L28 Functional Characteristics of Special Circulation PDF

Summary

This document covers the functional characteristics of various special circulatory systems, including coronary, pulmonary, cerebral, skeletal muscle, and cutaneous circulations. It details blood flow, regulation, and relevant mechanisms for each system.

Full Transcript

 Prof Dr. Abdelaziz M. Hussein
Prof and Chairman of Medical Physiology Department
Contacts :
Email: [email protected]
Mob. #: ………………………………….
Office hours : 10.0 AM- 11.0 AM Tuesday, Thursday
 Lecture contents
1. Functional characteristics of Coronary Circulation

2. Functional characteristics of Pulmonary Circulation

3. Functional characteristics of Cerebral Circulation
4. Functional characteristics of Skeletal ms Circulation

5. Functional characteristics of Cutaneous Circulation
 Coronary Circulation
▪Functional characteristics of coronary vessels
▪O2 consumption in heart tissues
▪Coronary blood flow
▪Regulation of CBF (Intrinsic and extrinsic)
 Coronary Circulation; Blood vessels
Coronary circulation concerned with the blood supplying the cardiac
ms
Are 2 coronary arteries (Rt and Lt) arising from the aorta just above
the aortic valve
There are little anastomoses () the 2 coronaries, which are not
sufficient to supply the cardiac ms with blood, if one of them is
occluded→ functional end arteries
Capillaries run parallel to the
cardiac ms fibers and about one
coronary capillary for each ms
fiber.
Venous drainage occur by
coronary sinus and anterior
cardiac vein drain into right
atrium and deep veins drain
directly into the all chambers
 Coronary blood flow and O2 consumption
O2 Consumption of Heart
Value:
At rest → is about 70% of O2 in the coronary arterial blood.
On other tissues → is about 25% of O2.
The coronary venous blood has low venous O2 reserve.
Coronary Blood Flow
Value:
During rest: is about 250 ml/minute (about 5% of the COP).
In severe exercise: ↑es to 3-4 fold i.e. may reach 1 L/min
 Phasic changes in Coronary blood flow
1) During systole:
CBF ↓ during ventricular systole (maximal during ICP) (the flow may stop
completely)
Such ↓ in CBF during systole is compensated by O2 delivered from
myoglobin
2) During diastole:
The cardiac ms relax completely and so, the blood flows rapidly into the
coronary arteries.
The highest CBF occurs during isometric relaxation phase.

N.B.:
Phasic changes in the Rt ventricle is
more on Lt vent than right vent due
to low pressure values
So, the ischemic necrosis
(myocardial infarction) affects
mainly parts of the Lt ventricle
rather than Rt ventricle
Regulation of Coronary Bl. Flow
1) Intrinsic regulation (autoregulation)
2) Extrinsic regulation
a) Nervous regulation
b) Mechanical regulation
c) Chemical regulation
 A) Intrinsic or autoregulation of CBF
Definition
It is the ability of the heat to maintain its flow constant in absence of
extrinsic factors
Mechanism: O2 demand is the major factor in local blood flow
regulation.
Hypoxia or increase in O2 demand

Direct relaxing effect on Release of Adenosine, K, H, CO2,
smooth ms of bl vessels Bradykinin and PGI2

Stimulate endothelium to
secrete Nitric oxide
N.B. Active hyperaemia (marked ↑ of CBF during exercise) and reactive
hyperaemia: (marked ↑ of CBF after temporary occlusion)
 B) Extrinsic regulation of CBF
1) Nervous system :
a) Sympathetic stimulation:
Direct action → VC due to ++ of α1 receptors and mild VD due to ++ of
β2 receptors.
Indirect action → ↑es the metabolic activity of the heart → strong VD.
❖Net effect of sympathetic ++ is an ↑ in the coronary blood flow.
b. Parasympathetic stimulation → opposite effect to sympathetic ++
c. Anrep's reflex:
↑ VR and venous pressure in the Rt atrium → reflex coronary VD and
↑es the coronary B.F. via Vagus nerve.
It is important in exercise to supply the cardiac ms with more O2.
d. Gastrocoronary reflex:
Distension of the stomach with heavy meal → reflex coronary VC and
↓es the CBF→ anginal pain may be felt in certain persons after heavy
meals
B) Extrinsic regulation of CBF
2) Mechanical factors
a) Phases of cardiac cycle: as above.
b) Heart rate:
↑HR → ↓es the coronary blood flow by shortening of the
diastolic period.
↓ HR → ↑es the coronary blood flow by prolonging the diastole.
c) ABP:
↑ed ABP→ ↑es coronary flow
↓ed diastolic BP as in aortic regurgitation→ ↓es coronary flow, so
anginal pain may occur in these patients.
d. Cardiac output: ↑ed COP → ↑es coronary blood flow
e. Mechanical occlusion of coronary artery: reactive hyperaemia
occurs
B) Extrinsic regulation of CBF
3) Chemical factors
a. Nitroglycerin sublingually has a fast coronary dilating effect,
within 2-3 minutes.
b. Long acting nitrates as isosorbide dinitrate given orally also
produce coronary dilatation.
c. Beta-blockers, e.g. propranolol and atenolol act by reducing
myocardial O2 requirements during exertion and stress.
d. Calcium entry blocking agents, e.g. nifedipine and verapamil
also reduce myocardial O2 requirements and induce coronary VD.
Cerebral Circulation
1) Functional characteristics of cerebral vessels
2) Cerebral blood flow
4) Regulation of CBF (Intrinsic and extrinsic)
Cerebral Circulation; Blood Vessels
Cerebral Circulation; Blood Supply
6 cerebral arteries, no crossing between 2 sides and functional
end arteries
Cerebral blood flow in normal adult the brain weights 1400 gm
and receives 750 ml blood /min (14% of cardiac output).
In children cerebral blood flow is nearly double it's value in
adult and it falls to the adult level at puberty due to sex
hormones
Blood flow of the grey matter is about six times that of the
white matter.
Blood flow increases in active area and decreases in the inactive
one i.e. change in regional blood flow
Very sensitive to hypoxia (fainting occurs within few seconds of
cerebral ischemia) and hypoglycemia
Regulation of Cerebral Bl. Flow
1) Intrinsic regulation (autoregulation)
2) Extrinsic regulation
a) Chemical factors e.g. CO2, O2 & H+
b) Nervous e.g. role of sympathetic Innervation
c) Mechanical i.e. Role of ICP
A) Intrinsic Autoregulation of Cerebral Bl. Flow
Cerebral BF remains more or less constant
with a change in ABP between 60-150 mm
Hg (autoregulatory range)
Theories for autoregulation:

- Myogenic (↑ABP→ ↑ BF → stretch of vascular
smooth muscle → stretch-induced ms
contraction → ↓ BF back to normal)
↓ ABP → ↓BF→ inhibition of smooth ms→
vasodilatation→ ↑BF back to normal
- Metabolic theory:

↓BF→ accumulation of metabolites
(adenosine, K+, lactate, ATP) →VD→↑BF
B) Extrinsic regulation of Cerebral Bl. Flow
1) Chemical factors: role of CO2, O2 & H+
Changes in CO2, O2 & H+
concentrations have important effect
on Cerebral BF
70%↑in PCO2 will double CBF
The effect is not direct but through H+
which causes VD of cerebral Bl.V
This is beneficial to get rid off excess
H+ that causes depression of nervous
system
A decrease in cerebral tissues PO2
below 30 mm Hg stimulates VD of
cerebral blood vessels
 B) Extrinsic regulation of Cerebral Bl. Flow
2) Mechanical factors: intracranial
pressure (ICP)
The brain is enclosed within the rigid cranium
(having a volume of ~ 1600-1700 ml)→ so
the volume within the cranium (blood, brain
and CSF) must be kept constant
ICP is produced by presence of CSF
Normally from 0-10 mm Hg
Cerebral perfusion pressure (CPP) which is the
pressure pushing blood inside the brain =
MAP-ICP
Thus, any factor that increases ICP will
decreases CPP & consequently can reduce CBF
Marked rise in ICP >33 mm Hg will compress
blood vessels → marked reduction in CBF
 B) Extrinsic regulation of Cerebral Bl. Flow
3) Nervous factors:
Sympathetic nervous stimulation
The cerebral vessels have rich sympathetic innervations
However, under normal conditions they have no role in
regulation of cerebral BF (overridden by autoregulatory
mechanism)
Their importance have been outlined as protective in cases of
marked increased of ABP where it constrict the large & medium
sized vessels thus protecting the smaller vessels from rupture
 Pulmonary Circulation
1) Functional characteristics of pulmonary vessels
2) Pulmonary blood flow
4) Regulation of PBF(Intrinsic and extrinsic)
Pulmonary Circulation; Blood Vessels
It is concerned with passage of blood from the Rt ventricle, through
the lungs and then to the Lt atrium.
It's time is about 7 seconds at rest.
It equals the COP from the Rt ventricle.
The lung is supplied with blood from 2 sources; i) pulmonary arteries (venous
blood) and ii) bronchial arteries (oxygenated blood)
There are many anastomoses between the bronchial and pulmonary arteries
Regulation of Plumonary Bl. Flow
1) Intrinsic regulation (autoregulation)
2) Extrinsic regulation
a) Chemical factors e.g. CO2, O2 & H+
b) Nervous e.g. role of sympathetic
Innervation
c) Mechanical i.e. Role of ICP
A) Autoregulation of Pulmonary Bl. Flow
It is the automatic control of local pulmonary blood flow distribution.
O2 concentration in the alveoli→ pulmonary V.C this effect is
opposite to the response of systemic blood vessels to hypoxia which is
V.D.
Hypoxia leads to release of V.C substances from lung tissues.
The amount of blood flow through the poorly ventilated lung is
restricted and redistributed to better ventilated area.
B) Extrinsic regulation of Pulmonary Bl. Flow
a) Cardiac output: -
Increased C O P, increases pulmonary blood flow with slight increase
in pulmonary BP.
The pulmonary capacity can change to buffer excessive changes in
pulmonary BP
b) Peripheral resistance:
It equals 1/6 systemic resistance.
Any  in pulmonary PR→ increase pulmonary B.P→ the Rt ventricle
enlarge to  the power of contraction (starling law)
If the increase in pulmonary B.P persists→→ Right ventricular
hypertrophy and failure occurs
c) Nervous factors
Sympathetic stimulation → V.C of pulmonary blood vessels.
Vagal stimulation produces dilatation of the pulmonary blood vessels.
Skeletal Muscle circulation
Functional characteristics
Regulation of skeletal ms blood flow
Skeletal ms blood vessels and blood flow
The primary function of skeletal muscle is contraction & generation
of mechanical force, therefore, it needs delivery of large amount of O2
& nutrients with removal of waste products
This is achieved by high blood flow to skeletal muscles
Value of Sk.ms BF:
During resting
Skeletal ms BF is about 20% of COP (1-4 ml/min/100gm tissue; low
when compared with other organs).
This relative high fraction (20% COP) because skeletal muscle
represents ~ 40 -50% of TBW
During exercise
skeletal ms blood flow can increase by more than 20 folds and
becomes ~ 80% of COP i.e. 20 L/min
The maximal flow is 50-100 ml/min/ 100 gm.
 Regulation of skeletal ms Bl. Flow
1) Nervous regulation (dominant in resting ms)
2) Local regulation (dominant in exercising ms)
A) Nervous regulation of skeletal ms blood flow
It is the dominant regulatory factor in resting ms.
It is mediated by sympathetic NS supplying skeletal ms
blood vessels
a) α receptors → VC
b) β2 & cholinergic receptors → VD
Stimulation of symp. noradrenergic VC nerves (α
adrenoreceptor-mediated) →↓ ms BF by ½ or 1/3 of
normal (e.g. in Haemorrhage).
During exercise or stress → vasodilatation of skeletal blood
vessels occurs via blood-borne catecholamines (secreted by
suprarenal medulla) acting on β2-receptor & via
sympathetic cholinergic nerve fibres.
B) Local regulation of skeletal ms blood flow
It is the dominant regulatory factor in exercising ms.
The marked increase in BF during muscle exercise is mediated by
local metabolic factors that override the nervous control.
The most important factor is reduction in O2 in muscle tissues
(hypoxia has a direct effect & acts through releasing NO)
Other VD metabolites such as adenosine, lactate, K+, ATP & CO2
Skeletal Muscle Circulation;
Effect of Exercise
During exercise, the increased O2 demand by the muscles will be met
by an increase in:
O2 extraction; increases from 7Vol% to 15Vol%
Blood flow to muscles which is mediated by local metabolites, increased
temperature & acidosis
This increase in BF occurs in spite of increased sympathetic activity
that is associated with exercise
Distribution of COP in rest and exercise
Skin or cutaneous circulation
Functional characteristics
Regulation of cutaneous blood flow
 Cutaneous Circulation

The major function of skin blood
flow is regulating body temperature
Skin represents ~ 4-5% of TBW
Receives 6 % of COP
The arterio-venous O2 difference is
only 3 ml%→ so the flow is mostly
non-nutrient flow.
Blood vessels in skin are either;
a) Nutritive vessels or
b) Non nutritive vessels→
concerned with body temp.
regulation.
Regulation of cutaneous Blood Flow
1. Nervous regulation
2. Local metabolite regulation
A) Nervous regulation of cutaneous blood flow
The sympathetic supply to skin vessels is so powerful that
cutaneous BF can range from 1% to 30% of COP e.g.
a) Skin blood flow is