SYSTEM FOR MEASURING THE TRUE DIMENSIONS AND ORIENTATION OF OBJECTS IN A TWO DIMENSIONAL IMAGE
The invention is a system for measuring the true dimensions and orientation of objects in a two dimensional image. The system is comprised of a ruler comprising at least one set of features each comprised of two or more markers that are identifiable in the image and having a known spatial relationship between them and a software package comprising programs that allow extension of the ruler and other objects in the two dimensional image beyond their physical dimensions or shape. The system can be used together with radiographic imagery means, processing means, and display means to take x-ray images and to measure the true dimensions and orientation of objects and to aid in the identification and location of a surgery tool vs. anatomy in those x-ray images. The invention provides a method of drawing and displaying on a two dimensional x-ray image measurements of objects visible in said image, graphical information, or templates of surgical devices.
This Application is a continuation of U.S. Utility patent application Ser. No. 14/106,771, titled “A System For Measuring The True Dimensions And Orientation Of Objects In A Two Dimensional Image”, filed by the inventors of the present Application on Dec. 15, 2013;
which, in turn, is a continuation of U.S. patent application Ser. No. 12/665,731, titled “System For Measuring The True Dimensions And Orientation Of Objects In A Two Dimensional Image”, filed by the inventors of the present Application on Jun. 1, 2010;
which, in turn, is a national phase entry of PCT Application No. PCT/IL08/00841 titled “A System For Measuring The True Dimensions And Orientation Of Objects In A Two Dimensional Image”, filed by the inventors of the present Application on Jun. 19, 2008.
Based on the above listed priority chain, priority is hereby claimed from all of the above listed Applications, all of which are hereby incorporated by reference into the present Application.
FIELD OF THE INVENTIONThe invention is related to the field of medical radiography. More specifically the invention relates to devices and methods of accurately measuring the dimensions in a specific orientation of objects observable in two-dimensional images, e.g. radiographic images.
A portion of the disclosure of this patent document contains material which is subject to copyright protection. The copyright owner has no objection to the facsimile reproduction by anyone of the patent document or the patent disclosure, as it appears in the Patent and Trademark Office patent file or records, but otherwise reserves all copyright whatsoever.
BACKGROUND OF THE INVENTIONThe technical problem that is addressed by the present invention has been known since the earliest application of x-rays as an aid in medical diagnostics and the performance of medical procedures. The problem is easily understood with reference to
As mentioned above, this problem was recognized very early in the development of the field of medical radiography. In January 1897, only a little over one year after the ground breaking paper by Roentgen that gave the first scientific explanation of the phenomenon that he called x-rays, a patent application that eventually became U.S. Pat. No. 581,540 was filed in the U.S. Patent Office. The invention comprises a grid of radiopaque wires placed between the object being x-rayed (inside a human body) and the planar surface on which the images are recorded and an “angle plate” which is applied to the body to insure parallelism of the x-rays. The object of the invention being to provide “an improved radiographic apparatus whereby the exact location of an invisible object, not permeable or difficulty permeable by the so-called “Roentgen” or “X” rays, may be accurately ascertained and measurements made by which operations necessary for the removal of such objects are controlled and guided”.
In the intervening years since the publication of U.S. Pat. No. 581,540 and the present, numerous patents have been granted and scientific articles published that provide different solutions to different aspects of the same problem. A brief review of some of these solutions can be found by reviewing the following patents:
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- U.S. Pat. No. 1,396,920 describes an indicator comprising radiopaque marks on a plane parallel to the object to be observed and the x-ray sensitive plate. In this way the indicator appears on the x-ray image and the known distances between the marks can be used to determine the correct scale of the distances that appear in the image and thus the size of the object can be accurately determined.
- U.S. Pat. No. 5,970,119 describes a scaling device comprising an easily observable radiopaque member having radiolucent gaps spaced a known distance apart. The embodiments of the scaling device can be use externally or incorporated into a catheter to allow the device to be manipulated into a position in the vicinity of the anatomical structure to be measured as close as possible to the plane of the structure while being oriented as closely as possible to perpendicular to the x-ray beam.
- U.S. Pat. No. 5,052,035 describes a device comprised of a transparent substrate on which is created a grid of parallel radiopaque lines. The film is placed over the area of the body of the patient of interest and an x-ray image is taken. The grid appears in the x-ray image as an overlay on the anatomical structure. The transparent substrate is adapted so that, by use of a marking instrument, marks can be applied to the body. In this way features that appear in the x-ray image can be accurately located on/in the body of the patient.
- U.S. Pat. No. 3,706,883 describes an elongated probe (catheter) that includes at least one radiopaque segment of known length. The probe is introduced into the body and is brought into proximity to the object to be measured. The radiopaque portion of the probe appears on the x-ray image next to the object whose size is unknown. The ratio of the apparent length of the radiopaque portion of the probe to its known length provides the scale factor necessary to determine the length of the other objects that appear in the x-ray image.
- U.S. Pat. No. 4,005,527 describes a depth gauge comprised of alternating sections of radiopaque and radiolucent material of known length. The depth gauge can be inserted into a hole or cavity to be observed using x-ray methods. The gauge will be seen on the x-ray image and can be used to provide a scale to measure the depth of the hole and dimensions of other features seen in the image. In one embodiment, the depth gauge is the shaft of a drill and serves to enable the surgeon to know the depth of the hole that he has drilled into a bone.
This brief survey of the prior art gives an indication of a fact of life that is well known to surgeons, i.e. that the solution to the problems first recognized in the earliest days of medical radiography has not yet been found. Each of the solutions proposed to date, while it might represent an improvement over prior proposals or may give adequate results for certain procedures, has not provided an overall solution.
A surgeon using any of the previous measurement techniques, whether involving using a regular ruler to measure objects directly (not through x-ray) or measuring objects on the image itself will experience the same limitations. Measuring objects directly is often problematic since access is limited to the objects measured and measuring on the image itself, besides requiring a calibration, can only provide measurements on the projection of the object and in the projection plane.
While x-ray images are two dimensional and prior art techniques allow reasonably accurate two dimensional measurements in the plane of the image itself, the surgeon would ideally like to have the ability to make three dimensional measurements and measure the objects at any direction he desires. In particular orthopedic surgeons would like to be able to accurately measure objects not in the image plane and to measure objects, without penetrating them, while retaining the measurement accuracy.
It is therefore a purpose of the present invention to provide a ruler which improves upon and overcomes the limitations of prior art rulers used for measuring distances in radiographic images.
It is another purpose of the present invention to provide a ruler which allows a surgeon to make three dimensional measurements and measure objects in a radiographic image at any direction he desires.
It is another purpose of the present invention to provide a ruler which allows a surgeon to accurately measure objects not in the image plane, while retaining the measurement accuracy.
It is another purpose of the present invention to provide a ruler which allows a surgeon to accurately measure objects without penetrating them, while retaining the measurement accuracy.
Further purposes and advantages of this invention will appear as the description proceeds.
SUMMARY OF THE INVENTIONIn a first aspect, the invention is a system for measuring the true dimensions and orientation of objects in a two dimensional image. The system is comprised of a ruler comprising at least one set of features each comprised of two or more markers that are identifiable in the image and having a known spatial relationship between them and a software package comprising programs that allow extension of the ruler and other objects in the two dimensional image beyond their physical dimensions or shape.
In embodiments of the invention the markers in each set are arranged in one or more rows having a known spatial relationship between them. If there is more than one of the sets, at least some of the sets are aligned in a direction non-parallel to the measurement direction or to each other.
Embodiments of the system are adapted to measuring x-ray images. Embodiments of the system are adapted to enable it to be used for measuring the true dimensions and orientation of objects and for aiding in the identification and location of a surgery tool vs. anatomy in a radiographic image.
In a second aspect, the invention is an apparatus adapted to enable it to take x-ray images and to measure the true dimensions and orientation of objects and to aid in the identification and location of a surgery tool vs. anatomy in those x-ray images. The apparatus comprises:
a. a system comprising one or more rulers and a software package according to the first aspect of the invention;
b. radiographic imagery means;
c. processing means; and
d. display means
characterized in that the software package comprises programs that allow the processing means to recognize the features of the ruler on the radiographic image and to use the features to create a virtual extension of the at least one ruler and to draw the virtual extension of the at least one ruler on the radiographic image as an overlay, thereby enabling the user who is pointing the at least one ruler and looking at the radiographic image to accurately measure objects that appear in the radiographic image.
In embodiments of the invention the software package comprises a program that allows the zero scale on the virtual extension of the ruler to be dragged and moved around at will. In other embodiments, if a three dimensional ruler is used to determine a measuring plane and a feature known to be on the measuring plane, then the software package comprises a program that allows the processing means to measure the angle between two lines projected on the measuring plane.
In embodiments of the invention the software package comprises a program that allows the processing and display means to provide real time visualization by using either a one or a three dimensional ruler in order to draw how at least how a part of the result of the operation will look given the positioning of the ruler or some other surgical tool visible in the image.
In embodiments of the invention the software package comprises a program that allows the processing and display means to find markers in the image and place templates of implants or other objects on the image.
In embodiments of the invention the software package comprises a program that allows the processing means to automatically determine the location of a surgical tool in the image and to apply an image enhancement algorithm that automatically concentrates on the specific area of interest to the surgeon.
In embodiments of the invention the software package comprises a program that allows the processing and display means to synchronize AP and axial images.
In a third aspect the invention is a ruler for use in the system of the first and second aspects. The ruler has at least one set of features each comprised of two or more markers that are identifiable in the image having a known spatial relationship between them. In embodiments of the invention the markers in each set are arranged in one or more rows having a known spatial relationship between them and, if there is more than one of the sets, at least some of the sets are aligned in a direction non-parallel to the measurement direction or to each other.
The ruler can be a hand-held ruler used to “point and “measure”. The ruler may comprise means for slideably attaching it to a tool. The ruler may be an integral part of a tool, made by making at least part of the tool from a translucent material and embedding opaque markers into it. The ruler may be comprised of small radiopaque markers, with a known spatial relationship between them, embedded in a radiolucent envelope.
In a fourth aspect the invention is a method of drawing and displaying on a two dimensional x-ray image measurements of objects visible in said image, graphical information, or templates of surgical devices. The method comprises the steps of:
- a. identifying the location and orientation of at least one known object; and
- b. drawing and displaying the measurements, graphical information, or templates on the x-ray image on the basis of the location and the orientation of the known object.
The method is characterized in that the measurements, graphical information, or templates are not a part of the known object. The known object can be a ruler according to the third aspect of the invention, a surgical tool, or an anatomical feature.
All the above and other characteristics and advantages of the invention will be further understood through the following illustrative and non-limitative description of preferred embodiments thereof, with reference to the appended drawings.
The invention is a system that can be used for measuring the true dimensions in a specific orientation of objects in two and three dimensional images. In order to illustrate the invention and in preferred embodiments thereof, the images considered herein are radiographic images, in particular x-ray images, wherein by x-ray images are meant radiographic images, fluoroscopic images, digital fluoroscopy images, or images taken using any other type that uses x-rays to obtain them. However it is to be understood that the device and methods of the invention can be used in any imaging situation. In the case of x-ray radiography, the device and system of the invention are used to measure the true dimensions and orientation of objects that appear in the image and to aid the surgeon in the identification and location of surgery tools vs. anatomy in the radiographic image.
The system of the invention comprises two components: a calibration device 70, which is called a “ruler” herein and a computer software package 216. Radiolucent ruler 70 comprises radiopaque markers 76. It is placed in the space between source 202 and detector 204 such that at least some of the markers 76 will be visible in the images gathered by imaging system 200. Computer software package 216 is loaded into computer 206 in order to provide the computer with advanced capabilities for processing and displaying the images as a graphical overlay, displayed over the x-ray image on the display 206, thereby providing the user with information not previously available. Illustrative embodiments of the ruler and of the software as well as descriptions of the new types of visual information that can be provided to the user will be described herein below.
Herein the word “markers” is used to mean features that are visible in the image, by virtue of their color, luminance or intensity. In the case of x-ray images, markers have a different radio-opacity than their immediate surrounding, or comprise different radio-opacity levels. Markers are regarded as a singular point in space, e.g. the center of a ball or a corner of a cubical shape, which is well defined and can be noticed in the image. Herein the words “marker” and “feature” are used interchangeably.
In one embodiment, the ruler comprises two or more features having a known spatial relationship between them that are visible and recognizable in a radiographic image. For the purpose of the measurement the two or more features are aligned parallel to the measurement direction. The associated software allows, amongst many other modes of operation to be described herein, the automatic recognition of features of the ruler in the radiographic image and the use of these features to create a virtual extension of the ruler, i.e. to extend the ruler beyond its physical dimensions, and drawing the virtual extension on the image as an overlay. The invention enables the surgeon who is pointing the ruler and looking at the image to accurately measure dimensions of objects that appear in the radiographic image. The invention is especially useful and convenient for use with x-ray imaging in which frequently it is desired to measure the internal organs, bones, etc. of a body. However, as mentioned above, in principal the invention can be used with any technique of producing two dimensional images, e.g. regular photography.
All prior art methods known to the inventors use the physical scales on a ruler to measure the dimensions of or distances between objects of interest either directly or to take a picture and make the measurements directly on that picture in two dimensions. These methods are generally not accurate for the reasons mentioned hereinabove and do not enable easily measuring objects in different three dimensional orientations. The approach taken to the problem of making accurate measurements by the inventors is fundamentally different than that of the prior art since it makes use of control of both the tool, i.e. the ruler, and the display, i.e. the visual image including graphic overlay thereof. The measurement method is dependent on the combination of the ruler, which cannot be used to achieve the desired result when used alone and the software, which cannot, be used to make the measurements without the ruler. Only through the combination of ruler and software, as described hereinbelow can the desired result be obtained.
The invention, in its various embodiments, can be used to assist the operator in any procedure in which it is desirable or necessary to measure distances or dimensions of objects in radiographic images. Such procedures range from common chest x-rays, that are analyzed “off-line”, to orthopedic and other surgical procedures that can only be carried out “on-line”, i.e. with the aid of inter-surgery radiographic imagery using, for example, a mobile C-arm x-ray unit. Typical non-limitative examples of on-line procedures that can be performed with the aid of the invention are:
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- Spinal fusion/lumbar spine fixation—insertion of pedicle vertebral screws;
- Vertebroplastia—injecting cement to a vertebral body via the pedicles;
- Bone biopsy—inserting a long needle through bone, to reach a tumor or lesion;
- Dynamic hip screw (DHS) placement procedures for per-trochanteric and intertrochanteric hip fractures;
- Three Cannulated Screws placement procedures for sub-capital fractures;
- Proximal Femur Nail (PFN) placement procedures for oblique-reversed and for sub-troch hip fractures; and
- Trochanteric fixation nail (TFN) fixation.
For purposes of illustrating the invention, its use in relation to dynamic hip screw (DHS) placement procedures for hip trauma procedure under fluoroscopy will now be described. It is emphasized that the invention is not limited to use in any particular procedure and is expected to be useful for a wide range of applications. According to statistics made available by the American Association of Orthopaedic Surgeons, about 450,000 procedures for treatment of hip trauma were carried out in 2004. Nearly 90% of the procedures were carried out on persons aged 65 or older who had suffered breaks in the proximal end of the femur as a result of a fall. The surgical procedures for treating the fractures are well known and documented, including descriptions in textbooks, scientific journals, and even complete protocols that can be found on the internet. Generally speaking, depending on the exact nature of the break, the procedure involves attaching one of a number of different styles of commercially available compression hip plates to the femur by means of pins or screws inserted into holes drilled into the bone. A good review of the state of the art can be found in “Intertrochanteric Fractures” by Dr. Kenneth J. Koval and Dr. Robert V. Conto, which is a chapter in the book: Rockwood and Green's Fractures in Adults; Authors: Robert W. Bucholz, M D; James D. Heckman, M D; Publisher: Lippincott Williams & Wilkins; 6th edition, 2005.
A specific protocol for carrying out the surgical procedure can be downloaded from the web site of Smith & Nephew at [http://www.smithnephew.com/Downloads/71180375.pdf]
The most demanding part of the procedure is creating the hole into which the lag screw is inserted. For a successful procedure, the hole must pass through the bone in a path following the central axis of the neck of the femur towards the apex of the femoral head. The surgeon, assisted by a series of x-ray images taken during the course of the proceeding, uses a small diameter guide drill to make an initial guide hole. The first problem is to determine the neck angle to select an appropriate angle plate, which is used to help determine the proper entry point and to aim the guide drill. The surgeon, referring to the x-ray images, estimates the correct angle and entry point and begins to drill with the guide drill. After drilling a short distance into the bone, he stops and takes at least two x-rays at right angles to each other to ascertain that he is indeed drilling in the correct direction and along the center of the neck. In order to do this he must mentally project the image of the drill forward through the anatomical features, a task that is complicated, especially given the required precision and the challenging image quality. In addition, a typical C-arm equipped with an image intensifier tube for generating the images creates a distortion to the image usually causing straight lines to appear curved in the images: It is noted that if the surgeon has only to extend the line from the drill theoretically he is not influenced by the scale and a line in three dimensional world will still appear to be a line in the two dimensional projection image; however this theoretical extension is not an easy task, especially when precision is so important. If the drill path appears to be correct, then the surgeon drills a bit further before stopping to check again by repeated x ray imaging. If, at any stage, the path appears to be incorrect, then the surgeon must withdraw the guide drill and begin drilling again using a different angle and/or entry point. Another difficulty is ascertaining exactly where to stop drilling. It is essential that the lag screw be attached to as much of the bone as possible; however sufficient bone must remain at the apex of the head to prevent the lag screw from breaking through into the hip joint when the screw is inserted in the hole. This issue involves not only measurement of drilling orientation but also of drilling depth.
A typical procedure of this type carried out by an experienced surgeon takes a considerable amount of time, most of which is consumed by trial and error attempts to obtain the proper alignment. Additionally between 100-150 x-ray images are typically required, which, despite all precautions, represents a serious health hazard for both the patient and, to a greater extent, for the operating room staff that can be present for several similar operations each day.
The reason that so much time and care is taken to insure proper alignment of the guide hole is that failure of fixation of intertrochanteric fractures that have been treated with a fixed-angle sliding hip-screw device is frequently related to incorrect position of the lag screw in the femoral head. To insure success of the procedure and prevent mechanical failure, i.e. bone cut-out, an accuracy of ±2-3 mm of screw location is crucial. A simple measurement called the tip-apex distance (TAD) is used to describe the position of the screw. This measurement is illustrated in
TAD=(Xap×Dtrue/Dap)+(Xlat×Dtrue/Dlat)
The results of many studies show that the failure rate approaches zero if the TAD is less than 25 mm and the chances of failure increase rapidly as the TAD increases above 25 mm [M R Baumgaertner, S L Curtin, D M Lindskog and J M Keggi, “The value of the tip-apex distance in predicting failure of fixation of peritrochanteric fractures of the hip”, The Journal of Bone and Joint Surgery, Vol 77, Issue 7, 1058-1064, 1995]. Using present techniques, the DHS can only be determined after the procedure has been completed. Using the present invention the surgeon will be able to estimate the DHS at the preplanning stage before beginning to drill the guide hole and will be able to know the expected value at any stage of the procedure.
The exact distance between balls 76 is known so that when their shadows are detected on the x-ray image the dedicated software of the invention can identify them and measure the apparent distance between them directly from the image and use this measurement together with the known actual distance to calculate the scale that is used to create the overlays that allow the surgeon to determine the exact position of the guide relative to the anatomical structure, dimensions, and other related information displayed on a screen in “real time”. As a minimum, only two balls 76 in one row are needed to be visible in the image in order to create an acceptable approximation of the C-arm magnification factor and the sizes of organs and tools for most common cases. However, since increased accuracy is obtainable by using the averages of several apparent measurements and also since some balls may be hard to see in the image it is preferred to use a minimum of three or four balls in each row to get a more accurate mathematical extension of the ruler. Also, if the angle between the ruler and the image plane is large, the scale change along the ruler extension, in the image, is not negligible. It is therefore preferred to use more than one measurement, at different heights, so that an approximation of this effect can be calculated.
Another way of explaining the problem of crating an accurate scale for the images and the solution to the problem is the following: It is known that the magnification increases linearly with the distance from the x-ray source. Therefore, if there are only two markers, the distance between them can be measured, however, it is impossible to determine if this distance is accurate because the ruler may not lie in a plane parallel to the image. Therefore, the measured distance between markers can not be counted on to provide an accurate scale for creating virtual extensions, overlays and other advanced features provided by the present invention. To overcome this problem a ruler with several markers, having a known distance between them, is used. If the ruler is parallel to the image plane, then the scale is correct and a true 2D calibration is obtained. If, however, the ruler is not parallel to the image plane, the distance between markers, i.e. the scale, will grow smaller to one direction and larger in the other direction, changing with the distance from the x-ray source. In this case, if there are three markers or more, not only the distance between markers but also the rate of change of the distance can be measured and therefore an accurate scale in both directions can be calculated.
Many different arrangements of markers are described herein with regard to specific illustrative examples of the ruler. In principal the minimal requirement of the invention for the number and arrangement of markers is one of the following:
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- Two markers aligned in the direction of the measurement—This will enable determining a scale with not very good accuracy because of the other degree of freedom described herein above.
- Three markers aligned in the direction of measurement—This will enable higher accuracy.
- A set of at least three markers, not on the same line, is sufficient in order to create an accurate three dimensional orientation and thereby enable measurement of an object in every orientation.
- In all cases, the markers do not have to be equally spaced but must be in a known spatial arrangement.
- In the figures herein several rows of equally spaced markers have been included so that they will not occlude each other and therefore allow a better chance of detecting them. There is, however, no minimal requirement of the number of rows of markers that must be used.
In another embodiment, the triangular sleeve with handle that is used by orthopedic surgeons to aid them in maintaining the alignment of the drill in a DHS placement procedure, as known to persons skilled in the art, can be modified by embedding a three dimensional ruler of the invention inside it, in which case, the modified sleeve itself can be used to fulfill the functions of the ruler of the invention that are described herein. The sleeve is made of radiolucent material and comprises a set of metal balls, arranged in a known spatial arrangement, such that the 3D orientation of the ruler may be calculated using the balls that appear in the image.
In accordance with the discussion herein above, preferred embodiments of three dimensional rulers can be constructed comprising two sets of non-parallel rows of markers in order to provide a device for which the markers will be identified even when the ruler is partially occluded by other objects, e.g. bones or tools in the image. Using such a ruler, a three dimensional grid can be projected onto the image.
As discussed hereinabove, embodiments of the ruler of the invention comprise an elongated radiolucent body in which rows of radiopaque markers of known size and distance apart are symmetrically embedded. In its different embodiments, the ruler of the invention can be: a hand-held ruler used to “point: and “measure”; the ruler can comprise means for slideably attaching it to a surgical tool, e.g. handle 90 shown in
Generally, when the ruler is attached to a surgical tool as will be demonstrated by example hereinbelow, during a medical procedure the ruler stays in a fixed position, e.g. at a location on the surface of the body or an organ within the body of a patient, while the tool is advanced into or withdrawn from the body or organ during the course of a diagnostic or surgical procedure.
In some preferred embodiments the ruler is made of bio-compatible USP class 6 materials and is reusable after sterilization using, for example, ETO. In a preferred embodiment, the entire ruler, except for the metal balls, is made of plastic. Under x-ray the ruler is seen as semi transparent and the metal balls are seen “floating” around the guide/drill. Based on these fundamentals and the examples of the embodiments described herein, skilled persons should have no trouble designing a ruler suitable for use with any diagnostic or surgical tool.
Other display features are possible, e.g. color coding to easily distinguish between forward and rearward distances, the addition of transverse scales at locations selected by the operator to enable measurement of the distance from the center of the drill to the sides of the object for example to confirm that the hole is being drilled exactly through the center of the object, and the addition of color coded markings to indicate when the drill is approaching and/or has arrived at the location that drilling should cease.
The system of the invention is used with a C-arm X-ray unit or some other imaging system. It comprises a ruler, and software that enables display of the virtual extension and allows display of the overlays and other features described herein, e.g. the software may include computer vision and recognition algorithms that are used to identify implants, surgical tools and anatomical features and to draw their counterparts or extensions during the operation as an overlay on the x-ray image (see
Skilled persons will recognize that the system can be given the ability to display the images in many different formats to assist the surgeon, e.g. different colors can be used to differentiate how far the drill has penetrated into the bone from the remaining distance. In addition, other types of information, can be provided by audible signal, e.g. signifying the remaining distance or when to stop drilling.
In addition, for imaging systems equipped with an image intensifier, some embodiments provide an anti-distortion system for extra accuracy. The anti-distortion system is a conventional one, as known to persons skilled in the art, comprises a grid placed on the image intensifier (the receiving end of the C-arm) and software that uses the image of the grid to correct the image obtained from the C-arm. Anti-distortion systems suitable for use with the present invention are described in: [Gronenschild E., “Correction for geometric image distortion in the x-ray imaging chain: local technique versus global technique” Med Phys. 1999, December; 26(12):2602-16]. In cases in which an anti-distortion system is used, the detection of the ruler markers using the software of the present invention has to be done on the image after the anti-distortion process.
The next stage 502 is marker identification in the image. The marker, identification can be done either manually, where the user points at the location of the markers using a pointing device, such as a computer mouse; can be done in a semi-automatic manner, where some user input is required and some of the marker identification is done automatically; or can be done in a fully automatic manner, where an image processing algorithm, provided in the software of the system, is used to detect the markers in the image.
In the next stage 503, the software of the system calculates the scale, using the markers in the image identified in stage 502. If a one dimensional ruler has been used, then the markers are co-linear and the only scale that can be deduced is in the direction of the markers. Since the magnification of an object depends on its distance from the x-ray source, if only two markers are used, the exact position and orientation of the ruler cannot be determined, since a rotation of the ruler may have the same effect, as a change of distance from the x-ray source, on the distance between the markers on the image (see
When using a three dimensional ruler objects can be measured at any orientation. The minimal requirement in the three dimensional case is at least 3 markers that are not co-linear.
In the next step 504 the system draws an overlay over the x-ray image. The overlay may include any type of graphical or other information, drawn or printed over the image. Amongst other things, it may include a virtual extension of a drill, an implant image, taken from a pre-stored library of implants, or a virtual drawing of a measurement ruler, aligned with the device. The overlay can make use of the location and orientation of the device in the image. Preferred embodiments may include a GUI that enables the user to easily select and customize the overlay shown over the images.
The use of the invention and its advantages will now be demonstrated with reference a dynamic hip screw (DHS) placement procedure. The entire procedure is carried out in the operating room with the aid of a C-arm x-ray system. After completing the fracture reduction the surgeon begins the pre-operative planning. This stage is carried out before sterilization and cutting the skin to expose the bone. The common practice is to take one image from approximately an anterior/posterior (AP) angle, and do the entire operation planning on a single image while ignoring the three dimensional aspects of the bone. Since embodiments of the invention can be used to identify the surgeon's tools and draw their virtual extension, e.g. the track that a drill will follow, such embodiments can be used during the planning stage. The surgeon can attach a ruler, e.g. ruler 70 (
After the screw has been installed in the bone, the virtual ruler allows the surgeon to accurately measure the tip-apex distance and verify that the surgery has been performed properly.
As is apparent from the description hereinabove, embodiments of the invention are very versatile when applied to orthopedic surgery and the software package may have the capability of allowing the operator to choose from many different operating modes, depending on the requirements or stage of the procedure. A list of some prominent modes of operation, some of which are shown schematically in
1. Virtual extension of a tool or object in an image—This mode of operation can be carried out by the system of the invention using an image recognition program included in the software package without the use of the ruler or any other sensors.
2. Virtual extension of the ruler—The pointing aspect of the ruler of the invention is essentially different from image calibration or normal rulers. The system extends the ruler so that the operator only needs to look at the image, which also shows the ruler, and to point the ruler in the direction he wants to measure in order to get the measurement. The zero scale on the ruler of the virtual extension can be dragged and moved around on the image at will, thereby making it easy for the operator to make any measurement that he feels is necessary. Note that in prior art calibration techniques the points the operator wishes to measure must be marked on the image and the calibration device moved to measure between the points.
The pointing aspect is especially important in measuring objects in live video since in this case the operator can't take the time to mark the points of interest. An example of such a measurement is to measure the size of the heart under x-ray while injecting a contrast liquid to the blood.
3. Using one or three-dimensional rulers to project accurate grids on the image.
4. Projecting approximate grids on the image. For example, working with a one dimensional ruler the software simply assumes that the other axes have a similar scale.
5. Real time visualization—This has two aspects: Use either a one or a three dimensional ruler in order to draw how the result of the operation (or part of it) will look given the positioning of the ruler or some other surgical tool. For example, if it is decided to drill in a particular direction, the system of the invention can show how the DHS will be positioned. The other aspect, based on mode 1, is to simply use an approximate dimensional scale based on the known or approximate dimensions of the objects seen in the image to create the grids. This may be inaccurate and spatially wrong, but can sometimes be good enough. For example, it is enough to see a guide drill in the image to know the approximate scale of the image and draw the DHS screw or the entire DHS implant around it.
Real time visualization takes place after the planning stage, during the actual procedure itself.
6. Pre-operative planning—
7. Image enhancement—The processing means of the system automatically determines the location of the guide in the image, therefore an image enhancement algorithm can be applied that automatically concentrates on the specific area of interest to the surgeon.
8. Synchronizing AP/axial images—This is one of the most demanding tasks facing surgeons performing surgical procedures under guidance of a c-arm system. Consider a dynamic hip screw (DHS) placement procedure and suppose that the surgeon, using the system of the invention, first takes an image I from an axial angle, with a ruler on a guide. Then, without moving the guide, he takes another image J from AP angle. If afterwards he drills a bit more and then takes a third image K, also from an AP angle, then the system can calculate how deep the drill got in image I. This is only possible since the ruler is visible on all the images I, J, and K and is done by measuring the true distance of drilling between J and K, and virtually extending the drill by that distance in image I.
This is a very important feature that can save the surgeon the difficulty of going back to the axial angle and taking another image. This means less radiation and less operating time, and instant feedback.
It is to be noted that in certain applications the known shape and dimensions of surgical tools or even anatomical features that are visible in the x-ray image can be used in place of a ruler. In these cases the methods described above can be used to produce the same visual effects described hereinabove; e.g. virtual extension of the tool or placement of a template on a bone.
Although embodiments of the invention have been described by way of illustration, it will be understood that the invention may be carried out with many variations, modifications, and adaptations, without exceeding the scope of the claims.
Claims
1. A system for imaging based surgical support in orthopedic implant procedures, said system comprising:
- an invasive surgical tool including a set of features identifiable in a two dimensional (2D) medical image and having known spatial relationships between them;
- receiving circuitry adapted to receive a given 2D medical image of the surgical tool in contact with, or within, an organ of a subject of a given orthopedic implant procedure;
- an image processor adapted to derive, from the appearances of said features in the 2D medical image, a spatial relationship between said invasive surgical tool and the organ and determine, based on the derived spatial relationship, an expected collocation of an orthopedic implant in relation to the organ; and
- rendering circuitry adapted to render the expected collocation upon an associated display.
2. The system according to claim 1, wherein the 2D medical image is an x-ray.
3. The system according to claim 1, wherein:
- said receiving circuitry is further adapted to receive a series of 2D medical images of the surgical tool in contact with, or within, the organ of the subject of the given orthopedic implant procedure;
- said image processor is further adapted to derive from each given image of the series, from the appearances of said features in the given image, a given spatial relationship between said invasive surgical tool and the organ and determine for each given image of the series, based on the derived given spatial relationship, a given expected collocation of the orthopedic implant in relation to the organ; and
- said rendering circuitry is further adapted to render the given expected collocations in sequence in real time.
4. The system according to claim 1, wherein the image processing circuitry is further adapted to identify a contour of the organ in the given 2D medical image.
5. The system according to claim 1, wherein said image processor is further adapted to derive, from the appearances of said features in the 2D medical image, measurements of dimensions within the image and render the measurements on the image on the associated display.
6. A system for imaging based surgical support in orthopedic implant procedures, said system comprising:
- a two dimensional (2D) medical imaging device adapted to capture an image of a subject of a given orthopedic implant procedure, during the implant procedure;
- an image processor adapted:
- (i) identify, in real time, features of an invasive surgical tool in contact with, or within, an organ of a subject of the implant procedure;
- (ii) derive, from spatial relationships between the identified features, a spatial relationship between said invasive surgical tool and the organ; and
- (iii) determine, in real time, based on the derived spatial relationships, an expected collocation of an orthopedic implant in relation to the organ; and
- rendering circuitry adapted to render, in real time, the expected collocation upon an associated display.
7. The system according to claim 6, wherein the 2D medical imaging device is an x-ray device.
8. The system according to claim 6, wherein:
- said 2D imaging device is further adapted to capture a series of 2D medical images of the subject, during the implant procedure;
- said image processor is further adapted to derive from each given image of the series, from the appearances of said features in the given image, a given spatial relationship between said invasive surgical tool and the organ and determine for each given image of the series, based on the derived given spatial relationship, a given expected collocation of the orthopedic implant in relation to the organ; and
- said rendering circuitry is further adapted to render the given expected collocations in sequence in real time.
9. The system according to claim 6, wherein the image processing circuitry is further adapted to identify a contour of the organ in the given 2D medical image.
10. A method for imaging based surgical support in orthopedic implant procedures, said method comprising:
- capturing a two dimensional a 2D image of a subject of a given orthopedic implant procedure, during the implant procedure, using a (2D) medical imaging device;
- using an image processor to identify, in real time, features of an invasive surgical tool in contact with, or within, an organ of the subject;
- using the image processor to derive, from spatial relationships between the identified features, a spatial relationship between said invasive surgical tool and the organ;
- using the image processor to determine, in real time, based on the derived spatial relationships, an expected collocation of an orthopedic implant in relation to the organ; and
- rendering upon an associated display the expected collocation, in real time.
11. The method according to claim 10, wherein the medical imaging device is an x-ray device.
12. The method according to claim 10, further comprising:
- capturing a series of 2D medical images of the subject, during the implant procedure;
- using the image processor to derive from each given image of the series, from the appearances of said features in the given image, a given spatial relationship between said invasive surgical tool and the organ;
- determining for each given image of the series, based on the derived given spatial relationship, a given expected collocation of the orthopedic implant in relation to the organ; and
- rendering upon the associated display the given expected collocations in sequence in real time.
13. The method according to claim 10, further comprising using the image processor to identify a contour of the organ in the 2D medical image.
Type: Application
Filed: Sep 5, 2016
Publication Date: May 11, 2017
Inventors: Ram Nathaniel (Tel Aviv), Dan Rappaport (Tel Aviv), Oren Drori (Tel Aviv)
Application Number: 15/256,642