Hemodynamics and Venous Return Lecture Notes PDF

Summary

These lecture notes cover hemodynamics and venous return, focusing on the circulatory system, its components (heart, blood vessels, blood), and regulation of blood pressure. The document explores venous return, factors influencing it, and the relationships between venous return, cardiac output, and circulatory pressures. It includes figures and diagrams.

Full Transcript

PHYSIO-LEC: LE 3 | TRANS 4

DR. JUNE CATHLEEN C. CASTILLO, DPBA | Lecture Date (11/23/24)

OUTLINE ✔Compare the intrinsic and extrinsic mechanisms of
I. Circulatory System VI. Venous Return regulating blood pressure
A.Heart A.Venous System ✔Distinguish the venous system from the arterial system.
B.Blood vessels B.Venous Compliance ✔Describe the mechanisms that return blood to the heart.
C.Distribution of Blood C.Venous Return ✔Describe the venous return curve.
Volume D.Factors that can ✔Explain the relationship between venous return, cardiac
II. Hemodynamics cause transient output, and circulatory pressures.
A.Blood Flow changes in Venous I. CIRCULATORY SYSTEM
B.Hemodynamics Return The circulation functions to serve the needs of the body
III. Blood Pressure E.Venous Valves tissues.
A.Blood Pressure F. Central Venous → Transport of nutrients and hormones to tissues
B.Blood Pressure Pressure → Removal of waste products
Measurement G. Influence of CVP → Maintaining an appropriate environment in all the tissue
IV. Regulation of Arterial and PVP on VR fluids of the body for survival and optimal function of the
Blood Pressure H.CVP and Cardiac cells (internal homeostasis)
A.Intrinsic and Extrinsic Output Functional parts include:
Control of Vascular I. CVP Estimation by → Artery – Distribute oxygenated blood from the heart
Tone PE → Arterioles and Capillaries – Primary exchange vessels
B.Arterial VII. Exercise → Venules and Veins – Capacitance vessels
Baroreceptors VIII. Physiology of CPR
A. HEART
C.Neural Control IX. Review Questions [2025 Trans]
Acts as a pump
V. Autonomic Nervous X. References
Consists of two pumps in series
System XI. Appendices
→ Pulmonary circulation
A.Immediate Control
▪ Propels blood through the lungs for exchange of O2
B.Intermediate Term
and CO2
Control
→ Systemic circulation
C.Renal Blood Volume
▪ Propels blood to all other tissues of the body
Pressure Control
Intermittent, continuous blood flow occurs by distention of
SUMMARY OF ABBREVIATIONS the aorta during systole and elastic recoil of large arteries
ABP Arterial Blood Pressure during diastole.
Ca Arterial Compliance Unidirectional flow is achieved by the arrangement of
BP Blood Pressure valves - in verne

CO Cardiac Output B. BLOOD VESSELS
CVP Central Venous Pressure A series of distributing and collecting tubes filled with
EDV End-Diastolic Volume heterogeneous fluid (blood)
ESV End-Systolic Volume Arteries and veins transport blood into distinct circuits and
HR Heart Rate they share a common overall structure that consists of:
JV Jugular Vein → Tunica intima – Inner layer lined with a single layer of a
KE Kinetic Energy specialized semipermeable epithelium called
NTS Nucleus of Tractus Solitarius endothelium.
PE Potential Energy → Tunica media – Middle layer consists of helically
arranged smooth muscle cells. [2027 Trans]
PP Pulse Pressure
→ Tunica adventitia (externa) – Outer layer consists of
RVLM Rostral Ventrolateral Medulla
type I collagen fibers and elastic fibers [2027 Trans]
SBP Systolic Blood Pressure → Lumen – A hollow passageway through which blood
SV Stroke Volume flows [2027 Trans]
SVR Systemic Vascular Resistance
VR Venous Return
Must know Lecturer Book Previous Trans

LEARNING OBJECTIVES
✔Describe the component parts of the circulatory system.
✔Explain the effects of the determinants of blood
pressure.
✔Demonstrate the procedures for determining blood
pressure
✔Correlate the Korotkoff sounds to pressure changes in
the blood vessels.

LE 3 TRANS 4 TG-C10&11: *Rosales, Rosell, Roxas, Ruben, Salayo, Salazar, TE: Romero, Sabico, Sagun, AVPAA: E. Villa Page 1 of 25
Salinas, Sallan, Salongsongan, *San Andres, Sandoval, Santiago, E. Sampang, Santiago, G
 smaller:Presistance
:A pressure
-Maximal resistance to blood flow.
Very small artery that leads to capillaries
→ Lumen ranges from 30 μm or less in diameter
→ Slows down/resists blood flow causing a substantial
drop in blood pressure

Figure 2. Different types of arteries[Lecturer’s PPT}
[Lecturer’s PPT}
Figure 1. Diagram & Histology of arteries and veins CAPILLARIES
ARTERIES Thin, short tubes that are only 1-cell thick
Becomes narrow, thinner, less elastic, and more muscular Primary exchange vessels that supply blood to the tissues
as it branches from the aorta to peripheral arteries. in a process called perfusion
Tunica media – thickest and most visible layer Have the largest total cross-sectional and surface area
-

Thick walls help withstand the high pressure from the → Results to slow blood flow
ejected blood, especially the major vessels closest to the → Optimal condition for exchange of diffusible substance
heart. between blood and tissues
Pulsatile arterial blood flow caused by ejected blood is Lumen ranges from 5-10 μm in diameter
dampened by: → Barely wide enough -
for an RBC to squeeze through
→ Distensibility of the large arteries
→ Frictional resistance in the small arteries and arterioles
Have strong vascular walls since they accommodate blood
flows at a high velocity
Serve as a conduit absorbing the pressure generated by
systolic contraction
Contain a lot of elastin that allows stretch and recoil as
well as smooth muscles that allow constriction and
dilatation
ELASTIC ARTERIES
Conducting arteries near the heart
→ Usually >10mm diameter
Arteries with the thickest wall that contains a high amount
of elastic fibers/elastin
Frictional resistance is small and pressures are slightly
less than those in the aorta. Figure 3. Structure of arterioles, capillaries, and venules
[Lecturer’s PPT}
Examples:
IEC VEINS
, I
→ Aorta
Compared to arteries, veins have large lumens, thin walls,
advantity
→ Pulmonary artery
→ Brachiocephalic artery
→ Subclavian artery pousally -
and less smooth muscles and elastic tissue
→ Tunica media is less pronounced, making them look ↓eastn
→ Common carotid artery
→ Common iliac artery R -
on
=

Tr*
collapsed under the microscope
Low-pressure vessels equipped with valves promote
MUSCULAR ARTERIES O
↑ Blameter Arests. unidirectional blood flow to the heart.
-

Venules and capillaries are the primary sites of
Regulatory or distributing arteries further from the heart -- presse emigration or diapedesis
→ Ranges from 0.1-10mm in diameter → Diapedesis is the process through which WBCs adhere
Decreased elastic fibers in tunica intima to the endothelial lining of the vessels to squeeze
→ Limits ability to expand through adjacent cells and enter the tissue fluid. [2027
-
Increased smooth muscle in tunica media Trans]
→ Thick muscular layer regulates vasoconstriction and
vasodilation VENULES
Moderate resistance to blood flow Extremely small veins (usually 8-100 μm in diameter)
Examples:
→ Brachial artery mm Its walls consist of:
→ Endothelium

&muscles
→ Femoral artery → Thin middle layer with few muscle cells and elastic
→ Radial artery media fibers
→ Popliteal artery → Outer layer of connective tissue fibers making up the
very thin tunica externa/adventitia
ARTERIOLES

“Resistance vessels”
Decreased wall thickness
-
Thin
→ Tunica media is restricted to 1-2 smooth muscle layers
→ Very thin tunica externa

PHYSIOLOGY Hemodynamics and Venous Return Page 2 of 25
 C. DISTRIBUTION OF BLOOD VOLUME
The volume of the blood in different part of circulation:
→ 84% in the systemic circulation
▪ Greatest in veins and venules
▪ 64% in the venous system
− 46% in small veins
− 18% in large veins
→ 8.8% in the pulmonary circulation
▪ Equally divided among arteries, capillaries, and veins
→ 7.2% in the heart

Figure 4. Different types of veins[Lecturer’s PPT]

C 0
⑧ O
Figure 5. Relative proportions of elastic tissue, smooth
muscle and fibrous tissue change in each type of blood
vessel conferring significantly different physical and
physiological properties on the vessels [Berne & Levy, 6th Ed]
Summary:
The aorta is predominantly elastic. Figure 6. Distribution of blood (in percentage of total blood)
Peripheral arteries are less elastic and more muscular. in the different parts of the circulatory system[Lecturer’s PPT]
The arterioles are predominantly muscular. - > terminal
The elasticity and frictional resistance of arteries Table 1. Distribution of Blood Volume*[Berne & Levy, 6th Ed]
dampen pulsatile pressure Location Absolute Relative
→ Greatest drop of pressure at the level of small Volume (mL) Volume (%)
arteries and arterioles. Systemic circulation
Capillaries consist of short tubes with walls only one cell Aorta and large arteries 300 6.0
thick
-

-
Small arteries 400 8.0
The conditions in capillaries are ideal for the exchange
of diffusible substances between blood and tissues.
Capillaries
Small veins
300
2300
6.0
46.0 Fromphave
On its return to the heart from the capillaries, blood Large veins 900 18.0
passes through venules and into veins of increasing
Total 4200 84.0
size.
The number of veins decreases near the heart. The Pulmonary circulation
thickness and composition of the vein walls change. Arteries 130 2.6
Capillaries 110 2.2
Veins 200 4.0
I ran= ↑smoothe Total
Heart (End-Diastole)
440
360
8.8
7.2
Total 5000 100
*Value refers to a 70-kg woman.
II. HEMODYNAMICS
A. BLOOD FLOW
Quantity of blood that passes a given point in the
circulation in a given period of time
Overall blood flow in the total circulation of an adult person
at rest is about 5000 ml/min
B. HEMODYNAMICS
Physics of fluid flow through vasculature
Velocity – distance that a particle of fluid travels with
regard to time, and it is expressed in units of distance per
unit time (e.g., cm/sec)
Flow – rate of displacement of a volume of fluid over time,
-

volume per unit of time (e.g., cm³/sec)

PHYSIOLOGY Hemodynamics and Venous Return Page 3 of 25
 VELOCITY AND CROSS-SECTIONAL AREA BERNOULLI’S PRINCIPLE

~questvelouty
Sum of potential, kinetic, and pressure energy per unit
mass of an incompressible, non-viscous fluid remains
constant ↑ Pe
O KE
- >

Flowing blood has mass and velocity
→ Kinetic Energy (KE) of flowing blood is proportionate to-mean
mean velocity, it is the forward force of velocity of blood velocity
I cross section → Potential Energy (PE) is the pressure exerted laterally
- -
against the walls of the vessel
→ Total energy (E) of the blood flowing within the vessel
&↓ vellouty (assuming no gravitational effects):(conserved)
E = KE + PE
→ Increase in velocity of blood flow or KE leads to a
section reciprocal decrease in the magnitude of PE, resulting to
was a decrease in the lateral pressure against the vessel
wall

LPE
Figure 7. Velocity of blood flow and cross-sectional area of PKE=
blood vessels [Lecturer’s PPT]
(Total) Cross-sectional area significantly increases at the
level of capillaries due to the number of capillaries that are
in parallel with each other
Blood velocity is at the lowest point at the level of
capillaries, this slow flow is important as this allows
~>displacement
adequate time for exchange of nutrients Figure 8. Bernoulli’s principle in relation to stenosis [Lecturer’s PPT]

Co
In a rigid tube, velocity (V) and flow (Q) are related to one Through stenosis: (Narrowed vessels)
another by the cross sectional area (A) of the tube: → Cross sectional area decreases
-
→ α means directly proportional → Velocity increases
𝑄
𝑣= → Lateral pressure decreases
𝐴
Once past the narrowed segment, kinetic energy reverts to
𝑣α𝑄 Tv dA =

pre-stenosis value but since turbulence occurs and leads
to PE loss due to friction, the lateral pressure against the
1
𝑣α vessel walls remains low. This leads to vessel collapse and
𝐴
decrease in flow in distal segments
Area of a tube: A = π r2
→ Plugging this to the original equation: Given this example below:
1 1
𝑣α 𝐴
→ 𝑣α 2
π𝑟

→ For instance, if the r is halved, we get this relationship:
1 4
𝑣α 𝑟 2
→ 𝑣α 2
π ( )
2
π𝑟
→ Blue arrows represent KE; Green arrows represent PE
→ Given this example below: → This is an artery with stenotic areas made of plaques. At
▪ Before entering the constricted part, the velocity is the level of the stenosis, the decrease in area will lead
to an increase in velocity.
just 𝑣 and once it passes through it, the velocity ▪ KE increases → reciprocal decrease in the
increases by four (it gets faster) magnitude of PE which will lead to the decrease in
lateral pressure against the walls
→ After the blood had passed through the stenotic area,
KE will return to its pre-stenosis value since velocity is
dependent on the area, while PE will not return to its
Velocity of blood is DIRECTLY proportional to the pre-stenosis value since some energy is lost in the form ↓ pressur
blood flow and is INVERSELY proportional to the cross of friction at the level of stenosis (friction leads to a -

decrease in total energy and PE)
sectional area
▪ PE remains decreased as well as the pressure in
collapse
→ As the diameter ↓, the velocity in a tube ↑
Velocity decreases as blood traverses the arterial system, the lateral wall
is at minimum at the capillaries, and increases Clinical example: Atherosclerotic plaques
progressively towards the venous system → Narrowed vessels
→ Decrease in lateral pressure after the level of the
constriction would lead to vessel collapse and
decrease in perfusion to distal segments of the
↑v 4q dA
=

extremity
=

→ The patient would present with pain due to
hypoperfusion or ischemia, secondary to the vessel
collapse

PHYSIOLOGY Hemodynamics and Venous Return Page 4 of 25
 RELATIONSHIP BETWEEN VELOCITY AND PRESSURE Table 3. Type of flow based on Reynold’s number
Total pressure = PDyn + PLat Type of Flow Reynold’s Number
→ PDyn = blood flow with velocity Laminar flow 3000
Unsteady Flow: Reynold’s number is between laminar
and turbulent, it can be converted to laminar or turbulent
Where: flow anytime
▪ P - pressure
▪ p - density of fluid
* deuse-Fuelouty-Aplaris Application of Reynold’s Number:
▪ v - velocity

Figure 10. Application of Reynold’s Number: Anemia [Lecturer’s
PPT]

Given the total pressures of A, B, and C are the same, On the left is an example of laminar flow in a vessel, a
both the velocity and dynamic pressures are increased type of fluid motion where fluid moves in a series of layers
in the narrowed area thus, decreasing the lateral with different velocities wherein the highest velocity is the
pressure center of the tube
Anemia: low viscosity, high cardiac output
LAMINAR VS TURBULENT FLOW
→ The viscosity is dependent on the hematocrit. In anemic
Normal flow of blood in straight blood vessels: Laminar patients, hematocrit is low. To compensate for this low
viscosity, the heart increases the cardiac output.
→ Hematocrit must be controlled in anemic patients
because it can lead to turbulence which can cause
cardiovascular complications
→ Plugging it into the formula, the velocity increases and
the viscosity decreases. The effect is additive so the
Figure 9. Laminar Flow (A) and Turbulent Flow (B) [Lecturer’s PPT] Reynold’s number in anemic patients will be very high
Table 2. Laminar Flow vs Turbulent Flow
Laminar Flow Turbulent Flow
Type of motion wherein Fluid elements do not
fluid moves as a series of remain confined in a
individual layers, each specific lamina
layer moving at different Rapid and radial mixing
velocities Vortices (swirls) are
Center tube with highest present Figure 11. Application of Reynold’s Number: Thrombus
[Lecturer’s PPT]
velocity, velocity Distribution of velocities
decreases parabolically is chaotic 𝑁𝑅 =
ρ𝐷𝑣
towards the vessel wall Greater force needed to η
This layer in contact to push fluid out of the tube 𝑄
vessel wall → “motionless” -
→ increase work of heart 𝑉 = 𝐴
to pump out the fluid from
2 𝐷 2
that vessel 𝐴 = π𝑟 = π( 2 )
REYNOLD’S NUMBER 𝑄 4𝑄
Used in differentiating laminar from turbulent flow 𝑉 = 2 → 𝑉 = 2
π(𝐷/2) π𝐷
Predisposing factors to turbulent flow:
A puerta-more resistant ρ𝐷𝑣 ρ𝐷4𝑄 ρ4𝑄
→ High density ~
𝑁𝑅 = = 2 =
η ηπ𝐷 ηπ𝐷
→ Large diameter of tube
→ High velocity flow -more motions → Where:
→ Low fluid viscosity
A dimensionless number (no units) that represents the
▪ V is the velocity
▪ Q is the flow rate =
ratio of the inertial to viscous forces in the vessel
Determine the difference between laminar flow and
▪ A is the Area
▪ D is the diameter NR
pe
turbulent flow using the formula: ▪ r is the radius
ρ𝐷𝑣 In cases of thrombus, Reynold’s number is HIGH
𝑁𝑅 = In thrombus, the blood clot decreases the diameter by a
-
η
third, while the velocity increases. The effect of velocity
→ Where:
▪ ρ is the density ⑭ change is greater than diameter in terms of Reynold’s
▪ D is the tube diameter * number
▪ v is the velocity → The function of - velocity is significant in Reynold’s if the
▪ η is the viscosity flow would be -laminar or turbulent

PHYSIOLOGY Hemodynamics and Venous Return Page 5 of 25
 rad
POISEUILLE’S LAW
Relationship between pressure and flow
SAMPLE QUESTION FROM SYNCH
Q1: From 4mm in diameter, the diameter of a clogged
Applies to steady or non-pulsatile laminar flow of artery was halved. The flow through the artery would
Newtonian fluids through rigid cylindrical tubes decrease by how much? (given pressure gradient,
→ Applicable not only in blood vessels but also with viscosity, and length are constant)
anything that is introduced to the body via tubes or any a. 2x
body part that has tubes (e.g. trachea) b. 4x
→ This principle illustrates the factors affecting flow c. 8x

pousalte
e
→ Poiseuille's law is only accurate or applicable under d. 16x
specific conditions where its assumptions hold true ANS: D. 16x
Requirements: NOTE TO ANSWER: review the poiseuille’s law formula
ex → 1st: fluid must be newtonian (viscosity is constant)
→ 2nd: flow must be non-pulsatile or fully laminar
→ 3rd: tube must be rigid
The problem with our circulatory system is that it does not
necessarily or perfectly follow this principle due to the OHM’S LAW
following reasons: In physics: describes the relationship of flow or current to
→ Blood only has apparent viscosity which changes when the total resistance
the hematocrit changes (NOT newtonian) In physiology: it states that the total resistance is equal to
→ Flow is pulsatile since the heart is what pushes the the change in pressure over flow
blood to flow through the body Using Poiseuille’s law, the following formula is derived:
R=
→ Blood vessels are NOT entirely rigid ∆𝑃 8η𝑙
However, the following insights about the law still applies 𝑅= 𝑄
→ 𝑅= 4
π𝑟
to blood flow: Resistance to flow depends only on the dimension of the
→ Flow is proportional to radius and pressure tube and characteristics of the fluid
gradient ->
vans Radius –principal determinant of resistance to blood flow-
→ Flow is inversely proportional to viscosity and
tube length

1 ↓Vis
𝑄 =
π∆𝑃𝑟
8η𝑙
4

-Her
general YAGAIN
-
→ Where:
▪ η is the viscosity
4 How
↓ength
=

▪ Q is the flow rate

tradtes= ↑fle
▪ ∆P is the pressure difference
▪ l is the length of the tube
▪ r is the radius of the tube
Vessel Diameter – The biggest determinant of flow Figure 12. Resistance per unit length of individual small
If the radius is doubled, the increase in flow would be 24 or blood vessels [Lecturer’s PPT]
16 times the normal flow rate Highest resistance in individual capillary, but recall
Example in clinical setting: fundamental physics:
→ During CT Scan, a contrast dye is given. A big gauge → Resistors in parallel connection, total resistance =
needle is used because the fluid is viscous, having a resistance divided by number of resistors
slower flow → Billions of capillaries in the body are parallel to each
→ A big gauge is used for a faster infusion while a small other, therefore the total resistance significantly
gauge is used for a more cautious infusion. For decrease
example, in water vs. blood infusion, compare the two → Thus, the resistance vessels are not the capillaries
different types of fluids but with a constant length, but the-arterioles
diameter, pressure, and using the same G18 needle Application of Ohm’s Law: Vessel with a plaque resulted in
its diameter being halved shown in the figure below
−3
▪ At 20°C, viscosity of water is at 1𝑥10 Pa

→ Using the formula below, we compute for the resistance
and flow:
−3 ∆𝑃 8η𝑙
▪ At 37°C, viscosity of blood is at 4𝑥10 Pa 𝑅= 𝑄
→ 𝑅= 4
π𝑟
→ Computing for the resistance at the point of constriction:

⑰
8η𝑙 8η𝑙
𝑅= 𝑟 4
→ 𝑅= 1 4
π( ) 2
π( ) 16

▪ Therefore, the flow rate (Q) of blood is 4x less than → Resistance will go up by 16x if the diameter is reduced
the flow rate of water through a G18 needle by half.
→ Meanwhile for flow, it will go down by 16x.
▪ Computing for the flow:
∆𝑃 ∆𝑃
𝑅= 𝑄
→ 𝑄 = 𝑅

PHYSIOLOGY Hemodynamics and Venous Return Page 6 of 25
 ⑧ VASCULAR RESISTANCE
Changes in vascular resistance can occur when there is a
Why are severe hypertension more prone to
aneurysmal rupture?
change in caliber of vessels → Part of the core treatment of aneurysm is aggressive BP
Most important factor: contraction of circular smooth control, this is because if the distending pressure is too
muscle cells in tunica media high, the vessel will just continue to expand. Too much
Arterioles have thick coat of circularly arranged smooth expansion will increase the stress and the wall
muscle fibers → can vary lumen radius thickness will thin out, and the vessel will be more prone
to rupture. Thus, for patients with dilated aneurysm, the
WALL TENSION goal is to control the distending pressure or BP
Delicate structures of the vascular tree-like capillaries are → Cause of dilating blood vessels: the blood vessel’s
not prone to rupture due to the protective effect of their spherical shape would actually lessen the tension (as
small diameter as illustrated by the law of Laplace compensation). However, the increasing radius change
As blood flows through a vessel, it exerts a force on the has an effect on the blood vessels and the weakening of
vessel wall parallel to the wall the blood vessel wall in elderly having collagen that are
Transmural pressure is the difference in pressure inside not compliant as before. These factors may lead to
and outside the vessel increased stress on the vessel walls, disrupted blood
flow, and higher risk of rupture
→ Surgical management is stenting and pharmacological
management include BP control and antihypertensives
to decrease the distending pressure
SHEAR STRESS
Tangential force of the flowing blood on the endothelial
surface of the blood vessel
4η𝑄
τ= 3
π𝑟
Figure 13. Law of Laplace [Lecturer’s PPT] Shear stress → nitric oxide release → vasodilation
Law of Laplace: Factors increasing shear stress:
𝑇=
∆𝑃𝑟 → High velocity flow
𝑤 → Permeability of vessel walls
𝑇 → Biochemical activity of endothelial cells
𝑃= 𝑟 → Blood coagulation
Where: → Integrity of formed elements in blood
→ T is the tension stress on the wall Clinical Example: Hypertension
→ ∆P is the transmural pressure → Subendothelial and endothelial changes can predispose
→ r is the radius the vessels to tears and may ultimately lead to
→ w is wall thickness dissecting vessel aneurysm
Distending pressure or transmural pressure (P) is the wall
RHEOLOGIC PROPERTY OF BLOOD
tension divided by the radius. It is directed outward from
Blood is non-newtonian since viscosity may vary at
Balloon
=

the center against the wall
Wall tension is proportional to vessel radius for cylindrical different points
thinner vessels. Approaching a spherical shape gives less tension “Apparent viscosity”
At than the same radius cylinder, but continued expansion → Derived value of viscosity obtained under a particular

w produces wall tension exceeding that of the original condition of measurement
cylinder → Varies as a function of hematocrit
While the vessel is dilating, the tension you need to Blood is basically a suspension of formed elements
maintain the distending pressure would be higher. The (erythrocytes) in a homogeneous fluid (plasma);
larger the radius, the wall stress will increase adding shear Viscosity depends on hematocrit
stress and more prone to rupture or dissection of the → Resistance to blood flow is affected by viscosity or
aneurysmal wall hematocrit of whole blood. Hematocrit has little effect on
The smaller the radius, the lower the tension on the wall total -
peripheral resistance except when changes are
necessary to balance the distending pressure large. In large vessels, increase in hematocrit cause
Examples: increase in viscosity
→ Capillaries: receive a substantial amount of blood. It → Whole blood is 3-4x as viscous as water
does not rupture because the radius of the capillaries is Fahraeus-Lindqvist effect
very small, so to maintain the distending pressure and → In small vessels, erythrocytes move to the center of the
not to rupture, the wall tension you need is also small vessel, leaving cell free plasma at the vessel wall
→ Dilated aorta: increase in aortic radius, thus the need leading to a less appreciable increase in viscosity
for greater wall tension to maintain distending pressure Polycythemia vs. Anemia
Increased wall tension puts the vessel at higher risk for → High hematocrit in polycythemia increases the total
rupture or perforation resistance, increasing the work of heart and blood
→ Aneurysm: a portion of the vessel dilates, the radius pressure, while the opposite happens in anemia
increases. To balance the distending pressure from
inside the vessel, the wall stress should increase
proportionally to the radius of aneurysm. The more
dilated the aneurysm is, the higher wall stress and the
risk of rupture

PHYSIOLOGY Hemodynamics and Venous Return Page 7 of 25
 III. BLOOD PRESSURE You are a 25-year old healthy medical intern on duty at the
A. BLOOD PRESSURE ER today
Table 4. Blood Pressure Terms 1st patient: JJ, a 65 year old male, came in for nape pain.
Arterial Blood Force exerted by blood against the Nurse Marie carried the BP apparatus with an adult cuff
Pressure walls of the arteries with her to the ward, so you used the pediatric cuff to take
Maximal arterial pressure within the JJ’s BP.
Systolic BP
cardiac cycle
Minimal arterial pressure within the Q2: There is a high chance that JJ’s blood pressure
Diastolic BP
cardiac cycle would be measured
Difference between systolic and diastolic a. Erroneously low
Pulse Pressure
pressure b. Erroneously high ~
MEAN ARTERIAL PRESSURE (MAP) ANS: B. Erroneously high
Average force that drives blood flow into the blood
-
vessels Retaking JJ’s BP with the correct cuff using the
Considered a better indicator of perfusion to vital auscultatory method, you noted his BP at 160/90mmHg.
-
organs than SBP Nurse Marie asked you if you can recheck JJ’s BP since
The average arterial pressure during a single cardiac by palpatory method, she noted his systolic BP at 210.
cycle, ~80 mmHg [Guyton & Hall]
Pressure generated as blood is pumped out of the left Q3: Palpatory method should be done prior to
ventricle into the aorta and distributing arteries
MAP = (CO x SVR) + CVPcentral remove pressive
auscultatory method to avoid detecting an
a. Erroneously low systolic blood pressure- 2
deflate
SVR Expos
→ CVP is usually 0 at the level of the heart → MAP ≈ CO x b. Erroneously high systolic blood pressure wA too
→ MAP is directly proportional to CO and SVR (↑ SVR = ↑ ANS: A. Erroneously low systolic blood pressure
much
[2025 Trans]
MAP)
→ CO = HR x SV ~
Stroke Q4: After an hour, you checked JJ’s BP and it was
Normal MAP: 70-100 mmHg 180/120. What is the patient’s MAP?
At normal resting heart rates, MAP can be approximated or Given: SYS → 180 mmHg; DIA → 120 mmHg 180 240 +

-
computed clinically using this formula a. 100 mmHg !
PAP 3
b. 140 mmHg 140
-
180
c. 150 mmHg - 3 O
E ANS: B. 140 mmHg

Formula: MAP = (1 systolic + 2 diastolic)/3
[180 + 2(120)]/3 = 140 mmHg

DETERMINANTS OF ARTERIAL BP
Table 5. Determinants of ABP
Physical Factors Physiological Factors
Fluid Volume Cardiac output
→ ↑ means more fluid → HR x SV
presses against the wall of Total Peripheral harder
artery, ↑ pressure in arterial Resistance
walls [2025 Trans]
~
→ Also called Systemic
For
blood
Arterial Compliance → Vascular Resistance
to the
Figure 14. Mean Arterial Pressure with Cardiac Output and static elastic characteristic [2027 Trans]
Systemic Vascular Resistance [Lecturer’s PPT] of system
CASE SCENARIO ARTERIAL ELASTICITY
Your second patient, Michael, a 70 year-old male, came in
Table 6. Normal Artery vs Rigid Artery
at the ER with severe headache and nape pain. The ER
consultant asked you to take the patient’s mean arterial Normal Aorta and Rigid Artery
pressure. The first Korotkoff sound came in at 180 mmHg. Pulmonary Arteries
The last audible Korotkoff sound disappeared at 120 Systole: aorta distends Systole: no distension
mmHg. Diastole: recoils and Diastole: cannot recoil
7 80/128 propels blood forward
Q1: What is the patient’s Mean Arterial pressure?/ 90 High elastin, Highly With age, ↓ elastin & ↓ arterial
&e. 140 mmHg distensible compliance (Ca) → increased
180 2983 I20
+ -

f. 150 mmHg pulse pressure (PP)
- -2
Converts pulsatile output Increased pressure for
ANS: A. 140 mmHg into steady flow → ↓ work ventricles to pump blood vs a
NOTE TO ANSWER: of the heart large “afterload” → ↑ work of
1. Identify which is the given values heart
2. Recall the formula for Mean Arterial Pressure:
MAP = (1 systolic + 2 diastolic) / 3

PHYSIOLOGY Hemodynamics and Venous Return Page 8 of 25
 Figure 16.For a given volume increment (V2 − V1), reduced
~ over
left Ca results in increased PP, whereby (P4 − P1) > (P3 − P2).
[Berne & Levy, 7th Ed]

continue STROKE VOLUME AND PULSE PRESSURE
white diastole
Table 7. Stroke Volume & Pulse Pressure
STROKE VOLUME (SV) PULSE PRESSURE (PP)
Volume of blood pumped out Difference between systolic
of the left ventricle during and diastolic pressure
each systolic cardiac
contraction
SV = EDV - ESV PP = SV / Ca
Normal: 80 ml Normal: 40 mmHg
A large SV produces larger PP at any given compliance
Figure 15. Compliant arteries (A and B). Rigid arteries (C As the SV increases → greater mean BP → PP increases
and D). Blood flows through the capillaries during systole (C), Clinical Pearl:
but ceases during diastole (D). [Berne & Levy, 6th Ed] →Hemorrhage: decreased SV → decreased PP
→Advanced Age: decreased elastin in aorta →
In a normal compliant aorta decreased Ca → increased PP
→ During systole, the heart contracts and pumps out a Widened PP: ↑ systolic pressure and ↓ Ca (arterial
certain SV (volume of blood). compliance) (e.g. rigid arteries)
→ Since the Ca is normal, the aorta can stretch its walls Narrow PP: occur with ↓ SV (e.g. ↓ in blood volume, ↓
▪ It can save a substantial fraction of SV along its effectivity of pump (cardiac failure))
arterial walls.
▪ There is an amount of blood not pumped out during
systole
→ During diastole (heart relaxation), the aorta recoils.
▪ The volume of blood stored in the walls would be
displaced during the recoil.
▪ This ensures that though the heart is relaxed, the
capillary flow would still be continuous along the
tissues.
In a rigid artery
→ During systole, no blood (SV) is stored or saved in the
walls since they are not elastic or distensible
→ During diastole, no SV will be pushed forward by the
aorta to the capillaries
▪ Flow to the capillaries would cease or decrease

s
ARTERIAL COMPLIANCE (Ca) Figure 17. Effect of a change in SV on PP, in which Ca is
constant [Berne & Levy, 6th Ed]
Change in volume over a given change in pressure
Normal Ca = 2 ml/mmHg CASE SCENARIO
Compliance decreases with age because arteries become You took the BP again and it increased to 200/120. After
stiffer taking the Xray, the result indicated that Michael has a
If CO and TPR are constant, decrease in Ca → increased rigid, atherosclerotic aorta.
PP [Berne & Levy, 7th Ed] ↑P
↓ Ca also imposes a greater workload on the left ventricle -
Q5: What is the patient’s PP?
a. 80 mmHg 200
(i.e., increased afterload), even if SV, TPR, and arterial b. 120 mmHg
[Berne & Levy, 7th Ed]
pressure are equal in the two ventricles
ANS: A. 80 mmHg (Know the Definition of Pulse Pressure)

PULSE PRESSURE
Pulse Pressure = Systolic BP - Diastolic BP
Main determinants: SV and Ca (Physical determinants
of arterial BP); → PP = SV / Ca

PHYSIOLOGY Hemodynamics and Venous Return Page 9 of 25
 Q6: If his aorta is RIGID, which of the following is PALPATORY METHOD [2025 Trans]

TRUE?
a. The rigid aortic wall will not allow it to distend
during systole u
b. The rigid aortic wall will not allow it to distend
during diastole

ANS: A. Understand arterial compliance and how the aorta

Korotkoff
responds to the pumping action of the heart

B. BLOOD PRESSURE MEASUREMENT
BLOOD PRESSURE MEASUREMENT A real petore AP
is to Figure 19. Palpatory Method
Done before the auscultatory method to avoid auscultatory
gap
Performed by palpating the radial pulse at the wrist
Estimates only the SBP
→ Pressure at which the first pulse appears
Real-time BP can’t be measured

-
-
~
pressur Procedure:
1. Attach the cuff to the patient’s arm snugly, with the edge

pule of the cuff around 2 cm above the antecubital fossa
2. Connect the manometer to the cuff, making sure that
the patient does not see the meter
- 3. Palpate the patient’s radial pulse by placing your index
and middle fingers over the radial artery.
Figure 18. Schematic diagram of different non-invasive blood a. Do not use your thumb – has its own pulsation
pressure measuring methods [Lecturer’s PPT] 4. Inflate the cuff up to 20-30 mmHg above the point when
Non-invasive BP measurement that can be intermittent or pulse can no longer be felt. Slowly deflate at 2-4 mmHg
continuous [2027 Trans]
per pulse.
→ Intermittent BP measurement: use an inflatable cuff 5. Note the manometer reading at which the pulse the
▪ Can be done manually (through auscultatory or pulse reappears = PALPATORY SYSTOLIC BP
palpatory method) or by automated method (e.g., 6. After pulse felt, you can completely deflate cuff
oscillometry)
→ Continuous BP measurement: use volume clamp Note: You can only get one value which is the palpatory
method and arterial applanation tonometry systolic blood pressure
▪ Arterial applanation tonometry can be automated AUSCULTATORY BP MEASUREMENT
(automated systems) and can be done manually
(hand-held sensors)
[2025 Trans]
Table 8. Factors leading to inaccurate BP readings
↓ Variance Cause ↑ Variance
(mmHg) (mmHg)
Cuff is too small 10 - 40
10-40 Cuff over clothing 10 - 40
Arm unsupported 10
Back/feet unsupported 5 - 15
Legs crossed 5-8
Figure 20. Auscultatory Method
Not resting 3-5 minutes 10 - 20
More sensitive and precise compared to the palpatory
Patient talking 10 - 15 method [2025 Trans]
Labored breathing 5-8 Use a sphygmomanometer, which cuffs an artery, and a
Full bladder 10 - 15 stethoscope to listen for the Korotkoff sounds.
Pain 10 - 30 Steps:
Arm below heart level 1.8/inch 1. Ask the patient to loosen any tight clothing or to
1.8/inch Arm above heart level remove long sleeve garments to access their upper
arm (do not use the arm that may have a medical
PROPER BLOOD PRESSURE MEASUREMENT problem).
Use an accurate and properly maintained device 2. Place the cuff around the upper arm and secure it.
Recognize subject factors, such as anxiety and recent 3. Connect the cuff tubing to the sphygmomanometer
nicotine use tubing and secure it.
Position the subject appropriately 4. Rest the patient’s arm on a surface that is leveled with
Select the correct cuff and position it correctly their heart.
Perform the measurement using the auscultatory or 5. Place the bell or the diaphragm of the stethoscope on
automated oscillometric method and accurately record the the cubital fossa approximately above the brachial
values obtained. artery.
6. Inflate the bag with the rubber bulb at a pressure
20mmHg higher than the palpatory reading.

PHYSIOLOGY Hemodynamics and Venous Return Page 10 of 25
 7. Deflate the bag 2-4 mmHg per pulse Sound is louder in between systolic and diastolic.
8. Manometric reading at appearance of first sound → Sound will be softer until it disappears, at the level of the
note as SYSTOLIC BP diastolic pressure (B) -> continuous
[2025 Trans]
9. Continue releasing the pressure → Last sound detected is diastolic pressure
10. Manometric reading just before the disappearance of
sound → note as DIASTOLIC BP
11. Completely release the pressure
12. Tell the patient their BP monitoring.

Figure 24. Korotkoff Sound Volume Phases [Lecturer’s PPT]
OSCILLOMETRIC MEASUREMENT
Figure 21. Position for Auscultatory BP Measurement [Lecturer’s Used for self monitoring of blood pressure
PPT] Use of maximum volume change as an indication of the
average of systolic and diastolic blood pressure within the
artery
Uses reliable solid-state transducers and
microprocessors that allow pressure changes in the cuff
to be detected
Pulse detection by oscillometric machines depends on the

-i
amount of change in the volume of the arm with each
pulse and on the regularity and rate of those pulses
→ With - regular pulses and relatively smooth changing
arm volume, it is much easier for the microprocessor to
estimate the systolic and diastolic blood pressure.
→ However, if pulses are irregular and there are arm
movements under the cuff, pressure changes in the cuff
will not rise and fall smoothly, leading to difficulty in
making precise calculations.

Ionotkoft.e
voitin

florfxastolic
Figure 22. Brachial artery vs sounds heard during the
manual auscultatory measurement [Berne & Levy, 6th Ed]
KOROTKOFF SOUNDS
Pulsatile sounds you can hear when taking blood pressure.
-
Due to the turbulence caused by brachial artery
compression.

Figure 25. How to Read an Oscillometric Reading [Lecturer’s PPT]
OTHER NON-INVASIVE BP MONITORING
Volume Clamp Method
→ Continuous non-invasive BP monitoring
→ Obtained by applying pressure via the finger cuffs such
that the blood volume flowing through the finger arteries
Figure 23. Korotkoff Sound Volume in Between Systolic (Left) is held constant
and Diastolic (Right) [Lecturer’s PPT] → CNAP – the machine
When the BP apparatus is pumped way above the systolic ▪ Detects blood volume changes in the finger,
BP, the Korotkoff sound disappears. transforming plethysmograph signals into continuous
As you deflate the cuff, the Korotkoff sounds will reappear blood pressure information
once it reaches the systolic BP (A)
[2025 Trans]
→ First sound detected is systolic pressure

PHYSIOLOGY Hemodynamics and Venous Return Page 11 of 25
 2. Miscuffing
Ideal cuff: Bladder length 80% of arm circumference and
Figure 26. BP-monitoring Device and Reading width of at least 40% of arm circumference (length-to-width
[Lecturer’s PPT]
ratio of0
2:1)
INVASIVE BLOOD PRESSURE MONITORING → Available cuffs per range (i.e. pediatric cuffs, small
Continuous BP Monitoring adult cuffs, obese cuffs)
Done through the cannulation of a peripheral artery → Cuff too small: erroneously high BP
(usually radial artery [2025 Trans]
) → Cuff too big: erroneously low BP
Commonly utilized in the management of critically ill and Edge of cuff 2-3 cm above the antecubital fossa
perioperative patients Ask for patient’s permission to lift their sleeve before cuffing
[2025 Trans]
More accurate because it provides real-time BP 3. Auscultatory Gap (Cook & Taussig in 1917)
This is the reason why you always take your palpatory
BP before you take your auscultatory BP
Refers to the absolute or relative silence occasionally
found on listening over an artery during deflation of the

cresive
blood pressure cuff
Usually begins at a variable point below the systolic

-1wart
pressure and continues for 10 to 50 mmHg
-
Said to occur in up to 20% of elderly hypertensive cases

in
Figure 27. Arterial Cannulation Technique [Lecturer’s PPT]
anthat
Figure 29. Auscultatory Gap [Lecturer’s PPT]
Errors that may be noted if palpatory BP is not taken before
auscultatory BP:
→ Underestimation of systolic BP
▪ Example in Figure 29: True systolic BP is at 180,
true diastolic BP is at 80
▪ For instance, you did not take the palpatory BP and
Figure 28. How BP is Measured Using Arterial Cannulation you stopped inflating the cuff at 160. The next count
[Lecturer’s PPT] that you hear will be at 140, so you’ll be reporting
the BP of the patient at 140/80 instead of 180/80
COMMON CAUSES OF ERROR IN MEASUREMENT → Overestimation of diastolic BP
1. Patient Factors ▪ If you miss the auscultatory gap, the systolic
Alcohol and nicotine consumption, bladder distention, pressure that you’ll detect would be the true systolic
exercise, and body temperature. pressure (180 mmHg) but the diastolic pressure that
→ Caffeine and smoking should be avoided at least 30 you'll pick up would be the start of the auscultatory
minutes before getting the BP
Ask the patient to remove clothing at cuff location
--
gap (160 mmHg)
4. Observer Error
Patient should be positioned properly “Terminal digit preference” → Some practitioners round off
→ Middle of cuff below level of the right atrium → to nearest tens
erroneously HIGH BP
→ Above the right atrium→ erroneously LOW BP
°.
Should read to the nearest 2 mmHg and slowly deflate cuff
at 2-4 mmHg
→ Crossed legs → Increase in BP by 2-8mmHg
-

Measure on both arms during initial visit → >10mmHg 5. Device/Equipment Error
difference can be pathologic - Miscalibrations
-
At least 3 measurements should be made, 1-2 mins in Get multiple readings from both manual and automated BP
between readings Among adult Filipinos, what device is recommended for
accurate blood pressure determination and monitoring?
From Philippine Society of Hypertension (2020):
→ A properly validated - automated oscillometric
sphygmomanometer (digital device) is recommended
for in-office or out-of-office use

PHYSIOLOGY Hemodynamics and Venous Return Page 12 of 25
 → The aneroid sphygmomanometer (manual device) SUMMARY OF FACTORS AFFECTING THE CALIBER OF
may be used provided that the examiner is efficient ARTERIES
and well trained and that the device is periodically
Table 10: Summary of factors affecting the caliber of the arteries
checked according to standard maintenance
procedures Vasoconstriction Vasodilation
→ The aneroid sphygmomanometer is recommended in middle Local Factors
for special cases like presence of arrhythmias or star Decreased local temperature Increased CO2 and
extremes in BP levels decreased O2
6. White Coat Hypertension (WCH) Autoregulation Increased K+, adenosine,
“Kinabahan lang ako” as said by patients lactate
Elevated clinic BP with normal ambulatory or home BP Decreased local pH
ESH (European Society of Hypertension) definition: office Increased local temperature
reading of at least 140/90 and a mean 24 hour BP of Endothelial Products
→ Increase in parasympathetic activity through muscarinic
receptors and this would lead to a decrease in HR

GABA mp) Aca
PHYSIOLOGY Hemodynamics and Venous Return
↑Capp)vasoconstrictors
MICK (24
21
=

Page 14 of 25
131-A inotropy B2 Nosidanfy
=
 AR
H
-

& Figure 37. Respiratory Sinus Arrhythmia
Figure 34. Baroreceptor Response during the decrease in Also shows the interaction between Baroreceptor and
arterial pressure [Lecturer’s PPT] Bainbridge.
More pronounced in children
A decrease in arterial pressure results in decreased
Heart rate increases during inspiration and decreases
baroreceptor firing. The response is the opposite. -

during expiration.
We see an increase in sympathetic outflow and decrease
→ Rate increases during inspiration because stretch
in Parasympathetic or Vagal outflow.
receptors are activated.
Under normal physiological conditions, baroreceptor firing
-
exerts a tonic inhibitory influence on sympathetic outflow
from the medulla.
→ Phenomenon caused by the effect of breathing on vagal
voirver tone

R &
The change in intrathoracic pressure would increase
venous
-
-

return to the right atrium and activate the
-Bainbridge reflex.
High ventricular output would also lead to high BP and
-

baroreceptor activation, lowering the heart rate.
0 OTHER REFLEXES
Atrial and Pulmonary Artery Reflex
Figure 35. Bainbridge Reflex IBp -> HR → Low-pressure stretch receptors (cardiopulmonary
receptors) in atria and pulmonary arteries minimize
Through the Bainbridge reflex, an increase in volume arterial pressure changes in response to a change in

LBP
increases the right atrial pressure, stimulating the atrial blood volume.
receptors, and leading to higher heart rate and
- → Upon activation - minimize atrial pressure changes from
contractility. high blood volume
e
However, this sudden volume and atrial pressure ▪ The action is similar to baroreceptor (making it more
increase would also increase the BP through the potent)
baroreceptor reflex, lowering the heart rate. Volume Reflex and Atrial Natriuretic Peptide (ANP)
Thus, the actual change in heart rate from a sudden → Stretch of Atria ⟶ Decreased ADH release in Posterior
increase in blood volume, for instance during transfusion, Pituitary ⟶ Decreased afferent arteriolar resistance in
is the result of the balance of these two opposing factors.
RESPIRATORY SINUS ARRHYTHMIA
kidneys ⟶ Increased GFR ⟶-> mad
Increased fluid filtration
→ Release of ANP from Atria ⟶ Vasodilator effects and

leavee
potent natriuretic and diuretic on kidneys.
PERIPHERAL CHEMORECEPTORS

↓BP

⑧
Figure 36. Respiratory Sinus Arrhythmia Diagram
Figure 38. Anterior View of the Aortic Arch Showing the
Innervation of the Aortic Bodies and Baroreceptors
Small, highly vascular bodies in the region of the Aortic
arch, medial to the carotid sinuses.

PHYSIOLOGY Hemodynamics and Venous Return Page 15 of 25
 Sensitive to changes in Po2, Pco2, and pH of arterial
blood
Work to primarily regulate respiration and also
influence the vasomotor regions
A reduction in