• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
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    • 专利摘要:

    公开号:BR112012019616A2
    申请号:R112012019616-2
    申请日:2011-01-14
    公开日:2020-05-26
    发明作者:Chan Raymond;Shechter Guy;Emmanuel Desjardins Andrien;'t Hooft Gert;Stephen Hall Christopher
    申请人:Koninklijke Philips Electronics N.V.;
    IPC主号:
    专利说明:

    APPARATUS FOR DETERMINING A POSITION, ORIENTATION AND / OR FORM AND SYSTEM FOR TRACKING A PORTION OF AN IMAGE GENERATION OR THERAPY DEVICE
    This disclosure refers to medical devices, and more particularly to medical devices that employ fiber optic technology for tracking the shape, position and orientation of transducer treatment and imaging devices.
    In ultrasound applications, the spatial tracking of the transducers was performed with mechanical sweeping (for example, an intravenous ultrasound retraction device - IVUS), recording based on 2D or 3D probe data images, stereo vision based on infrared (IR) camera, or electromagnetic sensing (EM). Mechanical devices to restrict the movement of the transducer are cumbersome to use (and can potentially impact the quality of the image, since the trajectory defined by the mechanical movement may not coincide with ideal acoustic views). In addition, mechanical devices have limited accuracy that depends on a tightly controlled mechanical retraction.
    Image-based registration is computationally intensive and time-consuming, and reduces a possible number of image frame rates. In addition, image-based recording is limited to tracking relative movements between volumes, and cannot provide absolute position estimates of the transducer path (especially when the transducer movement occurs along a non-linear surface). The location based on the IR camera is sensitive to line of sight occlusions, which limits its usefulness, especially for clinical configurations in which a clear line of sight between the tracked transducer and the IR cameras cannot be guaranteed. The EM location
    2/22 exhibits limited spatial accuracy and precision, with sensitivity to changes in the spatio-temporal characteristics of the local EM environment. These limitations in tracking performance, in turn, affect the ability of the ultrasound imaging device in terms of providing high-quality images, anatomical accuracy, larger fields of view, or high temporal frame rates. All of these tracking technologies measure the location of the rigid transducer as a single entity, while a tracking technology that allows the sensing of the dynamic shape of the transducer elements would allow for flexible transducer configurations with improved image acquisition and reconstruction when data from element tracking are used in combination with the transducer signals in the imaging process.
    It would be advantageous to provide systems and methods in which the positioning and placement of medical devices is done reliably, and in which position sensing can occur in a spatially distributed manner to allow flexible imaging matrices that are not possible today in conventional probes.
    According to the present principles, an apparatus, a system and a method for determining a position, orientation or shape includes a transducer device configured to receive signals from a console and generate images based on the reflected waves. A flexible cable is attached to the transducer device to provide excitation energy for the transducer device from the console. An optical fiber has a shape and position corresponding to a shape and position of the cable during operation. A plurality of sensors are in optical communication with the optical fiber. The sensors are configured to measure the
    3/22 deflections and curvature in the optical fiber, so that the deflections and curvature in the optical fiber are used to determine the positioning information about the transducer device.
    The optical position and orientation sensing of a transducer and current cabling overcomes the limitations of conventional tracking methods, which allows for improved imaging capabilities, such as real-time extended field of view imaging, live spatial composition through the generation of images from multiple angles, the generation of simultaneous images from multiple transducers, and the enhanced image resolution and quality improvement through the formation and beam of the ultrasound reconstruction in an intensified way. In addition, sensing the optical shape embedded in the body of a flexible / reconfigurable transducer matrix will allow real-time knowledge of the transducer geometry that can be used to improve image acquisition and reconstruction by allowing dynamic adaptation of the geometry of according to clinical application (transducer arrays will not continue to be forced into rigid geometric configurations and allow unconventional flexible geometries, for example, multiple transducer elements distributed along the length of an optically scanned catheter to form a deformable transducer array spatially prolonged).
    An apparatus for determining a position, orientation and / or shape includes a transducer device configured to receive signals from a console and generate images based on the reflected or transmitted energy. A flexible cable is attached to the transducer device to provide excitation energy for the transducer device from the console. At least
    4/22 an optical fiber has a shape and position corresponding to a shape and position of the cable during operation. A plurality of sensors are provided in optical communication with at least one optical fiber, the sensors being configured to measure deflections and curvature in the optical fiber, so that deflections and curvature in the optical fiber are used to determine at least one information shape and positioning on the transducer device.
    Another device for determining a position, orientation and / or shape includes a medical instrument, a transducer device configured to receive signals from a console and generate images based on reflected or transmitted energy, and a flexible cable attached to the transducer device to provide excitation energy for the transducer device from the console. At least one optical fiber has a shape and position corresponding to a shape and position of the medical device during a procedure. At least one other position sensing device is provided for sensing the shape and position of the medical device with respect to at least one optical fiber. A plurality of sensors are in optical communication with at least one optical fiber, the sensors being configured to measure deflections and curvature in the optical fiber, so that the deflections and curvature in the optical fiber and at least one other sensing device. position are used to determine at least one shape and positioning information about the medical device during a procedure.
    A system for tracking a portion of an imaging or therapy device includes Fiber Bragg Gratings (FBGs - Fiber Bragg Gratings) integrated into an optical fiber and arranged inside a flexible cable. An ultrasonic transducer is coupled to an
    5/22 ultrasonic console via flexible cable. An optical system is configured to distribute light to the FBGs and receive light from the FBGs, so that the deflections of the optical fiber in the flexible cable are measured. A computer system includes a shape determination program configured to calculate the parameters related to the deflections of the optical fiber and determine a flexible cable configuration, so that the flexible cable configuration provides an ultrasonic transducer position.
    A method for tracking the position of an imaging device includes providing a transducer device configured to receive signals from a console and generating images based on reflected waves, a flexible cable attached to the transducer device to provide excitation energy for the transducer device from the console, and at least one optical fiber with a shape and position corresponding to a shape and position of the cable during operation, and a plurality of sensors in optical communication with at least one optical fiber. The transducer device is positioned, and deflections and curvature are measured on at least one optical fiber that corresponds to the shape and position of the cable, so that deflections and curvature in the optical fiber are used to determine shape information and positioning on the transducer device.
    These and other objects, characteristics and advantages of the present disclosure will be clear from the following detailed description of their illustrative achievements, which should be read in connection with the attached drawings.
    This disclosure will present in detail the following description of the preferred achievements with reference to the following figures, in which:
    FIG. 1 shows an optical fiber that includes a
    6/22
    Optical Fiber Bragg Grid (FBG), a graph of the refractive index as a function of distance and spectral response due to FBG;
    FIG. 2 shows a fiber trio deflected in three-dimensional space;
    FIG. 3 is a diagram showing a system for determining the position of an ultrasonic probe according to an illustrative embodiment;
    FIG. 4 is a diagram showing an ultrasonic device and a cross-sectional view of a cable with a set of optical sensors according to one embodiment;
    FIG. 5 is a diagram showing an ultrasonic device with a plurality of transducer elements coupled to a single set of optical sensors according to another embodiment;
    FIG. 6 is a diagram showing an ultrasonic device connected to a shape-sheath, so that a cable from the ultrasonic device and a set of fiber optic sensors match according to another embodiment;
    FIG. 7 is a diagram showing an ultrasonic device with a plurality of transducer elements, each coupled to its own set of optical sensors according to another embodiment;
    FIG. 8 is a diagram showing an ultrasonic device, a medical device and at least one set of optical sensors used to orient the medical device according to another embodiment;
    FIG. 9 is a diagram showing the optical sensors formed in a matrix to detect an applied pressure of a transducer element according to another embodiment; and
    FIG. 10 is a block / flow diagram showing
    7/22 a method for determining the position of an ultrasonic device in accordance with these principles.
    The present disclosure describes systems and methods for sensing the position of transducers, transducer elements, or various array arrays. In a particularly useful embodiment, an intravascular ultrasonic transducer is located using fiber optic sensors. Optical sensors can include Fiber Optic Bragg Grids (FBGs). In one embodiment, an ultrasound imaging system functionalized by the FBG employs shape sensing capabilities to enable new imaging capabilities (for example, real-time extended field of view imaging, spatial composition through generation of images from multiple angles, generation of simultaneous images from multiple transducers, flexible transducer matrices / adhesives, and enhanced image resolution / quality improvement through beam formation / enhanced ultrasound reconstruction.
    optical shape sensing with the use of a multitude of FBG grids and optical interrogations allows high-resolution spatio-temporal tracking of the transducer (s) and the corresponding cabling / catheter forms (cabling for transthoracic or body ultrasound, transesophageal echo, or catheter for intracardiac echo, just to name a few). By comparison, conventional tracking approaches based on electromagnetism (EM), for example, currently do not exhibit the tracking accuracy or robustness to environmental conditions that are possible with position sensing and optical fiber shape orientation.
    It should be understood that the present invention will be
    8/22 described in terms of medical instruments. However, the teachings of the present invention are much broader, and are applicable to any instruments employed in tracking or analyzing complex biological or mechanical systems. In particular, these principles are applied to internal ultrasonic procedures of biological systems, procedures in all areas of the body, such as the lungs, gastrointestinal tract, other organs, blood vessels, etc. The teachings are not necessarily limited to ultrasonic sensing, but can also be applied to the development and use of flexible sensor arrays of any other modality, for example, X-ray detector arrays, scintillating arrays, MRI coils, optical sensors (for example, tracked distribution of optical fiberscopes), etc. The elements represented in FIGS can be implemented in various combinations of hardware and software, and provide functions that can be combined into a single element or multiple elements.
    The functions of the various elements shown in the FIGS can be provided through the use of dedicated hardware, as well as hardware capable of running the software in association with the appropriate software. When provided by a processor, functions can be provided by a single dedicated processor, by a single shared processor, or by a plurality of individual processors, some of which can be shared. In addition, the explicit use of the term processor or controller should not be interpreted as referring exclusively to the hardware capable of running the software, and may implicitly include, among others, the hardware of the digital signal processor (DSP - Digital signal processor), the read-only memory (ROM) for the storage software,
    9/22 random access memory (RAM), and non-volatile storage.
    In addition, all the statements present here recite the principles, aspects and achievements of the invention, as well as its specific examples, are intended to cover both its structural and functional equivalents. In addition, it is intended that such equivalents include the equivalents known today, as well as the equivalents developed in the future (that is, any developed elements that perform the same function, regardless of the structure). Thus, for example, those skilled in the art can claim that the block diagrams presented here represent conceptual views of the components of the illustrative system and / or the circuits that incorporate the principles of the invention. Likewise, it can be said that any flowchart, state transition diagram, pseudocode, and the like represent various processes that can be substantially represented on computer-readable storage media, and thus be executed by a computer or processor, be it computer or processor explicitly known or not.
    In addition, the embodiments of the present invention may take the form of a computer program product accessible from a computer-usable or computer-readable medium that provides program code for use by a computer or in connection with a computer or any other instruction execution system. For the purposes of this description, a computer-usable or computer-readable medium can be any device that can include, store, communicate, propagate or transport the program for use by or in connection with the system, device or device for executing the program. instruction. The medium may be an electronic, magnetic, or electronic system (or apparatus or device)
    10/22 optical, electromagnetic, infrared or semiconductor, or a propagation medium. Examples of a computer-readable medium include a semiconductor or solid-state memory, magnetic tape, a removable floppy disk from the computer, a random access memory (RAM), a read-only memory (ROM) ), a magnetic hard disk and an optical disk. Current examples of optical discs include compact disc - read only memory (CDROM - compact disk - read only memory), compact read / write disk (CD-R / W - compact disk - read / write) and DVD.
    According to useful realizations, ultrasonic transducer tracking sensors can employ a plurality of different technologies. According to current principles, optical fiber technologies are described. The voltage sensing based on optical fiber can be done with the use of optical sensors. In one case, the sensors can include FBGs. By integrating voltage measurements over a length, a local shape of an optical fiber length can be determined. Optical measurements of geometry are attractive for at least the following reasons. The measurements are immune to electromagnetic interference and do not require electromagnetic emissions. The sensors are passive and, therefore, intrinsically safe. The multiplexing capability of the sensors in a matrix exists. The possibility of multiple sensing parameters (voltage, temperature, pressure, etc.) exists. Distributed sensing is possible, and the sensors have high sensitivity (even nano voltages when interferometry is used in optical interrogations). In addition, the fibers are small and light, and are ideal for minimally invasive applications. The fibers are insensitive to the variation in signal amplitude (when Bragg sensors
    11/22 in fiber are used with wavelength detection).
    For many medical applications, in particular for those requiring minimally invasive navigation and instrumentation, fiber optic sensing with Fiber Optic Bragg Grids offers high accuracy and high precision localization in high spatio-temporal resolution along the length of the fiber . Given the light weight, elongated form factor of the optical fiber and its compact cross-sectional reach, fiber technology provides improvements for ultrasound applications that require transducers chained to a console via a cable, endoscopic support or catheter (ICE) . The incorporation of Bragg Grids in Optical Fiber in the body of the cable / endoscope / catheter support allows a fine space-time tracking of one or more elements / matrices of the transducer inside the elongated medical instrument.
    Referring now to the drawings in which similar numbers represent the same or similar elements, and initially to FIG. 1, the Bragg Grids in Optical Fiber (FBG) 10 is depicted illustratively. In a particularly useful embodiment, the FBG 10 includes a short segment of an optical fiber 12 that reflects particular wavelengths of light and transmits all others. This is achieved with the addition of a periodic variation 14 of the refractive index in a fiber core 16, which generates a dielectric mirror of specific wavelength. A graph 20 of the refractive index of the core as a function of distance is shown illustratively.
    A Fiber Optic Bragg Grid 10 can therefore be used as a built-in optical filter to block certain wavelengths, or as a specific wavelength reflector. An input spectrum 22 and
    12/22 the respective output spectra 24 and 26 illustratively show a transmitted portion (spectrum 24) and a reflected portion (spectrum 26) of the input spectrum 22. The fundamental principle behind the operation of a Fiber Bragg Grid Optics 10 is the Fresnel reflection on each of the interfaces on which the refractive index changes. For some wavelengths, the reflected light from the various periods is in phase, so that there is constructive interference for reflection and, consequently, there is destructive interference for transmission.
    Bragg's wavelength is sensitive to voltage as well as temperature. This means that Bragg grids can be used as sensing elements in fiber optic sensors. In an FBG sensor, the voltage causes a change in the Bragg wavelength, Δλβ. The relative displacement in the Bragg wavelength, Δλβ / λβ, due to an applied voltage (ε) and a change in temperature (ΔΤ) is ^ = € 3 ε + € Ί ΛΤ given approximately by:
    The coefficient of C s is called the stress coefficient, and its magnitude is usually about 0.8 x 10 ~ 6 / με or in absolute quantities of about 1 pm / με). The Ct coefficient describes the temperature sensitivity of the sensor. It consists of the thermal expansion coefficient and the thermo-optical effect. Its value is about
    7x10 ~ 6 / K (or as an absolute amount of 13 pm / K). Since FBGs are particularly suitable for use in accordance with these principles, other sensors can also be employed.
    With reference to FIG. 2, a fiber trio 30 includes three fibers 34 and three FBGs 32. An advantage of using the trio 30 or a multiple fiber / FBG element is that the various sensor elements can be distributed along the
    13/22 length of a fiber. For example, by incorporating three cores with several sensors (gauges) along the length of the fiber embedded in a structure, the three-dimensional shape of that structure can be precisely determined. The FBG 32 sensors are located in various positions along a length of a fiber 34. From the measurement of the tension of each FBG 32, the curvature of the structure 30 can be inferred at that position in the three-dimensional space (x, y, z) . From the multiplicity of measured positions, the total three-dimensional shape is determined.
    The 34 fibers are preferably one material flexible, such as polymers in medical degree (per example, PEEK ™) . The nuclei of fiber 35 are shown in an seen in cut transversal of insertion. a coating 36 around
    The fibers can be constructed from medical grade polymers, silicone or other suitable materials.
    With reference to FIG. 3, an imaging or treatment system 100 is illustratively shown with ultrasound transducers according to an illustrative embodiment. System 100 includes a medical imaging device 101 with orientation feedback through shape sensing. Device 101 includes one or more transducer elements 102. Device 1010 can be employed for treatment procedures in other embodiments. Transducer elements 102 can include piezoelectric transducer elements that generate ultrasonic energy in response to electrical impulses. It should be understood that other forms of mechanical and electromagnetic energy can be used, and that the transducer elements can include other structures. Transducer elements 102 can be connected to a cart / console 104 via a cable 108. Cable 108 can include an endoscopic support or other medical device, a catheter
    14/22 or another flexible member. Cable 108 includes at least one optical sensing fiber 110 embedded in it for real-time, high-precision spatial location of transducer elements 102 and associated cables (108).
    The transducer elements 102 are housed in a flexible assembly 120. The cart / console 104 includes an ultrasound console 112 that is configured to provide power to drive the transducer elements 102 that generate the ultrasonic waves. The shape sensing fiber or fiber bundles 110 extend over at least a portion of the cable 108, and interconnect to the console 104 to allow accurate and real-time assessment of the geometries and dynamics of the transducer element.
    Console 104 includes an optical console 116 that distributes light to the optical sensors 122 (e.g., FBGs) of the fiber bundles and receives light from them. An optical source on console 116 (or another location, if desired) is provided for illuminating the shape sensing fiber. A receiver of the optical interrogation unit (such as a transceiver 117) is provided on the console 116 to read the multiplexed signals that return from the FBGs 122 on all fibers 110.
    console 116 may be connected to computer system 130 which includes memory storage 128 and an operating system 124 with a correspondingly determined program 132 that calculates parameters related to deflection of optical fibers 110. Computer system 130 may include console 116 or can be a standalone system. Optical transceiver 117 transmits and receives optical signals to / from fibers 110. Light signals are interpreted to determine a shape of the fiber and thereby determine a position or orientation of transducer element 102 in a body. The data from sensors 122 is
    15/22 transmitted through optical fibers 110 and can be correlated to a 3D volume or map or a reference position (e.g., trolley 104) to determine position information on transducer elements 102 or cable 108.
    computer 130 includes a processor 131 that implements FBG sensing methods in real time 132 for sensing fiber deflection and the derivation of the corresponding fiber bundle shapes, and calculates the spatial geometry of one or more transducer elements 102 that form a extended transducer matrix. Computer 130 calculates spatially located 3D ultrasound data sets based on the calculated spatial geometry of one or more transducer elements 102. An input / output (I / O) device or an interface 152 provides real-time interaction with the computer 130, the device 101 and a spatially located ultrasound imaging visualizer 138, and an orientation, shape and / or position of the cable 108 can be displayed. Computer system 130 may include user interface 152 for interacting with console 116, console 112, and device 101. Interface 152 may include a keyboard, mouse, touch screen system, etc.
    A data connection 154 connects the ultrasound console 112, the optical interrogation unit 117 and the console 116 to the processor 131 for determining the geometry / shape of the transducer. The optical interrogation unit or console 116 provides real-time spatial location data for the 112 ultrasound console for the dynamic reconstruction of spatially accurate 3D ultrasound data for improvement. Improvements may include generation of real-time extended field of view images; spatial composition live through generation
    16/22 images from multiple angles; simultaneous imaging of multiple transducers; enhanced image resolution / quality improvement through beam formation / enhanced ultrasound reconstruction (eg ultrasonic tomographic reconstruction). The flexible set of transducer elements 102 can be adapted to the anatomy of the patient in question (e.g., skin surface, tortuous vascular anatomy, gastrointestinal tract, etc.). The shape of the optical fiber 110 allows for the precise determination of one or more transducers 102 in relation to each other and in relation to a fixed reference location (e.g., an ultrasound cart reference) to enhance imaging performance.
    With reference to FIG. 4, device 101 is shown according to an illustrative embodiment. In this embodiment, device 101 includes a single transducer element 102. Transducer element 102 is coupled to a cable 108 that can include a catheter, an endoscope, etc. Cable 108 includes at least one voltage / shape sensing assembly in it. Detail 202 shows a cross-sectional view of cable 108.
    tension / shape sensing set 204 includes fibers 110 with sensors (eg, FBGs) 122 that allow optical sensing of tension and shape. In the illustrative embodiment of FIG. 4, the sensing set 204 includes a fiber trio to better track the shape, rotation and position of the Bragg Grids in Fiber Optics. The device 101 includes the sensing set 204 with the elements of the ultrasound transducer 102. Thus, based on the positioning information provided by the sensing set 204, the positions and orientations of the transducer elements 102 can be determined in relation to a reference and tracked throughout a procedure. At
    17/22 recorded images can now include shape / positioning information with ultrasound images in real time or for later retrieval.
    The transducer elements 102 can be included in an elongated ultrasound probe, for example, in a hand, endoscopic, or catheter set connected to the ultrasound cart (104, FIG. 3) that includes the optical source and the interrogation unit (117, FIG. 3). The sensing set 204 is embedded along the bracket / cabling 108 to allow the location of device 101, followed by the visualization of 3D ultrasound data spatially tracked and reconstructed.
    With reference to FIG. 5, an ultrasound probe 210 includes a plurality of transducer elements 102 arranged in an extended geometry. The geometry may include a one-dimensional distribution of 102 elements over the length of a catheter (for example, an Intracardiac Echocardiography (ICE) catheter), a probe (for example, a transesophageal echocardiogram (TEE) echocardiography)), etc., or it may include a flexible multi-dimensional adhesive probe that shapes the patient's anatomy, (for example, a flexible carotid probe that surrounds the patient's neck) or other configuration. Another geometry may include the combination of existing imaging probes, such as TEE with ICE or ICE with transthoracic echocardiogram (TTE - transthoracic echocardiogram), etc., and all other permutations. The optically shaped fiber assembly 204 interconnects with transducers 102 in this assembly to allow high precision tracking of movement relative to the transducer. With this information, body surfaces and other information can be collected with imaging data
    18/22 ultrasonic. This configuration allows the optimization of the acquisition and reconstruction of multiple transducers through the simultaneous exploration of triggering / receiving elements of the matrix in combination with the 3D location information.
    With reference to FIG. 6, the embodiments described here can be employed or connected to a shape-adjusting liner 240 which is elastically connected or via other means of secure attachment to an ultrasound transducer element 102. Transducer element 102 is fixed with respect to liner 240. Liner 240 may include a cuff, gloves, etc., to be attached to a user or the patient's body. Jacket 240 is tied to an ultrasonic cable 241 and connects to an ultrasonic console to be powered. The sensing set 204 is coupled to cable 241 using connectors 243 or, alternatively, sheath 240 can be extended, and cable 241 and set 204 can be placed within sheath 240, so that they are coincident and remain so during operations or procedures. In this way, the movement of the transducer element 102 is determined with the position of the cable 241 using the sensor set 204. A light source (not shown) in a reference position is used to illuminate the optical sensor set 204 for determining the voltage in the optical fiber to provide the shape and position of the cable 241 and, therefore, the transducer element 102. An advantage of this realization is that it allows the retrofitting of the existing transducers or probes.
    With reference to FIG. 7, a high intensity focused ultrasound transducer (HIFU - High Intensity Focused Ultrasound) 250 can be employed whose independent elements 252 are separately tracked by multiple fibers 254 (for example, sensor sets 204). At
    19/22 fibers 254 include the FBGs to determine the shape and position described above. This realization allows the identification of the position (and shape) for each of the plurality of elements 252, and allows flexible geometries in which the transducer elements 252 can be positioned so that they are not obscured by bones (as in the ribs) or pathways filled with air (as in the lungs or intestines). The ability to monitor its position with precision on the order of less than 500 microns allows uncertainty in the phase of about 1/3 of a cycle. With accuracy of less than 250 microns, the phasing that is suitable for the additive HIFU phases that result in the ability to heat the tissue and therefore provide treatment for a patient can be achieved. Other treatments can also be provided, for example, ultrasonic treatments, etc.
    With reference to FIG. 8, a device 280 which may include a needle, a catheter, etc. includes a shape-sensing set 204 with fibers 110 and sensors 122 (FIGS. 3, 4). The 280 device has an image generated with ultrasound. In this embodiment, the relative positions of the device 280 and the fiber (204) are measured with two optical fibers (sets 204), or combinations of optical fibers and EM 282 sensors. The position of the device is determined, and the relative angle between the device 282 and an ultrasound transducer 284 is calculated. If device 280 is outside the perpendicular, most of the ultrasound signal 285 is expected to be reflected away from transducer 284. However, a component of the signal will reflect towards transducer 284. When sensing the relative orientation of the entire length of the device and the transducer, beam forming techniques can be employed in which only the channels that are expected to be perpendicular are included in the beam adding process. Besides that,
    20/22 knowing the relative position of the device 280, the beam formation can be applied only to a portion of the image, which allows the optimization of the generation of rigid reflector images and the generation of soft spreader images within a same image formation.
    With reference to FIG. 9, an adhesive 300 includes an optical fiber oriented in a circular formation or other closed or partially closed formation. The adhesive 300 is placed on a patient with an acoustic window 302 in the center. The deformation of the skin from the applied pressure of a transducer 306 with the knowledge of the relative position of the adhesive 300 and transducer 306 (in relation to a console 104 or 112, FIG. 3) allows not only the spatial registration, but also the recreatable pressure (real tension) that must be applied to the patient. Pressure (or pushing the 306 ultrasound transducer) is often necessary to obtain an ideal acoustic trajectory and to provide good acoustic coupling for the patient. This accomplishment could help to train less experienced operators, provide the ability to recover an acoustic view for patients in monitoring situations, and be used in closed return circuits, as in robotics, in which the controller needs to know how much pressure to apply to the patient with the transducer. It should be understood that other configurations and achievements are contemplated within the scope of these claims. The present achievements are applicable to all ultrasound imaging techniques for intervention applications using cabling in an ultrasound cart.
    With reference to FIG. 10, a method of tracking a position of an imaging device, such as an ultrasonic transducer, is shown. In block 402, a device is provided. The device includes a device
    21/22 transducer configured to receive signals from a console and generate images based on the reflected waves. A flexible cable is attached to the transducer device to provide excitation energy for the transducer device from the console, and at least one optical fiber has a shape, orientation and position corresponding to a shape, orientation and position of the cable during operation. A plurality of sensors is also provided in optical communication with at least one optical fiber. The transducer device is positioned in block 404. In block 406, the deflections and curvature in at least one optical fiber correspond to the shape, orientation and position of the cable. The deflections and curvature experienced by the cable are also experienced by the optical fiber. Deflections and curvature in the optical fiber are used to determine the positioning information about the transducer device. The sensors preferably include a plurality of Fiber Optic Bragg Grids distributed along a length of the optical fiber, and deflections and curvature are measured using Fiber Optic Bragg Grids.
    In alternative embodiments, different fiber and transducer configurations can be used to measure different parameters. In one embodiment, at least one optical fiber includes a plurality of sensors formed in a closed or partially closed formation, and the method includes placing the transducer device between the plurality of sensors to measure changes in position due to pressure applied to the transducer device in block 408. Position information (and / or pressure) can be stored in block 410. Position and pressure information can be stored with ultrasonic images or images from other technologies.
    In interpreting the appended claims, you must
    22/22 be understood that:
    a) the word comprises does not exclude the presence of other elements or acts in addition to those listed in a given claim;
    b) the word one or one that precedes an element does not exclude the presence of a plurality of such elements;
    c) any signs of reference in the claims do not limit its scope;
    d) several meanings can be represented by the same implemented item or hardware or software structure or function; and
    e) no specific sequence of acts is intended to be necessary, unless expressly indicated.
    Having described the preferred realizations for an apparatus, a system and a method for imaging and treatment using optical position sensing (which are intended to be illustrative, not limiting), it should be noted that the technicians in the subject they can make changes and variations in the light of the teachings described above. Therefore, it should be understood that changes can be made to particular achievements of the revealed disclosure and that they are within the scope of the achievements disclosed here, as outlined by the attached claims. Having thus described the details and particularities required by the patent laws, what is claimed and desired protected by the Patent Law is set out in the attached claims.
    权利要求:
    Claims (15)
    [1]
    1. APPARATUS FOR THE DETERMINATION OF A POSITION, ORIENTATION AND / OR FORM, characterized by comprising:
    a transducer device (102) configured to receive signals from a console (104) and generate images based on the reflected or transmitted energy;
    a flexible cable (108) coupled to the transducer device to provide excitation energy for the transducer device from the console;
    at least one optical fiber (110) with a shape and position corresponding to a shape and position of the cable during operation; and a plurality of sensors (122) in optical communication with at least one optical fiber, the sensors being configured to measure deflections and curvature in the optical fiber, so that deflections and curvature in the optical fiber are employed to determine at least shape and positioning information about the transducer device.
    [2]
    Apparatus according to claim 1, characterized in that the plurality of sensors (122) includes Bragg Grids in Fiber Optics distributed over a length of at least one fiber to measure the tension.
    [3]
    Apparatus according to claim 1, characterized in that at least one fiber includes a fiber trio (34).
    [4]
    APPLIANCE, according to claim 1, characterized in that the transducer device (210) includes a plurality of transducer elements (102) coupled to the same optical fiber (204) with sensors to determine the shape and position of the fiber and therefore, to determine a dynamic geometry of the transducer elements in relation to each other.
    2/4
    [5]
    Apparatus according to claim 1, characterized in that at least one optical fiber (110) includes a plurality of sensors (122) formed in a closed or partially closed formation (300), and the transducer device is placed between the plurality of sensors to measure changes in position due to pressure applied to the transducer device.
    [6]
    Apparatus according to claim 1, characterized in that the transducer device (102) includes a plurality of transducer elements (252), each transducer element being coupled to a corresponding optical fiber with sensors to determine the shape and position of the fiber.
    [7]
    7. Apparatus according to claim 1, characterized in that it additionally comprises a sheath (240), the transducer device (102) being attached to the sheath, and in which the cable and at least one optical fiber are coupled to each other along its length so that the shape and position of the cable corresponds to the shape and position of at least one optical fiber during operation.
    [8]
    Apparatus according to claim 1, characterized in that the transducer device (102) includes a plurality of transducer elements (252) coupled to one or more optical fibers with sensors to determine the shape and position of the fiber, the transducer elements configured to provide treatment to a patient.
    [9]
    9. APPARATUS FOR DETERMINING A POSITION, ORIENTATION AND / OR FORM, characterized by comprising:
    a medical instrument (280);
    a transducer device (284) configured to receive signals from a console (104) and generate images based on the reflected or transmitted energy;
    a flexible cable (241) attached to the device
    3/4 transducer to provide excitation energy for the transducer device from the console;
    at least one optical fiber (110) with a shape and position corresponding to a shape and position of the medical device during a procedure;
    at least one other position sensing device (282) for sensing the shape and position of the medical device with respect to at least one optical fiber; and a plurality of sensors (122) in optical communication with at least one optical fiber, the sensors being configured to measure deflections and curvature in the optical fiber, so that the deflections and curvature in the optical fiber and at least one other device Position sensing devices are used to determine at least one shape and positioning information about the medical device during a procedure.
    [10]
    Apparatus according to claim 9, characterized in that the plurality of sensors (122) includes Fiber Optic Bragg Grids distributed over a length of at least one fiber to measure the tension.
    [11]
    11. Apparatus according to claim 9, characterized in that at least one other position sensing device (282) includes another optical fiber with optical sensors and an electromagnetic sensor.
    [12]
    12. SYSTEM FOR TRACKING A PORTION OF AN IMAGE GENERATION OR THERAPY DEVICE, characterized by comprising:
    Bragg grids in optical fiber distributed spatially (122) integrated in an optical fiber (110) and arranged inside a flexible cable (108);
    an ultrasonic transducer (102) coupled to an ultrasonic console via the flexible cable;
    4/4 an optical system (116) configured to distribute light to the FBGs and receive light from the FBGs, so that the deflections of the optical fiber in the flexible cable are measured;
    a computer system (130) that includes:
    a shape determination program (132) configured to calculate the parameters related to the deflections of the optical fiber and determine a flexible cable configuration, so that the flexible cable configuration provides an ultrasonic transducer position.
    [13]
    13. SYSTEM, according to claim 12, characterized in that the ultrasonic transducer (102) includes a plurality of transducer elements (210) coupled to the same optical fiber with sensors to determine the position of the fiber.
    [14]
    14. SYSTEM, according to claim 12, characterized in that at least one optical fiber (110) includes a plurality of sensors (122) formed in a closed or partially closed formation (300), and the transducer device is placed between the plurality of sensors to measure changes in position due to pressure applied to the transducer device.
    [15]
    A system according to claim 12, characterized in that the ultrasonic transducer (102) includes a plurality of transducer elements (252) with each transducer element coupled to the corresponding optical fiber with sensors to determine the position of the fiber.
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    法律状态:
    2020-06-09| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]|
    2020-07-21| B25D| Requested change of name of applicant approved|Owner name: KONINKLIJKE PHILIPS N.V. (NL) |
    2020-08-11| B25G| Requested change of headquarter approved|Owner name: KONINKLIJKE PHILIPS N.V. (NL) |
    2020-08-25| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|
    2020-12-08| B11B| Dismissal acc. art. 36, par 1 of ipl - no reply within 90 days to fullfil the necessary requirements|
    2021-10-19| B350| Update of information on the portal [chapter 15.35 patent gazette]|
    优先权:
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    US30257110P| true| 2010-02-09|2010-02-09|
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    PCT/IB2011/050169|WO2011098926A1|2010-02-09|2011-01-14|Apparatus, system and method for imaging and treatment using optical position sensing|
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