You have to be registered and logged in for purchasing articles.

Abstract

50 Years LASERS: In Vitro Diagnostics, Clinical Applications and Perspectives by Basile Spyropoulos

1960 Theodore Maiman built the first Ruby-LASER, starting-point for half a century of R&D on Biomedical LASER continuous improvement.
The purpose of this paper is to contribute a review of the often disregarded, however, extremely important Industrial Property documents of LASER-based in vitro Diagnostics devices. It is an attempt to sketch-out the patent-trail leading towards the modern Biomedical Laboratory and to offer an introduction to the employment of "exotic" systems, such as the Free Electron LASER (FEL), that are expected to focus on the fundamental processes of life, following chemical reactions and biological processes as they happen, on unprecedented time and size scales.
There are various in vitro LASER applications, however, the most important ones include:
• Hybrid Coulter Principle-LASER Hematology Analyzers
• Flow Cytometry systems
• Fluorescent in situ Hybridization (FISH Techniques)
• Confocal LASER Scanning Microscopy and Cytometry
From the first fluorescence-based flow Cytometry device developed in 1968 by Wolfgang Göhde until nowadays, numerous improvements and new features related to these devices appeared. The relevant industrial property milestone-documents and their overall numeral trends are presented.
In 1971, J. Madey invented and developed the Free Electron LASER (FEL), a vacuum-tube that uses a beam of relativistic electrons passing through a periodic, transverse magnetic field (wiggler) to produce coherent radiation, contained in an optical cavity defined by mirrors. A resonance condition that involves the energy of the electron beam, the strength of the magnetic field, and the periodicity of the magnet determines the wavelength of the radiation.
The FEL Coherent Light Sources like the Linac Coherent Light Source (LCLS) at Stanford, CA, USA or the X-ray Free Electron LASER (XFEL) at Hamburg, Germany , will work much like a high-speed (< 100 femtoseconds) camera, enabling scientists to take stop-motion pictures, on the nanoscale, of atoms and molecules in motion.
The curve of FEL-related patents of the last 20 years is much smoother than the corresponding one for in vitro Diagnostics conventional LASERS. If the diodes brought a LASER into almost everyone’s pocket, the above-mentioned super-imaging systems are huge facilities of enormous cost - the price to steal a look at the fundamental processes of life.

DOI: Clin. Lab. 2011;57:131-142