Long-Lasting Imprint in the Soluble Inflammatory Milieu Despite Early Treatment of Acute Symptomatic Hepatitis C

An imaging system has been developed based on pulses of Terahertz (THz) radiation generated and detected using all-optical effects accessed by irradiating semiconductors with ultrafast (fs-ps) pulses of visible laser light. This technique, commonly referred to as T-Ray Imaging or THz Pulse Imaging (TPI), holds enormous promise for certain aspects of medical imaging. We have conducted an initial survey of possible medical applications of TPI and demonstrated that TPI images show good contrast between different animal tissue types (muscle, fat, kidney, skin, cartilage). Moreover, the diagnostic power of TPI has been elucidated by the spectra available at each pixel in the image, which are markedly different for the different tissue types. This suggests that the spectral information inherent in TPI might be used to identify the type of soft and hard tissue at each pixel in an image and provide other diagnostic information not afforded by conventional imaging techniques.Preliminary TPI studies ofpork skin show that 3D tomographic imaging ofthe skin surface and thickness is possible, and data from experiments on models of the human dermis are presented which demonstrate that different constituents of skin have different refractive indices. Lastly, we present the first THz image of human tissue, namely an extracted tooth. The time of flight of THz pulses through the tooth allows the thickness of the enamel to be determined, and is used to create an image showing the enamel and dentine regions. Absorption of THz pulses in the tooth allows the pulp cavity region to be identified. Initial evidence strongly suggests that TPI may be used to provide valuable diagnostic information pertaining to the enamel, dentine, and the pulp cavity.

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Theory of magnetic-field enhancement of surface-field terahertz emission

Johnston¹,

Whittaker²,

Corchia³

et al. 2002

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We present a theoretical treatment of surface-field THz generation in semiconductors, which explains the power enhancement observed when a magnetic field is applied. Our model consists of two parts: a Monte Carlo simulation of the dynamics of carriers generated by a subpicosecond optical pulse, and a calculation of the resulting THz radiation emitted through the semiconductor surface. The magnetic field deflects the motion of the carriers, producing a component of the THz dipole parallel to the surface. This causes the power transmitted through the surface to be increased by more than one order of magnitude.

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Enhanced coherent terahertz emission from indium arsenide in the presence of a magnetic field

McLaughlin

Corchia

Johnston

et al. 2000

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Biomedical applications of terahertz pulse imaging

Ciesla

Arnone

Corchia

et al. 2000

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Magnetic-field-induced enhancement of terahertz emission from III–V semiconductor surfaces

Johnston

Corchia

Dowd

et al. 2002

Physica E: Low-dimensional Systems and Nanostructures

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Mid-span spectral inversion without frequency shift for fiber dispersion compensation: a system demonstration

Corchia

Antonini

D’Ottavi

et al. 1999

IEEE Photon. Technol. Lett.

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Effects of magnetic field and optical fluence on terahertz emission in gallium arsenide

et al. 2001

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A. Corchia

Simulation of terahertz generation at semiconductor surfaces

Applications of terahertz (THz) technology to medical imaging

Theory of magnetic-field enhancement of surface-field terahertz emission

Enhanced coherent terahertz emission from indium arsenide in the presence of a magnetic field

Biomedical applications of terahertz pulse imaging

Magnetic-field-induced enhancement of terahertz emission from III–V semiconductor surfaces

Mid-span spectral inversion without frequency shift for fiber dispersion compensation: a system demonstration

Effects of magnetic field and optical fluence on terahertz emission in gallium arsenide

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