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Claims  |
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What is claimed is:
1. A magnetic resonance (MR) surgery system that comprises:
a) an invasive device having a tip adapted for being inserted into a
patient, the invasive device capable of transmitting optical energy at an
application point proximate to the tip;
b) an optical source for applying heat waves by pulsing optical energy
through the tip of the invasive device at a frequency f and amplitude Q at
the application point to create a heated region having a temperature
distribution T(r,t) around the application point described by:
T(r,t)=Q/.rho.c Exp[-kr]cos(2.pi.ft-kr)/r [4]
where Q is the amplitude of heat provided;
r is the radius from the center of the heated region;
t is time;
.rho. is density of the heated region;
c is specific heat of the heated region; and
k=Sqrt (.omega./2D), where D is the thermal diffusity of the tissue in the
heated region;
c) MR compatible positioning means, connected to the invasive device, for
positioning the tip of the invasive device such that the application point
is positioned to cause a selected tissue within the patient to have the
desired temperature distribution T(r,t);
d) an MR imaging means adapted for creating fast scan MR images of the
temperature distribution T(r,t) around the application point during
surgery using a temperature sensitive pulse sequence; and
e) display means, coupled to the MR imaging means, for interactively
displaying the temperature sensitive images to an operator to allow the
operator to control the temperature distribution T(r,t).
2. The MR surgery system of claim 1 wherein the optical source comprises a
laser.
3. A method of performing heat surgery on a patient, as guided by a
magnetic resonance (MR) imaging apparatus capable of producing temperature
sensitive MR images, comprising the steps of;
a) determining a position of a selected tissue to be destroyed in said
patient with said MR imaging apparatus,
b) positioning a tip of an optical fiber at an application point near the
selected tissue within said patient;
c) determining a desired temperature distribution T(r,t);
d) pulsing optical energy at a frequency f and amplitude Q in order to
create a heated region having the desired temperature distribution around
the application point, such that:
T(r,t)=Q/.rho.c Exp[-kr]cos(2.pi.ft-kr)/r [4]
where Q is the amplitude of heat provided;
r is the radius from the center of the heated region;
t is time;
.rho. is density of the heated region;
c is specific heat of the heated region; and
k=Sqrt (.omega./2D), where D is the thermal diffusity of the tissue in the
heated region;
e) monitoring the temperature distribution T(r,t) with said MR imaging
apparatus; and
f) adjusting the frequency f, the amplitude Q and the location of the
application point. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
The present invention relates to surgery performed by local heating guided
by magnetic resonance (MR) imaging methods of imaging, and more
particularly to surgery performed by pulsed local heating guided by
magnetic resonance (MR) imaging.
Conventional Magnetic Resonance Imaging (MRI) provides the radiologist with
cross sectional views of the anatomy for diagnosis of pathology. MRI
provides excellent contrast between different tissues and is useful in
planning surgical procedures. A tumor is much more visible in an MR image
than as seen in actual surgery because tumor and normal tissues often look
similar in surgery. The tumor can also be obscured by blood during
surgery. Researchers at Brigham and Womens Hospital, Boston, Mass. have
proposed treatment of deep lying tumors by laser surgery. F. A. Jolesz, A.
R. Bleire, P. Jakob, P. W. Ruenzel, K. Huttl, G. J. Jako, "MR Imaging of
Laser-Tissue Interactions", Radiology 168:249 (1989). Thus, in the case of
brain tumors, the patient is first scanned in an MRI system to locate the
tumor and plan a safe trajectory between the entry and target points. This
can be accomplished by a MRI device employing fast scan apparatus such as
U.S. Pat. No. 4,961,054 Gradient Current Speed-up Circuit for High-speed
NMR Imaging System by John N. Park, Otward M. Mueller, and Peter B.
Roemer, issued Oct. 2, 1990, or U.S. Pat. No. 5,017,871 Gradient Current
Speed-up Circuit for High-speed NMR Imaging System, by Otward M. Mueller,
and Peter B. Roemer, issued May 21, 1991 both assigned to the present
assignee and hereby incorporated by reference. A small burr hole is
drilled in the skull and a hollow needle containing an optical fiber is
then inserted into the tumor. The patient is then placed back into the MRI
system to view the region heated by the laser using a temperature
sensitive pulse sequence. Temperature Sensitive pulse sequence is
described in U.S. Pat. No. 4,914,608 In-vivo Method for Determining and
Imaging Temperature of an Object/Subject from Diffusion Coefficients
Obtained by Nuclear Magnetic Resonance, Denis LeBihan, Jose Delannoy, and
Ronald L. Levin issued Apr. 3, 1990 and hereby incorporated by reference.
Experiments on animals show that a heated zone above a critical
temperature destroys tissue. This zone increases in size with time as the
heat is applied to reach a steady state or both temperature and heat flow.
If the maximum temperature is limited to 100 deg. C, then the laser heated
zone, the area exceeding a critical temperature causing destruction of
tissue, approaches 1 centimeter in diameter. It is difficult to predict
the heated zone geometry because the heat flow depends on the profusion of
blood as well as the tissue thermal properties.
Tumors have been selectively destroyed in cancer patients using focussed
ultrasound heating at the University of Arizona, B. E. Billard, K. Hynynen
and P. B. Roemer Effects of Physical Parameters on High Temperature
Ultrasound Hyperthermia Ultrasound in Med. & Biol. Vol. 16, No. 4, pp.
409-420, 1990 hereby incorporated by reference. Billard et al. disclosed
that the control of heat was improved by using short laser pulses where
the effect of blood perfusion is negligible. However, since they did not
image the temperature distribution, it was difficult to hit small, deep
laying targets.
It would be beneficial to be able to accurately localize heat to
selectively kill or destroy tumor tissue without damage to surrounding
healthy tissue.
OBJECTS OF THE INVENTION
It is an object of the present invention to selectively destroy tumors
accurately with a non-invasive procedure employing the use of magnetic
resonance imaging, and focussed ultrasound.
It is another object of the present invention to selectively destroy tumors
accurately with a small degree of invasiveness employing the use of
magnetic resonance imaging, and a pulsed laser.
SUMMARY OF THE INVENTION
Pulsed heat is used to selectively destroy tumor tissue of a patient with a
minimum amount of surgery. Magnetic resonance (MR) imaging is employed to
provide to a surgeon performing the procedure images of a region within
the patient being heated, such region including the the tumor tissue. A
series of fast scan MR images are used to monitor the temperature with a
diffusion sensitive pulse sequence. The pulsed heat is received by the
tumor tissue in the form of coherent optical energy produced by a laser
and guided through optical fiber to a hollow needle placed into the tumor.
Another embodiment employs a focussed ultrasound transducer as the heat
source with the heat concentrated at a focal point. The heat is localized
by adjusting the frequency of the pulses, since an oscillating point heat
source creates a heat wave that decays exponentially with distance from
the source with a decay rate determined only by the frequency. The needle
or focal point is positioned by a mechanical guide under the control of
the surgeon.
BRIEF DESCRIPTION OF THE DRAWINGS
The features of the invention believed to be novel are set forth with
particularity in the appended claims. The invention itself, however, both
as to organization and method of operation, together with further objects
and advantages thereof, may best be understood by reference to the
following description taken in conjunction with the accompanying drawing
in which:
FIG. 1 is a logarithmic graph of Frequency vs. heat Penetration Depth of a
pulsed heat means according to the present invention.
FIG. 2 is a schematic block diagram of one embodiment of the present
invention.
FIG. 3 is a partial perspective view of a patient positioned for surgery
within the bore of the magnets of one embodiment of the present invention
employing a laser source and fiber optics.
FIG. 4 is a partial view of a patient positioned for surgery within the
bore of the magnets of another embodiment of the present invention
employing a focussed ultrasound source.
DETAILED DESCRIPTION OF THE INVENTION
By employing the present invention, tumor tissue in a patient can be
selectively destroyed by localized heating without affecting the
surrounding healthy tissue. A method of selectively heating material such
as diamond is disclosed in Thermal Diffusity of Isotopically Enriched
.sup.12 C Diamond by T. R. Anthony, W. F. Banholzer, and J. F. Fleischer
Phys. Rev. B Vol. 42, No. 2 Jul. 15, 1990 hereby incorporated by
reference. The source of the heat may be either a focussed ultrasound
transducer or a laser source routed to the tumor tissue through an optical
fiber. The heat is applied to the tumor tissue in a pulsed or oscillating
fashion. This oscillation creates a heat wave either at the tip of the
optical fiber or at the focus point of the transducer. The pulsed heat is
produced by a source driven in accordance with a sinusoidal component and
a constant component, and thus varies sinusoidally. Although the
sinusoidal component of the applied heat would imply a negative heating or
heat withdrawal, the constant heat term added to the sinusoidal component
keeps the heat flow positive. However, the constant heating from a point
source steadily adds to the background thermal distribution. The
temperature distribution T may be expressed as T(r, t) with r being the
radius from the center of the point of application, and t being time. The
temperature distribution satisfies the diffusion equation:
D.gradient..sup.2 T(r,t)+dT(r,t)/dt=Q(r,t)/.rho.c [1]
where .omega. is an angular frequency,
.rho. is the density of the heated tissue,
c is the specific of the heated tissue
and D is the thermal diffusity of the heated tissue.
In the case of a periodic point heat source of amplitude Q.sub.0 at the
origin r=0, the heat flow becomes:
D.gradient..sup.2 T(r,t)+dT(r,t)/dt=(Q.sub.0
/.rho.c)Cos(.omega.t).delta.(r) [2]
with frequency f=.omega./2.pi.. A radially symmetric solution is of the
form:
T(r,t)=Q/.rho.c Exp[-kr]cos(.omega.t-kr)/r [3]
where k=Sqrt [.omega./2D], and D is the thermal diffusity. The wavelength
L=2.pi./k of heat waves depends on the thermal diffusivity D and frequency
f, so that
T(r,t)=Q/.rho.c Exp[-kr]cos(2.pi.ft-kr)/r [4]
The heat from an oscillating point source decays exponentially with a
characteristic distance 1/k as shown in H. S. Carlsow and J. C. Jaeger
Conduction of Heat in Solids 2nd Edition, Oxford, Clarendon Press, 1959 at
pages 64-70 hereby incorporated by reference. The heat decay is given by:
##EQU1##
The frequency of the oscillating point source is controlled to vary the
size of the heated region. The size of the heated region can be seen with
the use of a Magnetic Resonant (MR) imaging system employing a temperature
sensitive MR pulse sequence. The MR imaging system also creates an image
of the tissue intended to be destroyed. By varying the frequency of the
oscillating point source, the surgeon can selectively destroy a small
region of tissue, thus performing non-invasive micro surgery. The operator
of the apparatus, such as a surgeon, can adjust the placement of the
oscillating point source and the size of tissue destroyed while monitoring
the images of the heated tissue and the tumor. In an alternative
embodiment, the frequency of the oscillating source and the placement of
the oscillating point source of heat are under the control of a mechanical
guide responsive to the MR temperature sensitive fast scan imaging system.
Consider heat applied at a point by either a laser fiber or focussed
ultrasound transducer. The heat may be applied over a spot of up to 1 mm.
in radius because of the laser optical absorption or diffraction limit of
focussed ultrasound. The thermal diffusivity D of tissue is similar to
that of water, which is 0.0015 cm.sup.2 /sec. The penetration depth for a
given frequency f is tabulated below
TABLE 1
______________________________________
FREQUENCY (Hz) PENETRATION DEPTH (mm)
______________________________________
0.001 6.9
0.01 2.2
0.1 0.69
1 0.22
10 .069
______________________________________
The temperature profile decays exponentially with distance from the
oscillating heat source with a penetration depth that, as evident from
Table 1, depends on the frequency. FIG. 1 is a logerithmic graph of
Frequency vs. Penetration Depth.
A schematic block diagram of the magnetic resonance surgery system is shown
in FIG. 2. A magnet 10 provides a uniform field for nuclear magnetic
resonance imaging using both gradient coils 20 and radiofrequency (RF)
coils 30 to detect the resonance of protons in the patient. A pulse
sequence is applied to the coils by gradient amplifier 40 and RF power
source 50 to the coils to acquire temperature sensitive images rapidly
during surgery. Operator's console 60 is used to control the imaging. A
mechanical guide 70 positions the laser fiber or ultrasound transducer 80.
Raw data is sent from receiver 90 to a surgical planning and control
workstation 100 that displays images 110 to the surgeon and enables him to
guide the heat source by means of a three-dimensional (3D) pointing device
120 such as a track ball or a mouse.
As shown in FIG. 3, a patient 200 lies on a table 210 that moves into the
bore of a two part magnet 260, 270. A laser fiber 230 is inserted into the
patient with a hollow needle 240 guided by a mechanical positioning device
250 such as a hydraulic positioner. The trajectory is computed from a set
of images of the patient taken during surgery planning. A safe trajectory
from the entry point to the target does not intersect critical anatomy
such as large blood vessels. Heat is applied to tumor tissue 280 by
periodically pulsing the laser through laser fiber 230 (i.e., a fiber
optic material) to selectively destroy tumor 280 while the operator views
a temperature sensitive magnetic resonance image. More than one needle may
be required to remove an irregular shaped tumor.
An alternative embodiment (not shown) may employ a heat source that creates
heat over a line segment instead of a point.
As shown in FIG. 4, patient 200 is placed on a table 310 designed to
accommodate a focussed ultrasound transducer 330 in a water bath 320. The
ultrasound transducer 330 can be moved inside the bore of magnets 260, 270
to focus on different locations within patient 200. Ultrasound transducer
330 is focussed onto the tumor tissue 280, avoiding bone or air in the
path of the ultrasound beam, and pulsed to selectively heat tumor tissue
280 at the focal point of the ultrasound transducer. The ultrasound
transducer is moved while the surgeon views cross sectional temperature
sensitive images.
While several presently preferred embodiments of the invention have been
described in detail herein, many modifications and variations will now
become apparent to those skilled in the art. It is, therefore, to be
understood that the appended claims are intended to cover all such
modifications and variations as fall within the true spirit of the
invention.
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Description |
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