HORIBA Worldwide

Steady State

• Sub-Picomolar Fluorescein
• Maintaining High Sensitivity when Working with Small-Volume Samples
• Front-face detection for high-concentrate, opaque or solid sample
• Photon Counting means sensitivity
• Immunoassay of Theophylline by fluorescence polarisation
• Kinetic determination of vitamin B1
• Screening and classifying hazardous waste samples
• Characterising galvenizing baths
• Flat panel displays
• Assessing UV damage of hair
• Characterisation of tooth decay
• FluoroMax multiwavelength capability
• Food science: increasing crop yields
• Non invasive in vivo determination of sunscreen UVA protection factors
• Linearization of SPEX-3D spectrofluorometer
• Fluorescent pigments in living coral
• Measurement of endogenous skin fluorescence in vivo on human skin
• How to select the best spectrofluorometer
• Wideband sensitivity of the FluoroLog-3
• Near IR capability of the FluoroLog
• Singlet Oxygen measurement
• Obtaining a contour map from multifiles or 3D data in DataMax
• Comparing spectrofluorometer specifications
• Automated sample handling
• Recording fluorescence quantum yields
• Low temperature macro photoluminescence and PLE
• Fluorescence Spectra from Carbon Nanotubes
• Photoluminescence Spectroscopy of Nanoparticles
• Microscope Adapter

LifeTime

• Cyclodextrin enhances room temperature phosphorescence
• Fluorescence lifetimes: time-domain or frequency domain?
• Phosphorescence lifetime measured using the SPEX® phosphorimeter
• Time gated separation of lanthanide luminescence
• Selective excitation of tryptophan fluorescence decay in proteins
  (Copyright 2005 American Institute of Physics. This article may be downloaded for personal use only. Any other use requires permission of the author and the American Institute of Physics. The article appeared in Applied Physics Letters 86, 261911 and may be found at: http://link.aip.org/link/?apl/86/261911)
• Excitation of fluorescence decay using a 265 nm pulsed light-emitting diode: Evidence for aqueous phenylalanine rotamers
  (Copyright 2006 American Institute of Physics. This article may be downloaded for personal use only. Any other use requires permission of the author and the American Institute of Physics. The article appeared in Applied Physics Letters 89, 063901 and may be found at: http://link.aip.org/link/?apl/89/063901)

Nanotechnology

• Fluorescence Spectra from Carbon Nanotubes
• Photoluminescence Spectroscopy of Nanoparticles
• Nanophotonics with Fluorescence Instruments

Biotechnology

• Immunoassay of Theophylline by fluorescence polarisation
• Kinetic determination of vitamin B1
• FluoroMax multiwavelength capability
• Fluorescent pigments in living coral

Applications:

Biology

Research marine organisms

Quantify cell-differentiation and green-fluorescent protein

Biochemistry

Protein-folding and conformation

Catalysis and transport

Mapping lipid bilayers

Chemistry

Properties of compounds

Detect reactions

Analyze effects of substituents

Donor-acceptor complexes

Singlet-oxygen

Photochemistry

Properties of macromolecules

Reactivity of photo-active organic compounds

Medicine

Trace amounts of active ingredients in biological samples

Quantify UV-damage to hair and skin

Study tooth-decay

Map tumors

Environmental Science

Trace levels of carcinogens and pollutants in water, soil, and air

Expose hazardous wastes

Improve crop yields

Food Technology

Trace components (proteins, vitamins, amino acids)

Trace contaminants

Food quality

Industry

Product reproducibility and reliability of manufacturing processes

Characterize optical brighteners in bleaches and detergents

Pharmaceuticals

Quality-assurance of drugs

Monitor drug-delivery, metabolites, and interactions during metabolism

Degradation and excretion rates of drugs

Materials-science

Research photoconductors, semiconductors, and phosphors

Characterize laser-diodes

Properties of nanomaterials, nanotubes, and nanotechnological devices