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Biomedical Optics: Multichannel Spectroscopy Andrew Berger The Institute of Optics University of Rochester Quantum-Limited Imaging Detectors Symposium.

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Presentation on theme: "Biomedical Optics: Multichannel Spectroscopy Andrew Berger The Institute of Optics University of Rochester Quantum-Limited Imaging Detectors Symposium."— Presentation transcript:

1 Biomedical Optics: Multichannel Spectroscopy Andrew Berger The Institute of Optics University of Rochester Quantum-Limited Imaging Detectors Symposium Rochester Institute of Technology March 2, 2009 3 biomedical spectroscopy arenas detectors used daring to dream

2 Biomedical Optics: Application Areas diffuse photon propagation fluorescence lifetime spectroscopy Raman spectroscopy barely imaging!!!

3 Breast imaging: Computed Tomography CT-scan (x-ray) detectors sources scattering << absorption  paths = straight lines numerical reconstruction (courtesy F. Bevilacqua)

4 Breast imaging: Optical Computed Tomography near-infrared light detectors sources scattering >> absorption  broad probability of paths http://www.medphys.ucl.ac.uk/research/borg/index.htm (courtesy F. Bevilacqua)

5 Area #1: Diffuse photon propagation

6 Where biomedical optics lives…. DNA courtesy V. Venugopalan, http://www.osa.org/meetings/archives/2004/BIOMED/program/#educ biological window

7 Important near-IR absorbers 0.3 g/cm 3 fat 19 M water 11mM Hb 32 mM HbO 2

8 Near-infrared cerebral blood monitoring light in (690, 830 nm) light out

9

10 Seeing functional responses: visual stimulation

11 far Sample near 830 nm 690 nm Avalanche photodiodes High Speed DAQ Card for demultiplexing Brain monitoring system layout 1-10 kHz modulation for wavelength encoding    Decoded Wavelength Data 830 nm 690 nm Source 1 Source 2 Analog Out DAQ Card

12 Typical detector for NIRS work Hamamatsu silicon avalanche photodiode modules Frequency rolloff in low MHz to GHz Spectral response out to 1000 nm

13 Time-resolved measurements pulse at t=0remitted light at t > 0 absorption and scattering r

14 Hand-Held Optical Breast Scanner

15 Pham, TH., et al. Review of Scientific Instruments, 71, 1 – 14, (2000). Bevilacqua, F., et al. Applied Optics, 39, 6498-6507, (2000). Jakobowski et al., J. Biomed. Opt., 9(1), 230-238 (2004). Hand-Held Optical Breast Scanner (courtesy F. Bevilacqua)

16 Heavily multiplexed systems! B. W. Pogueet al, Opt. Express 1, 391-403 (1997), http://www.opticsexpress.org/abstract.cfm?URI=OPEX-1-13-391

17 http://www-nml.dartmouth.edu/nir/instrumentation.html

18 Diffuse propagation: goals, requirements Distinguish benign from malignant tumor tissue Map blood activity (hemodynamics) within brain Sense deep within tissue (cm) Record at many locations Record at many wavelengths Time resolution to few psec

19 Area #2: Fluorescence lifetime spectroscopy Once again, psec-nsec timescale!

20 Fluorescence lifetime spectroscopy brain tissue Butte et al., “Diagnosis of meningioma by time-resolved fluorescence spectroscopy,” Journal of Biomedical Optics 10(6), 064026 (November/December 2005).

21 Instrumentation for temporal fluorescence Fang et al.

22 Same idea, different group!

23 Fluorescence lifetime: goals, requirements Distinguish benign from malignant tumor tissue Record at many wavelengths Time resolution required to few psec Desirable to record at many locations (imaging)

24 Area #3: Raman spectroscopy incident photon with energy E molecule

25 Raman spectroscopy molecule gains energy  E scattered photon has energy E -  E incident photon with energy E to detector

26 783 1005 1457 1651 1092 1340 1259 1211 902 853 813 720 667 619 1580 1127 phenylalanine guanine adenine cytosine, uracil phenylalanine C-H 2 def. amide I amide III C-N, C-C str. tyrosine Raman shift (cm -1 ) intensity (arb. units) aromatic amino acids RNA bases Raman spectrum of immune cell

27 Detectors for Raman spectroscopy Thermoelectrically-cooled CCD array detectors Sensitive out to ~1150 nm, limited by Si bandgap 25 micron square pixels typical dimensions, 256 x 1024 pixels Princeton Instruments PIXIS CCD

28 Raman spectroscopy: goals, requirements Distinguish one cell type/state from another Quantify chemical levels in biofluids (e.g. blood) Yes, distinguish cancer from non-cancer Record at many wavelengths Long acquisition times (sec-minutes) Necessary to wavelength-tune down the fluorescence Desirable to time-gate away the fluorescence (intensified CCD or more exotic gating)

29 Benefits of QLIDs for biomedical optics psec temporal resolution spectral resolution thousands of pixels spectral range [noise...] Diffuse photons Fluorescence lifetime Raman

30 Summary biomedical spectroscopy: characterize tissue, biofluids, cells frequently in near-IR multiple factors driving sub-nsec time resolution many-many-channel sensing: a game-changer get past the Si bandgap cutoff spectral resolution at each pixel: good for diffuse spectroscopy Questions?

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