СОСУДОДВИГАТЕЛЬНЫЙ ЦЕНТР СТВОЛА МОЗГА [ cardiovascular center ]
Сердечно-сосудистый центр - это совокупность специализированных структур, расположенных на разных уровнях нервной системы, управляющих кровообращением. Сердечно-сосудистый центр - главный специфический регулятор (в иерархии экзогенных регуляторов) системы кровообращения, организующий структуру системы и взаимодействие процессов различных частей системы кровообращения.
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Схема. Дистальные (эфферентные) связи сердечно-сосудистого центра ствола мозга (часть сердечно-сосудистого центра) с конечным исполнительным звеном. Структуры симпатического и парасимпатического отделов нервной системы, управляющие функциями сердца и сосудов. Модификация: Arthur C. Guyton, M.D., John E. Hall, Ph.D. Textbook of Medical Physiology, 11th ed., 2006. W.B. Saunders Company. A Harcourt Health Company. Philadelphia, London, New York, St. Louis, Sydney, Toronto.
Примечание:
В верхней части схемы показан сосудодвигательный центр продолговатого мозга и нижней трети моста. В нижней части схемы показаны конечное исполнительное звено регулятора - структуры спинного мозга и симпатическая цепочка.
Выделяют четыре уровня в иерархии регуляторов кровообращения, иерархии структур сердечно-сосудистого центра. Первый уровень - структуры спинного мозга (симпатические нейроны боковых рогов). Второй уровень - структуры сердечно-сосудистого центра, расположенные в стволе мозга (сосудодвигательный центр в области ретикулярной формации, бульбарных отделов моста). Стволовые центры управляют как работой сердца, так и сосудов. Третий уровень - структуры среднего и промежуточного мозга (ретикулярная формация, гипоталамус). Четвертый уровень - структуры коры больших полушарий (неокортекс в области наружной поверхности полушарий, палеокортекс медиальных поверхностей полушарий и базальных поверхностей лобных и теменных долей. Чем выше уровень структур, тем меньше их специфичность по отношению к функциям системы кровообращения. Управляющие сигналы от этих нервных (экзогенных) регуляторов поступают через вегетативный отдел нервной системы (симпатический и парасимпатический регуляторы) к местным (эндогенным) регуляторам частных процессов, составляющих сущность кровообращения. Местные регуляторы могут быть нейрогенной, миогенной или эндокринной природы. Управляющие сигналы регуляторов любого уровня иерархии могут быть непосредственными нервными или опосредованными - гуморальными (химическими, эндокринными). Главными управляемыми переменными для сердечно-сосудистого центра являются уровень и дисперсия: объёма систолического выброса крови желудочком сердца, частоты сокращений сердца, просвета (внутренний диаметр) сосудов, давления крови, скорости кровотока, фильтрации и реабсорбции в кровеносных капиллярах. |
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Схема. Связи сосудодвигательного центра ствола мозга с вышележащими отделами головного мозга. Модификация: Arthur C. Guyton, M.D., John E. Hall, Ph.D. Textbook of Medical Physiology, 11th ed., 2006. W.B. Saunders Company. A Harcourt Health Company. Philadelphia, London, New York, St. Louis, Sydney, Toronto.
Управление процессом кровообращения в целом осуществляется без непосредственного участия сознания.
Основным принципом оптимального (наилучшего с точки зрения быстродействия, точности, минимального действия одновременно) управления любыми процессами в системе кровообращения является прогнозирование (Трифонов Е.В., 1977, 1978, 1980). Такое управление осуществляется относительно координат пространства и времени. Благодаря прогнозированию, кровь подается туда, куда нужно, в тех количествах, в каких нужно, и заблаговременно, не раньше и не позже, чем в те моменты времени, когда это необходимо для достижения цели.
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См.: Система кровообращения: словарь, Система кровообращения: Литература. Иллюстрации, Управление кровообращением: Литература. Иллюстрации, Показатели деятельности системы кровообращения.
Arthur C. Guyton, M.D., John E. Hall, Ph.D. Textbook of Medical Physiology, 11th ed., 2006. W.B. Saunders Company. A Harcourt Health Company. Philadelphia, London, New York, St. Louis, Sydney, Toronto.
Vasomotor Center in the Brain and Its Control of the Vasoconstrictor System.
Located bilaterally mainly in the reticular
substance of the medulla and of the lower third
of the pons, shown in Figures 18–1 and 18–3, is an area
called the vasomotor center. This center transmits
parasympathetic impulses through the vagus nerves to
the heart and transmits sympathetic impulses through
the spinal cord and peripheral sympathetic nerves
to virtually all arteries, arterioles, and veins of the
body.
Although the total organization of the vasomotor
center is still unclear, experiments have made it
possible to identify certain important areas in this
center, as follows:
1. A vasoconstrictor area located bilaterally in the
anterolateral portions of the upper medulla. The
neurons originating in this area distribute their
fibers to all levels of the spinal cord, where they
excite preganglionic vasoconstrictor neurons of the
sympathetic nervous system.
2. A vasodilator area located bilaterally in the
anterolateral portions of the lower half of the
medulla. The fibers from these neurons project
upward to the vasoconstrictor area just described;
they inhibit the vasoconstrictor activity of this area,
thus causing vasodilation.
3. A sensory area located bilaterally in the tractus
solitarius in the posterolateral portions of the
medulla and lower pons. The neurons of this area
receive sensory nerve signals from the circulatory
system mainly through the vagus and
glossopharyngeal nerves, and output signals from
this sensory area then help to control activities of
both the vasoconstrictor and vasodilator areas of
the vasomotor center, thus providing “reflex”
control of many circulatory functions. An example
is the baroreceptor reflex for controlling arterial
pressure, which we describe later in this chapter.
Continuous Partial Constriction of the Blood Vessels Is Normally
Caused by Sympathetic Vasoconstrictor Tone. Under
normal conditions, the vasoconstrictor area of the
vasomotor center transmits signals continuously to
the sympathetic vasoconstrictor nerve fibers over the
entire body, causing continuous slow firing of these
fibers at a rate of about one half to two impulses per
second.This continual firing is called sympathetic vasoconstrictor
tone. These impulses normally maintain a
partial state of contraction in the blood vessels, called
vasomotor tone.
Figure 18–4 demonstrates the significance of vasoconstrictor
tone. In the experiment of this figure,
total spinal anesthesia was administered to an animal.
This blocked all transmission of sympathetic nerve
impulses from the spinal cord to the periphery. As a
result, the arterial pressure fell from 100 to 50 mm Hg,
demonstrating the effect of losing vasoconstrictor tone
throughout the body. A few minutes later, a small
amount of the hormone norepinephrine was injected
into the blood (norepinephrine is the principal
vasoconstrictor hormonal substance secreted at the
endings of the sympathetic vasoconstrictor nerve
fibers throughout the body). As this injected hormone
was transported in the blood to all blood vessels, the
vessels once again became constricted, and the arterial
pressure rose to a level even greater than normal for
1 to 3 minutes, until the norepinephrine was destroyed.
Control of Heart Activity by the Vasomotor Center. At the
same time that the vasomotor center is controlling the
amount of vascular constriction, it also controls heart
activity. The lateral portions of the vasomotor center
transmit excitatory impulses through the sympathetic
nerve fibers to the heart when there is need to increase
heart rate and contractility. Conversely, when there is
need to decrease heart pumping, the medial portion of
the vasomotor center sends signals to the adjacent
dorsal motor nuclei of the vagus nerves, which then
transmit parasympathetic impulses through the vagus
nerves to the heart to decrease heart rate and heart
contractility. Therefore, the vasomotor center can
either increase or decrease heart activity. Heart rate
and strength of heart contraction ordinarily increase
when vasoconstriction occurs and ordinarily decrease
when vasoconstriction is inhibited.
Control of the Vasomotor Center by Higher Nervous Centers.
Large numbers of small neurons located throughout
the reticular substance of the pons, mesencephalon,
and diencephalon can either excite or inhibit the
vasomotor center. This reticular substance is shown
in Figure 18–3 by the rose-colored area. In general, the
neurons in the more lateral and superior portions
of the reticular substance cause excitation, whereas
the more medial and inferior portions cause inhibition.
The hypothalamus plays a special role in controlling
the vasoconstrictor system because it can exert either
powerful excitatory or inhibitory effects on the vasomotor
center. The posterolateral portions of the hypothalamus
cause mainly excitation, whereas the anterior
portion can cause either mild excitation or inhibition,
depending on the precise part of the anterior hypothalamus
stimulated.
Many parts of the cerebral cortex can also excite or
inhibit the vasomotor center. Stimulation of the motor
cortex, for instance, excites the vasomotor center
because of impulses transmitted downward into the
hypothalamus and thence to the vasomotor center.
Also, stimulation of the anterior temporal lobe, the
orbital areas of the frontal cortex, the anterior part of
the cingulate gyrus, the amygdala, the septum, and the
hippocampus can all either excite or inhibit the vasomotor
center, depending on the precise portions of
these areas that are stimulated and on the intensity of
stimulus.Thus, widespread basal areas of the brain can
have profound effects on cardiovascular function.
Norepinephrine—The Sympathetic Vasoconstrictor Transmitter
Substance. The substance secreted at the endings of the
vasoconstrictor nerves is almost entirely norepinephrine.
Norepinephrine acts directly on the alpha adrenergic
receptors of the vascular smooth muscle to cause
vasoconstriction, as discussed in Chapter 60.
Adrenal Medullae and Their Relation to the Sympathetic Vasoconstrictor
System. Sympathetic impulses are transmitted
to the adrenal medullae at the same time that they
are transmitted to the blood vessels. They cause the
medullae to secrete both epinephrine and norepinephrine
into the circulating blood.These two hormones are
carried in the blood stream to all parts of the body,
where they act directly on all blood vessels, usually
to cause vasoconstriction, but in an occasional tissue
epinephrine causes vasodilation because it also has
a “beta” adrenergic receptor stimulatory effect, which
dilates rather than constricts certain vessels, as discussed
in Chapter 60.
Sympathetic Vasodilator System and its Control by the Central
Nervous System. The sympathetic nerves to skeletal
muscles carry sympathetic vasodilator fibers as well as
constrictor fibers. In lower animals such as the cat, these
dilator fibers release acetylcholine, not norepinephrine,
at their endings, although in primates, the vasodilator
effect is believed to be caused by epinephrine exciting
specific beta adrenergic receptors in the muscle
vasculature.
The pathway for central nervous system control of
the vasodilator system is shown by the dashed lines in
Figure 18–3. The principal area of the brain controlling
this system is the anterior hypothalamus.
Possible Unimportance of the Sympathetic Vasodilator System.
It is doubtful that the sympathetic vasodilator system
plays an important role in the control of the circulation
in the human being because complete block of the sympathetic
nerves to the muscles hardly affects the ability
of these muscles to control their own blood flow in
response to their needs. Yet some experiments suggest
that at the onset of exercise, the sympathetic vasodilator
system might cause initial vasodilation in skeletal
muscles to allow anticipatory increase in blood flow even
before the muscles require increased nutrients.
Emotional Fainting—Vasovagal Syncope. A particularly
interesting vasodilatory reaction occurs in people who
experience intense emotional disturbances that cause
fainting. In this case, the muscle vasodilator system
becomes activated, and at the same time, the vagal cardioinhibitory
center transmits strong signals to the heart
to slow the heart rate markedly. The arterial pressure
falls rapidly, which reduces blood flow to the brain and
causes the person to lose consciousness. This overall
effect is called vasovagal syncope. Emotional fainting
begins with disturbing thoughts in the cerebral cortex.
The pathway probably then goes to the vasodilatory
center of the anterior hypothalamus next to the vagal
centers of the medulla, to the heart through the vagus
nerves, and also through the spinal cord to the sympathetic
vasodilator nerves of the muscles.
Role of the Nervous System
in Rapid Control of
Arterial Pressure
One of the most important functions of nervous
control of the circulation is its capability to cause rapid
increases in arterial pressure. For this purpose, the
entire vasoconstrictor and cardioaccelerator functions
of the sympathetic nervous system are stimulated
together. At the same time, there is reciprocal inhibition
of parasympathetic vagal inhibitory signals to the
heart.Thus, three major changes occur simultaneously,
each of which helps to increase arterial pressure.They
are as follows:
1. Almost all arterioles of the systemic circulation
are constricted. This greatly increases the total
peripheral resistance, thereby increasing the arterial
pressure.
2. The veins especially (but the other large vessels of
the circulation as well) are strongly constricted.
This displaces blood out of the large peripheral
blood vessels toward the heart, thus increasing the
volume of blood in the heart chambers. The stretch
of the heart then causes the heart to beat with far
greater force and therefore to pump increased
quantities of blood. This, too, increases the arterial
pressure.
3. Finally, the heart itself is directly stimulated by the
autonomic nervous system, further enhancing
cardiac pumping. Much of this is caused by an
increase in the heart rate, the rate sometimes
increasing to as great as three times normal. In
addition, sympathetic nervous signals have a
significant direct effect to increase contractile
force of the heart muscle, this, too, increasing the
capability of the heart to pump larger volumes of
blood. During strong sympathetic stimulation, the
heart can pump about two times as much blood as
under normal conditions. This contributes still more
to the acute rise in arterial pressure.
Rapidity of Nervous Control of Arterial Pressure. An especially
important characteristic of nervous control of
arterial pressure is its rapidity of response, beginning
within seconds and often increasing the pressure to
two times normal within 5 to 10 seconds. Conversely,
sudden inhibition of nervous cardiovascular stimulation
can decrease the arterial pressure to as little as
one half normal within 10 to 40 seconds. Therefore,
nervous control of arterial pressure is by far the most
rapid of all our mechanisms for pressure control.
Increase in Arterial Pressure
During Muscle Exercise and Other
Types of Stress
An important example of the ability of the nervous
system to increase the arterial pressure is the increase
in pressure that occurs during muscle exercise. During
heavy exercise, the muscles require greatly increased
blood flow. Part of this increase results from local
vasodilation of the muscle vasculature caused by
increased metabolism of the muscle cells, as explained
in Chapter 17. Additional increase results from simultaneous
elevation of arterial pressure caused by sympathetic
stimulation of the overall circulation during
exercise. In most heavy exercise, the arterial pressure
rises about 30 to 40 per cent, which increases blood
flow almost an additional twofold.
The increase in arterial pressure during exercise
results mainly from the following effect: At the same
time that the motor areas of the brain become activated
to cause exercise, most of the reticular activating
system of the brain stem is also activated, which
includes greatly increased stimulation of the vasoconstrictor
and cardioacceleratory areas of the vasomotor
center. These increase the arterial pressure instantaneously
to keep pace with the increase in muscle
activity.
In many other types of stress besides muscle exercise,
a similar rise in pressure can also occur. For
instance, during extreme fright, the arterial pressure
sometimes rises to as high as double normal within a
few seconds. This is called the alarm reaction, and it
provides an excess of arterial pressure that can immediately
supply blood to any or all muscles of the body
that might need to respond instantly to cause flight
from danger.
Reflex Mechanisms for Maintaining
Normal Arterial Pressure
Aside from the exercise and stress functions of the
autonomic nervous system to increase arterial pressure,
there are multiple subconscious special nervous
control mechanisms that operate all the time to maintain
the arterial pressure at or near normal. Almost
all of these are negative feedback reflex mechanisms,
which we explain in the following sections.
The Baroreceptor Arterial Pressure Control
System—Baroreceptor Reflexes
By far the best known of the nervous mechanisms for
arterial pressure control is the baroreceptor reflex.
Basically, this reflex is initiated by stretch receptors,
called either baroreceptors or pressoreceptors, located
at specific points in the walls of several large systemic
arteries. A rise in arterial pressure stretches the
baroreceptors and causes them to transmit signals into
the central nervous system. “Feedback” signals are
then sent back through the autonomic nervous system
to the circulation to reduce arterial pressure downward
toward the normal level.
Physiologic Anatomy of the Baroreceptors and Their Innervation.
Baroreceptors are spray-type nerve endings that
lie in the walls of the arteries; they are stimulated when
stretched. A few baroreceptors are located in the wall
of almost every large artery of the thoracic and neck
regions; but, as shown in Figure 18–5, baroreceptors
are extremely abundant in (1) the wall of each internal
carotid artery slightly above the carotid bifurcation,
an area known as the carotid sinus, and (2) the
wall of the aortic arch.
Figure 18–5 shows that signals from the “carotid
baroreceptors” are transmitted through very small
Hering’s nerves to the glossopharyngeal nerves in
the high neck, and then to the tractus solitarius in the
medullary area of the brain stem. Signals from the
“aortic baroreceptors” in the arch of the aorta are
transmitted through the vagus nerves also to the same
tractus solitarius of the medulla.
Response of the Baroreceptors to Pressure. Figure 18–6
shows the effect of different arterial pressure levels on
the rate of impulse transmission in a Hering’s carotid
sinus nerve. Note that the carotid sinus baroreceptors
are not stimulated at all by pressures between 0 and
50 to 60 mm Hg, but above these levels, they respond
progressively more rapidly and reach a maximum at
about 180 mm Hg.The responses of the aortic baroreceptors
are similar to those of the carotid receptors
except that they operate, in general, at pressure levels
about 30 mm Hg higher.
Note especially that in the normal operating range
of arterial pressure, around 100 mm Hg, even a slight
change in pressure causes a strong change in the
baroreflex signal to readjust arterial pressure back
toward normal. Thus, the baroreceptor feedback
mechanism functions most effectively in the pressure
range where it is most needed.
The baroreceptors respond extremely rapidly to
changes in arterial pressure; in fact, the rate of impulse
firing increases in the fraction of a second during each
systole and decreases again during diastole. Furthermore,
the baroreceptors respond much more to a
rapidly changing pressure than to a stationary pressure.
That is, if the mean arterial pressure is 150 mm
Hg but at that moment is rising rapidly, the rate of
impulse transmission may be as much as twice that
when the pressure is stationary at 150 mm Hg.
Circulatory Reflex Initiated by the Baroreceptors. After the
baroreceptor signals have entered the tractus solitarius
of the medulla, secondary signals inhibit the vasoconstrictor
center of the medulla and excite the vagal
parasympathetic center. The net effects are (1) vasodilation
of the veins and arterioles throughout the
peripheral circulatory system and (2) decreased heart
rate and strength of heart contraction. Therefore, excitation
of the baroreceptors by high pressure in the
arteries reflexly causes the arterial pressure to decrease
because of both a decrease in peripheral resistance
and a decrease in cardiac output. Conversely, low pressure
has opposite effects, reflexly causing the pressure
to rise back toward normal.
Figure 18–7 shows a typical reflex change in arterial
pressure caused by occluding the two common carotid
arteries. This reduces the carotid sinus pressure; as a
result, the baroreceptors become inactive and lose
their inhibitory effect on the vasomotor center. The
vasomotor center then becomes much more active
than usual, causing the aortic arterial pressure to rise
and remain elevated during the 10 minutes that the
carotids are occluded. Removal of the occlusion allows
the pressure in the carotid sinuses to rise, and the
carotid sinus reflex now causes the aortic pressure to
fall immediately to slightly below normal as a momentary
overcompensation and then return to normal in
another minute.
Function of the Baroreceptors During Changes in Body
Posture. The ability of the baroreceptors to maintain
relatively constant arterial pressure in the upper body
is important when a person stands up after having
been lying down. Immediately on standing, the arterial
pressure in the head and upper part of the body tends
to fall, and marked reduction of this pressure could
cause loss of consciousness. However, the falling pressure
at the baroreceptors elicits an immediate reflex,
resulting in strong sympathetic discharge throughout
the body. This minimizes the decrease in pressure in
the head and upper body.
Pressure “Buffer” Function of the Baroreceptor
Control System. Because the baroreceptor system
opposes either increases or decreases in arterial pressure,
it is called a pressure buffer system, and the nerves
from the baroreceptors are called buffer nerves.
Figure 18–8 shows the importance of this buffer
function of the baroreceptors.The upper record in this
figure shows an arterial pressure recording for 2 hours
from a normal dog, and the lower record shows an
arterial pressure recording from a dog whose baroreceptor
nerves from both the carotid sinuses and the
aorta had been removed. Note the extreme variability
of pressure in the denervated dog caused by simple
events of the day, such as lying down, standing, excitement,
eating, defecation, and noises.
Figure 18–9 shows the frequency distributions of the
mean arterial pressures recorded for a 24-hour day in
both the normal dog and the denervated dog. Note
that when the baroreceptors were functioning normally
the mean arterial pressure remained throughout
the day within a narrow range between 85 and
115 mm Hg—indeed, during most of the day at almost
exactly 100 mm Hg. Conversely, after denervation of
the baroreceptors, the frequency distribution curve
became the broad, low curve of the figure, showing
that the pressure range increased 2.5-fold, frequently
falling to as low as 50 mm Hg or rising to over 160 mm
Hg. Thus, one can see the extreme variability of pressure
in the absence of the arterial baroreceptor
system.
In summary, a primary purpose of the arterial
baroreceptor system is to reduce the minute by minute
variation in arterial pressure to about one third that
which would occur were the baroreceptor system not
present.
Are the Baroreceptors Important in Long-Term Regulation of
Arterial Pressure? Although the arterial baroreceptors
provide powerful moment-to-moment control of
arterial pressure, their importance in long-term
blood pressure regulation has been controversial. One
reason that the baroreceptors have been considered
considerably; then it
diminishes much more slowly during the next 1 to 2
days, at the end of which time the rate of firing will
have returned to nearly normal despite the fact that
the mean arterial pressure still remains at 160 mm Hg.
Conversely, when the arterial pressure falls to a very
low level, the baroreceptors at first transmit no
impulses, but gradually, over 1 to 2 days, the rate of
baroreceptor firing returns toward the control level.
This “resetting” of the baroreceptors may attenuate
their potency as a control system for correcting disturbances
that tend to change arterial pressure for
longer than a few days at a time. Experimental studies,
however, have suggested that the baroreceptors do
not completely reset and may therefore contribute to
considerably; then it
diminishes much more slowly during the next 1 to 2
days, at the end of which time the rate of firing will
have returned to nearly normal despite the fact that
the mean arterial pressure still remains at 160 mm Hg.
Conversely, when the arterial pressure falls to a very
low level, the baroreceptors at first transmit no
impulses, but gradually, over 1 to 2 days, the rate of
baroreceptor firing returns toward the control level.
This “resetting” of the baroreceptors may attenuate
their potency as a control system for correcting disturbances
that tend to change arterial pressure for
longer than a few days at a time. Experimental studies,
however, have suggested that the baroreceptors do
not completely reset and may therefore contribute to
long-term blood pressure regulation, especially by
influencing sympathetic nerve activity of the kidneys.
For example, with prolonged increases in arterial pressure,
the baroreceptor reflexes may mediate decreases
in renal sympathetic nerve activity that promote
increased excretion of sodium and water by the
kidneys. This, in turn, causes a gradual decrease in
blood volume, which helps to restore arterial pressure
toward normal. Thus, long-term regulation of mean
arterial pressure by the baroreceptors requires
interaction with additional systems, principally the
renal–body fluid–pressure control system (along with
its associated nervous and hormonal mechanisms), discussed
in Chapters 19 and 29.
Control of Arterial Pressure by the Carotid and Aortic
Chemoreceptors—Effect of Oxygen Lack on Arterial Pressure.
Closely associated with the baroreceptor pressure
control system is a chemoreceptor reflex that operates in
much the same way as the baroreceptor reflex except
that chemoreceptors, instead of stretch receptors, initiate
the response.
The chemoreceptors are chemosensitive cells sensitive
to oxygen lack, carbon dioxide excess, and hydrogen
ion excess. They are located in several small
chemoreceptor organs about 2 millimeters in size (two
carotid bodies, one of which lies in the bifurcation of
each common carotid artery, and usually one to three
aortic bodies adjacent to the aorta). The chemoreceptors
excite nerve fibers that, along with the
baroreceptor fibers, pass through Hering’s nerves and
the vagus nerves into the vasomotor center of the brain
stem.
Each carotid or aortic body is supplied with an
abundant blood flow through a small nutrient artery, so
that the chemoreceptors are always in close contact
with arterial blood.Whenever the arterial pressure falls
below a critical level, the chemoreceptors become stimulated
because diminished blood flow causes decreased
oxygen as well as excess buildup of carbon dioxide and
hydrogen ions that are not removed by the slowly
flowing blood.
The signals transmitted from the chemoreceptors
excite the vasomotor center, and this elevates the arterial
pressure back toward normal. However, this chemoreceptor
reflex is not a powerful arterial pressure controller
until the arterial pressure falls below 80 mm Hg.
Therefore, it is at the lower pressures that this reflex
becomes important to help prevent still further fall in
pressure.
The chemoreceptors are discussed in much more
detail in Chapter 41 in relation to respiratory control,
in which they play a far more important role than in
pressure control.
Atrial and Pulmonary Artery Reflexes That Help Regulate Arterial
Pressure and Other Circulatory Factors. Both the atria and
the pulmonary arteries have in their walls stretch receptors
called low-pressure receptors. They are similar to
the baroreceptor stretch receptors of the large systemic
arteries.These low-pressure receptors play an important
role, especially in minimizing arterial pressure changes
in response to changes in blood volume. To give an
example, if 300 milliliters of blood suddenly are infused
into a dog with allreceptors intact, the arterial pressure
rises only about 15 mm Hg.With the arterial baroreceptors
denervated, the pressure rises about 40 mm Hg. If
the low-pressure receptors also are denervated, the pressure
rises about 100 mm Hg.
Thus, one can see that even though the low-pressure
receptors in the pulmonary artery and in the atria
cannot detect the systemic arterial pressure, they do
detect simultaneous increases in pressure in the lowpressure
areas of the circulation caused by increase in
volume, and they elicit reflexes parallel to the baroreceptor
reflexes to make the total reflex system more
potent for control of arterial pressure.
Atrial Reflexes That Activate the Kidneys—The “Volume Reflex.”
Stretch of the atria also causes significant reflex dilation
of the afferent arterioles in the kidneys. And still
other signals are transmitted simultaneously from the
atria to the hypothalamus to decrease secretion of
antidiuretic hormone.The decreased afferent arteriolar
resistance in the kidneys causes the glomerular capillary
pressure to rise, with resultant increase in filtration of
fluid into the kidney tubules. The diminution of antidiuretic
hormone diminishes the reabsorption of water
from the tubules. Combination of these two effects—
increase in glomerular filtration and decrease in reabsorption
of the fluid—increases fluid loss by the kidneys
and reduces an increased blood volume back toward
normal. (We will also see in Chapter 19 that atrial
stretch caused by increased blood volume also elicits a
hormonal effect on the kidneys—release of atrial natriuretic
peptide that adds still further to the excretion of
fluid in the urine and return of blood volume toward
normal.)
All these mechanisms that tend to return the blood
volume back toward normal after a volume overload act
indirectly as pressure controllers as well as blood
volume controllers because excess volume drives the
heart to greater cardiac output and leads, therefore, to
greater arterial pressure.This volume reflex mechanism
is discussed again in Chapter 29, along with other mechanisms
of blood volume control.
Atrial Reflex Control of Heart Rate (the Bainbridge Reflex). An
increase in atrial pressure also causes an increase in
heart rate, sometimes increasing the heart rate as much
as 75 per cent.A small part of this increase is caused by
a direct effect of the increased atrial volume to stretch
the sinus node: it was pointed out in Chapter 10 that
such direct stretch can increase the heart rate as much
as 15 per cent. An additional 40 to 60 per cent increase
in rate is caused by a nervous reflex called the Bainbridge
reflex.The stretch receptors of the atria that elicit
the Bainbridge reflex transmit their afferent signals
through the vagus nerves to the medulla of the brain.
Then efferent signals are transmitted back through
vagal and sympathetic nerves to increase heart rate and
strength of heart contraction. Thus, this reflex helps
prevent damming of blood in the veins, atria, and pulmonary
circulation.
Central Nervous System Ischemic
Response—Control of Arterial
Pressure by the Brain’s Vasomotor
Center in Response to Diminished
Brain Blood Flow
Most nervous control of blood pressure is achieved
by reflexes that originate in the baroreceptors, the
chemoreceptors, and the low-pressure receptors, all of
which are located in the peripheral circulation outside
the brain. However, when blood flow to the vasomotor
center in the lower brain stem becomes decreased
severely enough to cause nutritional defficiency—that is,
to cause cerebral ischemia—the vasoconstrictor and
cardioaccelerator neurons in the vasomotor center
respond directly to the ischemia and become strongly
excited.When this occurs, the systemic arterial pressure
often rises to a level as high as the heart can possibly
pump. This effect is believed to be caused by failure of
the slowly flowing blood to carry carbon dioxide away
from the brain stem vasomotor center: at low levels of
blood flow to the vasomotor center, the local concentration
of carbon dioxide increases greatly and
has an extremely potent effect in stimulating the sympathetic
vasomotor nervous control areas in the brain’s
medulla.
It is possible that other factors, such as buildup of
lactic acid and other acidic substances in the vasomotor
center, also contribute to the marked stimulation and
elevation in arterial pressure.This arterial pressure elevation
in response to cerebral ischemia is known as the
central nervous system ischemic response, or simply CNS
ischemic response.
The magnitude of the ischemic effect on vasomotor
activity is tremendous: it can elevate the mean arterial
pressure for as long as 10 minutes sometimes to as high
as 250 mm Hg. The degree of sympathetic vasoconstriction
caused by intense cerebral ischemia is often so great
that some of the peripheral vessels become totally or
almost totally occluded. The kidneys, for instance, often
entirely cease their production of urine because of renal
arteriolar constriction in response to the sympathetic
discharge. Therefore, the CNS ischemic response is one
of the most powerful of all the activators of the sympathetic
vasoconstrictor system.
Importance of the CNS Ischemic Response as a Regulator of Arterial
Pressure. Despite the powerful nature of the CNS
ischemic response, it does not become significant until
the arterial pressure falls far below normal, down to
60 mm Hg and below, reaching its greatest degree of
stimulation at a pressure of 15 to 20 mm Hg. Therefore,
it is not one of the normal mechanisms for regulating
arterial pressure. Instead, it operates principally as an
emergency pressure control system that acts rapidly and
very powerfully to prevent further decrease in arterial
pressure whenever blood flow to the brain decreases dangerously
close to the lethal level. It is sometimes called
the “last ditch stand” pressure control mechanism.
Cushing Reaction. The so-called Cushing reaction is a
special type of CNS ischemic response that results from
increased pressure of the cerebrospinal fluid around
the brain in the cranial vault. For instance, when the
cerebrospinal fluid pressure rises to equal the arterial
pressure, it compresses the whole brain as well as the
arteries in the brain and cuts off the blood supply to the
brain.This initiates a CNS ischemic response that causes
the arterial pressure to rise.When the arterial pressure
has risen to a level higher than the cerebrospinal fluid
pressure, blood will flow once again into the vessels of
the brain to relieve the brain ischemia. Ordinarily, the
blood pressure comes to a new equilibrium level slightly
higher than the cerebrospinal fluid pressure, thus allowing
blood to begin again to flow through the brain. A
typical Cushing reaction is shown in Figure 18–10,
caused in this instance by pumping fluid under pressure
into the cranial vault around the brain. The Cushing
reaction helps protect the vital centers of the brain from
loss of nutrition if ever the cerebrospinal fluid pressure
rises high enough to compress the cerebral arteries.
Special Features of Nervous
Control of Arterial Pressure
Role of the Skeletal Nerves and
Skeletal Muscles in Increasing
Cardiac Output and
Arterial Pressure
Although most rapidly acting nervous control of the circulation
is effected through the autonomic nervous
system, at least two conditions in which the skeletal
nerves and muscles also play major roles in circulatory
responses are the following.
Abdominal Compression Reflex. When a baroreceptor or
chemoreceptor reflex is elicited, nerve signals are transmitted
simultaneously through skeletal nerves to skeletal
muscles of the body, particularly to the abdominal
muscles. This compresses all the venous reservoirs of
the abdomen, helping to translocate blood out of the
abdominal vascular reservoirs toward the heart. As a
result, increased quantities of blood are made available
for the heart to pump.This overall response is called the
abdominal compression reflex. The resulting effect on
the circulation is the same as that caused by sympathetic
vasoconstrictor impulses when they constrict the veins:
an increase in both cardiac output and arterial pressure.
The abdominal compression reflex is probably much
more important than has been realized in the past
because it is well known that people whose skeletal
muscles have been paralyzed are considerably more
prone to hypotensive episodes than are people with
normal skeletal muscles.
Increased Cardiac Output and Arterial Pressure Caused by
Skeletal Muscle Contraction During Exercise. When the
skeletal muscles contract during exercise, they compress
blood vessels throughout the body. Even anticipation of
exercise tightens the muscles, thereby compressing
the vessels in the muscles and in the abdomen. The
resulting effect is to translocate blood from the peripheral
vessels into the heart and lungs and, therefore, to
increase the cardiac output.This is an essential effect in
helping to cause the fivefold to sevenfold increase in
cardiac output that sometimes occurs in heavy exercise.
The increase in cardiac output in turn is an essential
ingredient in increasing the arterial pressure during
exercise, an increase usually from a normal mean of
100 mm Hg up to 130 to 160 mm Hg.
Respiratory Waves in the
Arterial Pressure
With each cycle of respiration, the arterial pressure
usually rises and falls 4 to 6 mm Hg in a wavelike
manner, causing respiratory waves in the arterial pressure.
The waves result from several different effects,
some of which are reflex in nature, as follows:
1. Many of the “breathing signals” that arise in the
respiratory center of the medulla “spill over” into
the vasomotor center with each respiratory cycle.
2. Every time a person inspires, the pressure in the
thoracic cavity becomes more negative than usual,
causing the blood vessels in the chest to expand.
This reduces the quantity of blood returning to the
left side of the heart and thereby momentarily
decreases the cardiac output and arterial pressure.
3. The pressure changes caused in the thoracic vessels
by respiration can excite vascular and atrial stretch
receptors.
Although it is difficult to analyze the exact relations
of all these factors in causing the respiratory pressure
waves, the net result during normal respiration is usually
an increase in arterial pressure during the early part
of expiration and a decrease in pressure during the
remainder of the respiratory cycle. During deep respiration,
the blood pressure can rise and fall as much as
20 mm Hg with each respiratory cycle.
Arterial Pressure “Vasomotor”
Waves—Oscillation of Pressure
Reflex Control Systems
Often while recording arterial pressure from an animal,
in addition to the small pressure waves caused by respiration,
some much larger waves are also noted—as
great as 10 to 40 mm Hg at times—that rise and fall
more slowly than the respiratory waves.The duration of
each cycle varies from 26 seconds in the anesthetized
dog to 7 to 10 seconds in the unanesthetized human.
These waves are called vasomotor waves or “Mayer
waves.” Such records are demonstrated in Figure 18–11,
showing the cyclical rise and fall in arterial pressure.
The cause of vasomotor waves is “reflex oscillation”
of one or more nervous pressure control mechanisms,
some of which are the following.
Oscillation of the Baroreceptor and Chemoreceptor Reflexes.
The vasomotor waves of Figure 18–11B are often seen
in experimental pressure recordings, although usually
much less intense than shown in the figure. They are
caused mainly by oscillation of the baroreceptor reflex.
That is, a high pressure excites the baroreceptors;
this then inhibits the sympathetic nervous system and
lowers the pressure a few seconds later. The decreased
pressure in turn reduces the baroreceptor stimulation
and allows the vasomotor center to become active once
again, elevating the pressure to a high value. The
response is not instantaneous, and it is delayed until a
few seconds later. This high pressure then initiates
another cycle, and the oscillation continues on and on.
The chemoreceptor reflex can also oscillate to give the
same type of waves. This reflex usually oscillates simultaneously
with the baroreceptor reflex. It probably plays
the major role in causing vasomotor waves when the
arterial pressure is in the range of 40 to 80 mm Hg
because in this low range, chemoreceptor control of the
circulation becomes powerful, whereas baroreceptor
control becomes weaker.
Oscillation of the CNS Ischemic Response. The record in
Figure 18–11A resulted from oscillation of the CNS
ischemic pressure control mechanism. In this experiment,
the cerebrospinal fluid pressure was raised to
160 mm Hg, which compressed the cerebral vessels and
initiated a CNS ischemic pressure response up to
200 mm Hg. When the arterial pressure rose to such a
high value, the brain ischemia was relieved and the sympathetic
nervous system became inactive. As a result,
the arterial pressure fell rapidly back to a much lower
value, causing brain ischemia once again. The ischemia
then initiated another rise in pressure. Again the
ischemia was relieved and again the pressure fell. This
repeated itself cyclically as long as the cerebrospinal
fluid pressure remained elevated.
Thus, any reflex pressure control mechanism can
oscillate if the intensity of “feedback” is strong enough
and if there is a delay between excitation of the pressure
receptor and the subsequent pressure response.
The vasomotor waves are of considerable theoretical
importance because they show that the nervous reflexes
that control arterial pressure obey the same principles
as those applicable to mechanical and electrical control
systems. For instance, if the feedback “gain” is too great
in the guiding mechanism of an automatic pilot for an
airplane and there is also delay in response time of the
guiding mechanism, the plane will oscillate from side to
side instead of following a straight course.
Pressure (mm Hg)
200
160
120
80
40
0
A B
100
60
Figure 18–11
A, Vasomotor waves caused by oscillation of the CNS ischemic
response. B, Vasomotor waves caused by baroreceptor reflex
oscillation.
Chapter 18 Nervous Regulation of the Circulation, and Rapid Control of Arterial Pressure
Modulation of the autonomic nervous system
Visceral information arrives at the reticular formation from
the cerebral cortex, hypothalamus, and limbic system. Sensory
information from visceral structures that modulate the
cardiovascular and respiratory systems is transmitted to the
reticular formation via collateral branches derived from
the ascending sensory pathways and via the solitary tract,
which relays baroreceptor (from the carotid sinus, aortic
sinus), chemoreceptor (from the carotid body, aortic body),
volume receptor (from the heart atria), and stretch receptor
(from the lungs) information from the glossopharyngeal and
vagus nerves. The sensory information is processed in vasopressor
and vasodepressor centers located in the reticular
formation, which are believed to be involved in the control
of vital functions such as respiration and the control of heart
rate. The response from these centers is conveyed via the
reticulobulbar and reticulospinal tracts, to the autonomic
nuclei of the brainstem and spinal cord.
The vasopressor center that corresponds to the rostral
ventrolateral medullary reticular formation and the parvicellular
nucleus of the lateral zone nuclei, gives rise to fibers
that join the reticulospinal tract to descend to the spinal cord.
Here fibers synapse with preganglionic sympathetic neurons
of the intermediolateral column, which in turn synapse with
postganglionic sympathetic neurons that accelerate the heart
rate. Postganglionic sympathetic neurons also cause peripheral
vasoconstriction, and thus increase blood pressure.
The vasodepressor center that corresponds to the caudal
ventromedial medullary reticular formation includes the
raphe nuclei and the gigantocellular reticular nucleus of the
medial zone nuclei. This center gives rise to fibers that join
the reticulobulbar tract to terminate in the dorsal motor
nucleus of the vagus. Here, fibers synapse with preganglionic
parasympathetic neurons, which in turn synapse with postganglionic
parasympathetic neurons in the wall of the heart,
which decelerate the heart rate and lower blood pressure.
Stimulation of the gigantocellular nucleus of the brainstem
reticular formation induces inspiration, whereas
stimulation of the parvicellular nucleus induces expiration.
The cardiovascular centers and the respiratory centers are
thought to be overlapping. In addition, the neurons of the
pontine parabrachial nucleus give rise to fibers that terminate
in the brainstem and spinal cord where they exert their
influence on the preganglionic parasympathetic neurons of
the vagus nerve, the preganglionic sympathetic neurons of
the intermediolateral column of the spinal cord, and the
lower motoneurons of the phrenic and intercostal nerves that
innervate the diaphragm and the intercostal muscles associated
with breathing movements.
«Я У Ч Е Н Ы Й И Л И . . . Н Е Д О У Ч К А ?» Т Е С Т В А Ш Е Г О И Н Т Е Л Л Е К Т А
Предпосылка: Эффективность развития любой отрасли знаний определяется степенью соответствия методологии познания - познаваемой сущности. Реальность: Живые структуры от биохимического и субклеточного уровня, до целого организма являются вероятностными структурами. Функции вероятностных структур являются вероятностными функциями. Необходимое условие: Эффективное исследование вероятностных структур и функций должно основываться на вероятностной методологии (Трифонов Е.В., 1978,..., ..., 2015, …).
Критерий: Степень развития морфологии, физиологии, психологии человека и медицины, объём индивидуальных и социальных знаний в этих областях определяется степенью использования вероятностной методологии.
Актуальные знания: В соответствии с предпосылкой, реальностью, необходимым условием и критерием...
... о ц е н и т е с а м о с т о я т е л ь н о: — с т е п е н ь р а з в и т и я с о в р е м е н н о й н а у к и, — о б ъ е м В а ш и х з н а н и й и — В а ш и н т е л л е к т !
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