Title :
Thermal Monitoring: Raman Spectrometer System for Remote Measurement of Cellular Temperature on a Microscopic Scale
Author :
Pikov, Victor ; Siegel, Peter H.
Abstract :
A simple setup was demonstrated for remote temperature monitoring of water, water-based media, and cells on a microscopic scale. The technique relies on recording changes in the shape of a stretching band of the hydroxyl group in liquid water at 3,100-3,700 cm-1. Rather than direct measurements in the near-infrared (IR), a simple Raman spectrometer setup was realized. The measured Raman shifts were observed at near optical wavelengths using an inverted microscope with standard objectives in contrast to costly near-IR elements. This allowed for simultaneous visible inspection through the same optical path. An inexpensive 671-nm diode pump laser (<100 mW), standard dichroic and lowpass filters, and a commercial 600-1,000 nm spectrometer complete the instrument.
Keywords :
Raman spectroscopy; biothermics; cellular biophysics; low-pass filters; semiconductor lasers; water; Raman shifts; Raman spectrometer system; cells; cellular temperature; diode pump laser; hydroxyl group; inverted microscope; liquid water; lowpass filter; optical wavelengths; remote measurement; size 600 nm to 1000 nm; spectrometer; standard dichroic filter; thermal monitoring; water-based media; wavelength 671 nm; Optical filters; Optical microscopy; Optical pumping; Optical recording; Raman scattering; Remote monitoring; Spectroscopy; Temperature measurement; Temperature sensors; Wavelength measurement; Cell Physiological Phenomena; Equipment Design; Equipment Failure Analysis; Reproducibility of Results; Sensitivity and Specificity; Signal Processing, Computer-Assisted; Spectrum Analysis, Raman; Temperature; Thermography;
Journal_Title :
Engineering in Medicine and Biology Magazine, IEEE
DOI :
10.1109/MEMB.2009.935468
