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Next-Generation IR Microscopy: The Devil Is in the Detail

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John Coates, Coates Consulting

One of the most important attributes of infrared spectroscopy is its ability to handle physically small samples or small features on samples. Important applications include forensic analysis of a crime scene, where infinitesimal evidentiary samples are collected for identification and/or characterization. Another consideration is the ability to isolate and characterize cell defects, including the cancerous regions of a biological specimen.

In the early days of IR spectroscopy, the issue was how to handle such small samples and how to get sufficient energy to them to enable recording a useful spectrum. The options ranged from using relatively low cost microsampling accessories, such as beam condensers, to specially configured microscope accessories.

For more than a decade, the role of the IR microscope has been growing, and dedicated products are available that enable microscopic-scale samples to be handled and characterized on a routine basis. Although these products can be extremely expensive – ranging from approximately $40,000 to $200,000 – they are one of the most valuable and cost-effective tools in the analytical arsenal. More recently, the biggest advances have been in imaging areas, with either mapping stages or imaging arrays, or combinations of both.

Until now, the application has been limited to standard Fourier transform infrared (FTIR) instrumentation interfaced to standard microscope platforms or adapted/customized microscopes optimized to handle atmospheric interference issues.

This article introduces a concept for IR microscopy based on a broadly tunable IR quantum cascade laser (QCL), where the improved spectral radiance of the laser provides more efficient optical coupling to smaller sampling areas, which can translate to more efficient spectrally specific IR imaging. The LaserScope from Block Engineering of Marlborough, Mass., is expected to enable the technology to expand into new application areas, especially in bioscience research and medical diagnostics.

IR microscopy: A history

There is nothing new or modern about the IR microscope; in 1953, Vincent J. Coates (no relation) published a paper on the design and performance of an IR microscope attachment.1 The attachment was the precursor to the first commercial IR microscopy system, which was offered by Perkin-Elmer Inc. The microscope was interfaced to a Model 12 single-beam dispersive spectrophotometer (Figure 1a).

Figure 1a.
The original PerkinElmer Model 12-based infrared microscope was made circa 1953. Courtesy of Coates Consulting.

In his publication, Coates cited applications including the measurement of fibers, crystals and biological tissues, then a major milestone. However, relative to modern spectroscopy and modern-day demeanor, this was not a practical solution because of the very long time required to record a spectrum of good quality. It was used as a specialist metric tool for certain high-tech industries but not employed as a general-purpose analytical tool.

Not until 1983, with the introduction of Digilab LLC’s IRMA (infrared microscope accessory), did the spectroscopist really become re-engaged with IR microscopy. This system, designed to interface to an FTIR spectrometer, provided a transmission-only method of measurement. Within about a year, it was replaced by the company’s UMA-100, which included the option of reflectance measurement. In the ensuing years, right up to the 2000s, we have seen iterations of FTIR-based microscopy products, ranging from smaller in-compartment accessories, such as the original Spectra-Tech Inc.’s Spectra-Scope (circa 1985), to a fully integrated FTIR microscope, the IRμS, introduced by Spectra-Tech in the 1990s.

Figure 1b.
The Block Engineering LaserScope, a next-generation IR microscope, uses a broadly tunable IR quantum cascade laser. Courtesy of Block Engineering.

Today, essentially all commercial FTIR manufacturers offer optimized IR microscope systems, and IR microscopy has become a routine analytical tool. Most of these systems provide some form of hyperspectral imaging, an extremely powerful tool for advanced materials characterization, forensic identification and, most importantly, medical diagnostics.

Researchers have long wanted to be able to study the chemistry of biological tissue, and this has become a reality: Cell histology results, normally subjectively provided based on the experience of the pathologist, can be validated by the chemistry of the cell based on IR spectral imaging. The principle of this measurement is summarized in Figure 2, where the false-color image illustrated in Figure 2c represents the changing diagnostic chemistry of a diseased cancer cell.

Figure 2.
Cancer cell histology: Shown is a comparison of traditional microscopy (a and b) and an IR microscopy-mapped image (c) and recorded spectra (d). Courtesy of professor Max Diem, Northeastern University.

Working beyond the limits

The process of FTIR microscopic imaging involves serial movement of the mapping stage of the microscope, where the IR beam is imaged to an area of a few microns. On a conventional instrument, this process is slow because of the high level of attenuation of the IR beam and the need to scan each spot location to provide an optimum signal-to-noise ratio (SNR) from the conventional light source of the spectrometer.

In recent work, high-performance imaging has been made possible by the integration of the high brightness of the synchrotron light source with the FTIR microscope. This has enabled high-resolution imaging in a practical time frame. Although a good solution, it is practical only in a research environment, and not everyone has a synchrotron in his/her backyard.

Although maybe not as high in total radiance, the QCL provides higher spectral radiance than the synchrotron source and significantly more than the standard FTIR source, as indicated in Figure 3. The spectral radiance, as a function of wavelength of the QCL, is approximately seven orders of magnitude greater than the FTIR source (note that the synchrotron is about three to four orders greater in spectral radiance).

Figure 3.
Comparison of the spectral radiance between the QCL laser and the FTIR light source. Courtesy of Block Engineering.

The FTIR traditionally uses a conventional extended thermal source, commonly in the form of an electrically heated ceramic element or rod. This limits how small the focused image of the source can become, thereby limiting the area that is efficiently imaged by the source without excessive throughput losses. On the other hand, the QCL is a point source, and this can be imaged down to a small spot without the associated losses of throughput.

The benefit of this source for handling small samples with reduced focused beam size can be appreciated from Figure 4, which compares the relative SNR, a practical measure of optical throughput, for FTIR versus the QCL. With a sample size of 100 µm, the throughput of the two systems is comparable, in terms of SNR. At 20 µm, the SNR is approximately 30 times greater for the QCL, which can equate to better spectral quality for the reduced sample size and/or shorter acquisition times.

Figure 4.
Comparison of relative SNR as a function of sample spot size, QCL vs. FTIR. Courtesy of Block Engineering.

Laser-based spectroscopy

The QCL technology provides the opportunity to have the tunable range from 6 (~1665 cm-1) to 12 µm (~830 cm-1). For many applications, this is the sweet spot and covers most of the “fingerprint” region of the IR spectrum. This is particularly the case for biological tissue, where one typically works in an aqueous environment, and where the range indicated above falls conveniently within an absorption window for water.

The QCL, combined with a microscope configured for infrared applications (Figure 1b), offers significant benefits based on the greater brightness of this source (Figure 3) and the improved SNR for an apertured sample image (Figure 4). An example of the anticipated spectral quality for the imaged laser source is demonstrated in Figure 5a for a sample of a polymer mounted behind a 20-µm pinhole (obtained without microscope optics). This spectrum, gained in approximately 0.5 s, is of high quality and compares qualitatively with the FTIR spectrum of a standard reference sample of the polymer (Figure 5b).

Figure 5.
At left is the spectrum of a polymer film taken through a 20-μm pinhole; at right, comparison of a standard FTIR reference spectrum of the polymer film material. Courtesy of Block Engineering.

A major advantage is expected to be in chemical imaging. The source brightness, although not the same as the synchrotron source, should provide much of the performance gains experienced with the synchrotron source. Also, because individual wavelengths can be scanned without having to record the entire spectrum (the inverse multiplex advantage), the wavelength-specific information used for chemical functionality mapping will enable higher-quality, higher-SNR spectra to be obtained in much shorter time frames than the FTIR systems.

The QCL also does not require the liquid nitrogen cooling of the standard MCT detector, as used on the FTIR microscope, which is not only an inconvenience but imposes a constraint on the relatively long acquisition times experienced with conventional sample mapping.


The integration of QCL with a microscope provides not only a next generation of performance, especially for spectral imaging, but also an advantage over the FTIR microscope with regard to packaging. An IR microscope takes up a lot of benchtop real estate, and there is a relatively high operational overhead caused by the need for liquid nitrogen cooling of the detector.

The system shown in Figure 1b has a lot less lab benchtop real estate than the conventional FTIR microscope, and in the future, the laser’s packaging will become smaller. It is expected that it will become physically integrated into the microscope, much like a standard light source.

In a way, IR microscopy has come full circle from the dispersive system first introduced in 1953 – but today, it is much more efficient and more compact.

Meet the author

John Coates is principal consultant at Coates Consulting in Newtown, Conn.; e-mail: [email protected].


1. V.J. Coates et al (1953). Design and performance of an infrared microscope attachment. J Opt Soc Am, Vol. 43, pp. 984-989.

Oct 2010
hyperspectral imaging
Methods for identifying and mapping materials through spectroscopic remote sensing. Also called imaging spectroscopy; ultraspectral imaging.
spectral radiance
Radiance per unit wavelength interval at a given wavelength, expressed in watts per steradian per unit area per wavelength interval.
An instrument for measuring spectral transmittance or reflectance.
Basic ScienceBiophotonicsbioscienceBlock Engineeringcancercell biologyCoatesCoates ConsultingdiagnosticsDigilab LLCFeaturesforensic analysisFourier transform infraredFTIRFTIR sourceFTIR-based microscopyhigh-resolution imaginghyperspectral imagingimaginginfraredIR microscopyIR spectral imagingIR spectroscopyIRµSIRMAJohn Coateslaser-based spectroscopyLaserscopelight sourcesMCT detectormedicinemicrosamplingmicroscopesMicroscopyoptical couplingPerkin-ElmerQCLSensors & Detectorssignal-to-noise ratiosingle-beam dispersive spectrophotometerSNRSpectra-ScopeSpectra-Tech Inc.spectral radiancespectrophotometerspectroscopythermal sourcetunable IR quantum cascade laserUMA-100lasers

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