Light dosimetry in optical phantoms and in tissues: I. Multiple flux and transport theory

Star, W. M.; Marijnissen, Johannes P. A.; Gemert, Martin J. C. van

doi:10.1088/0031-9155/33/4/004

Cited by 144 publications

(78 citation statements)

References 29 publications

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“…In continuous media, these are typically considered the result of a pair of material constants (coefficients) 12 . Both scattering and absorption depend linearly on penetration, and the remitted light intensity is given by the ratio of the coefficients 11 .…”

Section: Ops Imagingmentioning

confidence: 99%

Orthogonal polarization spectral imaging: A new method for study of the microcirculation

Groner¹,

Winkelman

Harris³

et al. 1999

Nat Med

712

435

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Fig. 1 a, Orthogonal polarization spectral imaging probe. b, Optical schematic of the OPS imaging probe. A typical magnification of ×10 is maintained between the target and its image. This results in a resolution of approximately 1 µm/pixel, which is limited by the dimension of the CCD pixel. The probe can be focused from the target surface to 1.0-mm depth, depending on the type of target and the optics used. In vivo, the typical depth of focus is approximately 0.2 mm. c, Optical density of a graduated gray scale (catalog number 152-7662; Kodak) was measured in the presence of the polarization analyzer (b) or with a 0.5 OD neutral density filter (ć) used in place of the analyzer. Average light intensity for each gray level was converted to OD by the following formula: OD = log 10 ((I m -I d )/(I max -I d )) where I m = measured light intensity, I d = dark light intensity (obtained using a black velvet target), I max = intensity of white target. NEW TECHNOLOGYDifferent disease states, including diabetes, hypertension and coronary heart disease, produce distinctive microvascular pathologies. So far, imaging of the human microcirculation has been limited to vascular beds in which the vessels are visible and close to the surface (for example, nailfold, conjunctiva). We report here on orthogonal polarization spectral (OPS) imaging, a new method for imaging the microcirculation using reflected light that allows imaging of the microcirculation noninvasively through mucus membranes and on the surface of solid organs. In OPS imaging, the tissue is illuminated with linearly polarized light and imaged through a polarizer oriented orthogonal to the plane of the illuminating light. Only depolarized photons scattered in the tissue contribute to the image. The optical response of OPS imaging is linear and can be used for reflection spectrophotometry over the wide range of optical density typically achieved by transmission spectrophotometry. A comparison of fluorescence intravital microscopy with OPS imaging in the hamster demonstrated equivalence in measured physiological parameters under control conditions and after ischemic injury. OPS imaging produced high-contrast microvascular images in people from sublingual sites and the brain surface that appear as in transillumination. The technology can be implemented in a small optical probe, providing a convenient method for intravital microscopy on otherwise inaccessible sites and organs in the awake subject or during surgery for research and for clinical diagnostic applications.At present, the use of microvascular imaging in diagnosis and treatment of human disease is limited. Use has been made of nailfold capillaroscopy in the diagnosis and treatment of peripheral vascular diseases, diabetes and hematological disorders 1-3 . Problems with movement have restricted the use of the bulbar conjunctiva for clinical applications in opthalmology 4-6 . Other locations observed by intravital microscopy include the microcirculation of the skin, lip, gingival tissue and tongue 4 . Laser-sca...

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Section: Ops Imagingmentioning

confidence: 99%

Orthogonal polarization spectral imaging: A new method for study of the microcirculation

Groner¹,

Winkelman

Harris³

et al. 1999

Nat Med

712

435

View full text Add to dashboard Cite

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“…A more complete description would give more realistic results, but apart from the difficulty in choosing the correct constants, the equations and algorithms would rise in complexity very fast. More complete theories are described by Star et al (1988) and Keijzer et al (1988).…”

Section: Propagation Of Light In Absorbing and Scattering Mediamentioning

confidence: 99%

The Nature of Light and Its Interaction with Matter

Björn¹

2014

Photobiology

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“…Light reemitted by the tissue contains information about absorption and scattering effects. These effects can be decoupled with proper algorithms to obtain information about the optical properties of the tissue [6,[228][229][230][231]. This is the basis for non-invasive, diffuse near-infrared (NIR) spectroscopy and imaging in soft tissue.…”

Section: Diffuse Near-infrared Spectroscopy and Imaging Using Diode Lmentioning

confidence: 99%

Diode laser based light sources for biomedical applications

Müller

Marschall

Jensen

et al. 2012

Laser & Photonics Reviews

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Diode lasers are by far the most efficient lasers currently available. With the ever-continuing improvement in diode laser technology, this type of laser has become increasingly attractive for a wide range of biomedical applications. Compared to the characteristics of competing laser systems, diode lasers simultaneously offer tunability, high-power emission and compact size at fairly low cost. Therefore, diode lasers are increasingly preferred in important applications, such as photocoagulation, optical coherence tomography, diffuse optical imaging, fluorescence lifetime imaging, and terahertz imaging. This review provides an overview of the latest development of diode laser technology and systems and their use within selected biomedical applications. 670 nm external cavity diode laser for Raman spectroscopy built on a 13 × 4 mm 2 microbench (Copyright FBH/Schurian.com).

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Light dosimetry in optical phantoms and in tissues: I. Multiple flux and transport theory

Cited by 144 publications

References 29 publications

Orthogonal polarization spectral imaging: A new method for study of the microcirculation

Orthogonal polarization spectral imaging: A new method for study of the microcirculation

The Nature of Light and Its Interaction with Matter

Diode laser based light sources for biomedical applications

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