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Claims  |
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What is claimed is:
1. A vectographic guide device particularly adapted for use as a needle
guide for discolysis procedures for directing an injection needle into a
spinal disc of a patient on an operating table with the patient having a
saggital axis longitudinally oriented to the table, the guide device
comprising:
(a) mounting means for connecting the guide devide to the side of an
operating table;
(b) a guide mount having means for attaching a tool guide having a specific
directional orientation;
(c) a positioning component on which said guide mount is attached;
(d) a target structure having target means for targeting a point in three
dimensional space;
(e) adjustable support means supporting said target structure and said
positioning component, said support means being connected to said mounting
means locating said positioning component and target structure over the
operating table in a desired position, wherein said target structure has
targeting elements arranged on said structure to define a target point,
and wherein said positioning component has spherical surface tracking
means for selectively positioning said guide mount on a delimited
spherical surface locus equidistant from the target point and
directionally oriented toward said target point, and further,
wherein said adjustable support means comprises first carriage means
connected to the mounting means for tracking the target structure and
positioning component in a first horizontal direction, a screw operated
jig means connected to the first carriage means for raising and lowering
the target structure and positioning component, pivot means connected to
the jig means for angular pivot of the target structure and positioning
component in a horizontal plane and second carriage means connected to the
pivot means for tracking the target structure and positioning component in
a second horizontal direction.
2. A vectographic guide device particularly adapted for use as a needle
guide for discolysis procedures for directing an injection needle into a
spinal disc of a patient on an operating table with the patient having a
sagittal axis longitudinally oriented to the table, the guide device
comprising:
(a) mounting means for connecting the guide device to the side of an
operating table;
(b) a guide mount having means for attaching a tool guide having a specific
directional orientation;
(c) a positioning component on which said guide mount is attached;
(d) a target structure having target means for targeting a point in three
dimensional space;
(e) adjustable support means supporting said target structure and said
positioning component, said support means being connected to said mounting
means locating said positioning component and target structure over the
operating table in a desired position, wherein said target structure has
targeting elements arranged on said structure to define a target point,
and wherein said positioning component has spherical surface tracking
means for selectively positioning said guide mount on a delimited
spherical surface locus equidistant from the target point and
directionally oriented toward said target point, and further,
wherein the positioning component comprises an arcuate arm structure having
first, second and third segments wherein said first segment is fixed to
said adjustable support means, said second segment is pivotally connected
to said first segment on a first pivot axis intersecting said target
point, and said third segment is pivotally connected to said second
segment on a second pivot axis intersecting said target point angularly
displaced from said first axis, said third segment having a distal end on
which is mounted said guide mount.
3. The vectographic guide device of claim 2 wherein said target structure
comprises said first fixed segment of the positioning component.
4. The vectographic guide device of claim 3 wherein said first segment has
an arcuate portion exceeding 90 degrees.
5. The vectographic guide device of claim 4 wherein said target elements
comprises a first pair of projecting parallel pins arranged on said first
segment in a horizontal plane with pointed ends defining a first line and
a second pair of projecting parallel pins arranged on said first segment
in a vertical plane with pointed ends defining a second line intersecting
the first line defining a target point as the point of intersection.
6. The vectographic guide device of claim 2 wherein said target structure
comprises an arcuate arm juxtaposed to said positioning component, said
target structure having a first pair of projecting parallel pins arranged
in a horizontal plane with pointed ends defining a first line and second
pair of projecting parallel pins arranged in vertical plane with pointed
ends defining a second line intersecting said first line defining a target
point at the point of intersection.
7. A vectographic guide device particularly adapted for use as a needle
guide for discolysis procedures for directing an injection needle into a
spinal disc of a patient on an operating table with the patient having a
sagittal axis longitudinally oriented to the table, the guide device
comprising:
(a) mounting means for connecting the guide device to the side of an
operating table;
(b) a guide mount having means for attaching a tool guide having a specific
directional orientation;
(c) a positioning component on which said guide mount is attached;
(d) a target structure having target means for targeting a point in three
dimensional space;
(e) adjustable support means supporting said target structure and said
positioning component, said suport means being connected to said mounting
means locating said positioning component and target structure over the
operating table in a desired position, wherein said target structure has
targeting elements arranged on said structure to define a target point,
and wherein said positioning component has spherical surface tracking
means for selectively positioning said guide mount on a delimited
spherical surface locus equidistant from the target point and
directionally oriented toward said target point, and further,
wherein said spherical surface tracking means comprises a positioning
structure having a first segment attached to the adjustable support means
and an arcuate second segment with a first end pivotally connected to the
first segment on a pivot axis intersecting said target point, said arcuate
second segment having a slide support and a tracking means for tracking an
arcuate path about the target point as centerpoint, said guide mount being
carried by said slide support.
8. A vectographic guide device particularly adapted for use as a needle
guide for discolysis procedures for directing an injection needle into a
spinal disc of a patient on an operating table with the patient having a
sagittal axis longitudinally oriented to the table, the guide device
comprising:
(a) mounting means for connecting the guide device to the side of an
operating table;
(b) a guide mount having means for attaching a tool guide having a specific
directional orientation;
(c) a positioning component on which said guide mount is attached;
(d) a target structure having target means for targeting a point in three
dimensional space;
(e) adjustable support means supporting said target structure and said
positioning component, said support means being connected to said mounting
means locating said positioning component and target structure over the
operating table in a desired position, wherein said target structure has
targeting elements arranged on said structure to define a target point,
and wherein said positioning component has spherical surface tracking
means for selectively positioning said guide mount on a delimited
spherical surface locus equidistant from the target point and
directionally oriented toward said target point, and further,
wherein said mounting means for connecting the guide device to the side of
an operating table includes a clamp member having means to clamp the clamp
member to the side rail and ball interconnecting means for interconnecting
said clamp member and said adjustable support means with universal ball
joint pivot within a delimited range.
9. A vectographic guide device particularly adapted for use as a needle
guide for discolysis procedures for directing an injection needle into a
spinal disc of a patient on an operating table with the patient having a
sagittal axis longitudinally oriented to the table, the guide device
comprising:
(a) mounting means for connecting the guide device to the side of an
operating table;
(b) a guide mount having means for attaching a tool guide having a specific
directional orientation;
(c) a positioning component on which said guide mount is attached;
(d) a target structure having target means for targeting a point in three
dimensional space;
(e) adjustable support means supporting said target structure and said
positioning component, said support means being connected to said mounting
means locating said positioning component and target structure over the
operating table in a desired position, wherein said target structure has
targeting elements arranged on said structure to define a target point,
and wherein said positioning component has spherical surface tracking
means for selectively positioning said guide mount on a delimited
spherical surface locus equidistant from the target point and
directionally oriented toward said target point, and further,
wherein said support means is adjustable to a variety of positions, with
said positioning component and target structure arranged to maintain the
position of said guide mount equidistant and directionally oriented toward
said target point at all positions of said support means and at all
positions of said guide mount on said dilimited spherical surface locus. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
This invention relates to a needle guide apparatus for discolysis
procedures for the accurate insertion of an elongated injection needle
into a select intervertebral disc for injection of a lysing agent or dye
into the disc. The apparatus of this invention is particularly useful to
aid chemonucleolysis procedures for non-surgical treatment of a herniated
invertebral disc. The invention is of the type disclosed in the
application of Robert Moore, entitled, "Needle Guide Apparatus for
Discolysis Procedures" Ser. No. 744,392 filed, June 13, 1985 now U.S. Pat.
No. 4,638,799.
As discussed in that application, certain chemicals have been discovered
that dissolve nucleus pulposus material, the gelatinous substance within a
vertebral disc. These agents, known generally as lysing agents, when
injected into a herniated disc, cause the gelatinous material to dissolve,
relieving pressure on nearby spinal nerves. Of the two principal
applicable lysing agents, chymopapain and collagenase, chymopapain is used
most frequently. Chymopapain is an enzyme derivative from papaya and has
been found to dissolve the material forming the nucleus pulposus, without
adverse affect on the surrounding annulus fibrosis or thin top and bottom
plates of hyaline cartilage. Success from intradiscal injection of
chymopapain has provided, in many cases, an effective alternative to open
back surgery for removal of repair of a herniated disc by a laminectomy
procedure.
A major problem with the chemonucleolysis procedures however, is the
accurate placement of the needle into the nucleus pulposus of the
herniated disc. Prior to the Moore apparatus needle placement was in part
trial and error, often requiring up to one hour of a treating physician's
time to locate the tip of the needle at the desired point within the disc.
In addition to the tedium of the procedure and wasted time, misplacement
or repeated perforation can be harmful to the patient. Prior devices to
guide and locate the needle, as the device of the Moore reference, have
been devised to direct the needle to the desired spot in the disc. Such
devices, however, use complicated structures that in part restrict the
angle options available to the surgeon. The needle guide of this invention
expands the available angle option with a simplified structure using
spherical vectoring techniques.
The improved needle guide is primarily used in discolysis procedures, but
may be used in other procedures particularly where a substance is injected
into a disc or other internal regions where both depth of penetration and
direction of entry are critical.
SUMMARY OF THE INVENTION
The improved needle guide apparatus of this invention is devised to aid a
physician in accurately guiding and locating an injection needle into an
invertebral disc, particularly for chymonucleosis procedures during
diagnosis and treatment of a herniated disc. Proper needle placement is
important for injection of a dye and subsequent injection of a lysing
agent, or in some situations, injection of a combined dye and lysing agent
solution.
Chemical excision of herniated nucleus pulposus by injection of a lysing
agent, such as chymopapain or collagenase, is an effective alternative to
surgery. A most difficult step in the chumonucleosis procedure is accurate
insertion and placement of the needle through the annulus fibrosis and
into the nucleus pulposus. Because a direct posterior approach will
penetrate the spinal cord, and cause possible nerve damage, a more
difficult lateral approach is recommended. For discs between the third and
forth, and forth and fifth lumbar vertebrae, a 45.degree. angle from the
direct posterior axis is preferred, although some surgeons recommend a
55.degree. angle.
The most commonly affected disc is between the fourth and fifth lumbar
vetabrae. The second most commonly affected disc, however, is between the
fifth lumbar vertebrae and the sacrum, a particularly difficult disc to
reach. For this disc a needle positioned at an angle of 45.degree. from
the horizontal place of the sagittal axis must also be positioned at a
30.degree. angle from the cross sectional plane of the spinal column for a
diagonal entry into the disc center.
This compound angle requires a stereotaxic vectoring device for accurate
guide and location of a needle tip. While the prior device of Moore
provides for one or more angles of insertion according to fixed guides of
predetermined orientation, it allows only limited discretion to the
surgeon in defining the optimum angle of entry for a particular patient or
a particular condition.
The hemispheric vectoring guide apparatus of this invention in certain
embodiments permits a target point at the spine to be reached from
virtually any direction normal to a hemispherical surface. For most
chymoneucleosis procedures, this full range is not necessary, and a
preferred embodiment limits this range to all of the useful vectoral
directions by a more compact and accurate structure.
The hemispheric vectoring guide apparatus includes a mount for connecting
the apparatus to an operating table, plus horizontal and vertical
adjustment means for positioning a target structure and vectoring
component. The target structure comprises a first sighting device on a
horizontal axis and a second sighting device on a vertical axis in the
plane of the horizontal axis such that a intersection point of the two
axes defines the target point. The vectoring component is preferably
constructed with first second and third interconnected arcuate members
although a single articulating arcuate member with a slide component may
be used. The interconnections of the first and second, and the second and
third arcuate members are pivotal on axes radially directed to the target
point defined by the complimentary target structure. The pivotal
connection allows the second and third segments to articulate, whereby the
distal end of the vectoring component to which a needle holder is attached
is orientable at any point on a spherical surface within a limited field.
This enables the physician to select the precise direction desired for
entry of his needle. Each selection will position the needle holder such
that the distance to the target point is identical. The physician adjusts
the target structure using a floroscope or other radioscopic instrument to
center and align the target structure, using the sighting devices, over
the site of interest, for example the center of the spinal disc to be
penetrated. The physician selects his entry angle using the vectoring
component, adjusts the depth of penetration from the known standard and
makes his insertion.
The depth of penetration will determine the precise location of the needle
end, which can be predetermined to arrive, before, after or at the
centerpoint location.
For the lumbosacral disc, the compound angle is devised to permit a guide
needle to penetrate the upper edge of the disc, allowing a smaller
injection needle to concentrically feed through the guide needle and curve
into the center of the disc, using a double needle technique. The more
complicated angle and technique is necessary to avoid the protective iliac
crest of the sacrum. Proper centering of the target structure over the
center of the disc and positioning the vectoring component to the desired
compound angle position will accurately situate the guide needle end on
line for the disc axis, with a curve of the injection needle necessary to
situate the needle end centrally between the hyaline cartilage plates.
Once the needle guide apparatus is properly positioned and checked, the
inserted needle will be guided to the proper location for injection. Final
positioning may be determined through feel and subsequent x-ray imaging.
These precision techniques are substantially aided by use of the accurate
positioning and orientation devices described herein.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a side elevational view of the hemispheric vectographic guide
device of this invention.
FIG. 2 is a side elevational view of the device of FIG. 1.
FIG. 3 is an opposite side elevational view partially fragmented of FIG. 1.
FIG. 4 is an enlarged partial top view of the end of the guide device of
FIG. 1.
FIG. 5 is a partial view of an alternate embodiment of a portion of the
device of FIG. 1.
FIG. 6 is an end view of the alternate embodiment of FIG. 5.
FIG. 7 is a side view of an alternate positioning component for the device
of FIG. 1.
FIG. 8 is a cross sectional view taken on the lines 8--8 in FIG. 6.
FIG. 9 is a cross sectional view of an alternate slide component.
FIG. 10 is a side elevational view of an alternate mounting means for the
guide device.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
Referring to FIG. 1, the vectographic guide device designated generally by
the reference numeral 10, is shown in a side elevational view to
illustrate the hemispherical positioning component 12 for the actual guide
mount 14 for the injection needle 16 shown in phantom. Behind the
positioning component 12 is a target structure 18. The cooperative
arrangement of the positioning component 12 and the target structure 18 in
the embodiment of FIG. 1 is particularly designed for discolysis
procedures where the guide element need sweep over only a portion of a
hemispherical locus. If greater coverage is required, an embodiment as in
the schematic illustration of FIG. 4 may be preferred, where a greater
portion of a hemispherical locus is covered.
The hemispheric, vectographic guide device 10 of this invention is
constructed with a mounting mechanism 20 for affixing the device to a side
rail of an operating table (not shown). The mechanism 20 includes a
backing plate 22 having a pair of spaced upper clamp members 24, shown
also in FIG. 3, which wedge over the top of the side rail, and a
displaceable centrally positioned clamp member 26, which wedges under the
bottom of the rail. On tightening a turnscrew 28 threadably mounted in a
block 30, the backing plate 22 is drawn into alignment firmly against the
rail.
The backing plate 22 includes end plates 32 for end support of a pair of
displaced guide rods 34 on which is mounted carriage assembly 36. The
carriage assembly 36 is constructed with a carriage block 37 having
internal bearing sleeves which engage the rods 34 allowing the block 37 to
freely track along the length of the rods 34. A stop screw 38 passes
through a threaded hole in a step down segment 40 of the block 37 to
engage the backing plate 22 when the stop screw is tightened. This locks
the carriage to the backing plate at the desired position relative to the
length of the operating table.
In conjunction with the carriage feature of the block 30 are a vertically
oriented bearing sleeve and screw passage for engagement of a vertically
displaceable jig structure 42 constructed with an elongated turnscrew 44
and parallel guide rod 46 both clamped to a lower bar 48 and an upper bar
50. A turn collar 52 rotatably mounted to the carriage block 37 engages
the turnscrew 44. Rotation of the turn collar 52 raises or lowers the jig
structure 42 relative to the block.
The upper bar 50 forms a support platform for a guide block 54 which is
pivotally secured to the bar 50 by a threaded clamping knob 56, which
engages a segment of the turnscrew 44 extending above the upper bar 50.
The pivotal connection enables a slide support 58 carrying the needle
guide positioning component 12 and the target structure 18 to rotate in a
horizontal plane relative to the vertically adjustable jig structure to
compensate for a skewed orientation of the patient on the operating table.
The slide support 58 is constructed with two parallel rods 60 connected at
one end to a cross bar 62 and connected at their other end to a mount 64.
The rods slide in the guide block 54 which includes a clamp screw 65 to
lock the slide support 58 in a desired position. The mount 64 has a step
structure 66 for attaching and orienting an attachment arm 68. The
attachment arm 68 provides a support for the positioning component 18 and
the target structure 18.
The target structure comprises an arcuate member 70 secured to the
attachment arm 68 by a knobbed clamping screw 72. The arcuate member 70
has a pair of lower parallel sights 74 with pointed ends 76 arranged to
demarcate a horizontal axis and a pair of upper parallel sights 78 with
pointed ends 80 arranged to demarcate a vertical axis intersecting the
demarcated horizontal axis. The point of intersection is the target point
for purposes of targeting the tool mount 14 at the end of the positioning
component 12.
The positioning component 12 is constructed with three arcuate segments, a
first fixed segment 82, which is clamped to the attachment arm 68 by a
turnscrew 84, a central segment 86 connected at an end to the fixed
segment 82, and an end segment 88 connected at one end to the central
segment 86 and supporting the tool mount 14 at its distal end.
The fixed segment 82 is juxtaposed to the target structure on the opposite
side of the attachment arm and includes holes 90 through which the
horizontal sights 74 project for developing the horizontal radiosopic line
of sight. The end of the fixed 82 is pivotally connected to the end of the
central segment by a pivot clamping pin 92 having an axis oriented to
intersect the target point. The clamping pin 92 allows the central segment
to articulate on the pivot axis with respect to the fixed segment, and on
tightening the clamping pin 92 fixes the relative position of the central
segment with respect to the fixed segment. Similarly, the end segment 88
is connected to the central segment 86 by a pivot clamping pin 94 also
having an axis directed to the target point. The clamping pin 94 on
tightening fixes the position of the end segment relative to the central
segment.
The structure of segments are stepped as shown in FIG. 2 to orient the
guide mount 14 in the plane of the intersecting target lines when the
positioning component 12 is aligned with the target structure 18 for
convenient reference prior to desired repositioning according to the
angular specifications of a particular procedure.
The dual articulation permits the tool mount to be located anywhere on a
delimited spherical surface locus as limited by the reach of the
positioning component. At all points in the field, the guide mount is
oriented in order that a tool guide 96, such as the needle guide shown in
FIG. 1, is directed at the target point. At all positions, the guide mount
14 is equally distant from the target point as it follows the locus of a
spherical surface relative to the center point of the sphere which is
coincident with the target point.
The guide mount 14 in FIGS. 1 and 4 is a needle guide support that is
mounted to the butt end of the end segment 88 by a thumbscrew 97. The
guide mount 14 has an end clamp 99 with a smaller thumb screw 101 for
clamping the needle guide 96 in position. The needle is longitudinally
adjustable to permit location of the guide according to the length of the
needle and the desired final position of the needle tip. It is understood
that the guide mount 14 may be of different configuration where the tool
is a device other than a needle.
As guides for the physician a marked disk 98 rotates with the articulating
member relative to marker 100 on the connecting element to indicate
relative position by references that can be correlated with entry angles
using a correlation chart (not shown). The device of this invention allows
the physician to arrange for injections according to his own entry
specifications as well as in conformity to traditional trajectories.
While the embodiment of FIGS. 1-4 is preferred for discolysis procedures, a
modified target and positioning component as shown in FIGS. 5 and 6 may be
desired. In the partial embodiment of FIGS. 5 and 6 only the targeting and
positioning component 102 differ, the remaining support structure (not
shown) remaining the same. The combined target and positioning component
102 includes an arcuate support arm 104 having three segments. The first
segment 106 is attached to the attachment arm 68 (not shown) and includes
horizontal target pins 108 and vertical target pins 110. At the distal
L-configured end 111 of the fixed first segment 106 is an articulating
central segment 112 connected at one end to the fixed segment by a pivot
clamp 114 having a pivot axis directed to the target point formed at the
intersection of target lines from the target pins 108 and 110. At the end
of the central segment 112 is an end segment 116 connect at one end to the
fixed segment by a pivot clamp 118, again with a pivot axis directed at
the target point. The distal end of the end segment 116 supports guide
mount 120 for a needle guide 122 with an axis oriented at the target
point. Similarly, the dual articulation orients the needle guide
equidistant from and directed at the target point from whatever vector
selected by the surgeon.
As a further embodiment, a vectographic guide device may include the
adjustment structure of the embodiment of FIGS. 1-4 with a substitute
target structure and positioning component 124 as shown in FIGS. 7 and 8.
The positioning component includes a first segment 126 with target
elements as in FIG. 5, the first segment being fixed to the support mount
64. The positioning component includes a second split segment 128
pivotally connected at one end to the end of the first segment by a
clamping pivot pin 130. The axis of pivot is directed toward the target
point enabling the second arcuate segment to sweep a partial surface of a
sphere centered on the target point. On the arcuate second segment is a
guide track 132 for a slide support 134 which tracks an arcuate path
centered about the target point between the pivot end spacer 136 to the
distal end spacer 138. A guide mount 140 is attached to the slide support
134 to direct a surgical instrument toward the target point at all
positions within the delimited range of the articulating segment and
sliding support. As in the former embodiments the tool mount is properly
oriented and equidistant from the target point at all positions within its
range.
As a further modified embodiment, the device of FIG. 7 can be constructed
with an end segment 142 as shown in FIG. 9 that is not split, but has
instead an arcuate slot 144 through the end segment that is comparable to
the track 132 in FIG. 8. With this construction, a slider 146 with a side
projection 148 that engages the slot 144 can track along the slot and be
clamped in a select position by the opposed thumb screw 150 and washer
152. A needle clamp screw 156 clamps a needle guide 158 in a similar
manner as in FIG. 1.
Other modifications in the vectographic guide device may be made to improve
its versitility. For example, where it is difficult to properly orient a
patient on a table because the patient is unresponsive or has added
complications requiring certain positions to be avoided, then an alternate
table mounting means may be preferred. As shown in FIG. 10 a side rail
bracket 166 slides onto a conventional side rail (not shown) and is
secured by a clamping knob screw 168. Fixed to the top of the bracket 166
is a ball pedestal 170, which is engaged by a ball socket structure 172
that has a clamping crank 174 for fixing the relative desired position of
the socket structure to the bracket. The socket structure 172 is attached
to the backing plate 22 for slidably attaching the carriage assembly 36,
as in the FIG. 1 embodiment.
The ball and socket component allows the mounting mechanism to tilt to
allow the needle guide positioning component (not shown), to properly
align with the patient's back in discolysis procedures or along with a
planar frame of reference that is tilted from the normal to the table in
other medical procedures.
While in the foregoing embodiments of the present invention have been set
forth in considerable detail for the purposes of making a complete
disclosure of the invention, it may be apparent to those of skill in the
art that numerous changes may be made in such detail without departing
from the spirit and principles of the invention.
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Description |
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