Abstract: Some embodiments of the present disclosure discuss an apparatus comprising a transceiver configured to generate and/or receive radio frequency (RF) electromagnetic signals, one or more antennae configured to radiate the generated RF electromagnetic signals toward a surface and to output signals corresponding to received reflections of the RF electromagnetic signals, and a processing circuitry configured to process the received reflections and/or the output signals so as to determine change in position of the apparatus with respect to the surface. The apparatus may be incorporated into a wearable garment and/or an adhesive patch, and it may be attached to an outer surface of a human or an animal body.

Abstract: Diagnostic apparatus (20) includes an antenna 32, which is configured to direct radio frequency (RF) electromagnetic waves into a living body and to generate signals responsively to the waves that are scattered from within the body. Processing circuitry (36) is configured to process the signals so as to locate a feature in a blood vessel in the body.

Abstract: Diagnostic apparatus (24) includes a sealed case (80), comprising a biocompatible material and configured for implantation within a body of a human subject (22). A dielectrometric probe (26, 50, 63, 66, 70, 102, 160) is connected to the case and includes first and second conductors (40, 42, 54, 56, 64, 67, 68, 72, 74, 162, 164), which are configured to be placed in proximity to a target tissue (34) in the body. A driving circuit (82), which is contained in the case, is coupled to apply a radio-frequency (RF) signal to the probe and to sense the signal returned from the probe. Processing circuitry (84) is configured to evaluate, responsively to the returned signal, a dielectric property of the target tissue.

Abstract: Diagnostic apparatus (20) includes an antenna 32, which is configured to direct radio frequency (RF) electromagnetic waves into a living body and to generate signals responsively to the waves that are scattered from within the body. Processing circuitry (36) is configured to process the signals so as to locate a feature in a blood vessel in the body.

Abstract: Diagnostic apparatus (24) includes a sealed case (80), comprising a biocompatible material and configured for implantation within a body of a human subject (22). A dielectrometric probe (26, 50, 63, 66, 70, 102, 160) is connected to the case and includes first and second conductors (40, 42, 54, 56, 64, 67, 68, 72, 74, 162, 164), which are configured to be placed in proximity to a target tissue (34) in the body. A driving circuit (82), which is contained in the case, is coupled to apply a radio-frequency (RF) signal to the probe and to sense the signal returned from the probe. Processing circuitry (84) is configured to evaluate, responsively to the returned signal, a dielectric property of the target tissue.

Abstract: A method and apparatus are provided for determining and tracking location of a metallic object in a living body, and then directing a second modality such as ultrasound waves to the determined location. The metal detector may be a radar detector adapted to operate on a living body. The adaption may include disposing a transfer material having electromagnetic properties similar to the body between the radar detector and the living body, ECG gating the radar detector, and/or employing an optimal estimator with a model of expected stent movement in a living body. Applications include determination of extent of in-stent restenosis, performing therapeutic thrombolysis, or determining operational features of a metallic implant.

Abstract: Diagnostic apparatus includes a plurality of antennas, which are configured to be disposed at different, respective locations on a thorax of a living body so as to direct radio frequency (RF) electromagnetic waves from different, respective directions toward a heart in the body and to output RF signals responsively to the waves that are scattered from the heart. Processing circuitry is configured to process the RF signals over time so as to provide a multi-dimensional measurement of a movement of the heart.

Abstract: Embodiments of the subject application include a diagnostic apparatus including one or more antennas disposed on a thorax of a living body to direct radio frequency (RF) electromagnetic waves through tissue and output signals responsively to the waves that have passed through the tissue. The apparatus may also include processing circuitry configured to process the signals over time so as to measure one or more RF path characteristics of the RF electromagnetic waves. The RF path length may be defined by a length of time required for the RF waves to pass through the thorax to an antenna and/or pass to tissue and reflect therefrom to an antenna, based on the path characteristic to assess a fluid content of the tissue.

Abstract: An apparatus, a system, and a method for monitoring and/or performing a diagnosis. A first implantable device measures a property of a first tissue in a body and includes a housing. The housing includes a first processing circuitry for causing the first implantable device to measure the property of the first tissue. A second implantable device for measures a property of a second tissue in the body and includes a housing. The housing includes a second processing circuitry for causing the second implantable device to measure the property of the second tissue using at least one sensor. The second implantable device is communicatively coupled to the first implantable device and provides information about the measured property of the second tissue to at least one of the following: the first implantable device and at least one processing device disposed externally to the body.

Abstract: Diagnostic apparatus (24) includes a sealed case (40), including a biocompatible material and configured for implantation within a body of a human subject (22). At least one antenna (42) is configured to be implanted in the body in proximity to a target tissue (28) and to receive radio frequency (RF) electromagnetic waves propagated through the target tissue and to output a signal in response to the received waves.

Abstract: Diagnostic apparatus (24) includes a sealed case (80), comprising a biocompatible material and configured for implantation within a body of a human subject (22). A dielectrometric probe (26, 50, 63, 66, 70, 102, 160) is connected to the case and includes first and second conductors (40, 42, 54, 56, 64, 67, 68, 72, 74, 162, 164), which are configured to be placed in proximity to a target tissue (34) in the body. A driving circuit (82), which is contained in the case, is coupled to apply a radio-frequency (RF) signal to the probe and to sense the signal returned from the probe. Processing circuitry (84) is configured to evaluate, responsively to the returned signal, a dielectric property of the target tissue.

Abstract: A method and apparatus are provided for determining and tracking location of a metallic object in a living body, and then directing a second modality such as ultrasound waves to the determined location. The metal detector may be a radar detector adapted to operate on a living body. The adaption may include disposing a transfer material having electromagnetic properties similar to the body between the radar detector and the living body, ECG gating the radar detector, and/or employing an optimal estimator with a model of expected stent movement in a living body. Applications include determination of extent of in-stent restenosis, performing therapeutic thrombolysis, or determining operational features of a metallic implant.

Abstract: Diagnostic apparatus (20) includes an antenna 32, which is configured to direct radio frequency (RF) electromagnetic waves into a living body and to generate signals responsively to the waves that are scattered from within the body. Processing circuitry (36) is configured to process the signals so as to locate a feature in a blood vessel in the body.

Abstract: Diagnostic apparatus includes a plurality of antennas, which are configured to be disposed at different, respective locations on a thorax of a living body so as to direct radio frequency (RF) electromagnetic waves from different, respective directions toward a heart in the body and to output RF signals responsively to the waves that are scattered from the heart. Processing circuitry is configured to process the RF signals over time so as to provide a multi-dimensional measurement of a movement of the heart.

Abstract: A method and apparatus are provided for determining and tracking location of a metallic object in a living body, and then directing a second modality such as ultrasound waves to the determined location. The metal detector may be a radar detector adapted to operate on a living body. The adaption may include disposing a transfer material having electromagnetic properties similar to the body between the radar detector and the living body, ECG gating the radar detector, and/or employing an optimal estimator with a model of expected stent movement in a living body. Applications include determination of extent of in-stent restenosis, performing therapeutic thrombolysis, or determining operational features of a metallic implant.

Abstract: A template for performing a dental implantation procedure, comprising: a main body adapted to seat on a plurality of oral structures, and at least one mounting point on the main body for mounting at least one drill guide, wherein the main body is provided with exposed implantation spaces where the dental implantation is to be performed.

Abstract: Apparatus for measuring a surface geometry of hard tissue covered by a layer of soft tissue, including a plurality of elements each having a tip adapted to penetrate said soft tissue and not substantially penetrate said hard tissue; a frame supporting movement of said elements, each along a path, such that a plurality of said tips, when positioned along the paths, define a surface; and at least one position sensor which generates a signal indicative of a tip position of at least one of said elements.

Abstract: A method of dental registration, comprising, rigidly coupling a base element to a maxillofacial area; inserting an object comprising at least one of a tool and a tool guide into a mouth in said maxillofacial area; and determining a position of said object relative to said rigid element without a reference element outside of said mouth.

Abstract: Apparatus for measuring a surface geometry of hard tissue covered by a layer of soft tissue, including a plurality of elements each having a tip adapted to penetrate said soft tissue and not substantially penetrate said hard tissue; a frame supporting movement of said elements, each along a path, such that a plurality of said tips, when positioned along the paths, define a surface; and at least one position sensor which generates a signal indicative of a tip position of at least one of said elements.

Abstract: An apparatus for determining measurement element positions, comprising a plurality of measurement elements; at least one trigger element corresponding to each element of the plurality of measurement elements; a positional encoder configured to register a position of each of the measurement elements when the trigger element is activated; and a controller, wherein the controller constructs a surface geometry model from the registered measurement element positions.