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Time-domain diffuse optics

From Wikipedia, the free encyclopedia

Time-domain diffuse optics[1] or time-resolved functional near-infrared spectroscopy is a branch of functional near-Infrared spectroscopy which deals with light propagation in diffusive media. There are three main approaches to diffuse optics namely continuous wave[2] (CW), frequency domain[3] (FD) and time-domain[4] (TD). Biological tissue in the range of red to near-infrared wavelengths are transparent to light and can be used to probe deep layers of the tissue thus enabling various in vivo applications and clinical trials.

Physical concepts

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In this approach, a narrow pulse of light (< 100 picoseconds) is injected into the medium. The injected photons undergo multiple scattering and absorption events and the scattered photons are then collected at a certain distance from the source and the photon arrival times are recorded. The photon arrival times are converted into the histogram of the distribution of time-of-flight (DTOF) of photons or temporal point spread function. This DTOF is delayed, attenuated and broadened with respect to the injected pulse. The two main phenomena affecting photon migration in diffusive media are absorption and scattering. Scattering is caused by microscopic refractive index changes due to the structure of the media. Absorption, on the other hand, is caused by a radiative or non-radiative transfer of light energy on interaction with absorption centers such as chromophores. Both absorption and scattering are described by coefficients and respectively.

Multiple scattering events broaden the DTOF and the attenuation of a result of both absorption and scattering as they divert photons from the direction of the detector. Higher scattering leads to a more delayed and a broader DTOF and higher absorption reduces the amplitude and changes the slope of the tail of the DTOF. Since absorption and scattering have different effects on the DTOF, they can be extracted independently while using a single source-detector separation. Moreover, the penetration depth in TD depends solely on the photon arrival times and is independent of the source-detector separation unlike in CW approach.

Injected instrument response function and the reconstructed DTOF

The theory of light propagation in diffusive media is usually dealt with using the framework of radiative transfer theory under the multiple scattering regime. It has been demonstrated that radiative transfer equation under the diffusion approximation yields sufficiently accurate solutions for practical applications.[5] For example, it can be applied for the semi-infinite geometry or the infinite slab geometry, using proper boundary conditions. The system is considered as a homogeneous background and an inclusion is considered as an absorption or scattering perturbation.

The time-resolved reflectance curve at a point from the source for a semi-infinite geometry is given by

where is the diffusion coefficient, is the reduced scattering coefficient and is asymmetry factor, is the photon velocity in the medium, takes into account the boundary conditions and is a constant.

The final DTOF is a convolution of the instrument response function (IRF) of the system with the theoretical reflectance curve.

When applied to biological tissues estimation of and allows us to then estimate the concentration of the various tissue constituents as well as provides information about blood oxygenation (oxy and deoxy-hemoglobin) as well as saturation and total blood volume. These can then be used as biomarkers for detecting various pathologies.

Instrumentation

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Instrumentation in time-domain diffuse optics consists of three fundamental components namely, a pulsed laser source, a single photon detector and a timing electronics.

Sources

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Time-domain diffuse optical sources must have the following characteristics; emission wavelength in the optical window i.e. between 650 and 1350 nanometre (nm); a narrow full width at half maximum (FWHM), ideally a delta function; high repetition rate (>20 MHz) and finally, sufficient laser power (>1 mW) to achieve good signal to noise ratio.

In the past bulky tunable Ti:sapphire Lasers[6] were used. They provided a wide wavelength range of 400 nm, a narrow FWHM (< 1 ps) high average power (up to 1W) and high repetition (up to 100 MHz) frequency. However, they are bulky, expensive and take a long time for wavelength swapping.

In recent years, pulsed fiber lasers based on super continuum generation have emerged.[7] They provide a wide spectral range (400 to 2000 ps), typical average power of 5 to 10 W, a FWHM of < 10ps and a repetition frequency of tens of MHz. However, they are generally quite expensive and lack stability in super continuum generation and hence, have been limited in there use.

The most wide spread sources are the pulsed diode lasers.[8] They have a FWHM of around 100 ps and repetition frequency of up to 100 MHz and an average power of about a few milliwatts. Even though they lack tunability, their low cost and compactness allows for multiple modules to be used in a single system.

Detectors

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Silicon photomultiplier

Single photon detector used in time-domain diffuse optics require not only a high photon detection efficiency in the wavelength range of optical window, but also a large active area as well as large numerical aperture (N.A.) to maximize the overall light collection efficiency. They also require narrow timing response and a low noise background.

Traditionally, fiber coupled photomultiplier tubes (PMT) have been the detector of choice for diffuse optical measurements, thanks mainly due to the large active area, low dark count and excellent timing resolution. However, they are intrinsically bulky, prone to electromagnetic disturbances and they have a quite limited spectral sensitivity. Moreover, they require a high biasing voltage and they are quite expensive. Single photon avalanche diodes have emerged as an alternative to PMTS. They are low cost, compact and can be placed in contact, while needing a much lower biasing voltage. Also, they offer a wider spectral sensitivity and they are more robust to bursts of light. However, they have a much lower active area and hence a lower photon collection efficiency and a larger dark count. Silicon photomultipliers (SiPM) are an arrays of SPADs with a global anode and a global cathode and hence have a larger active area while maintaining all the advantages offered by SPADs. However, they suffer from a larger dark count and a broader timing response.[9]

Timing electronics

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The timing electronics is needed to losslessly reconstruct the histogram of the distribution of time of flight of photons. This is done by using the technique of time-correlated single photon counting[10] (TCSPC), where the individual photon arrival times are marked with respect to a start/stop signal provided by the periodic laser cycle. These time-stamps can then be used to build up histograms of photon arrival times.

The two main types of timing electronics are based on a combination of time-to-analog converter (TAC) and an analog-to-digital converter (ADC), and time-to-digital converter[11] (TDC), respectively. In the first case, the difference between the start and the stop signal is converted into an analog voltage signal, which is then processed by the ADC. In the second method, the delay is directly converted into a digital signal. Systems based on ADCs generally have a better timing resolution and linearity while being expensive and the capability of being integrated. TDCs, on the other hand, can be integrated into a single chip and hence are better suited in multi-channel systems.[9] However, they have a worse timing performance and can handle much lower sustained count-rates.

Applications

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The usefulness of TD Diffuse optics lies in its ability to continually and noninvasive monitor optical properties of tissue. Making it a powerful diagnostic tool for long-term bedside monitoring in infants and adults alike. It has already been demonstrated that TD diffuse optics can be successfully applied to various biomedical applications such as cerebral monitoring,[12] optical mammography,[13] muscle monitoring,[14] etc.

See also

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References

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  1. ^ Pifferi, Antonio; Contini, Davide; Mora, Alberto Dalla; Farina, Andrea; Spinelli, Lorenzo; Torricelli, Alessandro (2016-06-17). "New frontiers in time-domain diffuse optics, a review". Journal of Biomedical Optics. 21 (9): 091310. Bibcode:2016JBO....21i1310P. doi:10.1117/1.jbo.21.9.091310. hdl:11311/1000388. ISSN 1083-3668. PMID 27311627.
  2. ^ Matcher, Stephen J. (2016), "Signal Quantification and Localization in Tissue Near-Infrared Spectroscopy", Handbook of Optical Biomedical Diagnostics, Second Edition, Volume 1: Light-Tissue Interaction, SPIE PRESS, doi:10.1117/3.2219603.ch9, ISBN 9781628419092
  3. ^ Durduran, T; Choe, R; Culver, J P; Zubkov, L; Holboke, M J; Giammarco, J; Chance, B; Yodh, A G (2002-07-23). "Bulk optical properties of healthy female breast tissue". Physics in Medicine and Biology. 47 (16): 2847–2861. Bibcode:2002PMB....47.2847D. doi:10.1088/0031-9155/47/16/302. ISSN 0031-9155. PMID 12222850. S2CID 250873061.
  4. ^ Taroni, Paola; Pifferi, Antonio; Torricelli, Alessandro; Comelli, Daniela; Cubeddu, Rinaldo (2003). "In vivo absorption and scattering spectroscopy of biological tissues". Photochemical & Photobiological Sciences. 2 (2): 124–9. Bibcode:2003PhPhS...2..124T. doi:10.1039/b209651j. ISSN 1474-905X. PMID 12664972. S2CID 45269760.
  5. ^ Martelli, Fabrizio; Del Bianco, Samuele; Ismaelli, Andrea; Zaccanti, Giovanni (2009). Light Propagation through Biological Tissue and Other Diffusive Media: Theory, Solutions, and Software. doi:10.1117/3.824746. ISBN 9780819481832.
  6. ^ Andersson-Engels, S.; Berg, R.; Persson, A.; Svanberg, S. (1993-10-15). "Multispectral tissue characterization with time-resolved detection of diffusely scattered white light" (PDF). Optics Letters. 18 (20): 1697–9. Bibcode:1993OptL...18.1697A. doi:10.1364/ol.18.001697. ISSN 0146-9592. PMID 19823488. S2CID 29614936.
  7. ^ Selb, Juliette; Zimmermann, Bernhard B.; Martino, Mark; Ogden, Tyler; Boas, David A. (2013-03-25). Tromberg, Bruce J; Yodh, Arjun G; Sevick-Muraca, Eva M (eds.). "Functional brain imaging with a supercontinuum time-domain NIRS system". Optical Tomography and Spectroscopy of Tissue X. 8578. SPIE: 857807. Bibcode:2013SPIE.8578E..07S. doi:10.1117/12.2005348. S2CID 122062730.
  8. ^ Diop, Mamadou; Tichauer, Kenneth M.; Elliott, Jonathan T.; Migueis, Mark; Lee, Ting-Yim; St. Lawrence, Keith (2010-02-11). "Time-resolved near-infrared technique for bedside monitoring of absolute cerebral blood flow". In Vo-Dinh, Tuan; Grundfest, Warren S; Mahadevan-Jansen, Anita (eds.). Advanced Biomedical and Clinical Diagnostic Systems VIII. Vol. 7555. SPIE. pp. 75550Z. Bibcode:2010SPIE.7555E..0ZD. doi:10.1117/12.842521. S2CID 95205559.
  9. ^ a b Ferocino, Edoardo; Martinenghi, Edoardo; Dalla Mora, Alberto; Pifferi, Antonio; Cubeddu, Rinaldo; Taroni, Paola (23 January 2018). "High throughput detection chain for time domain optical mammography". Biomedical Optics Express. 9 (2): 755–770. doi:10.1364/BOE.9.000755. PMC 5854076. PMID 29552410.
  10. ^ BECKER, WOLFGANG. (2016). Advanced time-correlated single photon counting applications. SPRINGER INTERNATIONAL PU. ISBN 978-3319358420. OCLC 959950907.
  11. ^ Kalisz, Józef (2004). "Review of methods for time interval measurements with picosecond resolution". Metrologia. 41 (1): 17–32. Bibcode:2004Metro..41...17K. doi:10.1088/0026-1394/41/1/004. S2CID 250775541.
  12. ^ Torricelli, Alessandro (2014). "Time domain functional NIRS imaging for human brain mapping". NeuroImage. 85: 28–50. doi:10.1016/j.neuroimage.2013.05.106. hdl:11311/759006. PMID 23747285.
  13. ^ Grosenick, D. (2016). "Optical breast imaging and spectroscopy". Journal of Biomedical Optics. 21 (9): 091311. doi:10.1117/1.JBO.21.9.091311. hdl:11311/1013563. PMID 27403837. S2CID 42000848.
  14. ^ Contini, Davide; Zucchelli, Lucia; Spinelli, Lorenzo; Caffini, Matteo; Re, Rebecca; Pifferi, Antonio; Cubeddu, Rinaldo; Torricelli, Alessandro (2012). "Brain and Muscle near Infrared Spectroscopy/Imaging Techniques" (PDF). Journal of Near Infrared Spectroscopy. 20 (1): 15–27. doi:10.1255/jnirs.977. ISSN 0967-0335. S2CID 98108662.