The ATR-FTIR imaging enables one to make spatially resolved chemical snapshots of microscopic objects, specifically cells and tissue, as a function of time ("chemical photography") and this could be fully exploited in the study of biological objects such as cells and tissues (e.g. see Kazarian S. G., Chan K. L. A. "Applications of ATR-FTIR spectroscopic imaging to biomedical samples" Biochimica et Biophysica Acta (BBA) - Biomembranes 1758 (2006) 858-867  or  Kazarian S. G., Chan K. L.A. ATR-FTIR spectroscopic imaging: recent advances and applications to biological systems (Tutorial review) Analyst  138 (2013) 1940-1951 (doi)  or  our recent paper: Chan K. L. A., Kazarian S. G. Attenuated total reflection Fourier-transform infrared (ATR-FTIR) imaging of tissues and live cells   Chemical Society Reviews (2016) 45, 1850-1864 (doi)   

The range of our applications of ATR-FTIR imaging to biomedical field is broad. These were achieved by collaboration with scientists in different biomedical disciplines. Our successful collaboration with experts in atherosclerosis, Prof. M. J. Lever and Prof. Weinberg from the Department of Bioengineering at Imperial College London and Prof. R. K. Upmacis from Department of Pathology and Laboratory Medicine, Center of Vascular Biology at Cornell University showed ability of ATR-FTIR imaging to analyse arterial samples; while collaboration with the Department of Materials demonstrated success of imaging for biomaterials in tissue engineering. Collaboration with Dr. Mantalaris (imperial College London) resulted in successful applications of ATR-FTIR imaging in stem cells research while collaboration with Prof. N. Chayen (Department of Bio-Molecular Medicine, Imperial College London) led to the first example of imaging of crystallization of proteins. This research currently continues in collaboration with Dr. Bernadette Byrne (Department of Life Sciences, Imperial College London) via current grant from BBSRC (BRIC) "Application of ATR-FTIR imaging to industrial scale production of therapeutic antibodies". These successful applications open a broad and exciting range of opportunities for medical research. Indeed, ATR-FTIR spectroscopic imaging is destined to be successful in biomedical research and analytical applications.

Projects in this field have included:                                                                                    Chemical Society Reviews 45 (2016) back coverATR-FTIR imaging


Protein crystallisation

Skin and transdermal drug delivery

Live cancer cells and cancer tissues

Human hair