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Claims  |
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What is claimed is:
1. A method for gallstone localization using ultrasound imaging for
enabling a gallstone to be positioned with respect to a focal point of a
shock wave system comprising the steps of
providing an ultrasound image of a gallstone in a patient using an
ultrasound transducer by moving the ultrasound transducer adjacent the
patient,
detecting the position of the ultrasound transducer by imaging the
transducer means by first and second cameras, said cameras means being
calibrated with respect to a reference,
storing images of the transducer picked up by the cameras means and
processing said images,
capturing said ultrasound image of the gallstone, and
calculating the relationship of the gallstone with respect to the
ultrasound transducer using aid ultrasound image of said gallstone and
calculating the distance of the stone from the reference using said
calculated relationship of the gallstone with respect to the transducer
and the detected position of the transducer.
2. A method as in claim 1 wherein
said ultrasound transducer having a hood affixed thereto and wherein the
position of the hood with respect to the ultrasound transducer is
calibrated, said hood having a plurality of reference points thereon which
can are detected by said cameras for determining the position of the hood
with respect to the reference.
3. A method as in claim 2 wherein said reference points on said hood
comprise a plurality of sources which are viewed and imaged by the
cameras.
4. A method as in claim 1 wherein
said first and second cameras comprise a pair of video cameras which are
calibrated by positioning a calibration fixture on a dry table
lithotripter, said fixture including a plurality of reference points which
are imaged first by one video camera and then by the other video camera to
calibrate said cameras with respect to the position of the reference, the
reference being defined by a World Coordinate System (WCS), and
calibrating the focal point of the shock wave system with respect to the
WCS.
5. A method for locating an object in a human patient using ultrasound
imaging to enable the object to be positioned with respect to a focal
point of a shock wave generating system and wherein the focal point of the
shock wave system is calibrated with respect to reference coordinates,
comprising the steps of
scanning the patient with an ultrasound transducer means to provide on an
ultrasound system monitor an ultrasound image of the stone in the patient
imaging the position of the ultrasound transducer by stereo video cameras
means and wherein the camera images the ultrasound transducer means from
two different angles and wherein the camera have been calibrated with
respect to the reference coordinates,
capturing the ultrasound image and marking the location of the stone in the
ultrasound image, and capturing images of the transducer picked up by the
cameras,
processing the images from the cameras to
the location of the ultrasound transducer upon capture of the ultrasound
image of the object, and
calculating the relationship of the stone with respect to the transducer,
calculating the relationship of the stone to the reference coordinates,
and calculating the distance of the stone from the focal point.
6. A method as in claim 5 wherein
said ultrasound transducer having affixed thereto and spaced therefrom a
hood and wherein the position of the hood is calibrated with respect to
the ultrasound transducer, said hood having a plurality of reference
points thereon which can be detected by said cameras for determining the
position of the hood with respect to the reference coordinates.
7. A method as in claim 6 wherein
said cameras comprises a pair of video cameras displaced from one another
and aimed in the general vicinity of the focal point, and
said reference points on said hood comprise a plurality of light sources.
8. A method as in claim 7 wherein
said shock wave system comprises a dry table shock wave lithotripter having
a movable table upon which the patient can lay and be moved with respect
to the focal point, and including the step of moving said table to
position the stone at the focal point.
9. A method as in claim 8 wherein
said cameras are calibrated by positioning a calibration fixture on the
table of the lithotripter, said fixture including a plurality of reference
points which may be imaged first by one video camera and then by the other
video camera to calibrate said cameras with respect to the reference
coordinates, the position of the reference coordinates being defined by a
World Coordinate System (WCS), and
wherein, the focal point is calibrated by imaging with said cameras a focal
point target positioned at the focal point.
10. A method for locating an object within a body using ultrasound imaging
to detect the position of the object in the body, comprising the steps of
scanning the body with an ultrasound transducer to provide an ultrasound
image of the object,
imaging the position of the ultrasound transducer by stereo video cameras
and wherein the cameras image the ultrasound transducer means from two
different angles, the cameras being calibrated with respect to reference
coordinates,
capturing the ultrasound image and marking the location of the object in
the image, and capturing images of the transducer picked up by the
cameras,
processing the images from the cameras to determine the location of the
ultrasound transducer upon capture of the ultrasound image of the object,
and
calculating the relationship of the object with respect to the transducer
using said ultrasound image of said object and calculating the
relationship of the object to the reference coordinates, using said
calculated relationship of the object the respect to the transducer and
the detected position of the transducer.
11. A method as in claim 10 wherein
said camera means comprise a pair of video cameras displaced from one
another and aimed in the general vicinity of the body,
said ultrasound transducer having affixed thereto a hood whose position is
calibrated with respect to the ultrasound transducer, said hood having a
plurality of reference points thereon which can be detected by said
cameras for determining the position of the hood with respect to the
reference coordinates, said reference points on said hood comprising a
plurality of light sources.
12. A method as in claim 11 wherein said body is a human patient and said
object is a correction such as a gallstone or kidney stone in the patient.
13. A system for localization of a stone in a human patient using
ultrasound imaging of the stone for enabling the stone to be positioned
with respect to a focal point of a shock wave system, and wherein the
position of the focal point is calibrated with respect to reference
coordinates, comprising
first and second video cameras positioned with respect to a table of the
system to provide separate images from the general vicinity of the focal
point for providing images of an ultrasound transducer means which can be
used to provide an ultrasound image of the stone, said cameras being
calibrated with respect to the reference coordinates,
ultrasound means including said ultrasound transducer means an circuit
means for providing an ultrasound image of the stone and for enabling that
image to be captured,
system means connected to said video cameras for processing images of the
ultrasound transducer means from said cameras and for calculating the
location and orientation of the ultrasound transducer means with respect
to the reference coordinates, and
said ultrasound transducer means comprising an ultrasound transducer having
a hood affixed thereto and wherein the position of the hood is calibrated
with respect to the ultrasound transducer, said hood having a plurality of
reference points thereon which can be detected and imaged by said cameras
for enabling the position of the hood with respect to the reference
coordinates to be determined by said system means.
14. A system as in claim 13 wherein said hood comprises an arcuate member
spaced from the ultrasound transducer for enabling the ultrasound
transducer to be grasped and operated by the operator while allowing a
surface of the hood to be viewed by the cameras, said reference points
comprising a plurality of sources on said surface which can be viewed and
imaged by the cameras. |
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Claims |
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Description |
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SUMMARY OF THE INVENTION
The present invention relates to localization of objects in space, and more
particularly to the localization of gallstones and the like using
ultrasound imaging.
BACKGROUND OF THE INVENTION
Systems and methods have been developed for fragmentation of kidney stones
and gallstones by utilizing shock waves generated by a suitable source and
reflector system. Several systems and methods of this type have been
devised. The technique is generally referred to as shock wave lithotripsy.
The early approaches have involved immersing the patient in water and
directing the shock wave, generated by an underwater spark discharge, at
the stone. In such method and device, high pressure shock waves are
generated by the underwater spark discharge and are focused by an
ellipsoidal reflector toward the stone in the patient. When the shock
waves hit the stone, pressure and tensile forces are produced that lead to
its fragmentation. Such liberation of energy occurs when there is a change
of acoustic impedance from water or body tissue to the stone. That is,
pressure and tensile forces are created both when the shock wave enters
the stone and when it leaves, and the stone starts to disintegrate into a
fine grit or powder. A more recent development is the dry table system,
such as the Medstone International, Inc. Model 1050ST Lithotripter System,
which does not require the patient to be immersed in water for the shock
wave treatment.
These shock wave systems also require the stones to be appropriately
located and positioned with respect to the shock wave, and the
localization systems commonly used involve X-ray imaging. Basically, the
physician takes several X-rays to determine where the stone is in the
body, such as a stone in the right kidney. Prior to the application of the
shock waves, two oblique X-rays (head and foot) are taken and the
resultant developed films are digitized. Then, through automatic
computations by triangulation the location of the stone is determined with
reference to the focal point of the shock wave equipment.
A description of X-ray location systems in kidney lithotripters can be
found, for example, in U.S. Pat. Nos. 4,669,483 and 4,705,026.
While X-ray localization is used in the case of kidney stones, ultrasound
imaging can be used in the case of gallstones and it is actually easier to
find and locate gallstones through the use of ultrasound rather than
X-rays. In addition, the ultrasound techniques are safer inasmuch as there
does not need to be any exposure to X-rays. However, X-ray localization of
such stones has continued to be used because no suitable non X-ray
accurate localization technique has been developed.
SUMMARY OF THE INVENTION
The present invention is directed to a method and apparatus for enabling an
object to be located with respect to a reference point using ultrasound
imaging or the like. In the shock wave treatment of gallstones in a human,
for example, it is necessary to precisely locate and position the
gallstone with respect to the focal point (F2) of the shock wave
equipment. According to an exemplary embodiment of the present invention,
and wherein a dry table shock wave lithotripter is used, a pair of video
cameras detect the position of an ultrasound transducer which is used for
imaging the stone in the patient. The location of the stone in the
ultrasound image defines the relationship of the stone to the ultrasound
transducer. The location and orientation of the transducer itself are
arbitrary and only depend upon the way the transducer is held by the
operator.
The two cameras, along with suitable computer hardware and software for
performing image analysis and computations, are utilized to determine the
relationship of the ultrasound transducer with respect to a fixed, known
coordinate system called the World Coordinate System (WCS). The WCS is
defined during initial calibration which involves calibrating the cameras
with a calibration fixture related to the WCS, and calibrating the focal
point (F2) of the shock wave system with respect to the WCS. In addition,
and according to an exemplary embodiment of the present invention, a
location device referred to as a "hood" is attached to the ultrasound
transducer, and the location of the ultrasound transducer with respect to
the hood is calibrated. The hood provides a plurality of reference points,
such as from sources on the hood, which are viewed and imaged by the
cameras. The present system essentially utilizes triangulation and image
processing of stereoscope camera images to find the location of the stone.
With the patient positioned on the positioning table of the shock wave
lithotripter, as well as the system components calibrated as described,
the hood of the ultrasound transducer imaged by the cameras, and the
operator determining that a satisfactory ultrasound image exists,
sufficient information is available to readily calculate the distance of
the stone from the focal point (F2) of the shock wave system. The operator
then can be prompted to move the patient by this distance to thereby
position the stone at F2. The shockwave treatment can then begin. During
the shock wave administration, the stone disintegration can be monitored
in real time using ultrasound imaging if desired. This provides a
verification of the localization independent of computer calculations,
lithotripter table movement and operator responses to image digitization
prompts.
The techniques and apparatus of the present invention do not require the
prior X-ray imaging techniques which involve two oblique X-rays for
positioning of stones at F2. In such prior systems, these X-rays image the
stone and projection of an F2 target. In such prior systems, the
associated computer calculates the distance of the stone from F2, and
since the location of the F2 target is set during calibration, this
information is sufficient to determine the patient movement then required
to locate the stone at F2. Confirmation X-rays are required after patient
movement which verify the accuracy of the localization. These confirmation
X-rays provide a verification independent of computer calculations,
lithotripter table movement and operator responses to film digitization
prompts. However, it is necessary to use the bulky and cumbersome X-ray
equipment.
Accordingly, it is a principal object of the present invention to provide
an improved form of localization system for an object.
It is another object of this invention to provide a new form of stone
localization using ultrasound imaging.
Another object of this invention is a method and system for finding the
location of a stone in a patient through triangulation and image
processing of stereoscopic images and an ultrasound image.
BRIEF DESCRIPTION OF DRAWINGS
These and other objects and features of the present invention will become
better understood through a consideration of the following description
taken in conjunction with the drawings in which:
FIG. 1 is a general elevational view of a localization system according to
the present invention;
FIG. 2 is a perspective view further illustrating components of the
localization system;
FIG. 3 is a perspective view of a camera calibration fixture of the present
invention;
FIG. 4 is shock wave focal point location calibration fixture of the
present invention;
FIG. 5 is a perspective view of an ultrasound transducer and hood according
to the present invention;
FIGS. 6a and 6b illustrate typical images from head and foot cameras of the
present invention;
FIG. 7 is a typical ultrasound image;
FIG. 8 is a flow chart illustrating calibration and location steps in the
localization of the gallstone; and
FIG. 9 is an exemplary algorithm for gallstone localizations using camera
images and ultrasound.
DETAILED DESCRIPTION
An exemplary embodiment of the present invention will now be described,
first with reference to FIGS. 1 and 2. While the concepts of the present
invention will be described with reference to location of the stone by
ultrasound images in a dry table shock wave lithotripter system for
gallstone treatment, the concepts are applicable to localization of kidney
stones and other objects.
Turning first to FIG. 1, a conventional dry table shock wave lithotripter
10, such as the Model 1050ST lithotripter system manufactured by Medstone
International, Inc. of Costa Mesa, Calif., is shown with a patient 11
positioned thereon. The shock wave generating system is illustrated
generally at 12 for treating a gallstone 13. The lithotripter 10 has a
table 15 which is movable in the X, Y and Z directions (note the direction
of the WCS coordinates in FIG. 2) so as to enable the stone 13 and the
patient 11 to be positioned with respect to the focal point F2 of the
shock wave generating system 12 (the stone 13 is shown at F2 in FIG. 1).
An ultrasound transducer 18 is used to locate the stone 13, and the
transducer is connected by a cable 19 to an ultrasound imaging system 20.
The ultrasound system 20 and transducer or probe 18 are conventional and
provide an image on a monitor 22 of the ultrasound system 20. A typical
image is shown in FIG. 7 as is well known to those skilled in the art. A
conventional cursor (not shown) allows the stone to be located in the
image by the operator touching the cursor to the appropriate location on
the screen 22 in the usual manner. The image also may be shown if desired
on a computer display monitor 25 positioned over the lithotripter 10 for
convenient viewing by the operator. The monitor can also provide various
prompts to the operator.
The system of FIG. 1 further has an overhead imaging system comprising left
and right video cameras 30 and 31 which are aimed generally where the
patient is to be and in the vicinity of F2 and where the stone is to be
positioned. The purpose of these cameras is to detect the location and
position of the ultrasound transducer 18. A foot pedal 27 is provided to
enable the operator to capture images when desired from the cameras 30 and
31 and from the ultrasound transducer system. A computer system 28 can be
housed in the ultrasound system cabinet. The ultrasound system 20, cameras
30 and 31, display 25, lithotripter table positioning system, shock wave
generating system 12, and foot pedal 27 are all connected to the computer
as diagrammatically indicated in FIG. 1.
Turning now particularly to FIGS. 2 and 5, and according to the concepts of
the present invention, the ultrasound transducer 18 preferably includes
locating means in the form of a hood 40 affixed thereto and which is
imaged by the cameras 30 and 31. The hood 40 includes means by which it
can be readily imaged by the cameras 30 and 31, and in the exemplary
embodiment shown in FIGS. 2 and 5 includes six sources, which may be LED's
or infrared lamps or associated retro-reflectors (corner cube prisms) 42
through 47. These sources may be suitably energized through a cable 49
attached to the ultrasound transducer cable 19. These sources 42 through
47 on the hood 40 allow the cameras 30 and 31 to image the hood as the
operator moves the ultrasound transducer 40 in localizing the stone. The
sources thus provide reference points which can be detected to enable the
location of the hood to be accurately determined. Once the operator is
satisfied with the ultrasound image obtained, that image is captured or
stored and, at the same time, the images of the hood are stored. This
information allows suitable computations to be made by the associated
computer system 28 to define the relationship of the stone to the
ultrasound transducer. Further details of attachment of the hood 40 to the
ultrasound transducer 18 and calibration thereof will be described later
with reference to FIGS. 5, 8 and 9.
Before discussing further details of construction and operation of the
present method and apparatus, it may be helpful to briefly discuss the
sequence of operations involved in locating the stone 13 with respect to
the focal point F2 of the shock wave generating system. The cameras 30 and
31 are calibrated (note 32 in FIG. 8) using a camera calibration fixture
or jig as shown in FIG. 3 and which will be discussed in greater detail
later. This fixture is imaged by each respective camera 30 and 31
individually. Known points on the jig are defined in a suitable reference
system called herein a World Coordinate System (WCS). Using the images of
the fixture, the associated computer 28 determines the parameters of each
camera which defines its location, orientation, origin and focal length.
The WCS is implicitly defined during this camera calibration. The
relationship of the hood to the ultrasound probe is already known (29 in
FIG. 8) in the construction of the same which will be described later.
Additionally, the location of F2 is calibrated as indicated at 33 in FIG.
8. This is accomplished by using an F2 location calibration fixture as
shown in FIG. 4 and which will be described in more detail later. This
fixture is inserted into the ellipse shaped reflector of the shock wave
generating system 12 of FIG. 1 such that the tip of the fixture can be
imaged by the two cameras 30 and 31. The computer then determines the
location of F2 in the WCS as indicated at 34. As will be apparent, these
camera and F2 calibrations will hold as long as the physical relationship
between the camera 30 and 31 and lithotripter table 15 does not change. F2
calibration has to be performed every time the cameras are calibrated
since camera calibration also defines the WCS.
Next, the stone 13 is imaged using the ultrasound transducer 18 in a
conventional manner as indicated at 35. The external points on the hood
fixed to the ultrasound transducer are imaged by the cameras 30 and 31 as
indicated at 36 to detect the location and orientation of the ultrasound
transducer. When the operator determines that the ultrasound image of the
stone is acceptable according to conventional practice by viewing the same
on the CRT 22, the foot switch 27 is depressed and the images from the
cameras 30 and 31 and the ultrasound are captured by the computer 28
simultaneously. The operator then marks the location of the stone in the
ultrasound image on the CRT 22 using a cursor (not shown) in a
conventional manner. The computer scales the distance of the stone from
the transducer tip in screen coordinates to the physical distance using a
preprogrammed scaling factor, and this determines the location of the
stone in relation to the ultrasound transducer based on probe calibration
29 since the initial calibration includes calibration of the ultrasound
transducer with respect to the points on the hood fixed to the ultrasound
transducer.
The two images from the overhead cameras are processed. The images of the
external points of the hood fixed to the ultrasound transducer as viewed
by the two cameras determine the position of the hood in the WCS. Using
conventional coordinate transformation techniques, the mathematical
relationship between the coordinate system defining the transducer and WCS
is established. This transformation is then applied to the location of the
stone determined previously in relation to the hood. The location of the
stone in relation to WCS is therefore determined as indicated at 37.
As will be apparent to those skilled in the art, at this point the
associated computer 28 thus contains the following information:
1. Location of F2 in WCS, from initial calibration; and
2. Location of the stone in WCS. A simple subtraction operation determines
the distance the lithotripter table 15 must be moved to position the stone
13 at F2.
Stated briefly, the location of the stone with reference to F2 is
determined by effectively imaging the location of the ultrasound
transducer (via the points on the hood 40) with the cameras 30 and 31, and
storing the camera images and the ultrasound image when a suitable
ultrasound image exists as determined by the operator. The location of the
transducer with respect to the hood is known from its construction, the
location of each of the two camera 30 and 31 with respect to WCS is known,
and the location of F2 with respect to WCS is known. The image of the
stone provided by the ultrasound transducer system 20 tells the position
of the stone with respect to the transducer, and the camera images of the
hood affixed to the ultrasound transducer tell the location of the
ultrasound transducer with respect to the WCS. The computer then
calculates the location of the stone in the WCS to thereby provide
information to the operator, as through the computer display 25 in FIG. 1,
for adjusting the lithotripter table to thereby position the stone 13 at
F2.
During shock wave administration, the stone disintegration can be monitored
in real time using ultrasound imaging in a conventional manner. This
provides a verification of the localization independent of computer
calculations, lithotripter table movement and operator responses to image
digitization prompts.
Turning now to a more detailed discussion of the calibration fixtures,
camera and ultrasound images, and a flow chart of the present method and
apparatus, the camera calibration fixture is illustrated in FIG. 3. This
fixture 56 includes a base 57 with a lip 58. A resilient pad 59 may be
provided on the underside of the base 57. The base 57 is placed on the top
of the lithotripter table 15 (FIGS. 1 and 2) near the shock wave operating
system, and the lip 58 can extend downwardly along the side edge of the
table 15 to facilitate placement and orientation of the fixture on the
table. The fixture includes a raised portion 62 with a cap 63. The cap 63
includes a plurality of sources, such as red LEDs or infrared sources 64
through 71. Two rows of four each of additional sources, only sources 74
through 78 being seen in FIG. 3, are provided on the top of the base 57.
Thus, a total of sixteen sources are provided with two rows of four on
opposite sides of the top of the base 57 and two rows of four disposed on
the cap 63. These sources may include suitable retro-reflectors if
desired. The sources are connected through a cable 80 to the associated
computer system 28 so as to energize these sources during camera
calibration.
The camera calibration fixture is placed on the top of the lithotripter
table 15 near the shock wave generating system 12 as noted earlier. The
sixteen sources provide known points which are imaged by first one of the
cameras 30 or 31 and then by the other. As noted earlier, these points are
defined in the World Coordinate System, and the computer determines the
parameters of each camera using the images of these sources picked up by
the cameras, to thereby define the location, orientation, origin and focal
length of each camera and for defining the WCS as noted earlier. Thus, in
summary, the fixture 56 is placed on the lithotripter table 15 and one
camera 30 or 31 is operated at a time to pick up the images of the sixteen
sources. The sources provide bright points serving as known reference
points, and the images thereof are analyzed and processed in a
conventional manner to provide the camera calibration.
Turning now to the focal point F2 location calibration, an exemplary
fixture 86 is shown in FIG. 4. This fixture is essentially in the form of
an elongated rod 88 with a base 89 and an upper tip 90. The tip includes a
source 91, such as a LED or infrared source and which may include a
retro-reflector, like those used in the camera calibration fixture 56 and
hood 40. The LED is connected through a cable 93 to the computer system 28
which turns on the source 91 during F2 calibration. The base 89 is
configured to fit within the ellipse shaped reflector of the conventional
shock wave generating system 12 so that the source 91 extends upwardly
from the system 12 and above the lithotripter table 15 so that the source
91 is at F2. The length of the fixture is such that source 91 is at F2.
This provides a source 91 which can be imaged by the cameras 30 and 31 to
provide the location of F2 to the associated computer system.
Turning again to the hood 40 and particularly to the perspective view
thereof in FIG. 5, the ultrasound transducer 18 is conventional and
includes an elongated body 96 terminating in the ultrasound probe end 97.
The hood 40 is attached to the body 96 of the transducer 18 by a C-shaped
clamp 98 having a spacer 99 extending therefrom to which the hood 40 is
secured as by screw fasteners 100. It is necessary for the hood 40 to be
rigidly affixed to the ultrasound transducer 18 so that the position of
the transducer as detected via the sources 42-47 of the hood, can be
located and known by the associated computer system 28. The spacer 99 is
provided so that the operator can still grasp the body 96 of the
transducer 18 by hand underneath the hood 40 so as not to cover or
interfere with the camera views of the sources 42-47.
The hood 40 may have any suitable shape, it only being necessary that the
sources 42-47 be visible to the cameras 30 and 31 during movement of the
ultrasound transducer 18 in imaging the stone 13. It is preferred that the
hood have a slightly curved or arcuate configuration as seen in FIGS. 2
and 5 and to have the trapezoidal outline as shown. It is desirable that
the hood be as lightweight and as unobtrusive as possible, consistent with
the objective of providing a plurality of reference points thereon to be
imaged by the cameras 30 and 31.
FIGS. 6a and 6b illustrate typical head camera (31) and foot camera (30)
images of the sources on the hood 40 of FIG. 5. While all six sources or
any suitable number, can be imaged by each camera, it has been found
preferable with the method and system of the present exemplary embodiment
to turn off the two distant sources (which can be done automatically by
the computer system 28) during ultrasound imaging. Thus, in the head
camera image of FIG. 6a from the head camera 31 (FIG. 2), the two distant
sources 43 and 44 on the hood 40 are turned off, and only the sources 42,
45, 46 and 47 are imaged as indicated in FIG. 6a. Similarly, in the foot
camera image of FIG. 6b from foot camera 30, the two distant sources 46-47
are turned off and only the sources 42-45 are imaged as shown in FIG. 6b.
FIG. 7 shows a typical conventional ultrasound image provided on the CRT 22
of the ultrasound system 20 of FIG. 1. The stone 13 is generally indicated
by the reference numeral 13. The ultrasound imaging involved in the
present method and apparatus wherein the stone 13 is imaged with the
ultrasound transducer 18 and processed in the ultrasound system 20, and
the operator's capturing of the image through use of a cursor are all
conventional techniques. However, in conventional practice the ultrasound
transducer itself is not located or, in some systems, it may be disposed
on a robotic arm to provide feedback signals to give an indication of its
location. The present method and apparatus differs significantly in that
locator means (e.g., hood 40) are affixed to the ultrasound transducer to
allow imaging by an associated camera system to thereby precisely locate
the ultrasound transducer without the various errors encountered in a
robotic feedback locator system.
FIG. 9 illustrates an exemplary algorithm for gallstone localization using
camera images and ultrasound. The sequence shown is commenced after
calibrating the cameras 30 and 31, calibrating the ultrasound transducer
or probe 18 using the hood 40, and calibrating the shock wave generating
system focal point F2 using fixture 86 as noted earlier. The respective
calibration data is read as indicated at 107-109 in FIG. 9. These
operations store the calibration data for the cameras, ultrasound
transducer/hood, and focal point F2 so as to enable the subsequent
calculation of the location of the stone 13 with respect to WCS (and F2).
The stone is imaged using the ultrasound transducer 18 according to
conventional practice. When the operator has determined that the
ultrasound image of the stone is acceptable, the foot switch 34 is
depressed to capture the images from the cameras 30 and 31 and the
ultrasound image simultaneously and store the same in the computer.
Suitable prompts can be provided on the computer display 25 to guide the
operator through the various steps as will be apparent to those skilled in
the art. Thus, when the foot switch 34 is depressed as checked in step 111
in FIG. 9, the head camera 31 and foot camera 30 images can be captured as
indicated at 112-113, and the images processed as indicated at 114 and 116
the processing of these images is successful as interrogated at 115 and
117, the images are correlated for correspondence as indicated at 119. The
processing steps 114, 116 merely involve digitizing the respective camera
images through high pass filtering and thresholding to find the clump of
spots in the image (from the sources 42-47) so as to detect the centroid
of that clump to provide image resolution. The correlation of step 119
involves standard image processing, such as of the type described in
"Depth Perception for Robots" by A. C. Kak, School of Electrical
Engineering, Purdue University, West LaFayette, Ind., 47907, Technical
Report TR-EE-83-44 October 1983. See also "A System for Extracting
Three-Dimensional Images From a Stereo Pair of TV Cameras" by Y.
Yakimovsky and R. Cunningham, Computer Graphics and Image Processing 7,
1978, pages 195-120. Once the correlation is complete, the process
proceeds from step 121 to step 122 wherein the relationship of the
ultrasound transducer 18 is computed with respect to WCS using the probe
calibration data discussed subsequently. Thus, the locations of the six
sources on the hood 40 are known and therefore the hood and probe
relationship to WCS can be readily determined by applying the techniques
described in "Robot Manipulators: Mathematics, Programming, and Control"
by R. P. Paul, MIT Press Series in Artificial Intelligence, 1981.
After the relationship of the ultrasound transducer 18 is computed with
respect to WCS, the computer checks as indicated at 124 if the ultrasound
image has been digitized by the operator. This occurs by the operator
marking the location of the stone in the ultrasound image using a cursor
of the ultrasound system 20 in conjunction with CRT display 22 in a
conventional manner. The computer then scales the distance of the stone
from the transducer tip in screen coordinates to the physical distance
using a suitable ultrasound scaling factor to give the location in
millimeters as versus screen pixels by computing the relationship of the
stone with respect to the hood, and given the calibration of the hood with
respect to the ultrasound transducer, the relationship to WCS is computed
as indicated at 125, 126. As explained earlier, the hood 40 relationship
to WCS is determined at step 122, and the relationship of the stone with
respect to the hood is determined at step 125, and then the distance of
the stone 13 from WCS is determined at 126 given that the relationship
between the hood 40 and ultrasound transducer 18 is known from earlier
calibration step 108. Finally, the computer can then calculate the
distance of the stone 13 from the focal point F2 inasmuch as the
relationship of F2 to WCS has been determined in the earlier calibration
step 109. The computer can provide a suitable display on the computer
display 25 (FIG. 1) to indicate to the operator the directions and
distances the table 15 should be moved so as to position the patient 11
and therefore the stone 13 at F2 or the table can be moved automatically.
Then, shock wave administration can begin.
Accordingly, a new method and apparatus for localizing an object in space,
such as a gallstone in a human, through the use of stereo video images and
ultrasound imaging is provided.
While embodiments of the present invention have been shown and described,
various modifications may be made without departing from the scope of the
present invention, and all such modifications and equivalents are intended
to be covered.
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