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What is claimed and desired to be secured by Letters Patent of the United
Patent is:
1. An apparatus for the localization of cancerous tumors found in animal or
human tissue, wherein said cancerous tumors have absorbed a tumor-specific
marker, said apparatus comprising:
an optical excitation means for selectively radiating a portion of said
tissue with excitation light in the red wavelength band;
an optical detection means for detecting infrared fluorescence emitted by
said tumor-specific marker, wherein the detection of said infrared
fluorescence emissions identifies the presence of cancerous tumors in said
radiated tissue; and,
an indicator means, connected to said optical detection means for alerting
the physician when said infrared fluorescence emission is detected.
2. The apparatus of claim 1, wherein said optical excitation means further
comprises:
an excitation source for generating light; and,
a delivery guide means for selectively radiating a portion of said tissue
with light from said excitation source.
3. The apparatus of claim 2, wherein said optical detection means further
comprises:
a return guide means for collecting light emitted from said radiated
tissue;
a filter means for selectively allowing the passage of the infrared
component of light collected by said return guide means;
a photodetector means for detecting the intensity of said infrared
component and for generating a corresponding electrical signal; and
a signal processing means operably connected to said photodetector means
for amplifying and processing said electrical signal generated by said
photodetector means.
4. The apparatus of claim 3, wherein said indicator means connects to said
signal processing means for producing an acoustical signal for alerting
the physician when said infrared fluorescence emissions are detected.
5. The apparatus of claim 3 wherein said indicator means connects to said
signal processing means for producing a visual signal for alerting the
physician when said infrared fluorescence emission is detected.
6. The apparatus of claim 1 or 3, wherein frequency of said excitation
light is selected to optimize optical transmittance through said tissue
and absorption by said tumor-specific marker, thereby causing fluorescence
of said tumor-specific marker located at a maximum depth beneath said
tissue surface.
7. The apparatus of claim 3, wherein said filter means allows the passage
of an infrared diagnostic frequency band, said frequency band selected to
provide sufficient spectral separation enabling said optical detection
means to distinguish said infrared fluorescence emission from said
excitation light reflected from said tissue.
8. The apparatus of claim 7, wherein said diagnostic frequency band is
further selected to optimize optical transmittance through said tissue and
the integrated infrared fluorescence signal.
9. The apparatus of claim 8, wherein said diagnostic frequency band is
9,000-13,000 .ANG..
10. The apparatus of claim 1, wherein said excitation light is in the
6,200-6,400 .ANG. band.
11. The apparatus of claim 10, wherein said infrared fluorescence emission
is detected in the 9,000-13,000 .ANG. band.
12. The apparatus of claim 1, wherein said optical detection means detects
the infrared fluorescence at a particular diagnostic frequency band, said
diagnostic frequency band selected to provide sufficient spectral
separation from said excitation light, thereby enabling said optical
detection means to distinguish said infrared fluorescence emissions from
said excitation light reflected from said tissue.
13. The apparatus of claim 11, wherein said diagnostic frequency band is
further selected to optimize optical transmittance through said tissue by
said infrared fluorescence.
14. An apparatus for the localization of cancer tumors found in animal or
human tissue, wherein said cancer tumors have absorbed a tumor-specific
marker, said apparatus comprising:
an excitation source for generating long wavelength red light;
a delivery guide means for selectively radiating a portion of said tissue
with light from said excitation source;
a return guide means for collecting light emitted from said radiated
tissue;
a filter means for selectively allowing passage of an infrared diagnostic
band of infrared light collected by said return guide means;
a photodetector means for detecting the intensity of infrared light passing
through said filter means and for generating a corresponding electrical
signal;
a signal processing means operably connected to said photodetector means
for amplifying and processing said electrical signal generated by said
photodetector means and for generating an output signal in response to
detecting infrared fluorescence emitted by said tumor-specific marker;
and,
an indicator means operably connected to said output of said signal
processing means for alerting the physician when said infrared
fluorescence emission is detected.
15. The apparatus of claim 14, wherein said infrared diagnostic band is
selected to provide sufficient spectral separation from said long
wavelength red excitation light, thereby enabling said photo detector to
be substantially responsive to said infrared flourescence emitted by said
tumor-specific marker.
16. The apparatus of claim 14, wherein said infrared diagnostic band is
9,000 thru 13,000 .ANG..
17. The apparatus of claim 14, wherein said indicator means provides an
audio output alerting the physician when said infrared fluorescence
emission is detected.
18. The apparatus of claim 14, wherein said indicator means provides a
visual output alerting the physician when said infrared fluorescence
emission is detected.
19. The apparatus of claim 14, wherein said excitation source produces
pulsed emissions of said red light, and wherein said signal processing
means is a box car integrator.
20. The apparatus of claim 14, wherein said excitation source provides a
continuous emission of said red light, and wherein said signal processing
means further comprises:
a beam splitter in association with said excitation beam for spacially
separating a component of said beam;
a reference photodiode for detecting the amplitude of said excitation
source; and,
a lock-in-amplifier, connected to said reference photodiode and said
photodetector means for providing an output signal in response to the
detection of an infrared emission signal collected by said return guide
means.
21. The apparatus of claim 14, wherein said delivery guide means and said
return guide means each connect to a separate fiberoptic delivery system
used in association with a diagnostic radiator.
22. The apparatus of claim 21, wherein said diagnostic radiator is an
endoscope.
23. A method for the localization of cancer tumors found in animal or human
tissue, said method comprising the steps of:
injecting a patient with a tumor-specific marker;
photoradiating a portion of said tissue with excitation light in the red
wavelength band;
optically detecting the intensity of infrared fluorescence emitted by said
tumor-specific marker, wherein the detection of infrared fluorescence
emissions identifies the presence of cancerous tumor in said radiated
tissue; and,
alerting the physician when said infrared fluorescence emissions are
detected.
24. The method of claim 23, wherein said excitation light is in the
6,200-6,400 .ANG. band.
25. The method of claim 23, wherein said step of optically detecting
further comprises the steps of:
collecting light emitted or reflected by said photoradiated tissue;
filtering said collected light so as to only allow passage of light in an
infrared diagnostic frequency band, said diagnostic frequency band
selected to provide sufficient spectral separation from said excitation
light, to allow resolution and detection of said infrared fluorescence
emissions.
26. The method of claim 25 wherein said diagnostic frequency band is
9,000-13,000 .ANG..
27. The method of claim 23, wherein said tumor-specific marker is chosen
from a group consisting of water soluble porphyrins.
28. The method of claim 23, wherein said tumor-specific marker is
hematoporphyrin (HP).
29. The method of claim 23, wherein said tumor-specific marker is
hematoporphyrin derivative (HPD).
30. The method of claim 23, wherein said tumor-specific marker is chosen
from the group consisting of:
hematoporphyrin (HP)
hematoporphyrin derivative (HPD)
tetra carboxyphenylporphine (TCPP)
tetraphenylporphinesulfonate (TPPS)
protoporphyrin
coproporphyrin
uroporphyrin.
31. The method of claim 23, wherein said tumor-specific marker is chosen
from the group consisting of: riboflavin, fluorescein, acridine orange,
tetracyclines and berberine sulfate. |
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Description |
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BACKGROUND OF THE INVENTION
1. Field of the Invention
This invention comprises an improved apparatus and method for localizing
cancer tumors on or near the tissue surface based on the use of long
wavelength visible or near infrared excitation of intravenously injected
porphyrins and monitoring the resultant infrared fluorescence.
2. Description of the Contemporary and/or Prior Art
There is a great deal of concern and interest in the medical and scientific
community that an improved means to detect cancerous tumors be devised. In
order to decrease the death rate due to cancer, early diagnosis,
localization, and therapy must be undertaken. Early detection of tumor
lesions of only a few millimeters in extent and 100 micrometers thick is
possible by sputum cytology and immunodiagnostic procedures. However, such
small preinvasive lesions are not localizable by conventional radiography,
computer tomography or nuclear medicine techniques.
It is currently known that when certain porphyrin preparations, such as
hematoporphyrin (HP) or hematoporphyrin derivative (HPD), are injected
intravenously into the human body, they are selectively retained by
cancerous tissue. Two or three days after injection, significantly higher
levels of hematoporphyrin are retained in cancerous tissue. The selective
retention of porphyrins, such as hematoporphyrin, by cancerous tissue has
been used clinically as a "tumor-specific marker". It is known in the
prior art that in the presence of ultraviolet or short wavelength visible
light, the "tumor-specific marker" absorbed by the cancerous tissue will
exhibit a bright red light fluorescence while normal tissue appears light
pink.
A discussion of clinical investigations using the visible fluorescence of a
"tumor-specific marker" to localize malignant tissue can be found in an
article entitled "Hematoporphyrin Diacetate: A Probe to Distinguish
Malignant from Normal Tissue by Selective Fluorescence" by R. W.
Henderson, G. S. Christie, P. S. Clezy and J. Lineham, British Journal of
Experimental Pathology, Volume 61, pp. 325-350 (1980). Another reference
by D. R. Doiron and A. E. Profio entitled "Laser Fluorescence Bronchoscopy
for Early Lung Cancer Localization" published in "Lasers in Photomedicine
and Photobiology" (1980) teaches the use of a laser fluorescence
bronchoscope to detect and localize small lung tumors by observing this
red fluorescence.
Such prior art techniques have been used to develop endoscopes which use,
in addition to the normal viewing white light, a supplementary violet
light (at approximately 4200 .ANG.). The violet light is used to excite
hematoporphyrin or hematoporphyrin derivative, the tumor-specific markers
which are dissolved in an appropriate buffer solution and intraveneously
injected into the patient. The porphyrin tumor-specific marker is
selectively retained by cancerous tissue and when exposed to the violet
light emits a relatively bright red light fluorescence (at approximately
6,000-7000 .ANG.), whereas the surrounding tissue emits only weakly.
Similar techniques have been used to localize malignant tissue in the
spleen, liver, bladder, kidney, and lungs.
The prior art techniques have one major limitation--only tumors on or near
the tissue surface may be detected due to the high transmission loss of
the short wavelength violet excitation light. This transmission loss is
due to both absorption and scattering of the light by the patient's tissue
and/or skin. Tumor lesions occluded by healthy tissue are not detectable
using the prior art techniques.
SUMMARY OF THE INVENTION
Previous investigators did not realize that the fluorescence spectrum of
porphyrins, such as hematoporphyrin or hematoporphyrin derivative, extends
into the infrared band. An article by A. A. Krasnovsky, Jr. entitled
"Photosynthesized Luminescence of Singlet Oxygen in Aqueous Solutions"
printed in BIOFIZIKA 24: No. 4, pp. 747-748, 1979, describes long
wavelength tails of emissions being present in aqueous solutions of
riboflavin. However, Krasnovsky did not know whether the emissions were
due to the fast fluorescence or (time delayed) phosphorescence of
riboflavin.
The present inventors were the first to identify the origin of the long
wavelength tail as a fluorescence emission and apply that observation in
developing a method and apparatus of carcinoma localization. The present
inventors while studying the generation of singlet oxygen by
photoradiating hematoporphyrin and observing emissions in the 1.27 band,
discovered infrared emissions consisting of: (1) a prompt fluorescence
component of temporal duration equal to the laser exciting pulse of 10
nanoseconds: and, (2) followed by a temporally delayed, relatively slowly
decaying, component due to radiative transition of singlet oxygen. Further
research by the present inventors indicated that the prompt (or fast)
fluorescence extended from the visible band (red light) into the infrared
band (in excess of 14,000 .ANG.). The infrared fluorescence component has
the same origin, (i.e., fluorescence of the porphyrins) as did the red
visible light known to other investigators. The overall fluorescence
spectrum of porphyrins, such as hematoporphyrin or hematoporphyrin
derivative, may thus be regarded as a superposition of a visible line
spectrum and a continuous spectrum extending from 6,000 .ANG. to
substantially in excess of 14,000 .ANG..
The inventors recognized that detecting the presence of a porphyrin
tumor-specific marker, such as hematoporphyrin or hematoporphyrin
derivative, retained by the cancerous tissue could be enhanced, if the
infrared portion of the fluorescence emission spectrum were used as
opposed to the visible portion of the spectrum as used in the prior art.
Use of the infrared emission spectrum allows the inventors to choose an
excitation frequency band and a diagnostic frequency band which are
physiologically selected to deliver maximum optical signal penetration
into human or animal tissue. The prior art technique used a violet
excitation light primarily because of its spectral separation from the
known visible fluorescence band (6,200-7,500 .ANG.). Spectral separation
is necessary so that the fluorescence diagnostic signal, which is
temporally co-existent with the excitation pulse, can be resolved and
detected.
The invented technique thus allows the selection of excitation and
diagnostic bands having minimal transmission losses through human and
animal tissue. For example, red light (6,200-6,400 .ANG.) could be used as
the excitation source and would provide significantly reduced transmission
losses compared to the prior art short wavelength or violet excitation
frequencies. Similarly, use of a diagnostic band at the infrared
wavelength of 9,000-13,000 .ANG. could be chosen to provide sufficient
spectral separation from the visible red excitation frequency and to
provide maximum signal transmittance through animal or human skin and
tissue.
The present invention thus discloses a method and apparatus for improving
the sensitivity and maximizing the penetration depth of fluorescent cancer
localization techniques. In the preferred embodiment, maximum tissue
penetration is provided by detecting fluorescence emission in the infrared
band in conjunction with a red light excitation source. This combination
will optimize signal penetration below the surface thus permitting
detection of occult tumors.
A first novel feature is the use of the fluorescence emission, generated by
porphyrin tumor-specific markers in the infrared portion of the spectrum,
as a means for localizing cancerous tissue having selectively absorbed the
tumor-specific marker.
A second novel feature is the selection of an excitation frequency
physiologically chosen to provide maximum signal transmittance, so that
tumor lesions occulted by healthy tissue can be detected and localized.
A third novel feature is the selection of an excitation frequency which
provides spectral separation between the execitation frequency and the
diagnostic band so that the diagnostic infrared emission signal can be
resolved and detected.
A fourth novel feature is the selection of a diagnostic band in the
infrared frequency range, physiologically chosen to provide maximum signal
transmittance, so that tumor lesions occulted by healthy tissue can be
detected and localized.
A fifth novel feature is a method and apparatus of carcinoma localization
based on the use of long wavelength visible (red) or near infrared
excitation of intravenously injected porphyrins, such as hematoporphyrin
or hematoporphyrin derivative, and monitoring the resultant infrared
fluorescence.
These features, as well as other objects and advantages of the present
invention, will become readily apparent after reading the ensuing
description of several non-limiting illustrative embodiments and viewing
the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a graph illustrating the absorption and fluorescence emission
spectrum for hematophorphyrin derivative (HPD), a typical porphyrin
tumor-specific marker.
FIG. 2 is an expanded graph showing the infrared fluorescence spectrum of
hematoporphyrin (HP), a typical porphyrin tumor-specific marker.
FIG. 3 is a graph showing the transmittance of a light beam through human
skin as a function of wavelength.
FIG. 4 is a block diagrammatic view of the present invention when a
substantially continuous excitation beam is used.
FIG. 5 is a block diagrammatic view of the present invention when a pulsed
excitation beam is used.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT
The absorption and fluorescence emission spectra for hematoporphyrin
derivative, a typical porphyrin tumor-specific marker, are illustrated in
FIG. 1. The absorption spectrum 10 has a peak at approximately 4,000
.ANG., the violet range, and then falls off at the upper end to a
frequency of approximately 7,000 .ANG.. The fluorescence emission spectrum
12 contains a superposition of a visible line spectrum 14 and a continuous
spectrum extending from 6,000 .ANG. into the infrared band 16 (in excess
of 14,000 .ANG.). The infrared portion of the spectrum 16, as observed by
the inventors, is shown by the dotted portion of the emission spectrum 12.
The prior art techniques irradiate the porphyrin tumor-specific markers at
their maximum absorption wavelength of 4,000 .ANG. (violet light) and
observe the porphyrin's visible red fluorescence at 6,000-7,000 .ANG.. The
prior art techniques select the excitation and diagnostic frequency for
maximum absorption of the excitation signal and maximum fluorescence
emission by the porphyrin. However, the prior art techniques do not
consider the frequency dependence of light transmission through human
tissue and/or skin. The present invention photoradiates the porphyrin with
visible red light 18 in the 6,200-6,400 .ANG. band. As we shall see later
in this application, this frequency is chosen to optomize signal
transmittance through human or animal tissue. The present invention
selects the infrared section of the spectrum between 9,000-13,000 .ANG. as
the diagnostic frequency band 20. This band is selected to optimize: (1)
spectral separation from the excitation frequency to allow resolution and
detection of the diagnostic infrared fluorescence; and, (2) transmittance
of the diagnostic infrared fluorescence through the particular tissue
and/or skin.
FIG. 2 illustrates an expanded view of the infrared emission spectrum for
hematoporphyrin, a typical porphyrin tumor-specific marker. The
fluorescent emission spectrum in the infrared band is a slowly decreasing
function of increasing wavelength which appears to be approximately a
straight line when plotted on semi-logarithmic graph paper. The discovery
of the infrared portion of the emission spectrum allows the inventors the
flexibility to select the excitation and diagnostic bands so as to
maximize signal transmittance through tissue.
FIG. 3 is a graph illustrating the transmittance of a light beam through
human skin as a function of wavelength. The signal transmittance, which is
reduced by absorption and reflectance of the tissue, directly increases
with frequency from the visible light band into the infrared band and then
rapidly falls off after 13,000 .ANG.. If the invented apparatus were used
to localize tumor lesions below the skin surface, the excitation and
detection band should be chosen to maximize signal penetration through the
skin. The excitation frequency would be chosen to optomize both optical
transmittance (see FIG. 3) and signal absorption by the porphyrin (see
FIG. 1). If hematoporphyrin is used as the tumor-specific marker and the
tumor is located the beneath skin, the red visible frequency band
(6,200-6,400 .ANG.) is advisable. Similarly, the diagnostic frequency band
is selected to: (1) assure sufficient spectral separation from the
excitation frequency so that the fluorescence diagnostic signal can be
resolved and detected; and, (2) choose a frequency band in the infrared
range which has maximum signal transmittance through the skin or tissue
and at the same time allows maximum collection of the fluorescent
emission. In the above example, with a red visible excitable beam the
inventors have found a fluorescence diagnostic band at 9,000-13,000 .ANG.
to be satisfactory.
It is to be understood, however, that different tissue or skin types will
have a different frequency dependent optical transmittance curve, and that
various porphyrin tumor-specific markers will have absorption and infrared
flourescence spectrums which differ slightly from that shown in FIGS. 1.
and 2. However, it is within the contemplation of this invention to use
the above-described method to select an excitation frequency band and an
infrared diagnostic frequency band so as to optimize the ability of the
present invention to penetrate below the skin or tissue surface thus
permitting the detection of occulted tumors.
Porphyrin other than the previously discussed hematoporphyrin (HP) and
hematoporphyrin derivative (HPD), can act as tumor-specific markers. To
qualify as a tumor-specific marker in accordance with the present
invention, any photosensitive dye may be used which satisfies the
following categorical requirements:
1. must be optically absorbing at wavelengths greater than 6,000 .ANG.;
2. must be non-toxic;
3. must be injectable into the blood stream, i.e., watersoluble;
4. must be selectively retained by cancerous tissue;
5. must exhibit significant infrared fluorescence.
Porphyrins which pass the above criteria and which have been used in
addition to hematorphyrin (HP) and hematorporphyrin derivative (HPD)
include, tetra carboxyphenylporphine (TCPP), tetraphenylporphinesulfonate
(TPPS), tetra (4-N-methylpyridil) porphin (TMPP), protoporphyrin,
coproporphyrin and uroporphyrin. It appears that water soluble (and thus
injectable) porphyrins as a group act as tumor-specific markers as taught
by the present invention although experimentation to date indicates that
hematoporphyrin (HD) and hematoporphyrin derivative (HPD) are the two most
promising candidates.
It will be noted that hematoporphyrin derivative (HPD) according to R.
Bonnett, R. J. Ridge, P. A. Scourides and M. C. Berenbaum, J. Chem. Soc.
Chem. Comm., pp. 1198-1199 (1980) is a multicomponent substance containing
the following basic components: acetylhematoporphyrin,
diacetylhematoporphyn and acetoxyethylvinyldeuteroporphyrin,
protoporphyrin, and tumor-sensitive marker.
Other types of photosensitive dyes which are of interest include
riboflavin, fluorescein, acridine orange, tetracyclines and berberine
sulfate.
FIGS. 4 and 5 illustrate, in block diagrammatic form, the invented
apparatus used to localize carcinoma lesions. The apparatus generally
contains: a source of excitation light 22 (generally in the red visible
frequency band) which can be either continuous or pulse modulated; a
delivery guide means 24 for directing the excitation beam to the
appropriate point within the patient's body (the delivery guide means may
include a fiber optical delivery system in association with an endoscope
such as described in U.S. Pat. No. 4,072,147 or a diagnostic radiator such
as described in U.S. Pat. No. 4,336,809 for injection in the tumor mass);
a return guide means 26 for collecting both the reflected excitation
signal and the infrared fluorescence emission from the porphyrin
tumor-specific marker; a filter means 28 for allowing the passage of
fluorescence emission in an appropriate portion of the infrared band; a
photodiode 30 which detects the infrared fluorescence; signal processing
means 32 operably connected to said photodiode 30 for providing an
electrical output signal varying as a function of the intensity of
infrared fluorescence; and, an audio and/or visual indicator 34 for
alerting the physician of the location of carcinoma lesions.
In operation, the patient is injected with a tumor-specific marker, such as
hematoporphyrin or hematoporphyrin derivative, which after two or three
days lapse time is selectively retained by malignant tissue. The delivery
guide means 24 and return guide means 26 are normally incorporated into a
double fiber optical delivery system used in association with a diagnostic
radiator or endoscope such as described in U.S. Pat. No. 4,072,147. The
endoscope type device is brought in proximity to the tissue which is to be
tested. The delivery guide means 24 causes a portion of the tissue area to
be illuminated by the excitation beam. The return guide means 26 normally
has a narrow beam width allowing the physician to determine if a
particular spot emits the infrared fluorescence associated with the
tumor-specific marker. The endoscope type device, normally contains a
viewing telescope allowing the physician to note the particular spot to
return guide means 26 is pointed towards. The audio or visual indicator 34
alerts the physician when an infrared fluorescent signal is detected. In
this manner, the physician scans the tissue area and in response to the
audio/visual indicator 34 locates malignant lesions.
FIG. 4 is a block diagrammatic view of the invented apparatus when a
substantially continuous excitation source is used. The apparatus
generally consists of: a CW laser 36, which in the preferred embodiment
generates an excitation beam at 6,300 .ANG.; a beam splitter 38 which
produces two spacial components of the excitation beam; a modulator 40,
such as an acousto-optic modulator for chopping the excitation beam; a
delivery light guide mean 24 and a return guide means 26 which, as
discussed previously, can be incorporated into a double fiberoptic
delivery system used in association with a diagnostic radiator or an
endoscope; a filter 28 which allows the passage of a selected portion of
the infrared fluorescence spectrum; a photodiode 30 which may be an InGaAs
diode, a germanium diode or a silicon diode; a second photodiode 42; a
lock-in amplifier 44 which receive as inputs electrical signals from
photodiode 30 and photodiode 42 and produces an output signal responsive
to the amplitude of the detected infrared fluorescence; and, an indicator
34 which generate an audio and/or visible signal to alert the physician
when a detected infrared fluorescence diagnostic signal is received by the
return guide means 26. It is to be understood that the CW laser can be
tunable to deliver an excitation beam having a frequency selectable for
maximum tissue penetration and also maximum dye absorption as taught by
the present invention. It is also to be understood that various
audio/video indicators may be used to alert the physician and various
delivery and return guide means can be used to deliver the excitation beam
and collect the infrared fluorescence emissions.
FIG. 5 is a block diagrammatic view of the present invention when a pulsed
or chopped excitation source is used. The apparatus generally consists of:
a tunable dye laser 46, providing an excitation beam (in the preferred
embodiment an excitation signal of 6,300 .ANG. is used); a delivery guide
means 24 and return guide means 29 for selectively radiating tissue with
the excitation beam and collecting any infrared fluorescence emitted from
said radiated tissue (as discussed previously, the delivery and return
guide means can be incorporated into a double fiber optical delivery
system used in association with a diagnostic radiator or an endoscope); a
filter 28 which allows the passage of a selected portion of the infrared
fluorescent spectrum; a photodiode 30, which may be a InGaAs or Silicon
based photodiode; a box-car integrator 48 (or transient recorder combined
with a signal averager) to amplify and process the electrical signal
produced by the photodiode 30; and, an indicator 34 which produces an
audio or visual signal when a detectable infrared fluorescence diagnostic
signal is collected by the return guide means 26. It is again to be
understood that the laser 46 may be tunable to deliver an excitation beam
having a frequency selectable for maximum tissue penetration as taught by
the present invention. It is also to be understood that various
audio/visual indicators may be used to alert the physician and various
delivery and return guide means can be used to deliver the excitation beam
and collect the infrared fluorescence emissions. It is also within the
inventors' contemplation to use a silicon vidicon in association with the
present invention to generate a visual display corresponding to the
infrared fluorescence emission pattern.
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 that the invention may be
practiced otherwise than as specifically described.
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