Carmichael’s Concise Review Coming Events
2011 EMAS 2011 May 15–19, 2011 Angers, France
www.emas-web.net
IUMAS-V May 22–27, 2011 Inchon, South Korea
www.iumas5.org
MSC/SCM Annual Meeting June 7–10, 2011 Ottawa, Canada
Inter/Micro: 62nd Conference June 11–15, 2011 Chicago, IL
www.mcri.org/home/section/101/intermicro
Microscopy & Microanalysis 2011 August 7–11, 2011 Nashville, TN
Microscopy Conference MC 2011 August 28–September 11, 2011 Kiel, Germany
www.mc2011.de
ICXOM21 September 5–8, 2011 Campinas, Brazil
icxom21.lnls.br
EMAG 2011 September 6–9, 2011 Birmingham, UK
www.emag-iop.org
FEMMS 2011 September 18–23, 2011 Sonoma County, CA
www.femms2011.llnl.gov
CIASEM 2011 September 25–30, 2011 Mérida, Mexico
www.ciasem.com
Neuroscience 2011 November 12–16, 2011 Washington, DC
www.sfn.org
2012 Microscopy & Microanalysis 2012 July 29–August 2, 2012 Phoenix, AZ
2013 Microscopy & Microanalysis 2013 August 4–8, 2013 Indianapolis, IN
2014 Microscopy & Microanalysis 2014 August 3–7, 2014 Hartford, CT
More Meetings and Courses Check the complete calendar near the back of this magazine and in the MSA journal Microscopy and Microanalysis.
8
Microscopy is Only Skin Deep Stephen W. Carmichael Mayo Clinic, Rochester, MN 55905
carmichael.stephen@
mayo.edu Light optical imaging techniques that don’t require labels are attractive for human studies
because they are not toxic nor do they perturb the system being studied. Whereas there are several methods available to provide microscopic imaging below the surface of a tissue, they each suff er from limitations, such as low spatiotemporal resolution and a limited number of molecular signatures that can be imaged. Raman spectroscopy off ers label-free contrast for major chemical species in tissue, such as water, lipids, DNA, and proteins based on vibrational spectra at light optical wavelengths. However, the Raman signal is very weak, which makes it diffi cult to image a sample with good temporal resolution. T e recent development of stimulated Raman scattering (SRS) microscopy can overcome these limitations as demonstrated by the elegant studies of Brian Saar, Christian Freudiger, Jay Reichman, Michael Stanley, Gary Holton, and Sunney Xie [1]. Saar et al. improved the optics and electronics for the acquisition of the backscattered signal of SRS. In SRS microscopy, the sample is excited by two lasers at diff erent frequencies. When the diff erence in frequency matches a molecular vibration in the sample, the intensities of the probes change in a predictable manner. T ese intensity changes are small, but Saar et al. developed a new method to detect them. T ey chopped one of the laser beams at high frequency (MHz) and detected the intensity change in the other beam, which off ered superior sensitivity. T e key component was a custom-made all-analog lock-in amplifi er with a very short (about 100 ns) response time. T e laser probe wavelengths were tuned to match a vibrational frequency of interest and raster-scanned across the sample. Frequencies were tuned to detect CH2 stretching (primarily for lipids), OH stretching (primarily water), and CH3 stretching (primarily proteins) vibrations. Imaging of water is of particular interest in studying the transport of water-soluble compounds such as drugs. SRS microscopy relies on back-
scattering of the forward-directed signal by the tissue sample. In biological tissues the backscattered signal is too weak to be detected by an objective lens to allow for high-speed imaging. T is limitation was overcome by placing a photodetector directly in front of the objective lens and sending the excitation probes through an aperture in the center of the detector. T is and other modifi cations allowed greater collection of backscattered signal to increase the imaging speed by three orders of magnitude! In a proof-of-concept experiment,
Saar et al. studied the penetration of a small-molecule drug (trans-retinol, which stimulates collagen synthesis) and showed that in vivo it penetrated mouse skin via the hair shaſt , one of three hypothesized penetration routes. Similar studies showed the value of SRS microscopy on human skin in a living volunteer (Figure 1). T is powerful label-free imaging modality can now be applied to a broad range of problems in whole living organisms. T is is likely to play an increasingly important role in clinical diagnostic procedures.
Figure 1: SRS skin imaging in living humans. (A-C) SRS images of
the stratum corneum and viable epidermis
tuned into CH3 stretching vibration of proteins (2950 cm–1) showing nuclei of variable size (A and B) as well as a hair (C). (D) SRS image of DMSO penetrating the skin at the same region as (C). DMSO accumulates in the hair shaft. Deuterium labeling was used to create a unique vibration of d6-DMSO at 2120 cm–1 for specifi c imaging. Images are acquired in the epi-direction on the forearm of a volunteer (the principal investigator). Image acquisition time was 150 ms for (A) and (B) and 37 ms for (C) and (D), all with 512 × 512 pixel sampling. Scale: 50 microns [1].
References [1] BG Saar, CW Freudinger, J Reichman, CM Stanley, GR Holtom, and XS Xie, Science 330 (2010) 1368–70.
[2] T e author gratefully acknowledges Drs. Sunney Xie and Brian Saar for reviewing this article.
doi:10.1017/S1551929511000368
www.microscopy-today.com • 2011 May
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