Vol. 276, Issue 2, H429-H437, February 1999
Synchrotron microangiography reveals configurational changes
and to-and-fro flow in intramyocardial vessels
Hidezo
Mori1,
Etsuro
Tanaka1,
Kazuyuki
Hyodo2,
Minhaz Uddin
Mohammed1,
Takafumi
Sekka1,
Kunihiksa
Ito1,
Yoshiro
Shinozaki1,
Akira
Tanaka1,
Hiroe
Nakazawa1,
Sumihisa
Abe1,
Shunnosuke
Handa1,
Misao
Kubota3,
Kenkichi
Tanioka3,
Keiji
Umetani4, and
Masami
Ando2
1 Departments of Physiology,
Internal Medicine, and Surgery, Tokai University School of Medicine,
Isehara 259-1193; 2 National
Laboratory for High Energy Physics, Tsukuba 305-0801;
3 Nippon Hoso Kyokai Science and
Technical Research Laboratories, Tokyo 157-8510;
4 Japan Synchrotron Radiation
Research Institute, Hyogo 675-5198, Japan
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ABSTRACT |
In 8 dogs, in situ
microangiography using synchrotron radiation visualized penetrating
transmural arteries (PTAs) with a diameter of >60 µm and allowed
quantitation of vessel diameters of >140 µm. Myocardial contraction
reduced the vascular short-axial diameters to 87 ± 17%
(n = 62, P < 0.001, paired
t-test) of the end-diastolic values
and increased the longitudinal dimension to 129 ± 5%
(n = 45, P < 0.001). The diameter
reduction in the subendocardial PTA segments was significantly more
marked than that in the subepicardial PTA segments (60 ± 12 vs. 88 ± 12%, n=13,
P < 0.001, paired
t-test). Intracoronary administration
of dobutamine (0.1 µg · kg
1 · min1)
increased, and in contrast, partial clamping of the coronary artery
(ischemia) decreased, the configurational changes. To-and-fro blood flow was clearly observed in PTAs with visual identification of
capacitive backflow, resistive forward flow during ischemia on
coronary arteriography, and even under baseline conditions in coronary
venography. Thus this method advances our understanding of mechanical
influences on the coronary circulation.
coronary artery; myocardial blood flow; synchrotron radiation; angiography
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INTRODUCTION |
SINCE Sabiston and Gregg (17) demonstrated that
contraction of the heart impedes coronary arterial inflow, the
characteristic phasic flow pattern of the coronary arterial system and
the mechanisms behind this phenomenon have been studied extensively
with reference to the susceptibility of the inner layer of the heart to
myocardial ischemia (4, 7, 24). Although many investigators
agree that the phasic flow pattern is related to the compression of intramural vessels, major controversy still persists as to the details
of the mechanisms because no laboratory has reported the effects of
cardiac contraction on intramural coronary diameters and flows, and
this information is essential to an understanding of the influences of
contraction on the phasic nature of perfusion.
The penetrating transmural arteries (PTAs) penetrate the heart wall
from the outer to the inner layers, are surrounded by muscle fibers,
and are affected by sagittally radiated left ventricular cavity
pressure during systole or by strains along circumferential and
longitudinal directions (16). Chilian and Marcus (3) and Kajiya et al.
(10) reported systolic retrograde flow in the proximal portion of the
septal artery. Ashikawa et al. (1) observed the configurational changes
and flow pattern in small epicardial coronary vessels. They reported
that vascular diameter in small subepicardial vessels is essentially
unchanged throughout the cardiac cycle and that systolic forward flow
is greater than in diastole. Judd and Levy (9) and Goto et al. (6)
measured the diastolic and systolic blood volumes of intramural vessels in arrested hearts. These studies were static, and it is uncertain whether barium contracture is identical to normal contraction. Yada et
al. (25) observed the configurational changes and flow pattern in small
coronary vessels on epicardial and endocardial surfaces during a
cardiac cycle, but not in intramural vessels. The intramyocardial pump
model proposed by Hoffman and Spaan (7), Spaan et al. (19), and Flynn
et al.(5) allows good organization of these observations. In this
model, during systole blood is squeezed out of the intramural coronary
vessels due to an abrupt increase in myocardial stiffness and
intramyocardial pressure predominantly in the inner layer. Intramural
vessels penetrating the heart (PTAs) are considered to be a common
pathway for anterograde flow in diastole and retrograde flow in systole.
In the present study, we visualized configurational changes of the PTAs
and the to-and-fro coronary blood flow (systolic elimination of
contrast material followed by refilling in diastole) through PTAs by in
situ microcoronary angiography using monochromatic synchrotron
radiation (SR) and a high-definition (HD) video-camera system with a
high-sensitivity image pick-up tube (8, 13, 14).
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MATERIALS AND METHODS |
Surgical procedures and experimental protocol.
In eight dogs (17.4 ± 1.2 kg body wt) anesthetized with morphine
hydrochloride (3 mg/kg sc) and 
-chloralose (80 mg/kg iv), in situ
coronary angiography was performed by using monochromatic SR with an
energy of 33.3 keV and an HD video-camera system. A silicon tube bypass
was set between the left subclavian artery and the left anterior
descending artery after left thoracotomy and pericardiotomy. Coronary
blood flow was monitored by an electromagnetic flowmeter prefixed in
the arterial bypass. The left ventricular pressure was monitored with a
catheter-tip manometer. In two of eight dogs, an additional bypass was
placed between the distal great cardiac vein and right atrium for
coronary venography. Two to three coronary arteriograms and/or
two venograms were obtained with a 15-min interval between the
injections; arteriograms were obtained at baseline in eight dogs,
during intracoronary dobutamine (0.1 µg · kg1 · min1)
in five dogs, and at coronary blood flow reduction to 40-50% of
the baseline value in four dogs, and coronary venography was obtained
at baseline in two dogs and during intracoronary administration of
dobutamine in one dog. Two to three milliliters per second of iodine
contrast material (iopamidol, Nihon Schering, Osaka, Japan, or
iomeprol, Eisai, Tokyo, Japan) were injected into the bypass circuit
via a three-way stopcock placed in the bypass for an injection period
of 1.5-2.0 s while the dog was irradiated with 33.3 keV SR. The
dogs were set nearly supine. The SR beam direction was set so as to
pass through the left ventricular free wall from the posterobasal to
the anteroapical direction. We also conducted fine adjustment of each
dog's posture to obtain an optimal visual field; the target diagonal
branch ran along the horizontal axis in the upper one-third of the
visual field, and the monochromatic SR was nearly perpendicular to the
virtual plane including the diagonal branch and its PTAs.
Microangiography using monochromatic synchrotron radiation.
The coincidental SR at the beamline North-East-5 of the Accumulation
Ring (ARNE5) or beamline 14-C from the Photon Factory (PF14) in the
National Laboratory for High Energy Physics (Tsukuba, Japan) were
monochromatized at 33.3 keV (just above the
k-absorption edge of iodine) to
optimize the detection of iodine and were magnified ×8-20 by
means of an asymmetrically cut silicon crystal in front of the objects
(Bragg reflection) (8). The angle of the coincidental beam direction
and the lattice plane of the silicon crystal (Bragg angle: 
)
determine the energy of the diffracted monochromatic X-ray, and the
angle of the lattice plane and the surface of the crystal () and the
Bragg angle determine the magnification ratio, as described
previously (8, 13, 14). Monochromatic X-rays passing through the
objects produced fluorescent images on the fluorescent screen. The
visual field (scanning area on fluorescent screen) of the object was
2-3 cm by 2 cm and was not affected by the geometric relations
among the light source, object, and detecting system, because
monochromatic SR is a nearly parallel beam. These images were scanned
by the HD video-camera system with a high-sensitivity image pick-up
tube (avalanche-type video camera, either New Super Harp, Nippon Hoso
Kyokai, or Harpicon, Hitachi, Tokyo, Japan) (12, 13, 21, 22) and then
stored on the digital video system (HDD-1000, Sony, Tokyo, Japan) or a
digital audio tape (C2594D, 2-8 GB, Hewlett-Packard, Palo Alto, CA) via a frame memory (12 bit/pixel) controlled by a work station (HP
9000 series 700, Hewlett-Packard). The image pick-up tube of the
avalanche-type HD video camera contains an amorphous
selenium-photoconductive target (12, 21) in which an electron-hole pair
produced by an incident photon is accelerated by the application of a
large electric field (avalanche phenomenon). The degree of
multiplication indicated by an effective quantum ratio increases as the
thickness of the selenium-photoconductive target, and the voltage of
the electric field increases. This mechanism allows internal low-noise amplification up to >600 times that of the conventional video camera
for the New Super Harp system and 30 times for the Harpicon system. A
resolution bar chart (MICK type 14:2.0-20.0 line pairs/mm) study
and a digital subtraction angiography phantom (type 76-700 Nuclear
Associates, Carle Place, NY) study confirmed that this system can
separate the adjacent lead line of 16 line pairs per millimeter (30 µm apart from each other) and can visualize vascular phantoms with a
diameter of 500 µm and a minimum concentration of iodine (2.5 mg/ml)
through a 7.5-cm-thick acrylic block. HD video-camera systems generally
lose their sensitivity when their spatial resolution is improved,
because the number of photons per unit area decreases as the spatial
resolution increases. In this regard, the present HD video camera,
which has an avalanche multiplication capacity, can be considered an
ideal detecting system for obtaining precise vascular images without
loss of sensitivity.
Assessment of configuration of penetrating transmural arteries and
dynamic flow appearance.
The configurational changes in PTAs and epicardial coronary arteries
during a cardiac cycle were assessed on a computer (Power Macintosh
7100/80AV, Apple Computers, Cupertino, CA) using software in the public
domain (NIH Image version 1.61) with some modifications after transfer
from a digital memory source, as described in a previous paper (20).
Before measurement, the angiographic images were processed using the
linear interpolation method (15). This method allows reduction of
effective pixel size to 9.8 × 9.8 µm by increasing the number
of pixels in a 2 × 2-cm visual field to 2,048 × 2,048. The
measured configuration indexes were the short-axial vascular diameter,
as an index of vascular compression, and the longitudinal dimension of
the proximal segment (a linear distance between the origin of the PTA
and the first bifurcation point), reflecting vascular stretch. We
selected a relatively late cardiac cycle in which PTAs were filled with
contrast materials substantially for the configurational assessment.
Vessel diameter is defined as the shortest distance between the two
edges of a target vessel filled with contrast materials. First, we
obtained the density profile at the measurement level. Local variation in the density profile was reduced by applying the running average method with a window value of 3 to 7 (15). The edges of the vessels
were defined as the distance between the bilateral half-maximum points
of the modified profile. In a preliminary study, the diameters of 37 vessels with a diameter range of 50-670 µm were independently measured by a medical student not involved in the experimental protocol
and by a core member of the project. Regression analysis of the two
sets of measurements yielded a regression coefficient of
y = 1.02x 
1.07 µm (r = 0.999, P < 0.001) and a very small standard
deviation of the independent variables from the regression line (6.36 µm). Observation of the longitudinal vascular segment in a cardiac
cycle allowed us to differentiate PTAs from the vessels on the surface,
because PTAs (white arrowheads in Fig. 1)
are stretched in systole, whereas surface vessels are shrunk (black arrowheads). The diameters of the PTA segments were measured at 62 sites with a mean depth of 3.2 ± 2.4 mm; sites were the midpoint of
the origin of the PTA and the first bifurcation point, the midpoint of
the first and second bifurcation points, or even lower levels. In 13 of the 62 segments, the diameter changes of
the subendocardial segments at the level of 6.9 ± 0.9 mm from the epicardial surface (echocardiographically determined myocardial thickness of 8.0-9.0 mm) were compared with that of their proximal segments at the level of 1.5 ± 0.7 mm. Diameter changes of
epicardial coronary arteries were determined at the midpoint of the
origins of adjacent PTAs (n = 31). End diastole was defined as one or two frames (33-66 ms)
before the time point at which the left ventricular pressure rose, and
end systole was the end of the systolic plateau phase of the left
ventricular pressure, based on simultaneously measured left ventricular
pressure patterns. The longitudinal dimension of the proximal segment
was defined as a linear distance between the origin of the PTA and the
first bifurcation point.
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Fig. 1.
Representative microangiograms of penetrating transmural arteries
(PTA) arising from diagonal branches: diastole at baseline
(A) and systole
(B). Single, double, and triple
white arrowheads indicate first-, second-, and third-order branches of
large penetrating transmural arteries; 2 broad arrows indicate
longitudinal dimension of proximal segment of a penetrating transmural
artery; and black arrowheads indicate epicardial coronary artery.
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The to-and-fro appearances of blood in PTAs were evaluated by employing
frame-by-frame analysis and slow-motion analysis on the HD video system
(HDD-1000). We selected a relatively earlier cardiac cycle than that
used for the configurational analysis. In this cardiac cycle, the
contrast materials completely filled the proximal segments of PTAs but
not the distal segments at the initial end diastole. When the border
between the contrast material- and the noncontrast material-containing
blood within the PTA moved retrogradely during systole (elimination)
and moved anterogradely during the next diastole (refilling), and then,
in the subsequent systole, the distal segments from which blood was
"squeezed out" became visible on frame-by-frame analysis or
slow-motion analysis, we judged these observations to represent the
"to-and-fro appearance" or "slosh phenomenon." However,
under baseline and dobutamine treatment conditions, often both the
proximal and the distal segments of PTAs were filled during the initial
cardiac cycle, or the filling of the distal segments with contrast
material was not adequate for visualization even in the later cardiac
cycle. In these cases, we could not confirm the existence of the
to-and-fro appearance, because we were not in a position to distinguish
whether blood was entering from the proximal artery or from distal
sites in the former, or to distinguish the two conditions of invisible distal segments due to the retrograde flow and reduction in the amount
of the contrast material below the detection limit during systole in
the latter. Thus such angiographic determination of the to-and-fro
appearance of blood flow in PTAs is expected to yield substantial
numbers of false negatives.
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RESULTS |
The present microangiographic system visualized a total of 189 PTAs
(diameter range 60-650 µm) arising from the 9 diagonal branches
as well as 7 distal portions of the left anterior descending artery in
8 dogs, more than 4 intramural coronary arteries (PTA) per 1-cm segment
of each mother epicardial branch. We measured the diameter change of
the vascular segments that had a diastolic value of 140-650 µm.
The PTA, the branches of which are indicated by white arrowheads in
Fig. 1, penetrated deep into the heart wall and probably fed deep
myocardium. Its first-, second-, and third-order branches could be
identified (single, double, and triple white arrowheads in Fig. 1). The
detection rates of the first-, second-, and third-order branches of the
189 PTAs were 62, 17, and 3%, respectively. The two broad arrows in
Fig. 1, A and
B, indicate the longitudinal dimension
of the primary segment defined by the distance between the PTA origin
and the bifurcation point of the first-order branch. Comparison of
angiograms at diastole (Fig. 1A)
and systole (Fig. 1B) revealed that
myocardial contraction compressed the PTAs (reducing the short-axial
diameter) along the circumferential direction and stretched the vessels
(increasing the longitudinal dimension) toward the ventricular cavity
(hemodynamic values in Table
1). As shown in Fig.
2, the linear distance of the proximal PTA
segments increased to 129 ± 25% of the diastolic value
(n = 45, Fig.
2A), and in contrast, the
short-axial diameters were reduced in systole to 87 ± 17% of the
diastolic value (340 ± 110 µm, n = 62, Fig. 2B). As shown
in Fig. 2C, the diameter of epicardial
coronary vessels increased significantly in systole to 110 ± 8% of
the end-diastolic value (from 700 ± 130 to 760 ± 150 µm,
P < 0.01, paired
t-test). The degree of vascular
compression (%diameter change in systole) was more marked in the deep
site than in the superficial site (60 ± 12 vs. 88 ± 12%,
P < 0.001, paired
t-test) in the 13 PTAs in which
diameter could be measured at both the primary segment and the
subendocardial segments (depths of measured sites: 1.5 ± 0.7 and
6.9 ± 0.9 mm, respectively). The percent change in diameter in
systole correlated roughly with depth of measurement site from the
epicardial surface (r = 0.51, P < 0.001, Fig.
3) but not with vessel size at end diastole
(r = 0.11, Fig.
2B). Intracoronary administration of
dobutamine (0.1 µg · kg1 · min1)
also revealed significant changes in the degree of the reduction in the
short-axial diameter (76 ± 12%, n = 19, P < 0.001, paired t-test) and the increase in the
longitudinal dimension (138 ± 35%,
n = 15, P < 0.001). In the groups of 19 and
13 PTAs in which contractile changes could be measured at both baseline
and during intracoronary administration of dobutamine (see hemodynamic
values in Table 1), the degrees of reduction in the short-axial
diameters (90 ± 7 vs. 76 ± 12%, respectively,
n = 19, P < 0.001, paired t-test) and the degree of increase in
the longitudinal dimension (127 ± 37 vs. 143 ± 35%,
respectively, P < 0.001, n = 13, paired t-test) were more marked during
dobutamine administration than at baseline. Partial clamping of the
proximal bypass circuit, causing a reduction of coronary blood flow to
40-50% of the baseline value (see hemodynamic values in Table 1),
attenuated the relative changes in the short-axial diameters (96 ± 13%, n = 18, P < 0.05 with end-diastolic value,
paired t-test) and longitudinal
dimension (110 ± 20%, n = 21, not
significant) in systole.
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Fig. 2.
Relationships of degree of stretch of proximal PTA segments
(A), relative diameter changes of
PTA (B), and relative diameter
changes of epicardial coronary segments
(C) in systole to their
end-diastolic values. As indicated by horizontal bars at level of
100%, proximal PTA segments increased longitudinally, PTA diameter
decreased, and diameter of epicardial coronary segments increased.
There was no significant correlation of either of the relative changes
in systole to the end-diastolic value.
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Fig. 3.
Correlation analysis of relative changes in PTA diameter to depth of
vessels from epicardial surface. There is a significant negative
correlation.
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The to-and-fro appearance of coronary blood flow (slosh phenomenon) was
more evident during partial clamping of the bypass circuit, causing a
coronary blood flow reduction to 40% of the baseline value (Fig.
4), than at baseline or during dobutamine treatment. The systolic squeezing of blood in the PTA (Fig. 4, arrowhead) was extended even into the epicardial coronary artery (Fig.
4, arrow) beyond the origins of PTAs (compare Fig. 4,
A and
B). The difference between the
contrast filling area of the PTAs in the two sequential end diastoles
(Fig. 4, A and
C, and D and
F) indicates the effective forward
flow toward the capillary beds (resistive flow) (2), and the difference
between the end systole and the preceding end diastole (Fig. 4,
A and
B, and
D and
E) represents the amount of
retrograde flow, which enhances the intravascular volume in the upper
stream and does not contribute to exchange of gas and nutrients in the
capillary beds (capacitive backflow) (2). The difference between the
end systole and the next end diastole (Fig. 4,
B and
C, and
E and
F) is the sum of the capacitive and
resistive flow. The degree of to-and-fro flow was not uniform among the
PTAs; the resistive forward flow in the PTA at the most distal site
(difference in contrast filling area of vessel as indicated by
arrowhead in Fig. 4, D and
F) is almost negligible and is
apparently less than that in the PTA at the proximal site (indicated by
arrowhead in Fig. 4, A-C). Systolic
forward flow is noted only in the terminal epicardial segment (Fig.
4E, arrow), which did not have any
intramural segments distally. Under baseline conditions and during
intracoronary administration of dobutamine, the to-and-fro appearance
of intramyocardial coronary blood flow was observed only in the deep
portions of PTAs and did not extend beyond the proximal segments. In
coronary venograms, systolic squeezing out of intramural blood was
noted even in the baseline condition (Fig.
5). The entire intramyocardial venous segment was filled with contrast material in diastole (Fig.
5A). During systole the whole
segment of PTAs became invisible (Fig. 5B), and in the subsequent diastole,
refilling of these venous segments with the contrast was seen (Fig.
5C).
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Fig. 4.
Angiograms showing to-and-fro appearance of intramural arterial flow
during partial occlusion of coronary vessels.
A-C: angiograms obtained during
initial diastole, in subsequent systole, and then in next diastole,
respectively, in early cardiac cycle.
D-F: angiograms obtained during
initial diastole, in subsequent systole, and then in next diastole,
respectively, in late cardiac cycle. Arrowheads and arrows indicate
visible terminal portion of PTAs and coronary arterial segments on
epicardial surface. Wide arrows in A
and B indicate increase of epicardial
vessel diameter in systole.
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Fig. 5.
Angiograms showing to-and-fro appearance of intramural venous flow
under baseline condition. Angiograms were obtained during initial
diastole (A), in subsequent systole
(B), and then in next diastole
(C). Arrowheads indicate intramural
veins.
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DISCUSSION |
Considerations of experimental model.
The principal advantage of the present method is the visualization of
intramural coronary vessels. Neither the floating-type microscope (1)
nor needle-probe videomicroscope (25) can be applied to visualize
intramural coronary vessels. In addition, the present method allows
less invasive visualization of intramyocardial vessels and epicardial
coronary artery. With the needle-probe videomicroscope, an inflated
balloon is attached to the myocardial surface surrounding the target
epicardial vessels. In addition, to observe endocardial arterioles, the
needle has to be passed through the left ventricular cavity. With the
floating-type microscope, the subepicardial muscle just below the
target epicardial vessels must be punctured with a needle to fix the
objective lens. One of the disadvantages of the present system is
concomitant contrast material effects, which alter the vascular tonus
and partially mask actual retrograde flow. In addition, the spatial
resolution in the present system was poorer (9.8 µm in pixel size)
than with the microscopic systems (1 and 5 µm, respectively). In the
baseline and under dobutamine treatment, accompanying a high filling
rate of contrast materials into the PTAs, the whole intramural arterial segments are filled with contrast materials within a single heart cycle. Under these conditions, the blood squeezing out of the distal
PTAs already contains the contrast materials and makes it difficult to
visualize the to-and-fro appearance. This might have affected the
to-and-for appearance of PTAs under dobutamine administration, which
was noted only in the deep (distal) PTA segments (see
RESULTS).
New observations.
In systole, the short-axial diameter of PTAs was reduced (compression
along the circumference of the left ventricle) and their longitudinal
dimension was increased (longitudinal stretching) toward the
ventricular cavity (Figs. 1 and 2). The degree of compression correlated to the depth of the vessels with a predominance in the
subendocardial segments (Fig. 3). These changes were enhanced by
intracoronary administration of dobutamine. Partial clamping of the
proximal site of the coronary arterial bypass almost abolished the
systolic compression. The to-and-fro appearance of intramyocardial blood flow was visualized with an identification of capacitive backflow
and resistive forward flow by the present angiographic system (Figs. 4
and 5). The relative magnitudes of resistive and capacitive flow
predict the degree of to-and-fro flow in each PTA. Under partial
occlusion of the proximal coronary artery, the relative magnitudes of
these flows were not uniform among the PTAs (compare the vessel
indicated by arrowheads in Fig. 4, A-C, and that in
D-F). On coronary venography, marked
squeezing out of intramural blood was noted even in the baseline
condition (Fig. 5).
Comparisons of present results with previous reports.
The present results could be interpreted as direct evidence supporting
the classic hypothesis of Scaramucci (18) in 1695 that "the
myocardial vessels are squeezed by the contraction of the muscle fibers
around them" and the newest hypothesis of the systolic-diastolic
interaction model in coronary circulation advocated by Spaan et al.
(19), Hoffman and Spaan (7), and Flynn et al. (5). The longitudinal
stretching of the vessels noted in the present study (Fig.
2A) allows the extravascular
pressure to be transmitted to the intramural vessels efficiently. Flynn et al. (5) speculated that the blood ejected from the endocardium flows
into epicardial small vessels during systole and that aortic pressure
acts as a back pressure to the reverse flow into extramural vessels
under baseline conditions. This hypothesis was confirmed by the direct
visualization of retrograde flow from PTAs into epicardial vessels
(Fig. 4) and the vascular diameter changes in intramural and
epicardial vessels (Fig. 2). However, the systolic forward flow in the
epicardial vessels reported by Ashikawa et al. (1) and by Yada et al.
(25) was noted only in the terminal segment without intramural branches
during partial clamping of the coronary bypass circuit. The more marked
emptying of the intramural veins during systole (Fig. 5) is compatible
with the description by Wiggers (24) that "the volume of blood that
can enter intramural vessels during diastole must depend to some extent
on the degree to which they are emptied during preceding systole."
The lower back pressure for the anterograde intramural venous flow
(right atrial pressure) than that for the retrograde PTA flow (aortic pressure) appears to be a major reason for this phenomenon. The degree
of diameter change in the subepicardial PTA segment (88% of diastolic
value, on average), measured at a depth of 1.5 ± 0.7 mm, was quite
different from changes in small epicardial vessels (negligible changes
throughout cardiac cycle) reported by Ashikawa et al. (1) using a
floating-type microscope. Changes in the subendocardial segments (60%
of diastolic value), measured at a depth of 6.9 ± 0.9 mm, was more
marked than change seen in the endocardial arteriole by Yada et al.
(25) employing a needle-probe videomicroscope with a charge-coupled
device camera (20% reduction). Ashikawa et al. (1) reported that
vascular diameter in small subepicardial vessels, i.e., those with a
diameter 
20 µm, is essentially unchanged throughout the cardiac
cycle, and systolic forward flow is greater than in diastole. Yada et
al. (25) also reported similar diameter changes in the epicardial
arteriole. However, in the present study, the diameters of proximal
segments of PTAs were significantly reduced. Judd and Levy (9) reported that the vascular volume in the diastolic arrested heart was larger than in the systolic arrested heart, even in the subepicardium. This
discrepancy and the more marked diameter reduction in the subendocardial vessels than in the report by Yada et al. (25) might be
related to the anatomic differences in the observed vessels. We
visualized subepicardial segments of PTAs that were running through the
heart wall toward the left ventricular cavity and, therefore, that were
being compressed nearly perpendicularly by the heart muscle along their
short axes. In contrast, Yada et al. (25) and Ashikawa et al. (1)
observed the vessels apparently running parallel to the epicardial or
endocardial surface. The difference in the size of the observed vessels
might account, to some extent, for the difference in the degree of the
compression between ours and those observed by Ashikawa et al. (1). The diameters of the vessels we observed (340 ± 10 µm) were much
larger than those (20 µm) studied by Ashikawa et al. (1). However, the difference between our data and those of Yada et al. (25) was
modest (169 ± 12 µm). Yada et al. (25) reported significant size
dependency in the degree of reduction in vascular diameter by measuring
the vessels ranging mainly from 50 to 250 µm. There was an obvious
difference in the degree of reduction in the vessel diameter of <100
µm and that of >100 µm. In contrast, our measurements did not
include so-called resistance vessels with diameters of <100 µm,
which were characterized by fewer diameter changes than the larger
segments. An alternative explanation is related to the technical
inherency of the methods. The puncture of subepicardial muscle (1) or
balloon attachment on the myocardial surface (25) might have reduced
the extravascular compression to small coronary vessels.
In conclusion, by using SR microangiography, we demonstrated the
effects of cardiac contraction on intramural coronary diameters and
flows. This information is essential for an understanding of the
influences of contraction on the phasic nature of perfusion, and in
future studies in which this method is used, the long-standing controversies concerning the intramyocardial coronary flow dynamics might be solved; i.e., the intramyocardial pump model (5, 7, 19) versus
the coronary vascular elastance model (11), the radiation of left
ventricular pressure (4, 23) versus the local stiffness or strain of
myocardial fibers (7, 16) as the major source of extravascular
compression, and the existence versus absence of the so-called
waterfall phenomenon (4) in intramural arteries and/or veins.
| |
ACKNOWLEDGEMENTS |
This project was supported by a Grant-in-Aid for Scientific
Research (07557060, 07807073, 09670756) from the Ministry of Education, Science, and Culture, Japan; Japan Society for the Promotion of Science
Grant JSPS-RFTF-97I00201; and Tokai University School of Medicine
Project Research (1997). This project was approved as a Joint Research
Program of the National Laboratory for High Energy Physics, Tsukuba
(93G241, 95G113).
| |
FOOTNOTES |
The costs of publication of this
article were defrayed in part by the
payment of page charges. The article
must therefore be hereby marked
"advertisement"
in accordance with 18 U.S.C. §1734 solely to indicate this fact.
Address for reprint requests: H. Mori, Dept. of Physiology, Tokai Univ.
School of Medicine, Boseidai, Isehara, Kanagawa 259-1193, Japan.
Received 29 June 1998; accepted in final form 7 October 1998.
| |
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Abstract
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