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Claims  |
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What is claimed is:
1. Apparatus for the measurement of retinal blood flow in an eye of a
subject, such apparatus comprising
a first light source for forming and projecting along a first path an
illumination beam which converges to an illumination spot on a retinal
vessel,
a second light source for forming and projecting along a tracking path at
least one beam of tracking light distinct from light of the first light
source,
light collection means for separately collecting light from the
illumination spot reflected along two directions separated by a fixed
angle,
Doppler analysis means for analyzing light collected by the light
collection means to provide an indication of blood flow in the retinal
vessel illuminated by the illumination spot,
an optical beam steering system for controllably directing a beam of light
incident thereon to the retina, said optical beam steering system moving
in response to control signals, and being located and aligned to receive
and direct to the retina said illumination beam and simultaneously to
receive light from said beam of tracking illumination reflected from the
retina,
imaging means for forming, back through said optical beam steering system,
an image of retinal tissue illuminated by said tracking light, and
tracking means responsive to motion of the image of retinal tissue for
providing a control signal to said steering system that maintains the
image stationary, said tracking means being operated at a rate effective
to limit jitter such that the illumination spot remains on the retinal
vessel and the Doppler analysis means detects the flow of blood in said
vessel.
2. Apparatus according to claim 1, wherein said beam-steering system
comprises separated forward and reverse paths defined by different faces
of a common set of steering mirrors, said illumination beam and said beam
of tracking light being steered along said forward path to the eye, and
said image being formed along said reverse path from the eye.
3. Apparatus according to claim 2, wherein said light collection means
collects light which returns along said reverse path from the eye past a
said steering mirror.
4. Apparatus according to claim 2, wherein said common set of steering
mirrors comprises a pair of galvanometer controlled steering mirrors, each
mirror being metallized on both sides.
5. Apparatus according to claim 1, wherein said illumination beam converges
to a spot of approximately fifty micrometers diameter.
6. Apparatus according to claim 1, wherein said collection and said imaging
means each collect light passing through a different region of the eye
pupil.
7. Apparatus according to claim 1, wherein said Doppler analysis means
includes a spectral analysis system which operates in real time to
determine a frequency distribution indicative of blood flow velocity.
8. Apparatus according to claim 7, wherein said Doppler analysis means
further includes means for determining a volumetric blood flow rate.
9. Apparatus according to claim 7, further including a means for comparing
a blood flow rate with a reference blood flow rate.
10. Apparatus according to claim 9, wherein said reference flow rate is a
stored flow rate indexed by at least one of vessel diameter and age of
subject.
11. Apparatus according to claim 1, wherein said light collection means
includes a fiber for translating received light without dispersion while
preserving phase relationships.
12. Apparatus according to claim 1, further comprising means for
determining the diameter of the retinal vessel.
13. Apparatus according to claim 12, wherein the tracking means detects
motion of the retinal image on a photodetector array and the means for
determining diameter determines the size of the image of a retinal vessel
on the array.
14. Apparatus according to claim 12, further comprising processing means
for determining at least one of a leakage condition, a blockage condition,
and total blood flow.
15. Apparatus according to claim 1, further comprising means for processing
the indication of blood flow to identify vascular pathology.
16. Apparatus for he Doppler measurement of retinal blood flow, comprising
operator viewing means for aiming the apparatus at a retina
first means for directing coherent light at a retinal vessel
second means for collecting light scattered by blood flowing in the retinal
vessel and directing it at a photodetector to develop an electrical signal
A/D conversion means for converting the electrical signal to a digital
signal
tracking means operative on a vessel image for stabilizing aim of the
apparatus at the retinal vessel as coherent light is directed at and
scattered light is collected from the vessel, and
digital processing means operative on the digitized signal to perform a
fast Fourier transform and develop a measure of blood speed in the retinal
vessel, said processing means further communicating with said tracking
means to develop an indication of vessel diameter and to functionally
combine said measure of blood speed and indication of diameter, operating
in real time to determine a retinal circulation value as the apparatus is
aimed at the retina, thereby achieving real time in vivo clinical
evaluation of observed tissue.
17. Apparatus according to claim 16, wherein said processing means
determines a volumetric flow rate of blood in the retinal vessel.
18. Apparatus according to claim 16, further comprising data storage means
for containing a compilation of normal values of retinal circulation, and
wherein the processing means compares a determined value to a stored
normal value to produce a diagnostic output.
19. A method for the measurement of retinal blood flow in an eye of a
subject, such method comprising the steps of
projecting along a first path an illumination beam which converges to an
illumination spot on a retinal vessel,
projecting along a tracking path at least one beam of tracking light
distinct from light of the illumination beam,
separately collecting light reflected from the illumination spot along two
directions separated by a fixed angle,
Doppler analyzing the collected light to provide an indication of blood
flow in the retinal vessel illuminated by the illumination spot,
providing an optical beam steering system for controllably directing a beam
of light incident thereon to the retina, said optical beam steering system
moving in response to control signals, and locating and aligning said
optical beam steering system to receive and direct to the retina said
illumination beam and simultaneously to receive light from said beam of
tracking illumination reflected from the retina,
forming, back through said optical beam steering system, an image of
retinal tissue illuminated by said tracking light, and
tracking motion of the image of retinal tissue and providing a control
signal to said steering system that maintains the image stationary, said
tracking being performed at a rate effective to limit jitter such that the
illumination spot remains on the retinal vessel and the step of Doppler
analyzing determines the rate of flow of blood in said vessel.
20. The method of claim 19, wherein said optical beam steering system
comprises separated forward and reverse paths defined by different faces
of a common set of steering mirrors, and wherein said illumination beam
and said beam of tracking light are steered along said forward path to the
eye, while said image is formed along said reverse path from the eye.
21. The method of claim 20, wherein the step of collecting light collects
light which has returned along said reverse path from the eye past a said
steering mirror.
22. A method for the Doppler measurement of retinal blood flow, such method
comprising the steps of viewing the retina through an apparatus and
directing coherent light at a retinal vessel
collecting light scattered from blood flowing in the retinal vessel and
directing it at a photodetector to develop an electrical signal
digitizing the electrical signal
detecting motion of an image of a vessel to develop control signs for
stabilizing aim of the instrument on the vessel as coherent light is
directed at and scattered light is collected from the vessel, and
digitally processing the digitized electrical signal in real time with a
fast Fourier transform to develop a measure of blood speed in the retinal
vessel while determining the vessel diameter from said image of the
vessel, and functionally combining the blood speed and vessel diameter in
real time to provide a diagnostic indicator of retinal circulation as the
apparatus is aimed at the retina thereby achieving real time in vivo
clinical evaluation of actual blood flowing in observed tissue.
23. The method of claim 22, wherein the step of processing includes
computing a volumetric flow rate of blood in the vessel.
24. The method of claim 22, wherein the diagnostic indicator output is
derived by comparison of measured blood flow information to stored blood
flow information.
25. The method of claim 22, further comprising the steps of
functionally combining information as the apparatus is aimed at plural
retinal vessels, and
comparing the functionally combined information to a stored table of
normative measurements to produce said diagnostic indicator.
26. The method of claim 22, further comprising the step of functionally
combining blood flow information from plural distinct arterial and venous
vessels to produce a diagnostic indicator of circulatory leakage or
blockage.
27. Apparatus according to claim 16, wherein the processing means further
includes program sequence means for combining a plurality of successive
values of retinal circulation as the apparatus is aimed at different
retinal vessels, and means for detecting circulatory leakage or blockage
conditions. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
The present invention relates to instrumentation for measuring blood flow
in vessels of the retina by Doppler velocimetry.
The general theory of laser Doppler velocimetry, as applied to the
measurement of a flowing fluid such as blood inside a blood vessel, is a
well known application of flow measurement technology. Briefly,
monochromatic light aimed at the vessel and into the flowing blood is
reflected by the blood cells as diffuse light with a frequency
distribution corresponding to the components of velocity of the individual
scatterers. By analyzing the frequency distribution of the reflected light
at two fixed receivers with a known separation angle, the velocity or,
ideally, the velocity profile of the flowing blood can be deduced.
When one attempts to apply this approach to detect blood flow rates in
vessels of the retina, however, practical obstacles are encountered.
First, individual retinal vessels have a diameter under several hundred
microns, so that in order to perform a reliable measurement it is
necessary to aim a beam of laser light of diameter approximately equal to
the diameter of the vessel. Smaller beam diameters introduce the risk of
missing the centerline flow measurement, while larger beam diameters
result in a lower signal to background ratio.
Second, the Doppler analysis requires collection of the reflected light
from two distinct directions having a specified angular separation. This
light collection must be done outside the eye. The optical paths therefore
will vary depending on the curvatures of the eye involved, and the
collected light will include extraneous light due to reflection at various
surfaces of the eye.
Third, it is necessary to perform this aiming and to collect a sufficiently
strong return signal, despite relatively fast and large scale movements of
the eyeball.
When it is considered that a small diameter beam must be used to maintain
an acceptable signal to noise ratio, and that the level of reflected light
from the fundus that can be collected outside the eye is highly
attenuated, the foregoing obstacles are seen to impose severe limits on
the quality of collected light available for Doppler analysis.
These difficulties have heretofore limited the clinical applicability of
laser Doppler velocimetry to carefully controlled and rather cumbersome
analytical investigations. Typically, the procedure is done by fitting a
rectifying lens directly on the cornea, and then, with the illumination
and collection optics manually positioned on a target vessel, recording
short time segments of the collected spectra. A large number of such
recordings are then analyzed and segments are pieced together to obtain an
analytically derived synthetic recording representing the flow during one
or more entire heartbeat intervals. The analysis and ultimate synthesis or
identification of a representative one- or two-second Doppler spectrum is
done some time after the recording, so that blood flow information is not
quickly provided.
One approach to simplifying the processing of the recorded Doppler spectra
is to develop algorithms for initially selecting only those recorded
spectrum segments which meet certain criteria representative of the
expected flow functions. Highly noisy or anomalous recording segments are
discarded, thus limiting the amount of remaining data that must be
processed. This approach, while clearly eliminating records resulting, for
example, when the beam misses a vessel entirely, may screen out some valid
flow information and render the system blind to clinically significant
details. Analysis of Doppler records would be simplified if the
instrumentation could be aimed with sufficient stability to record a
continuous record having a duration of a full heartbeat interval or
longer. More meaningful measurements of blood flow could also be obtained
if the stability were sufficient to allow aiming a Doppler illumination
spot on a central region of a blood vessel and on smaller vessels.
SUMMARY OF THE INVENTION
It is an object of the invention to provide a retinal Doppler velocimeter
of enhanced utility and performance.
It is another object of the invention to provide a retinal Doppler
velocimeter which is reliably positioned and maintained on a retinal
vessel.
It is another object of the invention to provide a retinal Doppler
velocimeter which provides continuous or real time vessel flow
information.
These and other desirable features are achieved in accordance with one
embodiment of the invention by providing an optical beam steering system
for controllably steering a beam directed at the retina, and by projecting
a Doppler illumination beam through the steering system in a forward
direction while forming an image of the retina along an optical path that
passes through the steering system in a reverse direction. A tracking
system detects motion of the image and develops control signals to produce
compensating motions of the steering system so that the Doppler
illumination beam remains centered on a thin blood vessel. With the
illumination thus stabilized, a set of collection optics collects the
light reflected from a retinal vessel along two distinct directions and an
analyzer determines the spectrum of collected light, and preferably also
computes or displays at least one of the peak or minimum velocity, the
time-averaged centerline velocity, or the corresponding volumetric flow
rate.
The steering system contains optical elements arranged so that the forward
and reverse optical paths are separated.
In a preferred embodiment, the Doppler collection optics are located behind
the steering system to provide an unobstructed area between the instrument
and the eye, and are positioned so the angles at which the light is
collected bear a fixed angular offset.
The steering system includes a pair of two sided mirror elements, each
pivotable about one of two mutually orthogonal steering axes, and an
optical relay system which places a face of each mirror element in a
conjugate relation to a face of the other mirror element.
In another or further preferred embodiment of the system, the blood vessel
is imaged as a tracking target transversely onto a linear CCD array, which
provides a direct measure of the vessel diameter. A processor computes the
vessel's volumetric flow rate as a function of centerline blood flow
velocity and vessel diameter. In a further embodiment according to this
aspect of the invention, the processor may include a stored table of
normal flow rates as a function of vessel size and the subject's age, and
may provide a diagnostic output based on a comparison of the detected and
the normal flow. In another embodiment, the processor may store diagnostic
programs for summing the flow over several vessels and detecting
discrepancies indicative of flow pathologies.
BRIEF DESCRIPTION OF THE DRAWINGS
These and other features will be understood by reference to the following
description of illustrative embodiments of the invention, together with
the drawings, wherein
FIG. 1 illustrates one embodiment of the invention;
FIG. 2 illustrates another embodiment of the invention;
FIG. 3 illustrates the Doppler collection optics of the apparatus of FIG. 1
or 2;
FIG. 3A illustrates alternate optics of the steering assembly;
FIG. 3B illustrates alternate optics of the Doppler collection apparatus;
FIG. 4 illustrates the processing of Doppler signals;
FIG. 5 illustrates a representative Doppler spectrum;
FIG. 6 illustrates the Doppler spectrum processed to identify flow rate;
FIGS. 7, 7(a), (b), and (c) illustrate the instantaneous maxima of Fourier
spectra plotted over time, and the Doppler signal processing;
FIG. 8 illustrates tracking and Doppler illumination of a retinal vessel;
FIG. 9 illustrates the CCD image signal for determining vessel diameter;
and
FIG. 10 illustrates processing of a diagnostic Doppler measurement system.
DETAILED DESCRIPTION
FIG. 1 illustrates a stabilized retinal laser Doppler system 10 in
accordance with one embodiment of the present invention. System 10
includes a steering assembly 20, a tracking assembly 30, a red laser
source 35 for illuminating a retinal vessel, and a two-channel Doppler
pick up and analysis assembly 40. The steering assembly, which includes x-
and y- axis deflection mirrors, is controlled by electrical signals to
direct the optical path 100 of the beam from the red laser to a desired
retinal vessel, and the beam is maintained centered on the targeted vessel
by a tracking system which monitors the position of the image of the same
or a nearby retinal blood vessel which has been imaged back through the
same steering system into an electronic sensor array, e.g., a CCD 38.
Change in position of the image on the CCD array is detected and used to
develop control signals that reposition the steering mirrors to prevent
motion of the image. The techniques for deriving a well defined tracking
signal and controlling the mirrors with a sufficient speed and accuracy to
aim the beam from laser 35 on a retinal target are described in U.S. Pat.
No. 4,856,891 commonly owned by the assignee of the present invention, and
the text of that patent is hereby incorporated herein by reference for
purposes of a complete description and full disclosure.
The red laser light scattered from a targeted retinal vessel at the back of
the eye is imaged by the eye objective optics back toward the steering
system and is deflected by a pair of mirrors 41, 42 each having a diameter
of approximately one millimeter and spaced approximately six millimeters
apart. These mirrors reflect collected light into respective channels of
the Doppler analysis unit. The mirrors each intercept about 1.4.degree. of
arc, and their spacing, corrected for the 3.times. magnification of the
objective assembly, corresponds to a fixed divergence angle within the eye
which allows calculation of absolute flow velocity values, when given the
axial length of the subject's eye.
Observation light for the system is provided by a yellow helium-neon laser
51, which is directed through a beam expander 52, past deflecting mirrors
53a, 53b, and through an attenuator 54 to provide a broad field beam which
is folded into the illumination path by beamsplitting mirror 55. The beam
illuminates a .+-.10.degree. field of the fundus.
Yellow observation light reflected from the fundus is returned through the
objective assembly consisting of lenses 61, 63 and an image rotator 65,
and passes through the steering assembly to an eyepiece or viewing
assembly 67 where it provides a visible image field that moves
synchronously with the tracking image and with the targeted vessel and
Doppler illumination spot. The viewing assembly may include a camera. The
function of the image rotator 65, described more fully in the aforesaid
U.S. Patent, is simply to rotate a tracking image, such as the image of a
retinal vessel, into a fixed orthogonal frame on the CCD. This allows the
tracker to lock onto an obliquely oriented vessel and apply its
fixed-frame orthogonal steering corrections. The image rotator thus
provides additional convenience in setting up the instrument, and removes
the need for image field transform computations in the tracking system.
In this illustrated embodiment, a green helium-neon laser 31 is provided
for the tracking system. Laser 31 provides a separate beam which is folded
into the same optical path 100 as that followed by the Doppler
illumination beam by a turning mirror 32 and a beam splitting mirror 33,
so that the green beam is also steered by the steering assembly 20. An
attenuator 101 in the path limits the intensity of the steered beam. The
green tracking beam has a small diameter, e.g., under several millimeters,
and thus beneficially limits the illuminated area of the eye. The
wavelength separation of the three described light sources allows
appropriately placed filters or dichroic beam splitters to eliminate
interference from each of the different sources on the viewing or sensing
units associated with the other sources. For example, the beamsplitter 37
which reflects the return tracking image to the CCD 38 may be a dichroic
beamsplitter which reflects substantially all the green light toward the
CCD, while passing substantially all the yellow light to the observation
optics 67. Further concrete examples of appropriate spectral separation
paths are more fully described in the aforesaid U.S. patent.
The steering system 20 includes two steering mirrors 21, 22 each arranged
to pivot about one of two orthogonal axes lying in a common plane P which
is conjugate to the eye fundus. A galvanometer control 21a, 22a attached
to a pivot shaft moves each mirror so that it is precisely turned to a
direction within an angular range of approximately .+-.1020 . Each mirror
has first and second sides, denoted the A (or inside) and the B (or
outside faces) herein, and according to a Principal aspect to the
invention these mirrors are arranged to maintain optical separation of the
input and output light paths.
This separation is achieved by an optical relay system which translates the
outside faces of the mirrors to each other, preferably including lenses or
focusing mirrors which place the turning axis of the one mirror conjugate
a plane containing to the turning axis of the other mirror with a 1:1
magnification. Such conjugation optics are more fully described in the
co-pending United States Patent application Ser. No. 522,376 of Yakov
Reznichenko and Michael Milbocker entitled Bidirectional Light Steering
Apparatus, filed on May 11, 1990 and commonly owned by the assignee of the
present invention. Said patent application is hereby incorporated herein
by reference.
For ease of illustration, however, the intermediate lenses or curved
reflective surfaces are omitted from the drawing, and the optical relay
system is shown simply by three flat mirrors 23a, 23b, 23c which translate
a beam impinging on the B face of one steering mirror to the B face of the
other steering mirror. As further described in the aforesaid patent
application, the steering mirrors may be thin plates which are metallized
on one side, but are preferably front-surface mirrors metallized on both
sides. This construction more effectively eliminates ghosting and internal
reflection from the steering system.
The return image along axis RI from the subject's eye is reflected from the
"A" face of mirror 22 to the "A" face of mirror 21, and thus passes
through the steering system with the same angular deflection as a
reverse-steered beam 200 passing to the tracking and observation optics,
so that the light input beam 100 and the return image beam 200 always
follow substantially fixed directions to and from the tracking/observation
optics. A pair of diaphragms 24a, 24b located in a fundus conjugate plane
screen out corneal and other reflections. The diaphragm opening is
approximately ten millimeters.
Turning briefly to FIG. 3, the Doppler signal reception assembly 40 of FIG.
1 is illustrated in greater detail. The pick-off mirrors 41, 42 deflect
two portions of the reflected Doppler beam which define in this embodiment
a precise angular separation corresponding to a 13.5.degree. divergence
outside the eye. The light is relayed to a fiber bundle 47 in each
channel. Each bundle 47 serves to channel the light received at one end of
the bundle without further divergence or attenuation, while preserving
phase relationships, to a photomultiplier tube 49 (RCA 8645). A red laser
line filter 48 (Melles Griot 632.8 nm) removes extraneous wavelengths.
If it is desired to retain a manual tracking or viewing port in the Doppler
assembly, a construction such as shown in FIG. 3B may be employed. In this
construction the mirrors 41, 42 may be larger, and a pair of pinhole
diaphragms 44 define the Doppler beam separation angle. An optical relay
assembly consisting of objective optics 46 and relay mirrors 46a, 46b in
each channel relay the collected light to the respective fiber bundles 47,
and an annular green filter (a Kodak Wratten filter #57A, not shown)
placed in the optical path together with an eye objective 50 provides an
additional or alternative way to view the targeted vessel during Doppler
measurement.
In any case, the Doppler illumination beam from laser 35 is focused to a
spot of a diameter approximately equal to the diameter of the targeted
vessel on the retina, and the incident beam power is attenuated to
approximately five microwatts, resulting in a biologically safe level of
retinal irradiance. While the photomultiplier tubes necessary to detect
return irradiation at these low levels would be driven to saturation by
normally encountered stray reflectances, in the illustrated apparatus the
photomultiplier tubes develop an acceptable signal due .in large part to
the above described separation of the tracking and illumination signals in
the steering system.
In a further embodiment shown in FIG. 2, the Doppler pick off and receiving
assembly 40 is positioned on the opposite side of the steering system from
the eye. In this embodiment, the angular relation between each pick-up and
the input illumination beam is a constant, thus eliminating second order
effects. A further construction difference resides in the replacement of
the mirrors 41 or 42 (FIG. 1) and 46a, 46b, (FIG. 3B) with a longer fiber
bundle 47 for each channel that extends directly into the return image
path and conducts light to the photomultiplier tube. The bundles have a
diameter of slightly over three millimeters, and translate the light from
the retinal conjugate image plane without dispersion while preserving
relative phase relationships.
FIG. 3A illustrates an alternative construction of the steering system 20
for use in the Doppler apparatus of FIGS. 1 or 2. In this embodiment, the
x- and y- steering mirrors 21, 22 are identical to those of FIGS. 1 and 2,
but the relay path between the outer faces of those mirrors consisting of
mirrors 23a, 23b, 23c and associated relay lenses has been replaced by a
pair of focusing mirrors 24a, 24b in a unity -magnification telecentric
arrangement. This simplifies the layout and alignment of the steering
assembly, reduces the number of reflective interfaces, and eliminates
solid scattering media from the illumination path.
FIG. 4 illustrates the processing of collected light of the Doppler
analyser. The reflected light includes light scattered from the surface of
the blood vessel which serves as a reference frequency, as well as light
which has Penetrated the vessel and is scattered from blood cells flowing
within the vessel. These two types of light are combined on the
photomultiplier tube 49 (FIG. 3), where they heterodyne to produce an
electrical signal having beat frequency components corresponding to the
individual velocities of the scattering cells. The electrical signal
developed by each photomultiplier channel is fed to a spectral analysis
system 110, which for each five millisecond interval provides an output in
real time representative of the frequency components of the analysed
signal, of which a representative trace is illustrated in FIG. 5. The
trace is quite noisy, as it is derived from the individual motions of
scattering objects which follow some general cross-sectional flow profiles
within the vessel, but which also have components of motion due to thermal
motion and fluid flow turbulance and irregularities. However, despite the
extreme noisiness of the signal, the frequency trace does have an
ascertainable upper or cut-off frequency 120 (FIG. 5) corresponding to the
maximum or centerline flow velocity value of the target vessel.
In order to detect this maximum flow velocity value, the signal trace (FIG.
5) of the spectral analysis processor 110 for each diameter is digitized
and passed to a processor 115 which determines the maximum frequency and
displays the corresponding flow velocity. In the preferred embodiment, the
cut-off frequency is identified by an integrator/differencer which
constructs a new function from the output of the spectral analysis system
110 such that the new function has a maximum value at the cut-off. This
processing is implemented in a software module, which for each frequency
value u defines a "window" of width 2A about the value, and slides the
window along the frequency scale. For each u, it subtracts the value of
the frequency signal integrated over a fixed interval of width A to the
right of .upsilon., from the value of the frequency signal integrated to
the left of .upsilon..
The resulting function, which for each frequency .upsilon..sub.o, is
defined by
##EQU1##
has a maximum precisely at the frequency where there is an extreme
discontinuity in fluctuation of the signal value. FIG. 6 shows the
function f(u) so defined, with the same frequency scale as illustrated in
FIG. 5. Thus, it is seen that despite the jumpiness of the spectral
output, the frequency corresponding to peak blood flow is readily
detected.
FIGS. 7, 7A, 7B and 7C illustrate the basic signal processing of the
above-described system. The line A of FIG. 7A shows an eight second signal
trace consisting of the frequency maximum at each instant in time derived
by the spectral analysis system 110 from the output of one photomultiplier
tube 49 when the Doppler illumination spot is aimed at a retinal artery.
The line of FIG. 7B shows the corresponding trace of the other
photomultiplier. Each channel has different absolute frequency range,
owing to their different light collection angles, but both show the
distinctive periodic pulses associated with arterial flow due to the
cardiac pumping cycles. The line of FIG. 7C shows the blood flow velocity
equal to a constant, for a given eye and instrument configuration, times
the difference between lines A and B. Specifically, line C represents the
peak instantaneous centerline blood flow velocity, which, at a given
instant, is directly proportional to the difference in peak or cutoff
frequencies of the two signals, lines A and B.
FIG. 7 illustrates the overall operation of the spectral analysis system
and processor of FIG. 4. Each PMT analog output is A/D converted and
stored in a computer-accessible form, e.g., on a disc. A software Fourier
transform module analyses each t-second block of signal values and
computes its power spectrum. Each power spectrum (channels 1 and 2) is
Processed by the frequency cut-off detection algorithrum described above
in relation to FIG. 6. In the prototype instrument, the processor operated
in real time to digitize and process eighty-nine five-millisecond samples
per second for each channel, producing the highly detailed traces
illustrated in the figures.
It further bears note that in FIGS. 4 and 7, the function of the spectral
analysis system and the processor are not clearly separated, for the
reason that in the preferred embodiment the spectral analysis and
subsequent signal processing steps may be primarily performed by the
processor, which may be a microcomputer equipped with numerical analysis
software and with Fourier transform software.
In a preferred embodiment of the invention, further functions are performed
in the processor on other opto-electronic signals to develop a number of
specific indicators or pieces of clinical information as more fully
described below, including volumetric blood flow outputs, vessel blockage
or flow anomaly determinations, and normative comparison of circulation.
It should be noted that because the Doppler analysis module uses the light
reflected from the outside of a blood vessel as a reference beam,
frequency shift effects caused by motion of the eye or of the illumination
spot cancel out, and the detected flow rate is substantially the same
whether the focused Doppler beam is stationary or is moving along the long
direction of the blood vessel, with or opposed to the flow direction. For
this reason, the tracking system need not control motion in two
dimensions, but may be a one-dimensional tracker with its tracking
components configured in an orientation to correct only for motion of the
eye in a direction transverse to the vessel at which the Doppler beam 100
is directed. This may be accomplished, for example, when using a tracker
as shown in the aforesaid U.S. patent, by choosing a tracking target
vessel which either is, or lies parallel to, the vessel on which Doppler
measurements are to be taken, and by tracking motion transverse to that
tracking target to develop steering correction signals.
It is also possible to use a two-axis tracking system to stabilize the
Doppler beam and return light for analysis and imaging.
In one presently preferred embodiment of the invention, a single-axis
tracker is employed, and output signals from the tracking CCD provide
quantitative measurements to convert the Doppler output to absolute
volumetric flow measurements.
FIG. 8 illustrates details of the Doppler imaging of such a device. A
retinal vessel 120 which may have a diameter of under fifty to a few
hundred micrometers, is illuminated by a green tracking beam 90 which has
a round or rectangular cross section of approximately 0.5-1.0 mm diameter,
and the Doppler illumination beam is focused to a spot 95 on the same
vessel. The retinal region illuminated by the tracking beam 90 is imaged
and aligned, via the steering system 20 as described above, as an image
90' onto a CCD line array 130 which is oriented perpendicularly to the
image 120' of the vessel. A magnifying objective assembly of five to
twenty five magnifications is used, such that the CCD lies entirely within
the image 90' of the tracking beam. For example, for a linear array
consisting of a one by two hundred fifty-six pixel CCD of approximately
twelve millimeters length, a twenty-five power objective assures that the
image of a five hundred micrometer wide tracking beam will cover the CCD
130. Correspondingly, the image of a fifty to one hundred micrometer
retinal blood vessel will cover approximately twenty-five to fifty pixel
elements of the CCD.
FIG. 9 illustrates the sensed illumination values, along the length of the
CCD, of tracking light reflected from the retina. The characteristic
double-valley minimum in detected light intensity corresponds to the blood
vessel image, with a central local maximum corresponding to the specular
reflection from the top center of the vessel wall. The full width half
maximum points of the illumination values, illustrated by the two arrows,
correspond to the vessel diameter d.
In the above described preferred embodiment, the tracker not only polls the
CCD at one millisecond intervals to determine position-correcting control
signals from the steering mirrors, but processes the CCD output to
determine the vessel diameter d by solving for the full width half maximum
points.
In a further preferred embodiment, the processor further performs internal
computations to combine the detected flow velocity and vessel diameter,
and to compute an absolute volumetric flow rate.
The preferred processing for determining the volumetric flow rate proceeds
as follows. First, the processor integrates the centerline flow velocity
(FIG. 5) over a time interval, by numerical processing, and divides the
integral to determine an average centerline blood speed "acb". Next, the
processor determines the vessel cross-sectional area A=.pi.(d/2).sup.2
from the vessel diameter d. For sufficiently large vessels, (over about
fifty micrometers) the assumption of Poiseuille flow holds, and the total
volumetric flow is calculated to be A (acb)/2.
This capability of directly computing the volume of blood flow in a vessel
during observation is advantageously augmented in several further
embodiments of the invention to provide systemic measurements of total
flow, branch flow anomalies, blockage or general sufficiency. In one such
embodiment, the processor stores a memory table listing the range of
normal blood flow as a function of vessel size. This information may be
stored separately for arteries (recognizable by their distinctly pulsatile
flow) and for veins (having a more uniform flow rate).
Once a vessel has been targeted by the tracker and its diameter d
determined, the stored normal value indexed by the diameter d is retrieved
and the normal value is compared to the computed flow value to determine
whether there is an anomaly.
In another embodiment, the "normal" value need not be a predetermined
universal value, but may be determined by measuring and storing the flow
values for vessels of varying diameters in a patient's healthy eye; and
the comparison is then made against the measured flow velocity or volume
values of the other eye. It will be understood that the "normal" values
need not be functions only of diameter, but may also be ordered or indexed
as functions of the subject's sex or age, the subject's blood pressure, or
other clinical parameter.
In a further variation of this embodiment, the processor may include means
for summing the flow rates of each of a plurality of arteries, and for
summing or subtracting the flow of a plurality of veins, thus providing
indications of the blood flow for whole regions of the retina. An
imbalance in the total flows into or out of a retinal region provides an
indication of flow anomaly indicative of possible pathology. In other
embodiments, a simple comparison to a threshhold flow value may indicate a
particular pathology such as hemorrhaging, or a detached retina. General
processing states for one or more of these further systems are illustrated
in FIG. 10.
This completes a description of the invention and several representative
embodiments thereof, together with subsidiary details and variations of
construction. The invention being thus disclosed, modification and
equivalents thereof will occur to those skilled in the art, and such
modifications and equivalents are considered to lie within the scope of
the invention, as determined by the claims appended hereto.
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