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BACKGROUND OF THE INVENTION
1. Field of the Invention
This invention relates to the production and medical use of X-rays, and
more particularly to the production, by X-ray micro-tubes, of low energy,
highly absorable, polychromatic X-rays and to the use of those X-rays in
the treatment of tumors when such X-ray micro-tubes are placed within, or
adjacent to, mammalian bodies in very close proximity to, or within,
tumors.
2. Description of Related Art
It has been stated that the goal of radiation therapy is to achieve in a
selected treatment volume, a dose distribution of radiation that provides
the patient with maximum tumor control and the least possible effect on
surrounding normal tissues. (PRINCIPLES AND PRACTICE OF RADIATION
ONCOLOGY, C. A. Perez, and L. W. Brady, Editors; J. B. Lippincott Company,
Philadelphia. 1987 Pg. 159).
To acheive that desired goal, many methods have been advanced over the last
90 or so years which have focused on the use of very high energy sources
of radiation. Current radiation treatment of tumors involves the use of
large external high energy devices such as X-ray machines, linear
accelerators, betatrons, or microtrons, or the use of very high energy
emissions from radiosotopes.
The radioisotopes may be placed in large external machines such as .sup.60
Cobalt teletherapy machine, or implanted near a tumor site. Present
Applicants are aware of a surgical procedure being utilized in the
treatment of brain tumors in which tiny holes are drilled in the skull.
The surgeon inserts thin tubes with closed bottom ends into the tumor.
Radioactive pellets the size of peas are inserted into the tubes. The
implants deliver strong radiation to the tumor. They are removed a few
days later.
The safety of these above-identified high energy radiation sources has been
a constant concern for health professionals. Not only can the tumor and
surrounding normal tissue within the patient be affected by these high
energy radiation sources, but the health professionals working near the
patient can be adversely affected if adequate safeguards are not taken.
Although the high energy devices have been designed to produce a maximum of
antitumor acitivity with a minimal effect on a patient's normal tissues,
the side effects of the radiation therapy on the patient's normal tissue
can still be the limiting factor in a course of therapy.
SUMMARY OF THE INVENTION
The present invention is a method and apparatus for treating tumors by low
energy, highly absorbable, polychromatic X-rays (also called
Bremsstrahlung or White radiation) produced by small X-ray micro-tubes
placed within, or adjacent to, a patient's body in close proximity to, or
within, a tumor. The design of the X-ray micro-tube can be relatively
simple: a miniature X-ray production source, generally a glass tube a
fraction of an inch in diameter and with a length of approximately
one-half of an inch, to several inches, containing at least an anode and a
cathode. The cathode may be a pointed cold cathode, or a heated filament,
and the tube must be evacuated to, at most, 10.sup.-6 Torr. The target
portion of the anode may be formed of tungsten, as in conventional X-Ray
tubes. The glass tube may be surrounded by a plastic envelope so as to
prevent injury to the patient or health professional should the glass
break. A metal jacket containing a window may be placed around the tube so
as to allow the X-rays to travel only in the direction of the tumor. The
X-ray micro-tube may be disposable or re-sterilized.
The depth of X-ray penetration into tissues can be easily and accurately
controlled by adjusting the voltage applied to the X-ray micro-tube.
Tissue penetration depths within a few centimeters from the surface of the
tube are characteristic of the White radiation produced by the
micro-tubes. This reduces damage to normal tissue except in the immediate
vicinity of the tumor. The X-rays are produced by applied voltages between
10 kilovolts and 60 kilovolts.
The voltage applied to the X-ray micro-tube may have an operable frequency
between direct current and 1,000,000 cycles per second, the higher
frequencies providing greater patient safety. The current through the
X-ray micro-tube is generally much lower than that conventionally used and
is in the micro-ampere range. Patient safety is assured by ground fault
interrupters and current limiting circuitry.
The micro-X-ray tubes may be placed in-situ by a number of methods,
including, but not limited to: implantation during surgery; insertion
through a normal body orifice; insertion in conjunction with a fiber-optic
scope through a normal body orifice; in conjunction with a fiber-optic
scope through a surgical incision; insertion through a trocar catheter; or
insertion through a catheter contained within a surgical incision.
Other objects, advantages and novel features of the present invention will
become apparent from the following detailed description of the invention
when considered in conjunction with the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a graph of Mass Absorption Coefficient, .mu./.rho., versus
Energy, MeV, showing the ranges for Photoelectric and Compton Scattering
absorption.
FIG. 2 is a graph illustrating the spectral distribution of the X-ray
energies and relative intensities emitted from a tungsten anode for
various constant d.c. potentials.
FIG. 3 is a graph illustrating examples of Penetration-depth curves of
constant d.c. voltage, KeV vs penetration depth in body tissue, in
centimeters, for monochromatic X-rays, showing distance for percentage of
intensity remaining.
FIG. 4 includes schematic curves showing the changes in the intensity
distribution of the White radiation spectrum from a tungsten anode at 50
KeV constant potential d.c. after penetrating through various depths of
tissue.
FIG. 5 includes schematic curves showing the changes in the intensity
distribution of the White radiation spectrum from a tungsten anode at 40
KeV constant potential d.c. after penetrating through various depths of
tissue.
FIG. 6 includes schematic curves showing the changes in the intensity
distribution of the White radiation spectrum from a tungsten anode at 30
KeV constant potential d.c. after penetrating through various depths of
tissue.
FIG. 7 includes schematic curves showing the changes in the intensity
distribution of the White radiation spectrum from a tungsten anode at 25
KeV constant potential d.c. after penetrating through various depths of
tissue.
FIGS. 8A to 8J illustrate short X-ray micro-tube designs.
FIG. 8A illustrates a short micro-tube with a heated filament cathode.
FIG. 8B illustrates a short micro-tube with a cold cathode electron
emitter.
FIG. 8C illustrates a very short micro-tube having the cathode and anode
positioned on the same end, with an internal glass tube for insulating the
anode connecting wire.
FIGS. 8D(a) and 8D(b) illustrate the use of a thin internal anode film on
the inside of the glass tube through which X-rays can penetrate to produce
a cylindrical transmitted X-ray beam.
FIGS. 8E(a) and 8E(b) illustrate the use of a thick internal anode film on
the inside of the glass tube, the resulting back-scattered X-ray beam
producing a hemicylindrical X-ray pattern.
FIGS. 8F(a) and 8F(b) illustrate the use of a thin internal anode film on
the inside of the glass tube resulting in a hemicylindrical transmitted
X-ray pattern.
FIG. 8G illustrates a short micro-tube with a spot-type anode (thick or
thin).
FIGS. 8H(a) and 8H(b) illustrate the use of a thin internal hemispherical
anode film used to produce a hemispherical X-ray pattern.
FIG. 9 illustrates a long micro-tube design with an enlarged end for
evacuation and sealing.
FIG. 10 is a schematic illustration of a short liquid-cooled microtube
assembly.
FIG. 11 is a schematic illustration of a short metal-jacketed microtube
assembly.
The same elements or parts throughout the figures of the drawings are
designated by the same reference characters.
DETAILED DESCRIPTION OF THE INVENTION
An understanding of X-ray interaction with tumors requires some background
understanding of the physical phenomena involved. Electromagnetic
radiation extends over a very wide range of wave lengths, i.e. from radio
waves (3.times.10.sup.4 m to 5 m), microwaves (5.times.10.sup.-2 m to
1.times.10.sup.-4 m), infrared (1.times.10.sup.-4 m 7.times.10 .sup.-7 m),
visible (7.times.10.sup.-7 m to 4.times.10.sup.-7 m), ultra-violet
(4.times.10.sup.-7 m to 1.times.10.sup.-8 m), X-rays and gamma rays
(1.times.10.sup.-8 m to 1.times.10.sup.-14 m). The wave lengths of X-rays
are frequently expressed in angstroms (.ANG.) with 1 .ANG. being equal to
10.sup.-8 cm. These selected wave length bands of radiation have been
classified as ranges which interact with matter in familiar ways. The
value of the wavelength determines the size of an object with which the
electromagnetic radiation will react. Radio waves will react with large
electrical conductors, visible and ultra-violet light react with the outer
shell electrons in atoms, and X-rays interact with the innermost orbital
electrons. The shorter the wavelength the higher the energy of the
radiation. The reciprocal of the wavelength is the frequency, with the
wavelength commonly being represented by the symbol .lambda., and the
frequency by the Greek letter .nu.. The energy, E, is equal to .nu.,
where is Planck's constant.
The nature and properties of the radiation within the X-ray band vary with
the energy (or wavelength) of the X-ray, just as the characteristics of
the light in the visible range vary with the wave length of the radiation,
the shorter wave lengths appearing as blue colors and the longer ones as
orange-red colors. A brief discussion of how the different wave lengths of
X-rays are produced and how they differ in their interactions with body
tissues provides an understanding of the uniqueness and value of the
present invention.
Medically useful X-rays are normally produced in evacuated tubes (usually
made of glass) containing two elements, a cathode and an anode. The
cathode is typically a tungsten filament that is heated to a temperature
sufficiently high to cause electrons to reach velocities permitting them
to escape from the filament. The escaping electrons are attracted to the
anode at the opposite end of the tube (also typically formed of tungsten),
which exists at a high positive potential, commonly in the range of 50,000
to 2 million volts.
The electrons are accelerated during their passage toward the anode,
reaching a high velocity before colliding with the anode and causing inner
shell electrons to be ejected from the tungsten atoms. When the high
energy ejected electrons return to normal positions in electron shells,
X-rays are created. The energy gained by the participating electrons is
measured in electron volts (eV) where e is the electrical charge of the
electron and V is the voltage difference between the cathode and the
anode. This measurement of energy is commonly used in the field of X-ray
diagnosis and therapy. (For the purpose of comparison, one electron volt
of energy per atom is equivalent to 23 kilocalories per mole of atoms).
In the X-ray range of wave lengths, several different phenomena occur when
matter is exposed to X-rays. These phenomena are known as Elastic (or
Coherent) Scattering, Photoelectric Absorption, Compton Scatter, and
Electron Pair Production (one electron and one position). When the energy
of the photon is less than the binding energy of the outer shell electrons
of the exposed material, the photons cause the orbiting electrons to
oscillate in phase with the X-ray and thus to emit electromagnetic
radiation of the same frequency as the incident ray. The re-radiated
X-rays are scattered with no absorption in the irradiated matter. This
phenomenon, called Elastic or Coherent Scattering, is of no consequence in
X-ray diagnosis or therapy. Electron Pair Production only occurs at
extremely high energies i.e., above one million electron volts (1 MeV),
which is much higher than the energies used in this invention. Thus, these
two phenomena will not be further discussed herein.
Photoelectric Absorption is the dominant form of X-ray absorption only in
the lowest range of X-rays (e.g. 10 to 60 kilovolts). It occurs when the
energy of the X-ray photons is equal to the energy binding the innermost
shell electrons of the atoms in the exposed matter. In this case, the
X-ray photons interact with the electrons orbiting closest to the nucleus,
causing them to be ejected from the atoms, and causing the photons to
loose all of their energy and disappear. This reaction cannot occur at
X-ray beam energies below the electron-atom binding energy. It is a
maximum when the two energies are equal, and decreases rapidly with
increasing X-ray energy above the maximum value.
Absorption of higher energy X-ray radiation (e.g. above 100 KeV) occurs
almost entirely by Compton Scattering. This process involves the
interactions of X-ray photons with any of the electrons in the cloud
surrounding the nucleus of the interacting atom. In this case, an incident
photon loses only part of its energy when it reacts with an electron,
which acquires the energy lost by the photon and is ejected from the
electron cloud of the atom. The resulting photon with diminished energy is
scattered and moves forward at some angle to the line of the incident
beam. The energy of the scattered photon is not absorbed locally within
the exposed material during this event, but the energy acquired by the
participating electron is completely absorbed within the material. Thus,
the energy change of the incident X-ray beam is divided into two parts,
only one of which is directly absorbed.
Between 10 KeV and 100 KeV the absorbed fraction of Compton energy
increases from a low value at 10 KeV, finally reaching a high value at 100
KeV, thereafter changing by a relatively small amount in the range between
100 KeV and 1 MeV as shown on the mass absorption coefficient vs energy
curves in FIG. 1. (FIG. 1 is prior art adapted from "Principles of
Radiological Physics" by Robin J. Wilkes. Second Edition, Pg. 483.
Churchill Livingstone, New York. 1987.) In this figure there are curves
showing how the absorption of X-rays by tissue and bone vary with photon
energy. Below about 50 KeV energy (in the Photoelectric Absorption range),
bones absorb about 13 times as much of the incident energy as does tissue.
Above about 100 KeV (in the Compton range) the difference is very small,
with bone absorption being only about 1.7 times as much as tissue. The
higher energy range is generally used for cancer therapy.
The photoelectric absorption of 10 KeV X-rays by tissue is very high, but
the absorption coefficient decreases drastically as the energy is
increased. At 50 KeV the absorption coefficient has decreased to about one
percent of the 10 KeV value. In the 10 KeV to 50 KeV range in which
Photoelectric Absorption is dominant. These lower energy X-rays penetrate
only short distances into tissue and consequently this is not normally
considered to be useful range for either medical diagnosis or therapy. It
is common practice in radiation therapy to remove as much as possible of
this skin damaging radiation from the X-ray beam. This is accomplished by
inserting thin sheets of aluminum or copper in the path of the beam to
absorb as much as possible of the low energy component of the beam. The
present invention makes it possible to utilize some of the X-rays in this
low energy range to treat some easily accessible cancerous tissue more
effectively than the higher energy methods now in use, but without the
sometimes severe damage to normal body tissue that occurs with currently
used practices.
Before entering into the detailed description of the new method and
equipment which are the subject of this invention, a brief description of
some of the well known characteristics and methods of utilizing X-rays is
considered. For example, traditional plots of absorption coefficients
versus X-ray energies, such as illustrated in FIG. 1, refer to
monochromatic X-rays, whereas the radiation from an X-ray tube actually
comprises a broad spectrum of energies, as illustrated by FIG. 2. (FIG. 2
is prior art adapted from "X-Ray Metallography" by A. Taylor, pg. 18, John
Wiley and Sons, New York, 1961.)
In this figure relative (X-ray) intensity is plotted against (X-ray) energy
for various constant d.c. tube voltages, and spectral curves of
Bremsstrahlung or White radiation are thus produced. The shapes of these
curves are affected by tube potential. The shapes of the curves are also
affected by the nature of the power source. Depending upon the design of
the power supply, the output may be constant d.c., a half-wave rectified
a.c., or a full wave rectified a.c.. The maximum intensities and the X-ray
energy distribution will be different for each type of power source. Also,
it must be remembered that the mass absorption coefficient for tissue
varies sharply with the energy (or wave length) of the X-ray, as shown in
FIG. 1. In reality, then, the effective absorption coefficient for a beam
consisting of a broad spectrum of X-rays is the fraction of the beam that
is absorbed during the passage of the beam through one centimeter of
material and is composed of two parts: one being the component contributed
by Photoelectric Absorption, and the other being due to the Compton
effect.
FIG. 3 shows examples of approximate depth of penetration curves (i.e. the
distance through material which causes a specific decrease in the X-ray
intensity to, for example, 1/2, 1/4, 1/10 etc. of the initial beam
intensity. I is the intensity, while I.sub.o refers to the initial
intensity.) The values shown in this figure are for monochromatic
radiation. From accurate plots of the mass absorption coefficients,
.mu./.rho., versus energy curves shown in FIG. 1, the linear absorption
coefficient, .mu., needed for calculating the decrease in X-ray intensity
versus penetration distance, as shown in FIG. 3, can be obtained by
assuming that the density, .rho., of tissue used for defining mass
absorption coefficient, .mu./.rho., is equal to 1. FIG. 3 highlights the
fact that in the 10-50 KeV range X-rays simply do not penetrate very far.
As an example of the method used to obtain the curves in FIG. 3, assuming
the voltage to be 50 KeV, the value of I/I.sub.o =0.5, and .mu., the
absorption coefficient=0.24, the interrelationship of these parameters is
given by I/I.sub.o =e.sup.-.mu.x where x is the penetration distance below
the surface of the absorbing material (x is a negative number).
Substituting the numbers given above in the equation yields a value of x
of 2.87 cm (corresponding to the value for the x=2.87 cm at 50 KeV and 50%
absorption in FIG. 3).
The actual radiation being emitted from the anode on an X-ray tube with,
for example, 50 kilovolts applied potential, is actually a whole spectrum
of radiant energies, producing what is commonly called "white" radiation.
This is illustrated in FIG. 2, which shows the distribution of energies
(in KeV) for a tube with a tungsten anode, when exposed to various
constant tube voltages. In spectra of this sort, each individual value
would have an absorption coefficient differing from those of the other
energies in the spectrum. The variation in absorption coefficients within
the spectrum must be taken into account when effective absorption is
calculated for the beam. In the lower end of the voltage range, i.e.,
below about 50 KeV tube voltage, the absorption coefficients may vary by
more than 100 to 1 (see FIG. 1). However, in the higher voltage range
currently in general use (i.e., about 100 KeV to 1 MeV) the absorption
coefficient is relatively constant. With white radiation in the energy
range of this invention, then, both the absorption coefficient and the
X-ray intensity are strongly dependent upon the energy of the photons
involved. For example, the mass absorption coefficient for tissue varies
from about 0.33 for 37 KeV to 3.3 at 12 KeV.
FIGS. 4, 5, 6, and 7 show intensity decreases in the initial intensity
values for white radiation from a tungsten anode X-ray tube at different
tube potentials, as the beam penetrates into tissue. The shape of the
Relative Intensity versus Energy (KeV) curve changes as the distance from
the outer surface of the tissue being penetrated is increased. At each
X-ray energy level the absorption coefficient differs, as shown in FIG. 1,
with a much higher fraction of the lower X-ray energy components of the
white radiation beam being absorbed than is the case for the higher energy
components. The curves in FIG. 4 illustrate this effect at various depths
in tissue.
Examples of how and why the shapes of the white radiation energy
distribution curves change at different depths in tissue will be helpful
in understanding the curves plotted in FIGS. 4, 5, 6, and 7. FIG. 4
illustrates examples of the nature of the changes that occur at a high
energy value within the 50 KeV generated white radiation spectrum, to
those of a low energy value of the same spectrum, by comparing initial
intensities on the I.sub.o curve to intensities on the same depth in
tissue curve.
In this example, let the high energy case be chosen as 42 KeV and the low
energy be selected as 20 KeV. For the high energy case (42 KeV), let:
I.sub.o =5.5 (from FIG. 4), .mu.=0.32 (from FIG. 1), and x=1 cm.
By rearranging the formula, I/I.sub.0 =e.sup.-.mu.x, we can solve for the
value of I at 1 cm using our parameters:
I.sub.1 cm =I.sub.0 e.sup.-.mu.x
I.sub.1 cm =5.5e.sup.-(0.32)(1)
I.sub.1 cm =5.5/1.38
I.sub.1 cm =4which is shown on FIG. 4.
Now, for the low energy case (20 KeV), let: I.sub.0 =9.5 (from FIG. 4),
.mu.=0.87 (from FIG. 1), and x=1 cm.
In this case, we have:
I.sub.1 cm =9.5e.sup.-0.87
I.sub.1 cm =9.5/2.38
I.sub.1 cm =4, which is shown on FIG. 4.
This demonstrates that for equal intensities at a penetration depth of one
centimeter, the initial intensity, I.sub.0, had to be only 5.5 for the
higher voltage (42 KeV) while the I.sub.0 value for 20 KeV had to be much
higher at 9.5. Thus, FIG. 4 further highlights the advantage of the use of
these low energy X-rays. They do not penetrate very far. The low energy
portions of the spectra illustrated in FIG. 4 are almost entirely absorbed
at 3 cm.
FIGS. 5-7 are generated in the same manner as FIG. 4 but for constant
potential d.c. voltages of 40 KeV, 30 KeV, and 25 KeV, respectively.
Information of this kind is necessary for determining suitable voltages
for treating tumors of different varieties and sizes while minimizing
damage to nearby tissues.
The micro-tubes are similar in principle to standard X-ray tubes except
that they are much smaller and require only a small fraction of the tube
current required in conventional commercial machines (i.e. microamperes vs
milliamperes). The physical size of a tube can be a fraction of an inch in
diameter and with a length as small as one-half of an inch, to as long as
several inches. A variety of useful tube designs is possible.
Referring now to FIG. 8a, a schematic illustration of an embodiment having
a filament cathode is shown, designated generally as 20. An evacuated
glass tube 22 contains a stable vacuum of at most 10.sup.-6 Torr. A heated
filament cathode 24 (preferably a small tungsten filament) and an anode 26
are provided which are connected to an appropriate power source (as will
be discussed below). The anode 26 can be made of any one of a number of
different metals typically used, but tungsten is preferred (as it is in
conventional commercial tubes).
Referring to FIG. 8b, a second type of X-ray tube that is suitable for
micro-tube use is schematically illustrated, designated generally as 28.
Tube 28 is a cold emission (or field emission) cathode tube (which has no
filament). The electrons are emitted from a sharply pointed electrode 30,
preferably formed of tungsten. A very high potential gradient develops
between the sharply pointed tip of the electrode and the anode 32 when a
high voltage is applied across the X-ray tube 28. For micro-tube use in
radiation oncology, use of a cold electron emitter tube has some
advantages. This type of tube is simpler to make in smaller sizes than the
heated filament type.
The depth of penetration of the present X-ray microtubes can be easily
controlled by varying the tube voltage. The total desired radiation
exposure can be controlled by selecting an appropriate time of exposure. A
great advantage of the micro-tube is that it can be placed on or very near
the surface of the tumor, or within the tumor, so that radiation damage to
normal tissue is minimized.
The source to tumor distance for the micro-tubes, therefore, is extremely
small compared with the source to skin distance (SSD) of 20 to 50
centimeters with the X-ray units now in common use. Since the intensity of
the X-ray beam varies inversely with the square of the distance from the
beam source, for a given tube voltage, the same effective intensity of the
X-ray beam at the site of a tumor can be produced by the micro-tube with
about one one-thousandth of the current required for the proper operation
of a large external tube. Therefore, the present invention operates in the
low microampere range, rather than the low milliampere range required for
currently used large tubes.
Micro-tubes are relatively inexpensive and may be manufactured to be
re-sterilized or disposable. The exterior surface of the tube is
preferably covered with a thin tough biocompatible plastic material, as
will be described below, to guard against damage to handlers or patients
should accidental breakage of the glass tube occur. The plastic tube cover
can also have a built-in water coolant jacket to dissipate the small
amount of heat generated by the tube (operating at a small fraction of a
watt).
The power supply required is relatively simple and inexpensive because of
the low current required (microamperes vs conventionally used
milliamperes) and because of the relatively low tube voltages required
(generally less than 60 kilovolts compared 60 kilovolts to one million
volts for conventional equipment). Aside from the micro-tube itself, only
state of the art equipment is necessary. However, one difference in detail
is necessary. Conventional 60 cycle a.c. destroys the many normal nerve
functions. The inventive concepts of the present invention provide for use
of a frequency that would be sufficiently high so that the normal nerve
functions of the body would not be affected if an inadvertent contact of
the high voltage lead with body tissue did occur. The use of high
frequency currents in electrosurgical cutting and coagulation machines is
common and has long been known to be safe (see, for example, U.S. Pat. No.
3,699,967, entitled "Electrosurgical Generator", and Chapter 3,
Electrosurgery, Handbook of Biomedical Engineering, 1988, Academic Press).
Furthermore, use of such high frequencies provides the ability for the
patient to act as a conduit for return of the anode current back to the
power supply if that anode is not directly connected to the power supply.
FIG. 8C illustrates the placement of the anode 34 and the cathode 36 on the
same side of a microtube 38 to accomplish a reduced length. An internal
glass tube 40 is used to support the anode 34 and to insulate the anode
connecting wire 42.
The micro-tubes of the present invention may be manufactured in a variety
of different ways to optimize their use. For example, in FIG. 8D(a) a
glass micro-tube 42 is illustrated with a thin internal anode film 44
formed on its inner surface (preferably vacuum deposited tungsten). An
axially extending filament cathode 46 is provided. Thus, when operated, a
cylindrical X-ray pattern, illustrated by the arrows 48 in FIG. 8D(b),
results. This design is particularly useful if the micro-tube is desired
to be inserted near the center of the tumor.
FIGS. 8E(a) and 8E(b) illustrate a relatively thick film anode 50 deposited
or otherwise formed on portions of the inside of the glass tube 52. This
results in a backscattered X-ray beam which produces a hemicylindrical
X-ray pattern, as illustrated by arrows 54. The X-ray pattern is
established at portions of the micro-tube which do not have the thick film
formed thereon.
In the micro-tube illustrated in FIG. 8F(a) and 8F(b) a thin anode film 56
is formed on only a portion of the micro-tube 58. This results in a
hemicylindrical X-ray pattern 60.
An alternate anode design is illustrated in FIG. 8G, the micro-tube being
designated as 62. In this instance, the anode 64 is a spot type of thin or
thick film.
In FIGS. 8H(a) and 8H(b) a hemispherical X-ray pattern 66 results from
formation of an anode film 68 near the end of the micro-tube 70.
The short micro-tubes illustrated in FIGS. 8A-8H are typically from
one-fourth inch to two inches in length, preferably approx. 1/2".
Diameters may range from 1/8" to 1", preferably 1/4". As noted, these
microtubes may be placed in-situ by a number of methods, including,
implantation during surgery; insertion through a normal body orifice;
insertion in conjunction with a fiber-optic scope through a normal body
orifice; insertion in conjunction with a fiber-optic scope through a
surgical incision; insertion through a trocar catheter; or insertion
through a catheter contained within a surgical incision. The micro-tubes
may also be placed adjacent to the body next to the skin.
Longer micro-tubes may alternately be used which may be up to several
inches (i.e. 2"-8") in length. FIG. 9 illustrates a schematic of a design
of such a long micro-tube 72. The lead wire 74 for the cathode 76 and the
lead wire 78 for the anode 80 connect to a power supply (not shown). Long
micro-tube 72 is particularly useful in the brain and is made thin, for
example, in the range of 1/8" to 1/4" in diameter. End 82 is enlarged and
extends outside of the body, serving as a "compass" for accurately
rotating the micro-tube and directing the X-rays in the desired manner. It
is understood that the various features shown in the previous Figures may
be implemented in the longer tubes of FIG. 9. Further, it is understood
that FIGS. 8 and 9 are meant only to be schematic representations of
possible micro-tube designs. Obviously, biocompatible safety shields would
be utilized to enclose the tubes in actual applications.
The principles of the present invention are preferably implemented with the
micro-tubes being used as part of a mechanically shielded and electrically
insulated assembly. Referring now to FIG. 10, such an implementation in
the form of a short liquid-cooled micro-tube assembly, designated
generally as 84, is illustrated. Liquid-cooled micro-tube assembly 84
includes a filament cathode 86 supported by a filament support structure
88 within an evacuated glass tube 90. Similarly, an anode 92 is supported
by another filament support structure 94 within the evacuated glass tube
90. Glass tube 90 may be formed as described in the above-discussion
regarding FIGS. 8 and 9. Glass tube 90 is positioned within a liquid
coolant chamber 96 which is supplied by coolant hoses 98,100. (Water would
be a suitable coolant. The walls of the coolant chamber may be formed of,
for example, glass or plastic). Coolant chamber 96 is, in turn, enclosed
within the main housing 102 of the micro-tube assembly 84. Housing 102 is
preferably formed of plastic. Filament lead wires 104,106, anode lead wire
108, and coolant hoses 98,100, extend through the main housing 102. These
five elements are preferably radially spaced and separated by walls to
confine any leaks to a specific portion of the assembly. Dashed lines 110
schematically illustrate these walls. Additionally, approximately water
seals 112 are provided.
A metal-jacketed micro-tube assembly, designated generally as 114, is
illustrated in FIG. 11. Assembly 114 includes a cathode 116 supported by a
cathode support structure 118 within an evacuated glass tube 120.
Similarly, an anode 122 is supported by another support structure 124
within the evacuated glass tube 120. Glass tube 120 is contained within a
metal jacket 126. Tube 120 may be formed as described in the
above-discussion regarding FIGS. 8 and 9. A window 128 is provided in the
metal jacket 126 for directing the radiation in the desired manner. Anode
and cathode cables 130,132 including lead wires are provided for
attachment to an external power source (not shown).
The power supply needed for X-ray micro-tube operation is unique in that it
is a low energy device that can be made easily portable and is less costly
to make than those now supplied with deep therapy equipment, which require
much higher levels of energy. Modern electronic designs and equipment
capable of providing the currents and voltages needed for the operation of
the micro-tubes are state of the art, and a variety of designs are
available. Another essential feature of the invention is that the power
supply circuit must contain a rapidly acting safety circuit interrupter
that will immediately operate should anything happen to cause the tube
current to suddenly increase to, for example, one milliampere, which is
still very safe for a patient but undesirable for micro-tube operation.
Obviously, many modifications and variations of the present invention are
possible in light of the above teachings. It is therefore to be understood
that, within the scope of the appended claims, the invention may be
practiced otherwise than as specifically described.
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