Patent Description:
Mobile, instrument or patient mountable tracking systems are described for surgical navigation in <CIT> and <CIT>. The tracking system of <CIT> is part of a surgical navigation system and locates and tracks arrays in real-time. The positions of the arrays are detected by cameras and displayed on a computer display. The tracking system is used to determine the three-dimensional location of the instruments which carry markers serving as tracking indicia. The markers may emit light, in particular infrared light or reflect such light. The light is emitted or reflected to reach a position sensor for determining the position of the instrument. The specific anatomical structure of the patient can be characterized by a limited number of landmarks, which can be used to generate a virtual patient specific instrument. The virtual patient specific instrument can be used to manufacture a patient specific instrument, e.g. by means of rapid prototyping. Such a patient specific instrument can be positioned on the patient's bone structure accurately and attached to the patient's bone structure. The patient specific instrument can include a tracking device, e.g. a reference array. The position of the reference array is thus known and can be used to position the patient specific instrument virtually on the display. Due the fact that rigid reference arrays can be obtained, the patient's bone structure can be tracked without the need of additional rigid array markers. The navigation system automatically recognizes the position of the reference array relative to the patient's anatomy. A system for performing a computer-assisted hip replacement surgery is disclosed in document <CIT>. The system comprises a pelvis sensor, a broach sensor and a femur sensor coupled to the respective bone or broach structure. The position of the sensors is recorded during the surgery by a processing device. The processing device can perform a femoral registration by measuring an orientation between the broach sensor and the femur sensor. The processing device can display a fixed target frame and a track frame, which can be matched by adjusting the positions of the bone and broach structures and when the matching position is reached, the change in leg length and a change in offset can be calculated. Each of the sensors can be configured as an optical reader or a beacon. These two documents relate thus to the concept of a miniaturized and mobile tracking system and their applications in surgical procedures.

The tracking system can also be used for multiple surgical interventions like orthopedics, trauma and spine surgery where tracking of an instrument relative to a single or multiple acquired C-Arm image is desired and can help to reduce the radiation dose in such interventions. This setup is described as virtual fluoroscopy for several applications (<CIT>, <CIT>, <CIT>, <CIT>, <CIT>). In a state of the art setup for virtual fluoroscopy the C-Arm imaging device needs to be equipped with a trackable reference frame and the imaging parameters must be calibrated with respect to this reference frame. An additional optical marker has to be positioned in a fixed position with respect to the patient or fixed to the patient and to the instrument for the intervention (e.g. a drill sleeve). Such a setup is complex in a surgical theater and requires always a line of sight to all tracked devices. For example, the Brainlab X-Spot device according to <CIT> is an x-ray marker device comprising an arrangement of x-ray markers defining device straight lines forming the edges of pyramids. This x-ray marker device allows to register the patient anatomy to a tracker fixed to the patient using a special tracker with fiducial marker elements, but still requires an external tracking system. Other solutions (<CIT>) propose to attach a tracking system to the C-Arm to limit the line-of-sight issues and omit the step of tracking the C-arm position. The C-arm imaging device can track the external environment with respect to the coordinate system fixed to the C-arm.

A problem associated with any of these prior art solutions is to integrate the surgical tracking device into the anatomical structure model generated from the images of the imaging device. The surgical tracking device can be a mobile surgical tracking device, such as an implant, a surgical instrument or a patient specific instrument. This integration requires complex coordinate transformation calculations to match the coordinate system(s) of the tracked device with the respective coordinate systems of the imaging device to determine the exact position of the tracked device both in the anatomical structure model and at the same time in the anatomical structure itself. There is thus a need for a simplified tracking system for tracking the position of a surgical tracking device by integration into the model of the anatomical structure obtained from the radiographic images generated by the imaging device.

<CIT> discloses a camera attached in a fixed position to a patient, a surgical tool including a tracking element readable by the camera, a computer processing unit comprising means for recognizing the tracking element in an image obtained by the camera and means for tracking the position of the surgical tool. A communication link is provided for transmitting images from the camera to the computer processing unit. The camera comprises one or more fiducial markers to define the position of the camera. The computer processing unit comprises means for registering the position of the camera from the position of the fiducial markers with an image of a patient in correlation with a scan image of the patient. The image processing steps as disclosed in <CIT> require considerable computational resources.

<CIT> discloses a redundant reciprocal tracking system composed of at least two trackers. A first tracker is able to sense partial or full pose data (orientation and position) of a second tracker in a first reference frame and the second tracker is able to sense partial or full pose data of the first tracker in a second reference frame.

There is thus a need to provide a simplified tracking system which requires less computational resources to localize a surgical tool in an image or scan image of a patient.

The problem is solved by a mobile surgical tracking system according to claim <NUM>. Further advantageous embodiments of the mobile surgical tracking system are subject to the dependent claims.

If the term «for instance» is used in the following description, the term relates to embodiments or examples, which is not to construed as a more preferred application of the teaching of the invention. The terms "preferably" or "preferred" are to be understood such that they relate to an example from a number of embodiments and/or examples which is not to construed as a more preferred application of the teaching of the invention. Accordingly, the terms "for example", "preferably" or "preferred" may relate to a plurality of embodiments and/or examples.

The subsequent detailed description contains different embodiments of the mobile surgical tracking system according to the invention. The mobile surgical tracking system can be manufactured in different sizes making use of different materials, such that the reference to a specific size or a specific material is to be considered as merely exemplary. In the description, the terms «contain», «comprise», «are configured as» in relation to any technical feature are thus to be understood that they contain the respective feature, but are not limited to embodiments containing only this respective feature.

The object of the invention is solved by mobile surgical tracking system comprising a mobile surgical tracking device comprising an integrated fiducial marker and an imaging device, whereby the imaging device is configured to generate an image of a patient's anatomical structure, whereby the mobile surgical tracking system comprises a tracking system coordinate frame. The integrated fiducial marker has a position which has a known relation to the tracking system coordinate frame for the direct registration of the image to the coordinate system of the mobile surgical tracking device. The image can be in particular a radiographic image. The anatomical structure can in particular be a bone structure.

Instead of locating the mobile surgical device in the model of the anatomical structure and in the anatomical structure of the patient, which requires complex calculations to match the coordinate systems of the surgical tracking device, the virtual surgical tracking device, the imaging device and the model of the anatomical structure generated by the imaging device required by the approach taken in the prior art solutions it is possible with the mobile surgical tracking system of the invention to directly register the image with the mobile surgical tracking device. The image is integrated into the mobile surgical tracking system coordinate frame, whereby the position of the mobile surgical tracking device with respect to the anatomical structure both virtually, thus in the anatomical structure model, and physically, thus in the anatomical structure of the patient, is simultaneously defined.

In other words, a direct registration of the acquired images to the tracking system reference frame can be achieved by the proposed solution of a miniaturized tracking system with integrated fiducial marker according to the invention. Such a registration can be more accurate as no transformation over a multiple coordinate system requiring multiple relative measurements of different trackers has to be made. The mobile surgical tracking device can comprise an instrument, such as a surgical instrument, a surgical tool, a patient specific instrument, an implant or combinations thereof. The instrument to be guided can be equipped with an optical marker which is directly measured in the target coordinate system of the tracking system. As the tracking system is attached directly at the site of intervention and the instrument is in close range of the tracking system, there are no line of sight issues as with existing external optical tracking solutions.

Other applications for the described invention are for example in the field of orthopedics, spine, cranial/neuro, ENT (ear, nose, throat), dental navigation or any other image guided surgical intervention. The mobile surgical tracking device can be used for image guided interventions where a CT or cone beam CT scan is acquired pre-operatively. The mobile surgical tracking device can be attached in a known positional relationship with respect to the patient close to the surgical field. According to this configuration, the scan can be made by integrating the integrated fiducial marker into the imaging volume. Thereby a direct registration of the imaging device coordinate frame to the patient coordinate frame is possible. Either the mobile surgical tracking device can be left on the patient until the surgical procedure is carried out or the mobile surgical tracking device can be fixed at the same location for the surgical intervention.

An application of the proposed invention includes a dental image based navigation system. A cone beam CT is made with the mobile surgical tracking device and the integrated fiducial marker mounted on the patient teeth using a dental tray. Later, the mobile surgical tracking device can be attached at the same location or position as during the CT scan and the dental drill can be navigated relative to acquired image data or computed 3D reconstructions.

In another embodiment the proposed mobile surgical tracking system can be used for intraoperative registration of pre-operatively acquired images like a CT or MRT scan of the patient's anatomy. This is described for example in <CIT> using an external optical tracking system. By using multiple C-Arm, images with the proposed tracking system in place, a registration of the preoperative images in relation to the intraoperative acquired radiographic images can be made.

In another application, the proposed mobile surgical tracking system can be used for intraoperative calculation of 3D models of the patient anatomy based on a single or multiple 2D radiographic image acquisition. This is described for example in <CIT> or <CIT> using an external optical tracking system. Using multiple C-Arm acquisitions with the proposed tracking system in place such a 2D-3D registration can be implemented and direct navigation of surgical tools in relation to these calculated 3D models is possible. Due to the small size of the tracking device and trackable marker the fixation to the patient can be made less invasive and closer to the surgical site.

According to an embodiment, the integrated fiducial marker comprises a computer detectable element, whereby the computer detectable element is detectable in the image, whereby the computer detectable element can be selected from the group of spheres, line segments, circles, ellipses, helices, patterns, holes or any combination thereof, whereby the image comprises an image coordinate frame or an image projection to allow the registration of the image coordinate frame or the image projection to the mobile surgical tracking system coordinate frame.

Integrated fiducial markers as described in this document always require a configuration of single or multiple geometrical elements that allow to register an image or image volume with respect to the coordinate frame of the mobile surgical tracking system including the integrated fiducial marker. The use of an integrated fiducial marker for the calculation of perspective projection parameters of a C-arm position can be beneficial for a great number of surgical applications. Another embodiment of such integrated fiducial markers are configurations for the registration of image volumes generated with conventional CT scanners of cone beam CT scanners (CBCT). Depending on the type of registration and registration accuracy required, the size and geometry of the integrated fiducial marker can be variable. In some implementations, the integrated fiducial markers comprise a number of radio-opaque spheres in a known spatial relationship. According to some embodiments, the integrated fiducial markers can be made of stainless steel, thus they can be specifically configured as spherical marker elements. An advantage of such spherical marker elements is their simple detection in radiographic images. In addition thereto, spherical marker elements are always visible as circles in the images. Other possibilities for integrated fiducial markers include line segments, elliptical lines or helical lines made from radio-opaque material. Also, additional elements/symbols such as arrows, concentric circles, letters, can be added to automatically identify the orientation of the marker or elements of the integrated fiducial marker. Alternatively, the integrated fiducial marker can be made from a radio-opaque material with a defined outer geometry and with holes at a given positions. The detection of outline edges, corners and holes can be made in radiographic images for fiducial detection. An integrated fiducial marker could also be configured as a pattern of transparent and opaque regions. Any combination of the described types of integrated fiducial markers is possible in combination with a mobile surgical tracking device.

According to an embodiment, the integrated fiducial marker is integrated in a printed circuit board (PCB) containing tracking system electronics. The printed circuit board (PCB) can comprise one of a single PCB, a multi-layer PCB, a plurality of PCBs, a flexible PCB. Alternatively or additionally, the integrated fiducial marker can be incorporated into the housing of the mobile surgical tracking device with a known relation to a coordinate frame of an optical tracking element.

The integrated fiducial marker can be integrated into a patient fixation device or can be attached to the patient fixation device. The mobile surgical tracking device can be attached to the integrated fiducial marker in a defined spatial position. In particular, the patient fixation device has a geometry usable as the integrated fiducial marker, such that the mobile surgical tracking device can be attached in a known position on the mobile surgical tracking device, e.g. an instrument, a surgical instrument, a patient specific instrument, a surgical tool.

The integrated fiducial marker may be integrated into the mobile surgical tracking device, but other embodiments are also possible and preferable for some applications. In one embodiment, the integrated fiducial marker and the mobile surgical tracking device are detachable. Thereby, the imaging can be made when the mobile surgical tracking device is removed. If the mobile surgical tracking device is temporarily removed, no artifacts from the mobile surgical tracking device become part of the images. According to this configuration, the mobile surgical tracking device does at least temporarily not interfere with the imaging device. Furthermore, a detachable mobile surgical tracking device would allow to use the integrated fiducial marker for imaging only and to use the mobile surgical tracking device only in the surgical intervention. Even more, it may be preferable for the surgical intervention to remove the integrated fiducial marker from the mobile surgical tracking device as the space used for the integrated fiducial marker may interfere with surgical tool path or other surgical procedure. Possible configurations comprise at least one of a detachable mobile surgical tracking device and a detachable integrated fiducial marker. If both the mobile surgical tracking device and the integrated fiducial marker are attachable to the same mechanical interface interchangeably, they could be mounted to a patient fixation device at the same positions, e.g. first the integrated fiducial marker for imaging and then the mobile surgical tracking device for surgical intervention.

In another embodiment, the integrated fiducial marker is formed by the patient fixation device itself, for example an external fixation device like a taylor spatial frame. In this setup, the fixation device itself has a geometric structure that is detectable in the images, in particular radiographic images, and can be used to calculate image registration. The mobile surgical tracking device can be mounted at a known position to this patient fixation device and like this to the integrated fiducial marker formed by the instrument fixation. For example, two frames in a taylor spatial frame application can be mounted to two bone segments and x-ray images from multiple directions can be made. A mobile surgical tracking device can be attached at one frame and on the other frame a trackable marker can be attached. Based on the x-ray images, the bone segments could be reconstructed as 3D models and fracture reduction could be planned and applied by the taylor spatial frame. The movements of the two fixation devices relative to each other can be tracked by the attached mobile surgical tracking device. According to a preferred configuration, the fixation devices comprise fixation rings. It is possible that additional fiducial elements are added to an existing patient fixation device to be able to use it as the integrated fiducial marker. The additional fiducial elements could be for example part of the attached mobile surgical tracking devices.

The mobile surgical tracking device according to any of the preceding embodiments is preferably lightweight to be mountable to a patient or fixed to an anatomical structure like a bone. Also, a small size is required not to interfere with imaging.

The mobile surgical tracking system comprises an integrated optical tracking system.

In one embodiment not according to the invention the optical tracking system could be implemented as a stereo- or multi-camera optical system. The optical tracking system can be used for tracking an active or passive marker. Such systems are known and well described but based on the required optics and computation tasks for tracking, an integration to a very small form factor is not straightforward. Alternatively, a single camera tracking system could be provided, as this system would require less space, but the achievable accuracy of this system is limited.

The integrated optical tracking system comprises a shadow imaging tracking, e.g., using a shadow mask above an imaging sensor in order to track the position of a marker equipped with three or more LEDs in a known configuration. In a preferred embodiment a shadow imaging technology is used as tracking system in the mobile surgical tracking device. This tracking system only requires an optical sensor, for example a CCD chip with a shadow mask on top of it and the computation can be implemented by a small size embedded system. It is possible to integrate all components in a single chip for further reduction of the possible form factor. The trackable elements require at least <NUM> LEDs in a known spatial configuration that are measured by the shadow imaging system. With the single LED position, the tracking system can compute the 6D position of the trackable element. Another advantage of the shadow imaging tracking is its large opening angle of <NUM>° or more, which is a substantial advantage for close range measurements as also intended with this invention. The principle of shadow imaging (<CIT>) and its integration with surgical instruments (<CIT>) is described in previous patent applications and other publications,.

In a preferred embodiment, the mobile surgical tracking system comprises a battery. In particular, the mobile surgical tracking device is battery driven and can operate completely wireless.

The mobile surgical tracking system can comprise a display device which can be configured to implement a wireless communication. The display device can be configured to retrieve preoperatively acquired tracking data, image data, planning data or other patient data stored in a memory of the mobile surgical tracking device. According to an embodiment, the display device comprises an augmented reality display device.

The tracking data can be transferred to a display device that guides the surgical intervention over a wireless link as for example Bluetooth LE. The battery operation should allow for tracking during a surgery normally for at least some minutes up to several hours. The battery can either be replaceable or rechargeable. For some applications it could be preferable to have a single use device that could only be used for one single surgery. For other applications, a resterilizable tracking system could be preferable. The highly integrated design of the mobile surgical tracking system according to any of the embodiments allows to produce a mobile surgical tracking device and trackable elements so that they can be used as single use devices. The display device computes and shows the instrument position in relation to the image data or generated data thereof. The display device may be one of a computer including a display or a smartphone or a tablet device. The information could be shown to the surgeon through wearable smart glasses instead of using a display device.

According to a further implementation, an augmented reality display device can be used for tracking the wearable position by the measurement system or an additional tracking system. In particular, the model of the anatomical structure model generated from the images generated by the image device can be combined with the patient's anatomical structure and/or the mobile surgical tracking device. The images or any anatomical structure model generated from the images can be matched directly with the patient, in particular, the anatomical structure of the body part which has to be treated by the surgery.

According to an embodiment, the image can be imported to the display device such as a tablet or a smartphone by taking a photo of C-Arm image with the display device.

According to an embodiment, the mobile surgical tracking device and a trackable device can both comprise integrated fiducial markers or only the trackable device can comprise an integrated fiducial marker, whereby the integrated fiducial marker can be attached to an anatomical structure and the mobile surgical mobile tracking device can be attached to the surgical instrument.

According to an embodiment, a plurality of mobile surgical tracking devices can be attached to a plurality of anatomical structures, whereby each mobile surgical tracking device can be equipped with trackable elements so that each mobile surgical tracking device can act as the tracker and/or a trackable device.

According to an embodiment, the mobile surgical tracking system comprises multiple optical tracking systems integrated to allow measurement in multiple directions, whereby each of the optical tracking systems can comprise a measurement volume, whereby at least one of the optical tracking systems can be separate or at least two of the optical tracking systems can be overlapping.

According to an embodiment, the imaging device comprises a radiographic imaging device, whereby the radiographic imaging device can be equipped with optical markers (LED) so that the position of the radiographic imaging device relative to the mobile surgical tracking device can be measured.

The invention will be explained in more detail in the following with reference to the drawings. There are shown in a schematic representation in:.

In <FIG>, a first embodiment of the mobile surgical tracking system of the invention is shown. The small sized mobile surgical tracking device <NUM> is mounted on an anatomical structure, in particular a bone structure <NUM> such as for example multiple vertebrae. This fixation device <NUM> can be one of a single or multiple bone screws, a pin fixation, clamps or other means for fixing the mobile surgical tracking device <NUM> in a stable position to the desired bone. The mobile surgical tracking system comprises the following elements: an optical tracking system <NUM>, a printed circuit board with processing unit, a wireless communication unit and an attached battery <NUM>, an integrated fiducial marker <NUM>, in particular a radio opaque fiducial marker, for registration of the radiographic images. Through a radiographic projection from an X-Ray source <NUM> to the detector panel <NUM> a radiographic image <NUM> is generated. In a preferred embodiment, such images are acquired after mounting the mobile surgical tracking device <NUM> using a C-Arm intraoperatively. The image is transferred from the image acquisition and storage unit of the C-Arm <NUM> using a defined protocol <NUM> to the mobile computation unit <NUM> that shows the navigation screen to the surgeon. In a preferred embodiment, the mobile computation unit <NUM> and display is integrated into a smartphone or tablet device that already provides wireless communication protocols <NUM>, <NUM> for data exchange. In another embodiment the transfer of the image from the C-Arm scanner to the mobile device could be by taking a photo of the C-Arm screen by means of the integrated camera in the mobile device. In such a setup an image distortion and rectification have to be applied to the image.

For the registration of the radiographic image to the mobile surgical tracking system a coordinate frame <NUM> of the integrated fiducial marker <NUM> can be used. Multiple known applications describe how to calculate the perspective projection from integrated fiducial markers <NUM> in a radiographic image <NUM>. The integrated fiducial markers <NUM> are detectable by a computer algorithm implemented on the display or navigation device. Once the relation from the image to the coordinate frame <NUM> of the mobile surgical tracking device <NUM> is known, an instrument <NUM>, such as a surgical instrument, can be tracked and visualized by a visualization element <NUM> in the image space <NUM>. The instrument <NUM> in this embodiment is equipped with an optical marker <NUM> of at least four LEDs <NUM> and the optical tracking system <NUM> implements a shadow imaging technology as described above to calculate the <NUM> DOF position of the optical marker <NUM> and the instrument <NUM>, here a drill sleeve. In another embodiment not according to the invention, the optical tracking system could be implemented also using a conventional single camera tracking system with lenses to track an optical marker <NUM>. The optical marker <NUM> can be one of the group including an active or passive optical marker. An active optical marker can be configured as a light-emitting marker, e.g., a LED. A passive optical marker comprises a reflecting surface. A passive optical marker can in particular include a sphere capable of receiving a light beam, which can be used for measurement purposes. In another embodiment not according to the invention, a small-scale stereo-camera system could be integrated into the mobile surgical tracking system to track optical markers <NUM>. The advantage of the shadow imaging technology is that it can be implemented in a very small form factor which is in particular less than 5x5x2cm and very lightweight, in particular less than <NUM> grams.

<FIG> shows a possible implementation of a mobile surgical tracking device <NUM> with integrated fiducial markers <NUM>. In this embodiment the integrated fiducial markers <NUM> are formed as an integral part of a printed circuit board <NUM>. The mobile surgical tracking device <NUM> includes a shadow imaging device comprising an image sensor <NUM> and a shadow mask <NUM>. The integrated fiducial markers <NUM> can either be commonly available electronic components <NUM>, conductive tracks <NUM> forming a defined pattern on the circuit board, radio-opaque elements placed on the printed circuit board <NUM>, radio-transparent holes in the printed circuit board <NUM>, or any combination thereof. The integrated fiducial markers <NUM> placed on the printed circuit board form can be detected in the radiographic image <NUM>. Different elements may have different radiographic properties, such as transparent, opaque, semi-transparent. The placement of the integrated fiducial markers <NUM> can be made as integral part of PCB during board production. Alternatively or additionally, the integrated fiducial markers <NUM> can be very accurately placed for example through a SMT (surface mount technology) placement machine.

The position of the integrated fiducial markers coordinate system to the tracking system coordinate system can either be guaranteed by very accurate production, placement of the components or by a factory registration method where the spatial relation (6DOF) is defined. The spatial relation can be stored in the memory of the mobile surgical tracking system. In further embodiments, the integrated fiducial markers <NUM> could be embedded on multiple PCB layers or multiple PCBs to form a three-dimensional arrangement. Such a three-dimensional arrangement of the integrated fiducial markers <NUM> allows for a more accurate registration of the radiographic images to the mobile surgical tracking device <NUM> and is preferred if for example C-Arm images are taken from different positions. In a further embodiment, the mobile surgical tracking device <NUM> can be made very small or even integrated in a single chip and the integrated fiducial markers <NUM> and this chip itself can include some integrated fiducial markers <NUM> or a certain geometric shape for detection in radiographic images. In a further embodiment, the integrated fiducial markers <NUM> could be placed on a flexible PCB where the flexible PCB is mounted in a housing this would also allow for two or preferably a three-dimensional arrangement of the LED by bending of the flexible PCB. In a further configuration, only the measurement system is mounted on a PCB that is placed at a defined position in a radio-transparent housing with integrated fiducial markers <NUM>. Such a configuration is preferred when a large-sized integrated fiducial marker <NUM> is required, for instance of a size of <NUM>-<NUM> and the measurement system and PCB is to be kept very small.

<FIG> shows a mobile surgical tracking device <NUM> according to a second embodiment comprising an integrated fiducial marker <NUM> rigidly attached with a fixation device <NUM> to a first bone structure <NUM> and in addition an optical marker <NUM> also equipped with an integrated fiducial marker <NUM> rigidly attached by an attachment element <NUM> on a second bone structure <NUM>. The setup allows registration of one or multiple radiographic images, such as C-Arm, of the first bone structure <NUM> to the mobile surgical tracking device <NUM> mounted on the first bone and registration of one or multiple radiographic images <NUM> of a second bone structure <NUM> to the trackable optical marker <NUM> mounted on the second bone structure <NUM>. This allows to calculate and display movements of the two-bone structure <NUM>, <NUM> with respect to each other and display the movements to the surgeon. By taking multiple C-Arm images, 3D models of the bone fragments can be established with their spatial locations relative to the reference coordinate systems of the mobile surgical tracking device <NUM> and trackable optical marker <NUM>. Such a setup could be preferably used for fracture reduction in trauma applications. Additionally, the system could measure the position of placed instruments <NUM> and implants in the radiographic images, for example trauma plates <NUM>, intramedullary nails, screws. In addition, one or multiple instruments <NUM> equipped with optical markers <NUM> can be tracked relative to images of the first or second bone generated 3D reconstructions of the two bones. Also, the instrument position can be tracked to implant feature like for example plate hole positions. The optical marker <NUM> may also be included in the handle to set the trauma, this would allow to track the plates position on the anatomical, in particular bone structures during placement. In another embodiment, a plurality of mobile surgical tracking devices <NUM> are mounted on both bones that are also optical markers <NUM>, thereby allowing both bones to be tracked to each other and the instrument <NUM> to be tracked directly to both bones. In another embodiment, the mobile surgical tracking device <NUM> can comprise a plurality of optical tracking systems <NUM> integrated to track multiple measurement volumes in different directions for tracking instruments in multiple locations with respect to the mobile surgical tracking device <NUM>. In a surgical setup it may be necessary to track one instrument on one side of the mobile surgical tracking device, for example a drill sleeve, while the plate handle to insert the plate is located on the opposite side of the mobile surgical tracking device. In on such setup, two tracking systems could be integrated pointing in opposite directions or any other configuration of two or more tracking systems to cover the required measurement volume.

<FIG> shows a mobile surgical tracking system according to a third embodiment in a setup for a dental application wherein the mobile surgical tracking device <NUM> is temporarily attached to jaw and teeth <NUM> using a dental tray <NUM>. The fixation can for example be achieved through molding of the teeth structure with a suited molding material. The dental tray <NUM> must allow to fix the mobile surgical tracking device <NUM> later in the surgical intervention at the same spatial location relative to the jaw and teeth <NUM>. With the mobile surgical tracking device <NUM> including the integrated fiducial marker fixed to the patient a cone beam CT scan <NUM> is carried out and the image volume <NUM> is saved on the scanner <NUM>. Based on the image volume a planning of dental implant positions can be carried out on the single slice images or based on a 3D visualization of the jaw and teeth <NUM>. Preferably, a dedicated dental planning software is used, and the planned values and image volume are transferred to the mobile computation unit <NUM> including the display device. The mobile computation unit can include one of a computer unit with display, a smartphone or a tablet device. The mobile computation unit imports the planning data and image data from the CBCT scan and dental planning software. For the intervention, the dental hand piece <NUM> with the drill <NUM> is equipped with an optical marker <NUM>, the position of the drill to the optical marker is either known a priori, e.g. pre-calibrated, or registered during the intervention. The mobile surgical tracking device <NUM> is attached with the dental tray <NUM> at the same position as during imaging procedure and the position of the image volume <NUM> and a reconstructed 3D model <NUM> is known through the integrated fiducial marker <NUM> in the image volume <NUM>. In an initial step the software identifies the integrated fiducial marker <NUM> in the image volume <NUM> and computes the registration transformation from the image coordinate frame to the tracker coordinate frame. Using this transformation and the position of the hand piece measured through the optical marker, the drill position <NUM> can be displayed relative to the reconstructed 3D model <NUM> and image volume on the display unit. In a preferred embodiment the mobile surgical tracking device <NUM> is operated battery driven and communicates the tracking data to display unit using wireless communication as for example through Bluetooth LE (low energy). In another embodiment such a setup could be used for ENT, interventional radiology and other applications where the mobile surgical tracking device <NUM> is fixed to the head or another part of the body of the patient and a CBCT scan is done. In other embodiments of the invention, a conventional CT scanner could be used. Also, an application with a MRI (magnet resonance imaging) scanner is possible. In this configuration, the integrated fiducial marker <NUM> must be designed to be detectable in MRI images and the mobile surgical tracking device <NUM> has to be either compatible with MRI imaging or detachable from the integrated fiducial marker <NUM> during the imaging procedure.

According to an embodiment, a miniaturized mobile surgical tracking device <NUM> for treatment of an anatomical structure <NUM> comprises an element for optical tracking system <NUM>, an integrated fiducial marker <NUM> for direct registration of a radiographic image <NUM> to the coordinate frame of the mobile surgical tracking device. The mobile surgical tracking device can be fixed to the anatomical structure <NUM> for radiographic imaging and surgical intervention <NUM>. Surgical instruments <NUM> can be tracked by the optical tracking system <NUM> and their position displayed for images for guided surgical interventions on a display device.

Claim 1:
A mobile surgical tracking system comprising a mobile surgical tracking device (<NUM>, <NUM>) mountable on an anatomical structure of a patient, an imaging device (<NUM>) and a display device, the mobile surgical tracking device (<NUM>, <NUM>) comprising an integrated fiducial marker (<NUM>) and an integrated optical tracking system (<NUM>) comprising a shadow imaging device comprising an image sensor (<NUM>) and a shadow mask (<NUM>), wherein the imaging device (<NUM>) is configured to generate an image (<NUM>) of the patient's anatomical structure and the integrated fiducial marker (<NUM>), whereby the mobile surgical tracking system comprises a mobile tracking system coordinate frame (<NUM>), wherein the integrated fiducial marker (<NUM>) has a position which has a known relation to the mobile tracking system coordinate frame (<NUM>) for a direct registration of the image (<NUM>) to the coordinate system of the mobile surgical tracking device (<NUM>, <NUM>), wherein the system further comprises an instrument (<NUM>) comprising an optical marker of at least <NUM> LEDs, wherein the instrument is trackable by the shadow imaging device and can be visualized by a visualization element (<NUM>) in an image space (<NUM>), once the relation from the image (<NUM>) to the coordinate frame (<NUM>) of the mobile surgical tracking system is known, wherein the image is integrated into the mobile surgical tracking system coordinate frame, whereby the position of the mobile surgical tracking device with respect to the anatomical structure both virtually, thus in an anatomical structure model generated by the imaging device, and physically, thus in the patient's anatomical structure, is simultaneously defined.