Abstract: A system for assessment of different kinds of bodily tissues and/or bodily fluids and/or air, in particular air being associated with a human body, wherein, for primary data assessment, the processor module is configured to process and/or analyse at least the MRI patient scan data of the first patient such that at least one set of Bone MRI data, in particular synthetic CT data, of the first patient is provided, and/or wherein, for a secondary data assessment, the processor module is configured to process and/or analyse at least the MRI patient scan data of the first patient such that at least one set of synthetic T1-weighted image data of the first patient is provided. Furthermore, the present disclosure refers to a method for training of a processor module, a method for providing a primary data assessment and/or a secondary data assessment by such a system and a computer-readable medium.

Abstract: A method is disclosed for generating a contrast image using MRI comprising a four-echo steady state free precession (SSFP) sequence. The method comprises: generating a pulse train of excitation pulses having a repetition time; generating between two subsequent excitation pulses of the pulse train a first S+ echo; a second S+ echo; a first S? echo; and a second S? echo sampling between the two subsequent excitation pulses the first S+ echo; the second S+ echo; the first S? echo; and the second S? echo; generating the contrast image based on the sampled first S+ echo, the sampled second S+ echo, the sampled first S? echo, and the sampled second S? echo.

Abstract: A method is disclosed for generating a contrast image using MRI comprising a four-echo steady state free precession (SSFP) sequence. The method comprises: generating a pulse train of excitation pulses having a repetition time; generating between two subsequent excitation pulses of the pulse train a first S+echo; a second S+echo; a first S?echo; and a second S?echo sampling between the two subsequent excitation pulses the first S+echo; the second S+echo; the first S?echo; and the second S?echo; generating the contrast image based on the sampled first S+echo, the sampled second S+echo, the sampled first S?echo, and the sampled second S?echo.

Abstract: The present invention is an apparatus used to connect a typical guitar strap in non-traditional positions on the body of a guitar or bass guitar, which affixes to the instrument to provide stability and balance. The core components of the apparatus are a resilient hollow plastic outer shell with an external protrusion extending from the apex, a protective non-slip thermoplastic rubber inner layer, and metal hardware, suitable for use with virtually all guitar straps presently in use, attached to the external protrusion. The invention can be used to attach a strap to a guitar or bass guitar securely, without damaging the finish or affecting the tonal integrity of the instrument. Furthermore, it should be noted that the apparatus is generally a parabolic shape, intended to securely fit over the upper or lower horn of a guitar or bass guitar.

Abstract: The present invention is an apparatus used to connect a typical guitar strap in non-traditional positions on the body of a guitar or bass guitar, which affixes to the instrument to provide stability and balance. The core components of the apparatus are a resilient hollow plastic outer shell with an external protrusion extending from the apex, a protective non-slip thermoplastic rubber inner layer, and metal hardware, suitable for use with virtually all guitar straps presently in use, attached to the external protrusion. The invention can be used to attach a strap to a guitar or bass guitar securely, without damaging the finish or affecting the tonal integrity of the instrument. Furthermore, it should be noted that the apparatus is generally a parabolic shape, intended to securely fit over the upper or lower horn of a guitar or bass guitar.

Abstract: The present disclosure is directed to a measurement system for measuring a reflection coefficient of a test sample, including: a transceiver antenna configured to be coupled to a source of electromagnetic radiation; and a RAM positioned between the transceiver antenna and a measurement region of the transceiver antenna, wherein the RAM comprises an aperture substantially orthogonal to and substantially aligned with a transceiving axis of the transceiver antenna. A method for obtaining error correction of a measurement system and a method of measuring a reflection coefficient in a test sample are also provided.

Abstract: The present disclosure is directed to a measurement system for measuring a reflection coefficient of a test sample, including: a transceiver antenna configured to be coupled to a source of electromagnetic radiation; and a RAM positioned between the transceiver antenna and a measurement region of the transceiver antenna, wherein the RAM comprises an aperture substantially orthogonal to and substantially aligned with a transceiving axis of the transceiver antenna. A method for obtaining error correction of a measurement system and a method of measuring a reflection coefficient in a test sample are also provided.

Abstract: The present disclosure is directed to a measurement system for measuring a reflection coefficient of a test sample, including: a transceiver antenna configured to be coupled to a source of electromagnetic radiation; and a RAM positioned between the transceiver antenna and a measurement region of the transceiver antenna, wherein the RAM comprises an aperture substantially orthogonal to and substantially aligned with a transceiving axis of the transceiver antenna. A method for obtaining error correction of a measurement system and a method of measuring a reflection coefficient in a test sample are also provided.

Abstract: The present disclosure is directed to a measurement system for measuring a reflection coefficient of a test sample, including: a transceiver antenna configured to be coupled to a source of electromagnetic radiation; and a RAM positioned between the transceiver antenna and a measurement region of the transceiver antenna, wherein the RAM comprises an aperture substantially orthogonal to and substantially aligned with a transceiving axis of the transceiver antenna. A method for obtaining error correction of a measurement system and a method of measuring a reflection coefficient in a test sample are also provided.

Abstract: The present disclosure is directed to an artificial skin having a radar absorbing layer and a conductive layer containing an electrically conductive material, wherein the artificial skin has a reflection coefficient substantially equal to a human skin reflection coefficient, the human skin reflection coefficient being determined at an electromagnetic radiation frequency ranging from 1-500 GHz. A human phantom composed of the artificial skin and methods of testing the contrast resolution sufficiency of and active millimeter wave imaging system using the human phantom are also disclosed.

Abstract: The present disclosure is directed to a measurement system for measuring a reflection coefficient of a test sample, including: a transceiver antenna configured to be coupled to a source of electromagnetic radiation; and a RAM positioned between the transceiver antenna and a measurement region of the transceiver antenna, wherein the RAM comprises an aperture substantially orthogonal to and substantially aligned with a transceiving axis of the transceiver antenna. A method for obtaining error correction of a measurement system and a method of measuring a reflection coefficient in a test sample are also provided.

Abstract: A system for bone imaging is disclosed. A processing unit is provided for processing an echo MRI dataset. The processing unit is configured to apply a phase ramp to the radial sampling lines of the complex data according to the radial sampling scheme to obtain a bone-enhanced image dataset, wherein a single phase ramp is applied to a radial sampling line of the sampling scheme, which radial sampling line extends on both sides of an origin defined by the echo time, and wherein the phase ramp is based on an equation. A combining unit is provided for combining the MRI dataset with the bone-enhanced image dataset to obtain a background suppressed image dataset.

Abstract: The invention relates to substituted bicyclic compounds, which are useful for inhibition of BET protein function by binding to bromodomains, pharmaceutical compositions comprising these compounds, and use of the compounds and compositions in therapy.

Abstract: The present disclosure is directed to an artificial skin having a radar absorbing layer and a conductive layer containing an electrically conductive material, wherein the artificial skin has a reflection coefficient substantially equal to a human skin reflection coefficient, the human skin reflection coefficient being determined at an electromagnetic radiation frequency ranging from 1-500 GHz. A human phantom composed of the artificial skin and methods of testing the contrast resolution sufficiency of and active millimeter wave imaging system using the human phantom are also disclosed.

Abstract: The present disclosure is directed to an artificial skin including: a radar absorbing layer; a conductive layer comprising at least one material selected from the group consisting of a semiconductive oxide deposited onto a substrate and an electrically conductive polymer, wherein the substrate is in contact with the radar absorbing layer, and wherein the artificial skin has a reflection coefficient substantially equal to a human skin reflection coefficient, the human skin reflection coefficient being determined at an electromagnetic radiation frequency ranging from 1-500 GHz. A human phantom composed of the artificial skin and methods of using the human phantom are also disclosed.

Abstract: The present disclosure is directed to an artificial skin including: a radar absorbing layer; a conductive layer comprising at least one material selected from the group consisting of a semiconductive oxide deposited onto a substrate and an electrically conductive polymer, wherein the substrate is in contact with the radar absorbing layer, and wherein the artificial skin has a reflection coefficient substantially equal to a human skin reflection coefficient, the human skin reflection coefficient being determined at an electromagnetic radiation frequency ranging from 1-500 GHz. A human phantom composed of the artificial skin and methods of using the human phantom are also disclosed.

Abstract: The present disclosure is directed to a measurement system for measuring a reflection coefficient of a test sample, including: a transceiver antenna configured to be coupled to a source of electromagnetic radiation; and a RAM positioned between the transceiver antenna and a measurement region of the transceiver antenna, wherein the RAM comprises an aperture substantially orthogonal to and substantially aligned with a transceiving axis of the transceiver antenna. A method for obtaining error correction of a measurement system and a method of measuring a reflection coefficient in a test sample are also provided.

Abstract: A system for bone imaging is disclosed. A processing unit is provided for processing an echo MRI dataset. The processing unit is configured to apply a phase ramp to the radial sampling lines of the complex data according to the radial sampling scheme to obtain a bone-enhanced image dataset, wherein a single phase ramp is applied to a radial sampling line of the sampling scheme, which radial sampling line extends on both sides of an origin defined by the echo time, and wherein the phase ramp is based on an equation. A combining unit is provided for combining the MRI dataset with the bone-enhanced image dataset to obtain a background suppressed image dataset.

Abstract: A set of computer executable instructions configured to calculate penalties for a vehicle pilot navigating a competition course which incorporates at least one virtual obstacle, said set of instructions being configured to execute the steps of: a) receiving a vehicle location identifier associated with the present position of the pilots vehicle, and b) comparing the vehicle location identifier with a collision region associated with at least one virtual obstacle of the competition course, and c) assigning at least one penalty to the pilot of the vehicle if the vehicle's location intercepts with the collision region of an obstacle, and d) repeating steps a) through c) as the pilot navigates the competition course and the position of the vehicle changes.

Abstract: An exemplary embodiment provides a medical implant with implant surfaces that are exposed to body tissue when the medical implant is inserted into a body of a recipient. The implant has a micro- or a nano-sized pattern on at least a portion of the implant surfaces. Optionally, the micro- or nano-sized pattern may be a periodic (or “repeating”) pattern. Further, the micro- or nano-sized pattern may have geometric features, such as grooves, circles, triangles, rectangles, pentagons and hexagons.