Multichannel time-resolved optical tomographic imaging system

Eda, Hideo; Oda, Ichiro; Ito, Yasunobu; Wada, Yoshinori; Oikawa, Yukio; Tsunazawa, Yoshio; Takada, Michinosuke; Tsuchiya, Yutaka; Yamashita, Yutaka; Oda, Masaomi; Sassaroli, Angelo; Yamada, Yukio; Tamura, Mamoru

doi:10.1063/1.1149965

Cited by 161 publications

(114 citation statements)

References 11 publications

Supporting

Mentioning

113

Contrasting

Order By: Relevance

“…9 The types are continuous wave ͑cw͒, 2,10-16 frequency domain, 17,18 and time domain. 19 The instrument presented in this paper is a cw type instrument. As it is required to monitor changes in the concentrations of Hb and HbO 2 in the tibia, rather than generate a topographic or tomographic image of that tissue, high spatial resolution is not required.…”

Section: Introductionmentioning

confidence: 99%

A near infrared instrument to monitor relative hemoglobin concentrations of human bone tissue in vitro and in vivo

Aziz

Khambatta

Vaithianathan

et al. 2010

Review of Scientific Instruments

View full text Add to dashboard Cite

A continuous wave near infrared instrument has been developed to monitor in vivo changes in the hemoglobin concentration of the trabecular compartment of human bone. The transmitter uses only two laser diodes of wavelengths 685 and 830 nm, and the receiver uses a single silicon photodiode operating in the photovoltaic mode. The functioning of the instrument and the depth of penetration of the near infrared signals was determined in vitro using tissue-equivalent phantoms. The instrument achieves a depth of penetration of approximately 2 cm for an optode separation of 4 cm and, therefore, has the capacity to interrogate the trabecular compartment of human bone. The functioning of the instrument was tested in vivo to evaluate the relative oxy-hemoglobin ͑HbO 2 ͒ and deoxy-hemoglobin ͑Hb͒ concentrations of the proximal tibial bone of apparently healthy, normal weight, adult subjects in response to a 3 min on, 5 min off, vascular occlusion protocol. The traces of the relative Hb and HbO 2 concentrations obtained were reproducible in controlled conditions. The instrument is relatively simple and flexible, and offers an inexpensive platform for further studies to obtain normative data for healthy cohorts, and to evaluate disease-specific performance characteristics for cohorts with vasculopathies of bone.

show abstract

Section: Introductionmentioning

confidence: 99%

A near infrared instrument to monitor relative hemoglobin concentrations of human bone tissue in vitro and in vivo

Aziz

Khambatta

Vaithianathan

et al. 2010

Review of Scientific Instruments

View full text Add to dashboard Cite

show abstract

“…In order to reduce the intensity that can reach the detector, a variable optical attenuator (VOA) can be used to attenuate light in a controlled way (Eda et al, 1999;Schmidt et al, 2000). It consists of a disk with a set of holes of different sizes, or neutral density filters with different optical densities.…”

Section: Detectors In Time-resolved Systemsmentioning

confidence: 99%

“…Instruments for diffuse optical imaging can be classified into three groups: time-domain systems which measure the full temporal point spread function of tissue to a pulse of light (Chance et al, 1988;Delpy et al, 1988, Eda et al, 1999Schmidt et al, 2000), frequencydomain systems which measure the amplitude and phase shift of the detected light with respect to an intensity-modulated source light (Lakowicz and Berndt, 1990;Chance et al, 1998b;McBride et al, 2001;Nissilä et al, 2002a), and continuous wave systems, which measure the DC intensity of detected light (Schmitz et al, 2002). The primary advantage of time-and frequency-domain techniques is that they may provide enough information for the separation of features in scattering and absorption.…”

Section: Introductionmentioning

confidence: 99%

Diffuse Optical Imaging

Nissilä

Noponen

Heino

et al.

Advances in Electromagnetic Fields in Living Systems

View full text Add to dashboard Cite

Diffuse optical imaging is a functional medical imaging modality which takes advantage of the relatively low attenuation of near-infrared light to probe the internal optical properties of tissue. The optical properties are affected by parameters related to physiology such as the concentrations of oxy-and deoxyhemoglobin. Instrumentation that is used for optical imaging is generally able to measure changes in the attenuation of light at several wavelengths, and in the case of time-and frequency-domain instrumentation, the time-of-flight of the photons in tissue.Light propagation in tissue is generally dominated by scattering. Models for photon transport in tissue are generally based on either stochastic approaches or approximations derived from the radiative transfer equation. If a numerical forward model which describes the physical situation with sufficient accuracy exists, inversion methods may be used to determine the internal optical properties based on boundary measurements.Optical imaging has applications in, e.g., functional brain imaging, breast cancer detection, and muscle imaging. It has the important advantages of transportable instrumentation, relatively high tolerance for external electromagnetic interference, non-invasiveness, and applicability for neonatal studies. The methods are not yet in clinical use, and further research is needed to improve the reliability of the experimental techniques, and the accuracy of the models used. In this chapter, we describe the interaction between light and tissue, light propagation models and inversion methods used in optical tomography, and instrumentation and experimental techniques used in optical imaging. The main applications of optical imaging are described in detail, with results from recent literature.

show abstract

“…Because time-resolved instrumentation was developed as laboratory-based devices, it has been difficult to use in the clinical environment. However, recent advances in technology have made the development of a compact 64-channel time-resolved optical imaging system possible [60]. Now, single-/two-channel TRS instruments are commercially available [61].…”

Section: (A) Time-resolved Spectroscopymentioning

confidence: 99%

“…In the 1990s, we developed the 64-channel TR-DOT system in a research and development project for optical tomographic imaging systems for the New Energy and Industrial Technology Development Organization and Ministry of International Trade and Industry of the Japanese Government [60]. This system has three 100 ps pulsed LDs (wavelengths of 761, 797 and 834 nm) and 64 fibre bundles that are connected to 64 corresponding time-resolved detection devices.…”

Section: (B) Time-resolved Domain Diffuse Optical Tomographymentioning

confidence: 99%

Towards the next generation of near-infrared spectroscopy

Hoshi

2011

Phil. Trans. R. Soc. A.

View full text Add to dashboard Cite

Although near-infrared spectroscopy (NIRS) was originally designed for clinical monitoring of tissue oxygenation, it has also been developing into a useful tool for neuroimaging studies (functional NIRS). Over the past 30 years, technology has developed and NIRS has found a wide range of applications. However, the accuracy and reliability of NIRS have not yet been widely accepted, mainly because of the difficulties in selective and quantitative detection of signals arising in cerebral tissue, which subject the use of NIRS to a number of practical restrictions. This review summarizes the strengths and advantages of NIRS over other neuroimaging modalities and demonstrates specific examples. The issues of selective quantitative measurement of cerebral haemoglobin during brain activation are also discussed, together with the problems of applying the methods of functional magnetic resonance imaging data analysis to NIRS data analysis. Finally, near-infrared optical tomography-the next generation of NIRS-is described as a potential technique to overcome the limitations of NIRS.

show abstract

Multichannel time-resolved optical tomographic imaging system

Cited by 161 publications

References 11 publications

A near infrared instrument to monitor relative hemoglobin concentrations of human bone tissue in vitro and in vivo

A near infrared instrument to monitor relative hemoglobin concentrations of human bone tissue in vitro and in vivo

Diffuse Optical Imaging

Towards the next generation of near-infrared spectroscopy

Contact Info

Product

Resources

About