Reprint
New Horizons in Time-Domain Diffuse Optical Spectroscopy and Imaging
Edited by
June 2020
246 pages
- ISBN978-3-03936-100-7 (Paperback)
- ISBN978-3-03936-101-4 (PDF)
This is a Reprint of the Special Issue New Horizons in Time-Domain Diffuse Optical Spectroscopy and Imaging that was published in
Biology & Life Sciences
Chemistry & Materials Science
Computer Science & Mathematics
Engineering
Environmental & Earth Sciences
Physical Sciences
Summary
Jöbsis was the first to describe the in vivo application of near-infrared spectroscopy (NIRS), also called diffuse optical spectroscopy (DOS). NIRS was originally designed for the clinical monitoring of tissue oxygenation, and today it has also become a useful tool for neuroimaging studies (functional near-infrared spectroscopy, fNIRS). However, difficulties in the selective and quantitative measurements of tissue hemoglobin (Hb), which have been central in the NIRS field for over 40 years, remain to be solved. To overcome these problems, time-domain (TD) and frequency-domain (FD) measurements have been tried. Presently, a wide range of NIRS instruments are available, including commonly available commercial instruments for continuous wave (CW) measurements, based on the modified Beer–Lambert law (steady-state domain measurements). Among these measurements, the TD measurement is the most promising approach, although compared with CW and FD measurements, TD measurements are less common, due to the need for large and expensive instruments with poor temporal resolution and limited dynamic range. However, thanks to technological developments, TD measurements are increasingly being used in research, and also in various clinical settings. This Special Issue highlights issues at the cutting edge of TD DOS and diffuse optical tomography (DOT). It covers all aspects related to TD measurements, including advances in hardware, methodology, the theory of light propagation, and clinical applications.
Format
- Paperback
License and Copyright
© 2020 by the authors; CC BY-NC-ND license
Keywords
breast cancer; diffuse optical spectroscopy; chemotherapy; time-domain spectroscopy; near-infrared spectroscopy; radiative transfer equation; diffusion equation; biological tissue; time-domain instruments; light propagation in tissue; optical properties of tissue; diffuse optical tomography; fluorescence diffuse optical tomography; diffuse optical spectroscopy; time-resolved spectroscopy; breast cancer; NIRS; diffuse optics; time-domain; time-resolved; brain oxygenation; tissue saturation; scattering; absorption; 3-hour sitting; near infrared time-resolved spectroscopy; compression stocking; tissue oxygenation; extracellular water; intracellular water; circumference; gastrocnemius; neonate; vaginal delivery; cerebral blood volume; cerebral hemoglobin oxygen saturation; near-infrared time-resolved spectroscopy; near infrared spectroscopy; aging; prefrontal cortex; TRS; magnetic resonance imaging; brain atrophy; VSRAD; optical pathlength; hemoglobin; cognitive function; time-domain NIRS; null source-detector separation; brain; diffuse optics; near-infrared time-resolved spectroscopy; noninvasive; subcutaneous white adipose tissue; tissue total hemoglobin; near-infrared spectroscopy; diffuse light; inverse problems; optical tomography; diffuse optical tomography; inverse problem; datatypes; diffusion approximation; radiative transfer equation; highly forward scattering of photons; diffusion and delta-Eddington approximations; characteristic length and time scales of photon transport; n/a