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BACKGROUND OF THE INVENTION
With the advent of third and fourth generation CT scanners, invasive and
interventive procedures that are performed under CT guidance are now used
extensively. CT guided needle aspiration biopsies have been highly
successful and have alleviated the need for diagnostic surgery in the vast
majority of cases: (Haaga J., Lipuma J., Bryon P., Balsara V., Cohn A.,
Clinical comparison of small and large caliber cutting needles for biopsy.
Radiology 164:665-667, March 1983; Mulari Sunduram, et al., Utility of CT
guided abdominal aspiration procedures. AJR 139:1111-1115, December 1982;
Harvey M. Goldstein, et al., Percutaneous fine needle aspiration biopsy of
pancreatic and other abdominal masses. Radiology 123:319-322, May 1977;
and Robert Isler, et al., Tissue core biopsy of abdominal tumors with a 22
gauge cutting needle. AJR 136:725-728, April 1981). In addition, CT now
guides the drainage of abdominal abcesses by way of a percutaneous route
eliminating the need for repeat surgery. At the present time, however, all
of these procedures are guided by hand, consequently it is usually a
time-consuming process that requires multiple needle manipulations with
repeat scanning to verify the position of the needle. Because of this lack
of proper instrumentation, it can take as long as an hour to biopsy a 2-3
cm lesion in the liver of a patient.
CT stereotaxis is a well established procedure for the head (Brown, R. A.,
A computerized tomography-computer graphics approach to stereotaxic
localization. J. Neurosurg., 50:715-720, 1979; Brown, R. A., A
stereotactic head frame for use with CT body scanners. Invest. Radiol.,
14:300, 1979; Brown, R. A., Roberts, T. S., Osborn, A. G., Stereotaxic
frame and computer software for CT-directed neurosurgical localization.
Invest. Radiol., 15:308-312, 1980; and Roberts, T. S., Brown, R. A.,
Technical and clinical aspects of CT-directed stereotaxis. Applied
Neurophysiology, 43:170-171, 1980). The brain, because of its consistent
relationship to the boney skull, can have a rigid frame attached to it
which can then provide the needed reference coordinates from which various
paths can be calculated. It should be noted that in all of the present
stereotaxic devices for the brain, the reference coordinates are taken
from the attached frame not the patient's skin and referenced to the
target. The body, however, does not have the constant relationships of its
surface anatomy to the underlying organs. In addition, there is no
structure to which a rigid frame can be attached. To add to the
difficulties, many of the organs within the abdominal cavity move with
respiration so that with the changes in the phase of respiration, the
relationship of the organs to the surface are different. It is for these
reasons that at present there has been no published attempt to use CT
stereotaxis in the guiding of probes or needle into the neck, chest,
abdomen, pelvis, and extremities.
BRIEF DESCRIPTION OF THE INVENTION
The present invention relates to a method and an apparatus to achieve
precist CT stereotaxic placement of probes anywhere in the body from
images on a CT scanning machine (x-ray, NMR, P.E.T., etc.). The invention
utilizes the technique of finding a reference point in the patient's body
that exactly correlates to a point on the CT scan. The reference point is
established by means of a localization device that is placed on the skin
of the patient. The localization device is identified in cross-section on
the CT scan. Measurements of the localization device on the CT scan are
then correlated to the device on the patient.
In addition to the general object of providing a method and apparatus for
allowing CT guided biopsies of the body, the present invention has the
following subsidiary objects and features:
(1) Use of a method for calculating multiple angled approaches from the
reference point;
(2) Use of a stereotaxic frame upon which the angles calculated can be set
and which will guide the probes to the target, the frame either being
attached to the CT table, or patient, or CT independent by mounting to the
floor;
(3) Use of a respirator gating device which will allow all scans and the
biopsy to be obtained in the same phase of respiration;
(4) Use of an immobilization device which comprises a vacuum bag filled
with plastic beads which molds to the patient's body; and,
(5) Use of a circular level or leveling systems on various axes attached to
the immobilization device which allows for repositioning the patient
outside the CT scanner making the CT biopsy scanner-independent;
(6) Use of a localizer device attached to the skin to determine a reference
point on the body;
(7) Use of a quick-release needle guide device for fast sequential
placement of probes in the body.
BRIEF DESCRIPTION OF THE FIGURES
These objects and other objects and features of the invention will best be
understood from a detailed description of a preferred embodiment of the
invention selected for purposes of illustration and shown in the
accompanying drawings in which:
FIG. 1 is a diagrammatic view showing a localization device placed on a
patient's skin with its base oriented in the axial plane (x axis);
FIG. 2 is a three-dimensional view of the localization device as it relates
to two different axial sections in a series of CT slices;
FIGS. 3A through 3D depict various types of localizer devices that can be
placed on the patient to determine a reference point on the patient's skin
from CT images;
FIG. 4 shows a two-dimensional representation of the two axial sections of
FIG. 2 with reference made to the fiducial reference point as defined by
the localization device, as well as the skin entry point and the target
point;
FIG. 5 shows the three-dimensional calculations employed for the definition
of oblique compound angle needle or probe paths;
FIG. 6 is a view in perspective of a biopsy guide that holds the needles or
probes and upon which is set the calculated angles;
FIG. 7 illustrates in perspective a patient stablization board upon which
the patient lies and integrated with the board is a strap that extends
around the patient's chest for positioning a respiratory gating device;
FIGS. 8A and 8B depict in perspective and plane view, respectively, a
leveling device for attaching to the patient or board to relocate the
patient out of the scanner; and,
FIGS. 9A, 9B and 9C are views in perspective of quick-release needle guide
systems.
DESCRIPTION OF THE METHOD
The present description relates to a new method and devices that allow
identification of a reference point on a CT scan and then allow
identification of that point on the patient's skin. From the point on the
patient's skin, any point of entry on the patient's skin can then be
calculated. From the CT scan, the coordinates of a target point can then
be identified. Using mathematical calculations, the path length and angles
needed to reach that target from the skin entry point can then be
calculated. A biopsy guide oriented in the plane of the CT scan can then
have the calculated angles set upon it which will aim the probe at the
identified skin entry point from which the target coordinates will be
reached.
FIG. 1 illustrates the localization device 1 placed on the patient's body
as viewed from above. The base 1A of the device is oriented along the x
axis parallel to the plane in which the axial sections of the CT scan will
be obtained. SP1 is the scan plane from which the reference point 2 and
the skin entry point 3 will be obtained. SP2 is the scan plane from which
the target point 4 will be identified. FIG. 2 shows in three dimensions
the two scan planes through which the CT scans will be obtained of the
patient's body. Point 2' is the reference point obtained from the
localization device. Point 3' is the skine entry point that was obtained
by moving calculated distances from the reference point 2'. Point 4' is
the target point whose coordinates were obtained from the CT scan. The
distance marked T is the distance along the z axis between the two scan
planes. The distances marked x and y are the distances needed to be
traveled along the x axis and y axis to get from the reference point 2' to
entry point 3' on the patient's skin.
It is understood that the surgeon can decide to use the point 2' itself as
the entry point through which the instrument will pass to a target. Thus,
it may be that point 3" `coincides` with point 2". This simply means that
X'=Y'=0. In the same way, referring to FIG. 2, it may be that target 4' is
actually in the scan plane SP1. Thus, the reference to the first and
second tomographic cuts coinciding is merely that SP2 is equal to SP1,
i.e., the entry point and target point are in the same axial scan.
The localizer device 1 in FIG. 1 is shown as a triangle with base 1A, but
other shapes or device types can be used to do the same localization. The
present invention is not intended to be limited to any particular form or
shape of localizer device 1. The device can be made of various materials
such as plastic, carbon fiber, etc. and be solid, hollow, or of tubular
construction.
FIGS. 3A through 3D illustrate other types of localizer devices. In FIG.
3A, an "N"-type structure consists of parallel rods 31 and 32 and a
diagonal 32 such that if the CT cuts the device and the CT axis is aligned
parallel to 31 or 32, then the ratio of distances d.sub.1 /d.sub.2 can be
related to the z distance from the devices end, thus giving information on
the location of the scan plane in real space. The rods can be made of
carbon fiber so as to show up on the CT image as spots. FIG. 3B shows a
stepped triangle localizer, where if axis 34 is aligned before the scan to
be parallel to the scan, then the distance d.sub.3 as measured on the scan
compared to the real localizer will give the position of the scan cut
along the axis 35 (z-axis). In FIG. 3C, right triangles 36, isoceles 37,
and hollow triangle 38 all are useful examples of localizers. Note in
triangle 38 there are lines 381 on it which are parallel to base line 382,
which can be aligned with the CT plane prior to scanning. Now if a certain
distance d.sub.4 is seen on the CT scan corresponding to a cut line 383
through 38, then this can be quickly located on 38 by the lines 381. If
the lines are placed such that d.sub.4 is an integral value across 38,
then one needs only to interpolate to get the position of 383. Note, too,
that any intersection of 383 with the four edges of 38 will serve as a
reference skin point (viz 2 of FIG. 1). By making 38 i.e., open in the
center hollow as shown, it may be flat on the patient's body and roughly
independent of the curvature of the skin under it. Localizer device 38 can
have a sticky underside so that it is quickly stuck to or removed from the
patient and may be served sterile-packed and disposable.
Box structures with more diagonals and rods as in FIG. 3D can be used and
attached to the patient to determine the entire plane of CT cut, even for
oblique planes or when no prior alignment is utilized. Intersection of all
the rods and diagonals determines an arbitrary scan plane. Note that it is
useful to align an edge or surface of these localizers to the scan plane
before scanning to simplify the localizer identification. This is not
essential, however, since, for example, sequential scan across a triangle,
as FIG. 3A, 3B, 3C, can lead to determination of the scan cut without
prior alignment. Once the localizer is attached to the skin or body, then
scanning allows a point to be identified on the patient's skin which is
related to a corresponding point on the localizer.
FIG. 4 shows axial CT slices through the previously noted planes which are
again labeled on the diagram SP1 and SP2. The scan slice marked SP1 shows
the cross sectional distance of the localization device labeled D. The
lateral margin of the cross section of the localization device defines
point 2" which can be related back to point 2' that was previously
identified on the patient in FIG. 2. Point 3" is the entry point as viewed
on the CT scan. The distances x' and y' are the calculated distances on
the CT scan that relate point 2" to point 3" and which correlate to the
distances marked x and y in FIG. 2. Point 4" as noted on SP2 is the target
point on the CT scan that relates to point 4' as seen in FIG. 2. It can be
seen that by measuring the distance D on the CT scan, and by then
measuring that same distance on the localization device on the patient,
that the point that is defined as 2" on the CT scan can then be directly
found on the patient previously defined as point 2'. All calculations then
made from point 2" in FIG. 2 and point 2 in FIG. 1 on the CT scan can then
be made from point 2' on the patient's body.
FIG. 5 shows point 3" with coordinates x1, y1, z1 as the needle entry point
and point 4" with coordinates x2, y2, z2, as the target coordinates. It
can be seen that by knowing the x" and y" as well as the distance T (all
distances that can be calculated from the cT scan and the scanning
parameters), the azimuth, the angle of declination, and the needle path
length N can be calculated.
FIG. 6 shows a stereotaxis guide instrument that can be used to guide the
needle or probe on the calculated course. In this version, the guide is
independent of the CT scanner or its table. The base 6 is placed on the
floor and has no connection to the CT table. The guide has two moving
members that provide displacements in the y-axis direction; a main
vertical post 7 and a smaller vertical bar 8. X-axis movement is
accomplished by an x-travel bar 9, through its guide yoke 10. Z-axis
movement is accomplished by movement of a z-bar 11. By these x,y,z
movements, the tip of a needle in needle holder 12 can be brought to the
exact entry point of the skin for any settings of the angular rotation
members of the device. Although two y-bars are shown, a single y-bar is
also workable.
Angular rotations about these axes enable any orientation of the needle
direction to be set for penetration to hit the target. Bearing 13 enables
x-bar 9 to be swung over the patient and 9 to be aligned parallel to the
scan plane. Bearing 14 provides, thereafter, the calculated azimuth angle
to be set, and bearing 15 enables the declination angle to be set. Thus,
once 13 is aligned, 14 and 15 are set according to the calculated angles
of FIG. 4, and the x,y,z translations made to set the probe tip to the
body entry point 2'. Advancing the needle by calculated distance N then
enables the tip to just reach target 4' in the body.
The stereotaxis guide instrument of FIG. 6 has specific advantages and
details. Thus, having base 6 on the floor makes it free of the CT table,
and therefore scanner independent. One does not have to modify or adapt
each table to hold the frame. Furthermore, it eliminates any complexity of
equipment which must be attached to the table or patient. Base 6 can have
a vacuum seal to the floor so that it is easily put in place or removed;
or placed on either side of the CT or operating table. The first vertical
(or y) travel is column 7, which moves in and out of column 23, so that
the overall height of x-bar 9 may be adjusted to suit the table height.
This is done by turning crank 24 which activates an internal gear system
to raise or lower 7. First aximuth (or O) bearing 13 has an angle dial on
it and enables arm 9 to be swung over the patient, or out of the way
altogether, with ease. The index and set stop on it enable easy alignment
of bar 9 over the patient and CT table so that bar 9 can be set up and
aligned initially to the CT plane. This can be important for quick
alignment on the CT or operating tables. Vertical bearing 25 allows 9 to
swing up or down, for alignment to the horizontal. A level or bubble gauge
26 makes this step easily done. Adjustment vernier 27 enable this angle to
be fine-tuned.
A second vertical bearing 25' allows z-bar 11 to be adjusted to be in the
horizontal or x-z plane defined by the scanner axes. Bearings 25 and 25'
can be replaced by a single ball type bearing with vernier screws to
achieve the same alignment of 9 and 11 to horizontal as is done in a
surveying transit. A level 26' checks the z-bar level. Arm 9 travels in
block 10, and set-stop 27 can clamp a position. A scale on 9 enables exact
x-movements to be measured, and roller bearings inside 10 can make the
movement of the bar more frictionless, for ease of handling.
Counter-weight 28 balances the arm 9. End block 29 has similar bearings
for ease of bar 11 travel in the Z direction. End block 40 and attachment
41 of bar 9 enable that 11 can be reversed on the Z direction, so that the
instrument can be set on either side of the patient. Bar 11 is graduated
for exact Z motion. A second aximuth bearing 14 makes quick setting of the
azimuth angle in FIG. 5 possible, and it is graduated in degrees for
direct setting of calculated angles. Bearing 42 allows second vertical (or
y) travel bar 8 to move easily and be set in an exact y-position. This
second vertical bar enables the probe carrier 12 to be brought down close
to the body, making possible oblique out-of-CT plane approaches with ease.
End bearing 15 is the declination angle of FIG. 5, and is graduated in
degrees to enable setting calculated angles of approach. An extension of
the electrode carrier 43 can enable the quick-release needle guide 44 to
be brought very close to the skin to minimize needle length.
This sequence of travels and bearings simplifies the movement of the needle
tip to puncture point 3' of FIG. 2 and to path N of FIG. 5. Unlike arc
system guides, the articulating arm configuration gives less interference
to the surgeon and to the CT equipment, while retaining full approach
flexibility. Note, bearing 14 can be located on the lower end of travel 8
and next to bearing 15 to achieve similar approaches. The adjustability of
alignment, and portable floor mount enable the unit to be moved from CT
table to operating table easily. Parallel needle paths are easily set up
by fixing the bearing settings of 15, 14, and 13 and simply moving the
bars 9, 11, and 8 (or 7) by discrete x, z, and y amounts, respectively.
The instrument of FIG. 6 is just one of many specific translation and
rotation devices which can set up mechanically the calculated path. Other
designs which are fixed to the patient or the CT device can be used to
accomplish the same thing, and are included within the present invention.
Various permutations of x, y, z, angle movement elements in series on the
arm also are included within the scope of the invention.
Since many of the internal abdominal organs move with respiration, it can
be required that the stereotaxic method for the body take respiratory
motion into account. A respiratory gating device similar to the device
described by Jones for use with chest CT: (Jones, K. R., A respiratory
monitor for use with CT body scanning and other imaging techniques. BRF
55, 530-533 and Robinson P. and Jones K., Improved control of respiration
during computed tomography by feedback monitoring), can be utilized. At
the present time there is no known published literature on the use of a
respiratory gating device for CT guided biopsies. The device employs a
water in tube strain gauge that is strapped around the patient's chest
which is connected to a transducer that will in turn give a digital
readout as to the patient's phase of respiration. In this way, all scans
can be taken in the same phase of inspiration.
In one possible configuration, the respiratory gating device, which can be
strapped around the patient's chest, is anchored to the patient
immobilization device. As shown in FIG. 7, the immobilizer comprises a
plastic bag 16 which is filled with foam pellets. A tube 17, which is
connected to the bag, is hooked up to wall suction which is activated
after the patient has laid down on the bag. The air is then evacuated from
the bag which becomes a rigid cast of the patient's body. Devices such as
this are available commercially for immobilization for other x-ray
procedures. There is no known published literature at the present time
that indicates a device such as this has ever been used in connection with
CT scanning or with CT guided biopsies. In fact, the commercially
available bags are all too wide to fit into the aperture of the CT
scanner.
The foam filled bag, which is shown in FIG. 7, in turn anchored to a rigid
board marked 18 on FIG. 7. The rigid board has a circular level 19 in one
corner and adjustable corner posts 20 which can change the angulation of
the support board. The circular level seen in FIG. 8 can rotate on a ball
joint 21. When the bubble is centered, the ball joint is locked with a set
screw 22. If this level is set while the patient is still on the CT table,
the patient, while still on the immobilization device, can be moved to a
different room for the biopsy. The patient can then be oriented to the
stereotaxic frame using the localization device as a reference and, using
the circular level, the patient can be oriented in space exactly as the CT
scan was obtained. A similar function can be accomplished by multiple
linear levels or other leveling device schemes.
FIG. 9 shows embodiments of two of many schemes for a quick-release needle
guide system, analogous to 44, 43, and 12 in FIG. 6. In FIG. 9A, bearing
15 corresponds to that of FIG. 6, and is the declination bearing on the
end of the articulating arm of the entire guide. Onto 15 is fastened a
holder 50, into which slides metered bar 51. Set 52 clamps 51 at a given
extension out of 50. Block 52 guides vertical bar 53, with scales on it
too, and set screw 54 enables clamping of the two pieces. On the end of 53
is needle guide plate 54 with groove 55 to guide a needle 56. Plate 57
articulates on 54 to close and trap 56 into 55, providing sure
directionality. Lever 58 enables quick opening of 57 relative to 54, so
that needles can be put in or out quickly. The scale on 53 enables easy
sighting on a depth stop 59 on 56 for determining depth of penetration.
FIG. 9B shows another needle clip, possible instead of 57 and 54. This has
two jaws 60 and 61 which open or close by pressing 60A and 61A, with
groove 62 to guide a needle. Thus either lever, screw, twist lock,
bobby-pin type, squeeze tab, or other type actuators are possible to
enable a quick-release type needle guide, and all of these styles are
intended to be included in this invention. It is noted that 55 and 57 or
60 and 61 may be spring loaded so that they tend to close or open
depending on design. This can make easier the control of the device. Note
too that upon inserting a needle in an upper right hand corner of an array
on the skin, rows of needles down or to the left can be placed
sequentially without interference of the guide shown in FIG. 9A. Thus a
large array of parallel needles may be placed quickly wiht such an
invention. Once a needle is guided into the body, 54 can be unlocked and
55 and 57 opened, and the slide bar 51 pushed to the left into 50 to clear
the guide from the needle shaft 56. Then the guide can be set up to new
settings, and the next needle inserted. In FIG. 9C, a V-groove type needle
guide is shown with friction hold. V groove 62 in plate 55' gives sure
guidance of needle shaft 63, and plate 57' gives clearance for 63. Spring
64 has tab end 65 that presses on 63 to hold it from slipping, yet allows
easy travel when pushed. Screw 66 holds 64 in place on 57'.
Having described in detail various embodiments of our invention, it will
now become apparent to those skilled in the art that many modifications
can be made therein without departing from the scope of the invention as
defined in the following claims.
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