The first chiral Raman spectrum report of a protein: a perspective of 20 years.

In 1990 the article on the first Raman spectrum of a protein using a circularly polarized light as excitation radiation, authored by the group of Prof. L. Barron, was published in ChemComm. In this viewpoint we analyze this pioneering work and we used it as a starting point to highlight, after 20 years since its publication, the most outstanding contributions in the application of the Raman Optical Activity to proteins and biological systems.

The road to medical vibrational spectroscopy--a history.

The present Editorial chronicles the journey from classical infrared and Raman spectroscopy to medical vibrational spectroscopy, as experienced by a contemporary witness of the times. During the second half of the last century vibrational biospectroscopy became a topic of increasing global interest and has spawned a number of international conferences of which the most recent, SPEC 2012 - Shedding New Light on Disease, constitutes the basis of the present themed issue.

Electron-enhanced Raman scattering: a history of its discovery and spectroscopic applications to solution and interfacial chemistry.

Raman scattering spectroscopy can be used to distinguish highly similar molecules and obtain useful information on local physical and chemical environments at their functional group levels. However, obtaining a high-quality Raman spectrum requires high-power excitation and a long acquisition time owing to the inherently small Raman scattering cross section, which is problematic in the analyses of living cells and real-time environmental monitoring. Herein, a new Raman enhancement technique, electron-enhanced Raman scattering (EERS), is described in which artificially generated electrons affect the polarizability of target molecular systems and enhance their inherent Raman cross sections. The EERS technique stands in contrast to the well-known SERS technique, which requires roughened metal surfaces. The history of EERS and its spectroscopic applications to aqueous solutions are presented.

Spectroscopic view of life and work of the Nobel Laureate Sir C.V. Raman.

Raman spectroscopic and microscopic techniques have been used for nondestructive characterization of tissues and to differentiate benign and malignant tissues. The discovery of the principles of spectroscopy is credited to Sir C.V. Raman of India, who in 1930 brought the Nobel Prize in Physics to the East side of Suez. We present the life and work of Sir C.V. Raman with brief review of the uses of Raman spectroscopy in urology.

Prospects for in vivo Raman spectroscopy.

Raman spectroscopy is a potentially important clinical tool for real-time diagnosis of disease and in situ evaluation of living tissue. The purpose of this article is to review the biological and physical basis of Raman spectroscopy of tissue, to assess the current status of the field and to explore future directions. The principles of Raman spectroscopy and the molecular level information it provides are explained. An overview of the evolution of Raman spectroscopic techniques in biology and medicine, from early investigations using visible laser excitation to present-day technology based on near-infrared laser excitation and charge-coupled device array detection, is presented. State-of-the-art Raman spectrometer systems for research laboratory and clinical settings are described. Modern methods of multivariate spectral analysis for extracting diagnostic, chemical and morphological information are reviewed. Several in-depth applications are presented to illustrate the methods of collecting, processing and analysing data, as well as the range of medical applications under study. Finally, the issues to be addressed in implementing Raman spectroscopy in various clinical applications, as well as some long-term directions for future study, are discussed.

Raman spectroscopy in the study of biocompatibility.

This review deals with the application of Raman spectroscopy to the study of the biocompatibility of orthopaedic and ophthalmological materials and includes an introduction, a brief theory on the fundamental concepts of the technique, a description of the method and of the traditional and non-traditional instrumentation and a brief treatment of the surface properties of the different classes of materials. In the orthopaedic field, Raman studies on the structures of glasses, ceramic materials, carbon fibres and polymers before and after implantation are reviewed, particularly as far as structural modifications at the biomaterial-tissues interface are concerned. In the ophthalmological field, the chemical biocompatibility of hydrophobic and hydrophilic polymers for intraocular and intrastromal implants and for soft contact lenses is considered with respect to the presence of monomeric reactive centres in hydrophobic materials and the water amount in hydrophilic ones. The progress of the multichannel Raman technique for 'in-vivo' measurements is also described.