Currently, there is an increasing interest in the study of
microcirculation, which is quite understandable, since the pathology of the
capillary network, which provides metabolism in tissues, is the basis of many
pathological conditions [1,2]. Diseases of various etiologies can affect the
skin microcirculation and lead to
inflammation. Capillaries, which are the
smallest and most numerous blood vessels in the human body, respond to various
pathologies much earlier than arteries and veins, changes in which indicate
that the disease is already in the development stage. Accurate monitoring of
the capillary system functioning often allows
in vivo
detection of the
disease at an early stage.
To put it more broadly than is customary,
microcirculation includes all the processes of blood transportation through
microvessels (up to 100 microns in diameter) and the exchange of fluids and
substances with tissues. These two processes are extremely difficult to
separate from each other. It is the state of the capillary network that
provides either normal or pathological metabolism in tissues.
In recent years, the pathogenesis of
cardiovascular diseases which notoriously continue to hold the first place in
mortality among the working-age population in the world according to WHO
statistics, has been significantly revised. The dominant theory is the
cardiovascular continuum, which describes the continuity of the development of
cardiovascular system diseases from the beginning of exposure to risk factors
to the death of the patient [3], where vascular damage is the link between
endothelial pathology and direct
tissue damage (heart attack, stroke). Previously,
much attention was paid to the assessment of vasomotor activity and remodeling
of large arteries of elastic and muscular type, which remains relevant today.
In recent years, special attention has been paid to changes in
microcirculation, suggesting that it is one of the universal development
mechanisms of cardiovascular diseases.
To identify
hidden hemodynamic disorders and assess possible reactions of the capillary
network to external provocative effects, various functional load tests have
been widely used, such as an occlusive test that assesses the amount of blood
flow in the absence of arterial inflow and the reserve capabilities of the
capillary network, a respiratory test that allows to assess the reactivity of
the vascular wall due to the activation of the sympathetic link of the
autonomous nervous system, which leads to spasm of the bringing microvessels
and a temporary decrease in blood flow, postural, assessing the venoarteriolar
reaction in the capillary network, thermal, etc. Of particular interest in the
study of microcirculation are the cold pressor and cold local tests, carried
out in the form of either immersion of the feet and / or hands of the subject
in cold water (pressor), or applying a test tube with ice to the test area for
15 minutes (local). The local cold test is not as indicative in terms of
changes in the capillary network as the pressor but allows it to be carried out
by a larger number of subjects due to less aggressive exposure.
During
the study, attention is usually paid to the color of the background (pale,
pink, red, cyanotic, cloudy), the number of capillaries, the width of their
lumen, the shape, length and width of the loops, the nature of the blood flow
(continuous, fast, slow, intermittent), the vulnerability of the capillary wall
(hemorrhages, rupture of individual capillaries) [4,5]. The normal picture of
capillaries is characterized by a pale pink or pink background, the number of
capillary loops is up to 10-12 in 1 mm, the shape resembles the heads of
hairpins arranged in the form of a palisade, the blood flow is continuous and
fast. Each loop consists of a narrow arterial and a wider venous knee. Spasm is
characterized by a significant decrease or disappearance of the arterial
branch. With atony, there is a sharp expansion of both branches. In spastic
atony, both changes are present simultaneously.
Samples
with the influence of aggressive environmental factors that can affect the
microcirculation are used to detect early changes in the capillary network. In
this case, accordingly, there may be an adequate or pathological reaction of
the microcirculatory bed. As one of these factors, cold exposure in the form of
a cold sample is used. Cold exposure in any case causes changes in the picture
of the microcirculatory bed, which can be observed using the capillaroscopy
method. The question is how adequately the microcirculation vessels react to
the cold and how quickly the normal blood flow and the state of the vascular
wall are restored.
When
cooling the human skin below 15°C, temperature reduction is combined with
vasoconstriction of arteries, resistive microvessels, and arteriolo-venous
anastomoses [6]. However, after a few minutes (usually 5-10 minutes with a cold
pressor test or faster with local cooling), there is an increase in the local
skin temperature and vascular dilation (cold vasodilation reaction). The cause
of cold vasodilation is cold paralysis of the leiomyocytes of the vascular
wall, especially arteriolo-venous anastomoses, as a result of which (with the
most pronounced reaction) they lose the ability to contract, expand and turn
into a passive vascular bed. As the temperature increases due to the heating of
the blood vessel walls, supplied in a large volume, the ability to reduce them
is restored, which leads to vasoconstriction. Such alternating episodes of
constriction-dilation can be repeated during prolonged cooling. Since the cold
vasodilation reaction can be observed in areas of denervated skin, it is
considered a local phenomenon. Cold dilatation is most pronounced in areas of
the skin with the presence of arteriolo-venous anastomoses (finger pads, nail
bed), where it is advisable to carry out cold test since it is the most
informative area. However, since the reaction of cold vasodilation can be
observed (although not constantly) in areas of the skin that do not contain
arteriolo-venous anastomoses (forearm, back of the hand and foot, hip, etc.),
the study can be carried out here if necessary. Many authors regard cold
vasodilation as an adaptive-protective reaction to cold stress. There is
information that with an organic lesion of the vascular wall (late organic
stage of Raynaud's disease, for example) this reaction is lost. From these
positions, the safety and severity of cold vasodilation can be considered as
one of the criteria for compensating the functional resources of tissue
microcirculation in conditions of pathology.
Thus,
the safety and severity of vasodilation in a cold skin test, evaluated using
the capillaroscopy method, can be an indicator of the safety or, conversely,
pathology of the capillary network, particularly in the early stages of
diseases affecting the microcirculation when the changes are still reversible
and functional in nature. Tracking the slightest changes in the blood vessels
will help patients avoid the serious consequences of diseases, such as ulcers
and necrosis.
Figure 1.
Experimental setup.
Experimental
setup is illustrated in
Figure 1. During image acquisition,
patient keeps
his hand on an adjustable wooden
mount. To flatten the inspected skin region in
the forearm area and to get rid of
glare from the epidermis upper
layer, the thin glass plate treated with oil covers the skin. Illumination
system is based on a powerful green LED with lens focusing light onto the
specimen. Image acquisition system includes long working distance 4.5x
microscope objective (LWD MO) and monochrome
CMOS camera (1936 ×
1216 pixels, 5.9 μm × 5.9 μm pixel pitch). They are both
attached to a
z-stage providing accurate focusing. This setup provides
high quality images of the small skin areas with close-to-micron resolution.
The linear field of view is 1.5
mm
´
1.5 mm.
Figure 2.
Image
processing pipeline.
The image processing pipeline is
presented in Figure 2 and described in detail in [7,8]. Figure 3 illustrates
the images obtained at different stages of the pipeline. Before the joint
processing of image stack the initial images acquired by the camera (Figure 3a),
pre-processing is necessary in order to eliminate the influence of uneven
illumination distribution across the field of view, body vibrations and patient
breathing. It includes contrast enhancement, illumination non-uniformity
correction, global and local matching [9]. We implement contrast enhancement by
normalizing initial image intensities using a preliminary calibration image of
a uniform test-object. Exclusion of the low-frequency components from each
image of the stack and intensity normalization allow illumination
non-uniformity correction. Local matching procedure includes evaluation of
local motion vectors between the consequent images in the stack and image
matching with respect to the directions and lengths of these vectors. The
common area of overlapped images is cropped after local matching. Thus, we
obtain the intensity-corrected, stabilized and aligned image stack (Figure 3b).
Figure 3.
Initial (a), pre-processed (b), blood flow (c) and vessel (d) images.
After pre-processing, the image stack
is treated as a spatiotemporal data cube Ik(x, y). Each image
pixel of this cube contains temporal dependences of the signal Ik = I(tk) reflected from the particular points of the
inspected skin area. The vessels may be distinguished from the surrounding
tissues by the presence of blood flow changes. Spectral analysis of the
temporal signal I(tk) using Fourier transform allows
detection of the dominant frequencies corresponding to the blood flow. After we
obtain the intensity deviation values in each pixel, we eliminate the background,
which is free from blood flow, and continue processing only the image pixels
with significant intensity oscillations in the frequency range of 0.5-20 Hz to calculate
blood flow images (figure 3c). The intensities of blood volume changes represented
as the ratio of high- and low-frequency spectral components in the Fourier
spectrum allow vessel image calculation (Figure 3d).
The described setup was implemented for the analysis of forearm
areas of 5 healthy people. To provide an adequate comparison of the inspected
skin areas before and after cold stress, we ensured their exact match by
selecting the areas with specific features (birthmarks, scars, etc.). Each
experiment included the acquisition of image stacks containing 3000 images of
1000
´
1000 pixels resolution obtained at 50 Hz camera
frame rate and processing according to the algorithm described above. The image
stacks were obtained before and 5 minutes after the cold stress, carried out by
applying a glass flask with ice to the selected skin area for 10 minutes. Figure
4
shows one of the acquired images (male, 33 years) and calculated vessel maps
before
and after cold stress. The changes in microcirculation may be clearly noticed
by the reduction of active capillaries amount.
Figure 4.
Acquired (left) and calculated blood vessel (center) images
in
the forearm area
before (upper row) and after (lower row) cold
stress and their overlap (right).
An important feature provided by the proposed technique is
photoplethysmogram acquisition. It is widely in use for detection and
quantitative analysis of volumetric changes in blood circulation, estimating
oxygen saturation, measuring blood pressure and other physiological parameters.
This technique has also become a powerful tool for analyzing the effect of the
external stressors on microcirculation, including the cold test [10]. Being
based on monitoring the changes in the intensity of light reflected from the
skin, it may be easily implemented by the processing of obtained images. After
the temporal dependence of integral intensity is calculated and aligned, we may
obtain a photoplethysmogram shown in
Figure
5 and measured from the same data as presented in
Figure
4. The frequency of the
pulses indicates the heartbeat. The pulse shape is usually associated with the
state of tissue and its pathologies. We may notice that cold stress changes the
amplitude of the pulses, introduces its temporal instability and makes the
pulse shape more rugged.
Figure 5.
Calculated
photoplethysmogram in the forearm area before (upper) and after (low) cold
stress.
In this study, we have demonstrated that video capillaroscopy may
become an effective tool for microcirculation analysis under external stress.
It provides non-invasive mapping of microvessels activity and assessment of the
morphology (quantity, density, shape, dimensions) of capillaries in the forearm
area. Proposed setup is quite easy-to-adjust, enables fast and high-quality
skin image acquisition and allows applying video capillaroscopy and
photoplethysmography methods. To shed the light on the mechanism of vessels
activation (or deactivation) after cold stress, more capillaroscopic
experiments accompanied with measurement of skin temperature, blood pressure
and other parameters have to be carried out. Further research may also include
quantitative study of blood flow parameters and mapping the blood flow
velocities across the whole area inspected.
This
study is supported by RF President Grant (project MD-32.2021.4).
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