U.S. patent application number 11/036548 was filed with the patent office on 2005-06-30 for optical imaging of subsurface anatomical structures and biomolecules.
This patent application is currently assigned to Rocky Mountain Biosystems, Inc.. Invention is credited to Flock, Stephen T., Marchitto, Kevin S..
Application Number | 20050143662 11/036548 |
Document ID | / |
Family ID | 22746451 |
Filed Date | 2005-06-30 |
United States Patent
Application |
20050143662 |
Kind Code |
A1 |
Marchitto, Kevin S. ; et
al. |
June 30, 2005 |
Optical imaging of subsurface anatomical structures and
biomolecules
Abstract
The present invention provides various methods/systems of
optical imaging of subsurface anatomical structures and
biomolecules utilizing red and infrared radiant energy. Also
provided are various applications of such methods/systems in
medical diagnosis and treatment.
Inventors: |
Marchitto, Kevin S.; (Mt.
Eliza, AU) ; Flock, Stephen T.; (Mt. Eliza,
AU) |
Correspondence
Address: |
Benjamin Aaron Adler, Ph.D., J.D.
Adler & Associates
8011 Candle Lane
Houston
TX
77071
US
|
Assignee: |
Rocky Mountain Biosystems,
Inc.
|
Family ID: |
22746451 |
Appl. No.: |
11/036548 |
Filed: |
January 14, 2005 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
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11036548 |
Jan 14, 2005 |
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09848596 |
May 3, 2001 |
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6889075 |
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60201592 |
May 3, 2000 |
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Current U.S.
Class: |
600/473 ;
600/476 |
Current CPC
Class: |
A61B 5/0086 20130101;
A61B 1/045 20130101; A61B 5/0071 20130101; A61B 2090/366 20160201;
A61B 5/0066 20130101; A61B 5/0075 20130101; A61B 5/0261 20130101;
A61B 1/043 20130101; A61B 5/0068 20130101; A61B 5/352 20210101;
A61B 5/489 20130101 |
Class at
Publication: |
600/473 ;
600/476 |
International
Class: |
A61B 006/00 |
Claims
What is claimed is:
1. A method of optically imaging subsurface anatomic structures and
biomolecules in an individual or animal with red light and infrared
radiant energy, comprising the steps of: illuminating a region of
interest with light from the red to radiant infrared portion of the
light spectrum; and, detecting red and infrared light from said
region of interest with a red and infrared light sensitive image
detector.
2. The method of claim 1, wherein said region is illuminated with
light energy having wavelengths ranging from 600 nm to 1100 nm.
3. The method of claim 1, wherein said infrared sensitive image
detector detects red and infrared light selected from the group
consisting of transmitted light, reflected light, absorbed light,
and emitted light.
4. The method or claim 1, wherein said light is detected by a
method selected from the group consisting of pulsatile enhanced
imaging, confocal enhanced imaging, Raman enhanced imaging, laser
speckle enhanced imaging, multiphoton interaction enhanced imaging,
optical coherence tomography enhanced imaging, time correlated
single photon counting enhanced imaging, optical rotary dispersion
imaging, circular dichroism imaging, and polarization enhanced
imaging.
5. The method of claim 1, wherein images from said infrared
sensitive image detector are displayed on a video monitor.
6. The method of claim 1, further comprising the step of adding an
exogenous chromophore to the region of interest.
7. The method of claim 6, wherein said chromophore is selected from
the group consisting of indocyanine Green (ICG) and
.delta.-aminolevulinic acid
8. A device for performing the method of claim 1, said device
comprising: a red to radiant infrared light source; a red and
infrared sensitive image detector; and, a means to display detected
images.
9. The device of claim 8, wherein said light is provided by a
source selected from the group consisting of light-emitting diodes
(LEDs) filtered with a bandpass filter, diode lasers and filtered
broadband illumination.
10. The device of claim 8, wherein said detector is selected from
the group consisting of a charge-coupled device (CCD) and a CCD
video camera.
11. A method of optically imaging subsurface anatomic structures
and biomolecules by pulse oximetry, comprising the steps of:
illuminating a region of interest with alternating wavelengths of
light from the red to radiant infrared portion of the light
spectrum; and, detecting red infrared light from said region of
interest with a pulse oximeter.
12. The method of claim 11 wherein said method is used to detect
blood in said region of interest.
13. The method of claim 12, wherein said region of interest is
illuminated with red light of 660 nm wavelength and infrared light
of 940 nm wavelength.
14. The method or claim 12, wherein imaging of arterial and
non-arterial blood is differentiated by discriminating between
time-varying signals and non-varying signals.
15. The method of claim 12, wherein an electrocardiogram (ECG)
electrode is used to monitor a heartbeat in order to match the
phase of the signal with the heartbeat.
16. The method of claim 12, comprising the further step of using
pulse oximetry data to determine the oxygen saturation of said
blood.
17. The method of claim 11, wherein illumination is performed with
multiple wavelengths of radiant energy to achieve enhanced imaging
contrast.
18. The method of claim 17, wherein said enhanced imaging contrast
is used to distinguish between hemoglobin within blood vessels
versus extravascular hemoglobin.
19. The method of claim 17, wherein said enhanced imaging contrast
is used to distinguish between myoglobin, oxyhemogloblin and
deoxyhemoglobin to obtain blood-tissue contrast.
20. A device for performing the method of claim 11, comprising, a
source of red to radiant infrared light of alternating wavelengths;
an red and infrared sensitive image detector; and, a means to
display detected images.
21. The device of claim 20, wherein said light is provided from a
broadband source and said detector is a camera fitted with a
rotating filter wheel.
22. A method of obtaining depth specific information when optically
imaging subsurface anatomic structures and biomolecules, comprising
the steps of: illuminating a region of interest with narrow bands
of light from the red to radiant infrared portion of the light
spectrum; and, detecting red and infrared light from said region of
interest by confocal imaging.
23. The method of claim 22, comprising the further step of
alternating red illumination with white light illumination so that
a normal image of the region-of-interest is obtained.
24. The method of claim 22, wherein said region of interest is
alternatively illuminated with radiant energy of 660 nm and 940 nm
wavelengths to collect information on oxyhemoglobin and
deoxyhemoglobin as a function of depth.
25. A device for performing the method of claim 22, comprising, a
source of red to radiant infrared light; an infrared sensitive
confocal image detector; and, a means to display detected
images.
26. A method of optically imaging the location of a specific
biomolecule in subsurface anatomic structures by Raman
spectroscopy, comprising the steps of: illuminating a region of
interest with a single wavelength of light from the red to radiant
infrared portion of the light spectrum; and, using Raman
spectrosopy to detect frequencies and intensities of light emitted
from said region of interest, wherein frequencies are specific to
given biomolecules and intensities are indicative of the amount
present; analyzing said data as a function of location to construct
a two or three dimensional image of the distribution of a detected
biomolecule.
27. The method of claim 26, wherein said region of interest is
illuminated with light from an 850 nm diode laser.
28. A device for performing the method of claim 26, comprising, a
source of red to radiant infrared light; a Raman Spectroscope; and,
a means to process and display detected images.
29. A method of using laser speckle imaging to detect movement when
optically imaging subsurface anatomic structures and biomolecules,
comprising the steps of: illuminating a region of interest with
coherent laser light in the red to radiant infrared portion of the
light spectrum; detecting a "speckle" pattern of light reflected
from said region of interest with a sensitive detector; and,
monitoring movement said "speckle" pattern to detect movement.
30. The method of claim 29, wherein said movment is blood flow.
31. A device for performing the method of claim 29, said device
comprising: a red to radiant infrared coherent laser light source;
a red and infrared sensitive image detector; and, a means to
display detected images.
Description
CROSS-REFERENCE TO RELATED APPLICATION
[0001] This non-provisional patent application claims benefit of
provisional patent application U.S. Ser. No. 60/201,592, filed May
3, 2000, now abandoned.
BACKGROUND OF THE INVENTION
[0002] 1. Field of the Invention
[0003] The present invention relates generally to the fields of
optical imaging and medical diagnosis. More specifically, the
present invention relates to advanced methods of optical imaging of
subsurface anatomical structures and biomolecules.
[0004] 2. Description of the Related Art
[0005] The importance of imaging structures and biomolecules in
humans is self-evident. Recently, many groups of investigators have
been trying to develop optical imaging techniques in order to
supercede, or reduce the requirements of using expensive and
potentially harmful techniques including x-rays, ultrasound or
magnetic and radio-frequency fields. Optical imaging techniques
employing non-ionizing electromagnetic radiation are not harmful to
biological tissue, and so are less hazardous and thus less
expensive. However, there is a major limitation in using
ultraviolet, visible and infrared radiant electromagnetic energy
for imaging in that most tissues are highly scattering, and often
strongly absorbing to such photons.
[0006] Nevertheless, infrared radiant energy is useful in
non-invasive imaging of anatomical structures since it is
relatively penetrating in tissue; the wavelengths of radiant energy
from about 600 nm to about 1100 nm penetrates tissue quite well,
when compared to visible, ultraviolet, or mid- to far infrared
radiant energy. Furthermore, biomolecules exhibit absorption
features in this red to near-infrared region of the spectrum due to
electronic and vibrational/rotational absorption.
[0007] The prior art is deficient in the lack of effective means of
imaging subsurface anatomical structures and biomolecules by using
red and infrared radiant energy. The present invention fulfills
this long-standing need and desire in the art.
SUMMARY OF THE INVENTION
[0008] The present invention provides various methods/systems of
optical imaging of subsurface anatomical structures and
biomolecules utilizing red and infrared radiant energy. Such
methods enhance contrast in medical imaging, and are generally
useful in non-invasive and relatively low cost imaging instruments.
The techniques used include pulsatile enhanced imaging, confocal
enhanced imaging, Raman enhanced imaging, laser speckle enhanced
imaging, multiphoton interaction enhanced imaging, optical
coherence tomography enhanced imaging, time correlated single
photon counting enhanced imaging, and polarization enhanced
imaging.
[0009] The present invention also provides a method of enhancing
vascular contrast for imaging, comprising the step of applying the
system disclosed herein in combination with the usage of exogenous
chromophores or a range of other molecules which have tendency of
concentrating in the tissue of interest.
[0010] Still provided is a method of detecting a disease in a
subject, comprising the steps of applying the system disclosed
herein to the subject to obtain an optical image, and then
comparing the image with a control image obtained from a normal
subject, wherein any difference between the two images is
indicative of a possibility of having a disease in the test
subject.
[0011] Further provided is a method of treating a subject having a
disease, or further monitoring the treatment, by applying to the
subject with the system disclosed herein in combination with the
administration of therapeutic agents including laser energy.
[0012] Other and further aspects, features, and advantages of the
present invention will be apparent from the following description
of the presently preferred embodiments of the invention given for
the purpose of disclosure.
BRIEF DESCRIPTION OF THE DRAWINGS
[0013] So that the matter in which the above-recited features,
advantages and objects of the invention, as well as others which
will become clear, are attained and can be understood in detail,
more particular descriptions of the invention briefly summarized
above may be had by reference to certain embodiments thereof which
are illustrated in the appended drawings. These drawings form a
part of the specification. It is to be noted, however, that the
appended drawings illustrate preferred embodiments of the invention
and therefore are not to be considered limiting in their scope.
[0014] FIG. 1A shows a dual wavelength illumination device
optionally employing an electrode to synchronize the video imaging
with the pulse rate. FIG. 1B shows a method for imaging in multiple
wavelengths whereupon optical filters are sequentially inserted
into the image axis at a rate which is synchronized with the video
capture rate.
[0015] FIG. 2 shows a confocal imaging device whereby white light
illumination and optionally infrared illumination and/or white
light illumination are used to image subsurface blood vessels.
[0016] FIG. 3 shows an imaging system employing Raman scattered
photons and a scanner positioned in front of the spectrograph
optical system or the infrared laser illumination.
[0017] FIG. 4 shows a blood vessel imaging device where motion
detection is employed.
[0018] FIG. 5 shows a blood vessel imager where multiphoton effects
are used for imaging.
[0019] FIG. 6 shows an optical coherence tomographic blood vessel
imager.
[0020] FIGS. 7A-7F show various ways in which polarized light and
polarizing filters over the detector can be used to enhance blood
vessel image contrast. FIGS. 7C-7F make use of an active device
called a photoelastic modulator which can be used in the creation
and analysis of polarized radiant energy.
[0021] FIG. 8 illustrates one configuration for altering the
intensity profile of the incident light to compensate for uneven
topography of the imaged anatomic object.
[0022] FIG. 9 shows one configuration for a blood vessel viewer
including a plurality of arms to hold an illumination source and
video detector over the region-of-interest.
DETAILED DESCRIPTION OF THE INVENTION
[0023] The present invention is directed to various methods/systems
of optical imaging of subsurface anatomical structures and
biomolecules utilizing red and infrared radiant energy. Such
methods enhance contrast in medical imaging, and are generally
useful in non-invasive and relatively low cost imaging
instruments.
[0024] In one embodiment of the present invention, there is
provided a method/system of enhancing optical imaging of an
anatomical structure or a biomolecule utilizing one or more
techniques selected from the group consisting of pulsatile enhanced
imaging, confocal enhanced imaging, Raman enhanced imaging, laser
speckle enhanced imaging, multiphoton interaction enhanced imaging,
optical coherence tomography enhanced imaging, time correlated
single photon counting enhanced imaging, and polarization enhanced
imaging.
[0025] In another embodiment of the present invention, there is
provided a method of enhancing vascular contrast for imaging,
comprising the step of applying the system disclosed herein in
combination with the usage of exogenous chromophores or a range of
other molecules which have tendency of concentrating in the tissue
of interest.
[0026] In still another embodiment of the present invention, there
is provided a method of detecting a disease in a subject,
comprising the steps of applying the system disclosed herein to the
subject to obtain an optical image, and then comparing the image
with a control image obtained from a normal subject, wherein any
difference between the two images is indicative of a possibility of
having a disease in the test subject.
[0027] In yet another embodiment of the present invention, there is
provided a method of treating a subject having a disease, or
further monitoring the treatment, by applying to the subject with
the system disclosed herein in combination with the administration
of therapeutic agents including laser energy.
[0028] The following examples are given for the purpose of
illustrating various embodiments of the invention and are not meant
to limit the present invention in any fashion.
EXAMPLE 1
[0029] Pulsatile Enhanced Imaging
[0030] Pulse oximeters are relatively common devices used to
measure the percent oxygen saturation of blood, wherein red
(.lambda..sub.1.apprxeq.6- 60 nm) and near infrared
(.lambda..sub.2.apprxeq.940 nm) radiant energy are passed through
tissue (typically the fingertip). Using this device, it is possible
to obtain a measurement of oxygen saturation of the blood based on
the relative signals transmitted through the fingertips at each
wavelength, knowing the absorption characteristics of the pertinent
absorbing chromophores (tissue, oxygenated hemoglobin or HbO.sub.2,
deoxygenated hemoglobin or Hb), and after extensive calibration of
the device with a direct measurement of blood oxygenation. One
important operating characteristic that makes the pulse-oximeters
useful is that they can discern between arterial and non-arterial
absorption by discriminating between time-varying signals (due to
the heart pumping and more evident in arterial blood) and
non-varying signals (venous blood and tissue).
[0031] FIG. 1 shows an imaging device (e.g. charge-coupled device
or CCD video camera, or vidicon) used to visualize an anatomic
structure or region of interest that employs concepts used in pulse
oximetry. The illuminating light consists of alternating pulses of
radiant energy produced by, for example, light-emitting diodes
(LEDs) filtered with a bandpass filter, or diode lasers, to produce
radiant energy impinging on the surface with a wavelength of, for
example, .lambda..sub.1=660 and .lambda..sub.1=940 nm. The detector
captures an image, for example, every {fraction (1/30)}.sup.th of a
second, and so the illuminating light is alternately pulsed once
every {fraction (1/30)}.sup.th second. The images captured can be
analyzed mathematically similar to standard transillumination
pulse-oximeters except in this case reflectance, R, is measured,
and not transmittance, T. The mathematical analysis is similar when
one considers that optical density, OD, is related to R by
OD=-Log(R) and T=1-R. In a fashion similar to pulse oximetry, the
signal can be decomposed into an time-varying signal (AC) and
steady state (DC) signal, whereby the former is due to absorption
within arteries (and to a much lesser degree, veins) while the
latter is primarily due to non-arterial absorption.
[0032] Alternatively, an electrocardiogram (ECG) electrode could be
used to monitor the heartbeat in order to match the phase of the
signal with the heartbeat, thus achieving the same aforementioned
result. In any case, this methodology would allow one to optically
differentiate arterial blood absorption from absorption due to
other biomolecular species, such as deoxygenated blood.
Furthermore, it could optionally be used to measure blood oxygen
saturation, which when combined with the imaging information,
provides useful diagnostic information.
[0033] Another way to obtain sequential images at different
wavelengths is to use a rotating filter wheel in front of the
camera and a single broadband illumination source that produces
radiant energy at both the necessary wavelengths, .lambda..sub.1
and .lambda..sub.2 (FIG. 1B). The rotation rate and phase of the
optical filter wheel could be adjusted to maximize the AC signal
(and thus would be in phase with the pulsatile arterial flow), or
could be controlled by a pulse rate signal from an optional ECG
electrode.
[0034] The aforementioned discussion of using multiple wavelengths
of radiant energy to achieve imaging contrast can be used in a
similar fashion to provide contrast between vessels and tissue
and/or hemoglobin within blood vessels versus extravascular
hemoglobin. Myoglobin (Mb) is a form of hemoglobin that transports
oxygen in muscles and which provides much of the visual appearance
of color in muscles. The absorption spectrum of myoglobin is
different from oxy- and deoxyhemoglobin. This difference can be
used to differentiate hemoglobin contained within vessels from
myoglobin in vessel walls, muscle or other tissue, thus producing
good blood-tissue contrast. Note that extravascular blood will not
optically change in a pulsatile fashion as will blood in arteries
(and to a lesser extent, veins), thus the aforementioned pulsatile
imaging scheme can be used to differentiate intervascular blood
from extravascular blood.
EXAMPLE 2
[0035] Confocal Enhanced Imaging
[0036] The concept of rejecting light scattered from locations
other than the point being imaged (that is, with coordinates
x,y,z), by using apertures in the imaging system, is referred to as
confocal imaging. This concept has been used to "optically section"
microscopic specimens being viewed with a microscope. Confocal
microscopy normally uses white light illumination, or ultraviolet
to green illumination to induce fluorescence in the sample. The
former illumination results in significant chromatic aberrations in
the final image, while the latter provides only a fluorescent
image.
[0037] It would be beneficial, in certain cases, to use red and/or
near infrared radiant energy in a confocal imaging optical system,
along with white-light illumination. Narrow band illumination
through the use of diode lasers or bandpass filtered broadband
light sources would be optimal (FIG. 2). By alternately
illuminating the region-of-interest (ROI), for example, 660 nm and
940 nm radiant energy in a confocal imaging system, it would be
possible to collect information on HbO.sub.2 and Hb as well as
information as a function of depth in the sample. Illumination at
these wavelengths could be alternated with illumination using white
light so that a normally appearing image of the region-of-interest
would also result. This could allow one to visualize blood vessels,
for example, below other normally appearing intervening structures
that reduce or eliminate the ability to visualize the vessels.
EXAMPLE 3
[0038] Raman Enhanced Imaging
[0039] Raman spectroscopy is a light scattering technique that uses
(typically) laser radiation to excite the sample, whereby the
scattered radiation emitted by the sample is analyzed. Emission
data has two main characteristics: the frequencies at which the
sample emits the radiation (a small number of the incident photons,
perhaps only 1 in 10.sup.6, is emitted at frequencies different
from that of the incident light), and the intensities of the
emissions. Determining the frequencies allows identification of the
sample's molecular makeup, since chemical functional groups are
known to emit specific frequencies and emission intensity is
related to the amount of the analyte present. Now, with highly
sensitive imaging light detectors (e.g. CCDs) and efficient optics
such as transmission holographic gratings and notch filters, Raman
spectroscopy has seen a resurgence of interest in the medical
field.
[0040] It would be useful to illuminate the anatomic structure of
interest with the radiant energy produced by, for example, a 850 nm
diode laser, and to use a Raman spectrograph for imaging (FIG. 3).
The Raman scattered photons specific to Hb and/or HbO.sub.2 could
then be used to detect and discriminate blood from other tissues
made of different biomolecules. Of course, the same idea can be
extended to other biomolecular species of interest such as
circulating pharmaceuticals, liver enzymes and glucose. To build up
an image using Raman scattered photons, it may be necessary to
either scan the collimated and focused illuminating light beam in a
raster-scan, for example, and capture information point-by-point so
that a two-dimensional image can be made up. Alternatively, the
detector (if it is not an imaging type) can be scanned. Still
alternatively, a two-dimensional imaging detector, such as a CCD,
can be used. In any case, the strong molecular specificity of Raman
scattering would allow for good rejection of signals not pertaining
to the molecule of interest.
EXAMPLE 4
[0041] Laser Speckle Enhanced Imaging
[0042] If the movement and/or texture of objects reflecting
coherent laser radiant energy have dimensions on the order of the
wavelength of the radiant energy, then constructive and destructive
interference can take place. To the eye, this can give the
appearance of a "speckle" pattern superimposed on the illuminated
object. If the object reflecting the laser light moves with respect
to the incident laser beam, then the speckle pattern moves. Such
movement can be used to detect motion. This concept could
beneficially be used to detect blood flow. Sometimes the tissue
overlying a blood vessel moves slightly as a result of pulsatile
blood flow. For example, FIG. 4 shows an imaging system being used
to detect blood within a vessel. The imaged vessel and surrounding
structures are illuminated with radiant energy produced by a laser,
preferably in the near infrared region of the spectrum so
relatively deep penetration of the radiant energy occurs, and yet
is reflected from red blood cells (RBC); for example, 805 nm light.
The reflected radiant energy can be captured by a detector, which
is positioned behind an aperture. Thus, any change in the speckle
pattern results in a change in the detector's signal output. Any
changing speckle pattern is a consequence of RBC movement. If the
infrared laser is scanned, then an image of the speckle pattern can
be built up and spatially dependent RBC movement can be detected,
thus providing a means with which to detect blood vessels. Again, a
normally appearing image using white-light illumination could be
captured and the blood-vessel movement information could be
superimposed on the image.
EXAMPLE 5
[0043] Multiphoton Interaction Enhanced Imaging
[0044] Under certain irradiation conditions, it is possible to have
photons, with a wavelength .lambda., interact with an atom or
molecule which normally would not absorb at .lambda., but which
does absorb at a different .lambda.. For example, fluorescein which
has an absorption peak around 500 nm can be induced to fluoresce
when irradiated with two photons with a wavelength of 1000 nm, that
arrive virtually simultaneously. Three-photon excitation can also
be used in certain circumstances, but in this case the wavelength
of the photons must be 1/3 that of the wavelength of absorption.
This multi-photon effect requires lasers which produce high peak
powers (e.g. >2 kW in a pulse length, .tau..sub.p<1 ps) and
yet have a low average power so that there are no undesirable
laser-tissue interactions such as photothermal coagulation. This
multi-photon effect can be used for fluorescence imaging as the
requisite high photon density can be made to occur only at the
focus of the laser beam, which can then be scanned in three
dimensions. The benefits of multi-photon excitation is that the
incident radiant energy is not attenuated by absorption of the
fluorochrome above the plane of focus and the longer excitation
wavelengths used are less Rayleigh scattered.
[0045] It is generally believed that multi-photon techniques are
useful only for fluorescence imaging. However, it is known that the
scattering and absorption effects of tissue are related to each
other by a mathematical relation from classical electromagnetic
theory. Thus, in the electromagnetic spectrum where tissue is
highly absorbing, it is also highly scattering. Thus, a multiphoton
effect can be used to gather absorption and scattering imaging
information. For example, considering that blood absorbs strongly
at about 400-425 nm, however radiant energy with this wavelength
(which appears blue) is so strongly absorbed in tissue that it only
penetrates superficially. However, it is possible with two-photon
scattering and absorption to obtain information about blood using
radiant energy at 800-850 nm. Such radiant energy is quite
penetrating in tissue, and yet will interact with blood if the
photon density per unit time is large enough. It is therefore
possible to obtain imaging information (FIG. 5) using a pulsed
laser producing near infrared radiant energy. For practical
reasons, such an imaging scheme may benefit from using a Q-switched
Nd:YAG laser (1064 nm), as such lasers are relatively inexpensive
and fortuitously blood absorbs strongly at 532 nm. The 532 nm
scattered information could be collected in synchrony with the
pulsed Nd:YAG laser. On alternate scans, white light or infrared
images could be captured. Comparison of the two could be used to
determine the location of the blood (or other light
absorbing/scattering chromophore) in the field of view.
EXAMPLE 6
[0046] Optical Coherence Tomography Enhanced Imaging
[0047] Optical coherence tomography (OCT) is based on low-coherence
interferometry (e.g. white-light Michelson interferometry). High
resolution depth-dependent imaging is obtained by focusing light
from an optical low coherence source (e.g. LED) on the biological
tissue and interfering the backscattered intensities with the
incident light (FIG. 6). Images in the first two dimensions are
obtained by performing the interferometric measurement as a
function of transverse (x,y) positions in the tissue. Third
dimension (depth) information in the tissue is collected by varying
the reference arm pathlength axially (z position) in the
interferometer. Useful interferometric information occurs only when
the optical pathlengths of the light traversing the reference path
and tissue path are identical to within the coherence length of the
source. Optical coherence tomography is beneficial in that is does
not require an illumination source with a long coherence length
(e.g. a laser) and can be done with the use of optical fibers.
[0048] It would be beneficial to use optical coherence tomography
with infrared radiant energy to obtain good penetration of the
light. By using several wavelengths of light sequentially, in the
same manner described for the pulsatile enhanced imaging scheme
described previously, specific images of arteries and veins could
be obtained, as well as a non-invasive measurement of blood oxygen
saturation in a particular imaged vessel.
EXAMPLE 7
[0049] Time Correlated Single Photon Counting Enhanced Imaging
[0050] Time-correlated single-photon counting (TCSPC) is a
statistical technique which may be used to measure the time profile
of the emission of a sample following excitation by a short light
pulse. The time delay between a trigger ("start") pulse, which is
fixed in time with respect to the excitation pulse, and the moment
of arrival of a photon emitted by the sample and then detected by a
photomultiplier ("stop" pulse) is recorded. By accumulating many
such intervals in a histogram, the probability that a photon is
emitted by the sample at a certain moment is measured, i.e., the
time profile of the emission is measured.
[0051] Time-correlated single-photon counting is a commonly used
technique in fluorescence spectroscopy due to its wide dynamic
range, high time resolution and high sensitivity. Time resolutions
of the order of 50 ps (FWHM) are easily achievable with commercial
ultrafast laser and detector systems. Typically, a mode-locked
argon-ion laser is used to synchronously pump a cavity-pumped dye
laser. The resultant train of picosecond pulses may be coupled into
an optical fiber in contact with the sample under investigation.
The pulse shape changes as it propagates through the medium. This
is due to the fact that photon pathlengths are altered through
interactions (scattering and absorbing) with the medium. In fact,
the optical properties of the medium may be inferred from the shape
of the emitted pulses. Typically, the emitted pulses are collected
with an optical fiber positioned on the sample at a known distance
from the input fiber. The distal end of the collection fiber is in
contact with the detector, which, for ultrafast applications, is a
microchannel plate-photomultiplier tube (MCP-PMT).
[0052] The optical properties (scattering and absorption) of the
material may be obtained through non-linear least squares fitting
of the data (amplitude vs. time spectra) to a model function. A
diffusion model is commonly used to fit the data. Analytic
solutions of the diffusion equation in homogeneous media exist for
various simple geometries. This data (absorption and scattering
coefficients) can be collected during scanning in the x-y plane in
order to build up an image. Depth z dependent information could be
obtained using one of the depth discriminate techniques, such as
OCT or confocal, described above.
EXAMPLE 8
[0053] Optical Rotatory Dispersion, Circular Dichroism and
Polarization Enhanced Imaging
[0054] Circular dichroism (CD) and optical rotatory dispersion
(ORD) are polarization dependent measurements whereby circular
dichroism measures a difference between the absorption in matter of
radiant energy that is left and right circularly polarized light,
while optical rotatory dispersion measures the difference in the
refractive indices for left (L) and right (R) circularly polarized
light. If a biomolecule is optically active, i.e., if dissymmetric
and non-superimposable mirror images of the molecule occur,
circularly polarized light interacts with the molecule depending on
the handedness of the light. Molecular shape and orientation also
determines the degree to which linearly polarized light interacts
with a molecule. For example, polarizing sunglasses have absorbing
chromophores that are mostly oriented horizontally; thus when light
specularly reflected from a roadway (which is, to a degree,
linearly polarized with the axis of polarization oriented
horizontally), then it is absorbed by the chromophores. Unpolarized
light retroreflected from a tissue interface will have a degree of
linear polarization; incident linearly polarized light
retroreflected (FIG. 7A) from deeper within the tissue will loose
the initial polarization, depending on how many scattering events
occur within the tissue; the more scattering events that photon
experiences, the more the polarization becomes random with respect
to the polarization of the injected photon.
[0055] These ideas can be used to improve the ability to image
subsurface anatomic structures. For example, specular reflectance
from tissue interfaces, which can tend to obscure the image of a
subsurface structure, can be reduced or eliminated by linearly
polarizing the incident light, and incorporating a linear analyzer
whose transmission axis is oriented orthogonal to the transmission
axis of the incident light polarizer. Similarly, by passing
unpolarized light through a linear polarizer and a wave retarder,
circularly polarized light is produced which, when retroreflected,
will be absorbed upon passing through the same wave retarder and
linear polarizer (FIG. 7B). Note that these polarization techniques
which serve to reduce unwanted specular reflection can also be used
to increase the ratio of photons scattered once or a few times
(i.e. superficially penetrating photons) to photons scattered many
times (i.e. deeper penetrating photons). Thus this serves as a way
to either reject highly scattered photons which serve to degrade
image contrast, or to get depth discriminate information.
[0056] These same methods can be used for molecular discrimination.
Note that devices to measure the reflectance and absorbance from
tissue of polarized light, and the state of polarization in the
reflected light, can make use of a photoelastic modulator (PEM),
which is a device that, depending on the waveform and phase driving
it, can be used to analyze polarized light when used in conjunction
with polarizers and waveplates. The frequency at which the PEM is
driven, and the frequency of signal detected, also play a role in
determining what exactly is being measured (Hinds Instruments,
Inc., Oregon).
[0057] For example, optically active molecules such as glucose can
be detected by transmission measurements using CD or optical
rotatory dispersion. PM-IRRAS stands for Polarization Modulation
Infrared Reflection-Absorption Spectroscopy. It is the differential
IR absorption between the s- and p-linearly polarized light for the
molecules in a tissue (FIG. 7C). In ellipsometry, the polarization
change of a light beam is measured when it is reflected by the
sample. This change in polarization is then related to the sample's
properties (FIG. 7D). Vibrational circular dichroism (VCD) is the
differential absorption between left and right circularly polarized
light. It is a measurement of the optical activity for chiral
molecules (FIG. 7E). Linear dichroism (LD) is the differential
absorption between two orthogonal, linearly polarized states.
Linear dichroism is a measurement of the sample's bulk property
that is a result of the regular orientation of the molecules in the
sample (FIG. 7F with the PEM set at 0.degree. and phase-sensitive
detector at the 2.sup.nd harmonic).
EXAMPLE 9
[0058] Image Processing
[0059] Image processing devices, which can manipulate digital image
data quickly, would be beneficially used in any of the above
methods. For example, Hamanatsu Photonic Systems (Bridgewater,
N.J.)) sells a unit which can perform real-time edge enhancement,
uneven illumination compensation and frame averaging.
Alternatively, with the advent of extremely fast video processing
hardware, it is possible to perform mathematical operations on the
video signals in real-time thereby allowing various enhancement
schemes. For example, a Fast Fourier Transform can be performed on
the video image, and edge enhancement can be done by high-pass
filtering the transform prior to performing the inverse Fast
Fourier Transform. One very important post-processing algorithm
involves pixel-stretching, whereupon the contrast of a low contrast
image is increased by altering the video image pixel values to
utilize the full spread of values (e.g. 256) available in the
digitizer. As the region-of-interest (ROI) is typically unevenly
illuminated, it would be beneficial to be able to select an ROI on
the video monitor, perhaps through the use of a mouse, and to apply
the image processing algorithms to that region only. This would
maximize the contrast in the region-of-interest and would allow the
user to ignore other unimportant information which may be very dark
or very light, and so can make automated image processing of the
full image difficult.
EXAMPLE 10
[0060] Vascular Contrast Enhancement
[0061] In order to improve the imaging contrast between blood
vessels, or other sub-surface structures, and the surrounding
tissue, it may be beneficial to use exogenous chromophores. For
example, Indocyanine Green (ICG) is a well know agent which has
been used for many years in quantifying cardiac output and imaging
retinal vasculature. When dissolved in plasma, it has an absorption
maximum at about 800 nm. By employing multiple-wavelength
illumination and/or detection whereby one of the images captured
was illuminated or detected around 800 nm, and the other at a
wavelength where indocyanine green is only weaking absorbing (say,
for example, 660 nm), then it is possible to differentially image
vasculature. However, when combined with the aforementioned
pulsatile imaging methodology, for example, further contrast
enhancement will be achieved. This same idea of using exogenous
chromophores can be extended with a range of other molecules, some
of which have a beneficial tendency of concentrating in diseased
tissue. For example, it is know that .delta.-aminolevulinic acid
(.delta.-ALA) preferentially collects in malignant tissue where it
greatly enhances the production of porphyrins. These porphyrins are
strongly absorbing and fluorescent, and so this compound combined
with the above discussed imaging techniques can be used to identify
(and actually treat) cancer.
[0062] It could be of importance to provide good contrast between
such things as endoscopes, fingertips, other surgical components,
etc., in the infrared image. Carbon and graphite, for example, are
strong absorbers of near infrared radiant energy. By coating
gloves, instruments, etc, in a thin layer of these materials would
appear dark in an infrared imaging system.
EXAMPLE 11
[0063] Alternating Color and Infrared Imaging and Rapid Sequential
Image Display
[0064] Most surgeons are most familiar with endoscopic images
obtained using white-light illumination and color sensitive
cameras. Color information is also used by the surgeon for
diagnostic information (e.g. detecting erythema or malignancies).
On the other hand, infrared sensitive cameras produce only a
black-and-white (B & W) image. It would be beneficial to devise
an imaging system whereby the surgeon can either select to quickly
change from color to B & W imaging, or to collect the most
relevant infrared image information (for example, the location of a
subsurface blood vessel) and to superimpose this information on the
color image. Another way to achieve the same thing is to use an
infrared sensitive CCD detector, in front of which is positioned a
rotating filter wheel with red, green, blue and infrared bandpass
filters. The filters are positioned in front of the CCD at a known
rate and in synchrony with the capture of information from the CCD.
The information can then be processed into an infrared image and
into a color image (by combining the red, green and blue
information).
[0065] Another way to enhance the visual appearance of blood
vessels in these images is to use a process sometimes referred to,
by astronomers, as "blink" imaging. The eye (and brain) are
apparently quite sensitive to small changes in the appearance of a
visual field, more so than small differences in a static field. It
would therefore be beneficial to configure the image processing and
display system such that the image would switch rapidly (e.g. 2 Hz)
between a white-light illuminated black-and-white or color image
and the infrared image. This mode of display would serve to enhance
the visualization of the blood vessels.
EXAMPLE 12
[0066] Combining with Therapeutic Laser Energy Delivery Devices
[0067] Optical fibers can be used to guide the radiant energy of a
laser down an endoscope, whereupon it is used to cut, coagulate, or
induce fluorescence in tissue. It would be beneficial in certain
surgeries, such as third ventriculostomy, to be able to use
infrared imaging to identify sensitive subsurface structures such
as blood vessels, and then to use the radiant energy produced by a
laser (the 2.94 micron wavelength radiation produced by an Er:YAG
laser, for example) to produce a fenestration in the membrane
(floor of the third ventricle). The use of the imaging technology
in conjunction with therapeutic laser radiant energy would be
important clinically.
EXAMPLE 13
[0068] Coherent Imaging Fiber Bundle
[0069] Some of the embodiments of the inventions described will be
too bulky to mount on devices that can be easily manipulate by the
health-care provider. It might therefore, in certain cases, be
beneficial to optically guide the image from a small handpiece over
to the image collection and processing device, which could be
positioned on a table nearby. Coherent imaging fiber bundles are
suitable for this purpose. The input end of the bundle is
positioned in the image plane of an optical system directed at the
ROI, and the output end of the bundle is positioned in the object
plane of the image collection system. This arrangement is light and
flexible, thus, gives the health-care provider necessary
freedom-of-movement.
EXAMPLE 14
[0070] Magnification
[0071] Making use of magnification would be a useful addition to
the imaging device in many instances. For example, blood vessels in
babies are very small and quite difficult to see. Small,
telangiectasia vessels are also difficult to see during treatment.
The combination of the image contrast improving methods described
herein and optical magnification would serve to improve clinical
efficiency during blood vessel puncture procedures or treatment of
diseased blood vessels.
EXAMPLE 15
[0072] Infrared Transillumination
[0073] The illumination systems used in the described applications
can also be applied as transilluminators. When a beam of light is
held against tissues, such as skin or mucous membranes, whether
applied externally or internally, much of the light scatters
through the tissues and illuminates the area beneath the skin and
laterally. This scattered light illuminates tissue structures in
proximity to the site where the photons are injected. By using an
infrared sensitive detector and infrared incident light or light
which has an infrared component, it is possible to observe
subsurface anatomic structures such as blood vessels beneath the
skin.
EXAMPLE 16
[0074] Heads-Up and Projection Display
[0075] It is typical that the health-care provider needs to keep
both hands free for procedures, therefore, any imaging system that
is most beneficial is the one that does not need to be hand-held or
manipulated. Furthermore, it is of benefit that the imaging system
is possible to simultaneously view the actual region of interest on
the patient, if it is required that the image of the ROI needs to
be displayed for the provider.
[0076] In one embodiment of the invention, the video information
could be inputted into a video projector whereupon the image of the
ROI is projected back onto the actual ROI on the patient. The
projected image could be enhanced so that the structures of
interest (typically blood vessels) are made as contrasty as
possible and the rest of the image is made uniform. Thus the
projection would serve to outline the actual position of the
structures on the patient, thus enhancing the ease with which they
are manipulated b y the health-care provider. Another way to
achieve a similar effect is to project the video image onto a
partial reflecting screen which reflects the image back to the
provider; the subject is positioned on the opposite side of the
screen so that the video image appears to the provider to be
superimposed on the actual subject. This form of display is similar
to that used in fighter-aircraft and is sometimes called a
heads-up-display.
EXAMPLE 17
[0077] Illumination Compensation
[0078] As the dynamic range of CCD video cameras is much less than
the human eye, displaying all of the structures of interest in an
unevenly illuminated ROIs can be problematic. This problem will be
minified by using a camera with a greater dynamic range, such a s
tube-type cameras. Alternatively, another solution to this is to
either tailor the light field to compensate for an uneven
topography in the ROI, or to adjust the gain of the CCD pixels
non-uniformly. For example, in the case of the former, the addition
of anodized mask over the illumination source that has, to a first
approximation, a spatially dependent transmittance that is similar
to the shape of the ROI (FIG. 8). Another way to achieve the same
effect is to control the gain in each pixel of the CCD
individually, instead of the typical way whereby they are adjusted
together. For example, the health-care provider could outline an
ROI on a video screen with a mouse, and the computer to which the
screen is interfaced could then direct information to the CCD video
camera such that the gain of the relevant pixels are adjusted, and
the rest of the pixels in the image are ignored. A similar sort of
non-uniform gain is used in, for example, the Hamamatsu C2400-1
controller which allows the user to adjust the gain of the CCD in
four quadrants of the image by adjusting four potentiometers.
EXAMPLE 18
[0079] Intravascular Versus Extravascular Blood Discrimination
[0080] One problem in surgery and endoscopic surgery is when
bleeding occurs, the pooling blood can inhibit the surgeon from
visualizing what is below. Unfortunately, this often makes ligating
or cauterizing the bleeding vessel difficult to do. The blood
flowing out of a vein or artery has a pulsatile flow which is
related to the heart beat. The blood pooling in and around the
bleeding tissue does not have a pulsatile flow, but instead flows
at a steady rate, if at all. Therefore, using the aforementioned
pulse imaging concepts would allow the surgeon to remove from an
image the absorption due to static blood, and yet still provide
imaging information of vascular blood and tissue. In this case,
since it may be necessary to differentiate between HbO.sub.2, Hb,
and Mb, either three different wavelengths of illumination will be
necessary, or a rotating filter wheel with three filters may be
required.
EXAMPLE 19
[0081] Varicose Veins
[0082] Treatment of varicose veins can be problematic in that
accurately imaging the vein before and during the procedure can be
difficult. Loss of blood from the vein or presence of extravascular
blood can further obscure the veins during procedures. The infrared
imaging technology described herein would be useful during the
therapeutic processes (e.g. vein stripping, laser irradiation,
sclerotherapy, etc.) by allowing the surgeon to visualize the
vessels accurately (FIG. 9). This device could have a plurality of
support arms which serve to allow placement of the device on the
patient thus freeing the hands of the surgeon. Alternatively, the
device could be positioned on a support employing a ball joint such
that it could be positioned in any way by the surgeon and will be
kept in that position. The support arms could have incorporated an
optical wave guide, such as an optical fiber bundles, which
transmits illumination from the source to the surface of the skin.
The arms terminate in an infrared filter and optionally a
polarizing filter. The light will be directed out of the terminal
portion of the arms either perpendicularly to the skin surface, or
at an oblique angle directed into the ROI. A video camera can be
affixed to the light source such that it images the ROI; the output
of the camera is conducted through a cable to the video controller
and/or monitor.
[0083] In a related surgical strategy, following localization of
the vessels by these and other methods not described here, varicose
veins may be treated by intraluminal insertion of an optical fiber
which guides laser radiant energy (e.g. Nd:YAG 1064 nm radiation)
into the vessel and inducing coagulation. This procedure would
further be improved as the fiber could be coated in an infrared
absorbing agent (such as ICG) whereby it could be imaged with the
technology discussed herein.
EXAMPLE 20
[0084] Endoscopic Surgery
[0085] Endoscopic surgery, such as a third ventriculostomy, would
benefit from the technology described herein. It is always
important for the endoscopic surgeon to avoid dissecting blood
vessels during insertion and advancement of the endoscope. The
infrared imaging technology and other blood discrimination
techniques described herein would be of benefit in allowing the
endoscopist to avoid such vessels.
EXAMPLE 21
[0086] Localizing Blood Volumes for Analytical Spectral
Measurements
[0087] Measuring analyte levels in blood or other tissues with
minimally invasive techniques is a very desirable objective. A
problem encountered during optical spectral measurements of blood
analyte levels is the inability to measure the volume of tissue
interrogated. This problem is further compounded by the fact that
differences may exist between analyte concentrations
extravascularly versus intravascularly. These differences may be
difficult to differentiate, resulting in skewed values. The vessel
imaging technology described herein allows for the blood in a
vessel to be identified. In other words, the blood can be located.
Thus, in effect, a virtual optical isolation of a volume of blood
may be performed. Once the volume is isolated in this way, the
available spectral analysis techniques could be further employed to
obtain the information of interest regarding analyte concentration,
or regarding any blood disorders that are characterized by unique
spectral shifts.
EXAMPLE 22
[0088] Disposables
[0089] To maintain sterility or at least to keep anything from
being positioned near or on a patient, it would be beneficial to
employ a disposable shield in many of the aforementioned methods
such that any biological material (blood, saliva, ablated tissue,
etc.) could not contaminate the imaging process. For example, a
disposable plastic sheath that covers the objective lens, scanner
and/or camera of the imaging system would be useful. The contact
probe illustrated in FIG. 9 could itself be disposable.
Alternatively, disposable plastic sheaths could be also employed on
each of the components that actually touches the patient.
EXAMPLE 23
[0090] An infrared sensitive CCDvideo camera (e.g. Hamamatsu
C2400-79, Hamamatsu Photonic Systems, Bridgewater, N.J.) and an
image processing and analysis system (Hamamatsu Argus-20) are
coupled together. A 250 W quartz incandescent light source is
optically coupled into a light transmitting fiber bundle which is
coupled to an endoscope (e.g. Smith & Nephew Dyonics No. 3626S
focusing video arthroscope). The proximal end of the endoscope is
connected to a custom-made coherent fiber optic bundle (Schott
Fiber Optics, MA) which carries the imaging information to the
infrared camera. Between the fiber bundle and infrared camera is
located an infrared long-pass filter (e.g. Edmund Scientific RG715
glass filter, Edmund Scientific, Barrington, N.J.). A macrolens on
a c-mount, attached to the CCD camera, is used to image the end of
the fiber bundle. The image processing unit is set to enhance edges
and frame average in order to minimize the appearance of noise in
the image.
EXAMPLE 24
[0091] An infrared sensitive CCD video camera (e.g. Dage-MTI CCD
300) was fixed with a 19-38 mm zoom lens and the output was sent to
a standard video monitor. An optical infrared long-pass filter
(Edmund Scientific, Inc.) was positioned in front of the lens of
the video camera. The device was used to image the varicose veins
of a patient undergoing surgical removal of the veins. The (epi-)
illumination was optionally a 30 W quartz camcorder light source,
which had a Kodak Wratten No. 29 (red) gelatin filter placed in
front of the source, or a white-light source (Smith and Nephew,
Inc.) connected to an endoscope, which was interstitially
positioned within the patient's leg below the varicose veins in
order to provide back-illumination of the veins. During this
experiment, it was determined that the greatest vein-tissue
contrast was achievable when the black-level control on the CCD
camera controller was minimized, and the gain was then adjusted in
order to obtain a visible image on the video monitor. The veins
were imaged well with either interstitial transillumination, or
red-filtered epi-illumination. It was also determined that by using
an oblique (non-normal) viewing angle and/or oblique illumination
angle, the contrast of the blood vessels was enhanced.
[0092] Any patents or publications mentioned in this specification
are indicative of the levels of those skilled in the art to which
the invention pertains. These patents and publications are herein
incorporated by reference to the same extent as if each individual
publication was specifically and individually indicated to be
incorporated by reference.
[0093] One skilled in the art will readily appreciate that the
present invention is well adapted to carry out the objects and
obtain the ends and advantages mentioned, as well as those inherent
therein. The present examples along with the methods, procedures,
treatments, molecules, and specific compounds described herein are
presently representative of preferred embodiments, are exemplary,
and are not intended as limitations on the scope of the invention.
Changes therein and other uses will occur to those skilled in the
art which are encompassed within the spirit of the invention as
defined by the scope of the claims.
* * * * *