques allowed the specificity of antibody-hapten bonds and naturally occurring ligands to be used to generate specific probes. New filter designs made it possible to simultaneously detect multiple fluorophores with even greater specificity. These, however, were only qualitative observations. The latest developments in engineered probes and microscopy methods such as radiometric imaging, fluorescence resonance energy transfer imaging, and fluorescence lifetime imaging have permitted quantitative measurements. This review examines the latest in quantification techniques and their applications.

AB - Quantitative fluorescence microscopy has exploited the principle that the excitation wavelengths of biological molecules is always lower than their emission wavelengths. This has enabled scientists to visualize biological structures and their functions. The addition of immunofluorescence techniques allowed the specificity of antibody-hapten bonds and naturally occurring ligands to be used to generate specific probes. New filter designs made it possible to simultaneously detect multiple fluorophores with even greater specificity. These, however, were only qualitative observations. The latest developments in engineered probes and microscopy methods such as radiometric imaging, fluorescence resonance energy transfer imaging, and fluorescence lifetime imaging have permitted quantitative measurements. This review examines the latest in quantification techniques and their applications.

KW - Emission wavelengths

KW - Excitation wavelengths

KW - FLIM

KW - FRET

UR - http://www.scopus.com/inward/record.url?scp=0033865705&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=0033865705&partnerID=8YFLogxK

U2 - 10.1179/his.2000.23.3.229

DO - 10.1179/his.2000.23.3.229

M3 - Article

AN - SCOPUS:0033865705

SN - 0147-8885

VL - 23

SP - 229

EP - 234

JO - Journal of Histotechnology

JF - Journal of Histotechnology

IS - 3

ER -

Quantitative fluorescence microscopy

Abstract

Keywords

Access

OpenUrl availability

Other files and links

Fingerprint

Cite this