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Blood Vessels and Circulation
Chapter 21
Fundamentals of Anatomy and Physiology
Martini/Nath/Bartholomew
 The anatomy of the blood vessels

Learning objectives
❖ Identify the three layers that constitute the walls of
most blood vessels.
❖ Compare the different types of blood vessels in
terms of their structure, functions and location.
❖ Briefly describe the distribution of blood amongst
the different types of blood vessels.

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 Classes of Blood Vessels
Five general classes of
Return blood vessels Carry blood
blood to away from
heart heart

Collect blood Are smallest
from capillaries branches of
Are smallest blood arteries
vessels
Location of chemical and
gaseous exchange
between blood and
interstitial fluid

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 Blood Vessels

The Tunica Intima (tunica interna) the inner layer includes:
The endothelial lining
Connective tissue layer with variable numbers of
elastic fibers
Internal elastic membrane (In arteries, is a layer of
elastic fibers in outer margin of tunica intima)

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 Blood Vessels

The Tunica Media (Middle Layer):
Contains concentric sheets of smooth muscle in loose
connective tissue
External elastic membrane (arteries) of the tunica media
Separates tunica media from tunica externa
Thickest layer in a small artery
Smooth muscle contraction = decrease on vessel diameter
Smooth muscle relaxation = increase on vessel diameter

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 Blood Vessels

The Tunica Externa (tunica adventitia) the outer layer:
Connective tissue sheath
Anchors vessel to adjacent tissues.
In arteries
Contains collagen fibers with scattered elastic fibers
In veins
Generally thicker than tunica media
Contains elastic fibers and smooth muscle cells

Vasa vasorum (“vessels of vessels”)
Small arteries and veins
In walls of large arteries and veins
Supply cells of tunica media and tunica externa

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 Blood Vessels
Differences between Arteries and Veins
Arteries have thicker walls and higher blood pressure
Tunica media of artery contains more smooth muscle and elastic
fibers than does that of a vein
Collapsed artery has small, round lumen (internal space)
Vein has a large, flat lumen
Endothelial lining of artery cannot contract → when the artery
constricts, its endothelium becomes folded
Endothelial lining of vein contracts → lining of the vein lacks
folds
Arteries more elastic
Veins have valves

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 Task!! Tabulate the differences between arteries and veins

ARTERIES VEINS
Vessel walls
Vessel lumen
Vessel lining
General appearance
in sectional view
Presence of valves
Tunica intima
Tunica media
Tunica externa

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Figure 21-1 Comparisons of a Typical Artery and a Typical Vein (Part 1 of 2).

Tunica externa

Tunica media

Tunica intima

Smooth muscle Lumen
of vein
Internal elastic
membrane

External
elastic
Lumen
membrane
of
artery
Endothelium

Elastic fiber

ARTERY Artery and vein LM × 60

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Figure 21-1 Comparisons of a Typical Artery and a Typical Vein (Part 2 of 2).

Tunica externa

Tunica media
Tunica intima

Lumen
of vein

Smooth
muscle

Lumen
of
artery
Endothelium

Artery and vein LM × 60 VEIN

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 Structure and Function of Arteries
Arteries
Elasticity allows arteries to absorb pressure waves that
come with each heartbeat
Permits vessel diameter to change passively in
response to blood pressure changes
Contractility
Arteries change diameter actively
Controlled by sympathetic division of autonomic
nervous system (ANS)
Vasoconstriction- contraction of arterial smooth
muscle by the ANS
Vasodilation- The relaxation of arterial smooth muscle

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 Structure and Function of Arteries

Elastic Arteries (conducting arteries)
Large vessels (e.g., pulmonary trunk and aorta)
Tunica media has many elastic fibers and few
smooth muscle cells=more resilience
Elastic arteries help to make blood flow continuous

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 Structure and Function of Arteries

Muscular Arteries (distribution arteries)
Are medium sized (most arteries)
Distribute blood to skeletal muscles and internal organs
Tunica media has many smooth muscle cells
Superficial muscular arteries = pressure points

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 Structure and Function of Arteries
Arterioles
Are small
Have little or no tunica externa
Have thin or incomplete tunica media

Artery Diameter
Small muscular arteries and arterioles
Change with sympathetic or endocrine stimulation
Constricted arteries oppose blood flow
Resistance (R)
Resistance vessels - arterioles
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 Structure and Function of Capillaries

Capillaries
Are smallest vessels with thin walls
Microscopic capillary networks permeate all active tissues
Capillary function
Location of all exchange functions of cardiovascular
system
Materials diffuse between blood and interstitial fluid

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 Structure and Function of Capillaries

Capillary Structure
Endothelial tube, inside thin basement membrane
No tunica media, no tunica externa
Diameter is similar to red blood cell

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 Continuous Capillaries Fenestrated Capillaries
Have pores or “windows” in endothelial lining
Location Structure
Have complete endothelial
lining

Are found in all tissues Choroid plexus, Endocrine organs
except epithelia and (hypothalamus, pineal), Kidneys (filtration sites),
cartilage Intestinal tract

Permit diffusion of water, Permit rapid exchange of water and larger
Function

small solutes, and lipid- solutes between plasma and interstitial fluid
soluble materials
Block blood cells and
plasma proteins
Sinusoids (Sinusoidal Capillaries)
Have gaps between adjacent endothelial cells
(liver, spleen, bone marrow, endocrine organs)
Permit free exchange of water and large plasma
proteins between blood and interstitial fluid

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Figure 21-3 Capillary Structure.

Basement
membrane

Endothelial cell

Nucleus

Endosomes

Endosomes Fenestrations,
or pores

Boundary
Boundary
between
between
endothelial Gap between
Basement endothelial Basement
cells adjacent cells
membrane cells membrane

a Continuous capillary b Fenestrated capillary c Sinusoid

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 Structure and Function of Capillaries

Capillary Beds (Capillary Plexus)
Connect one arteriole and one venule
Precapillary Sphincter
Guards entrance to each capillary
Opens and closes, causing capillary blood to flow in pulses
Thoroughfare Channels
Direct capillary connections between arterioles and venules
Controlled by smooth muscle segments (metarterioles)

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Figure 21-4a The Organization of a Capillary Bed.

Vein
Collateral
Smooth arteries
muscle cells Venule

Arteriole
Thoroughfare
Metarterioles channel

Capillaries
Section of
precapillary
sphincter

Small
venule

Precapillary
sphincters
KEY
Arteriovenous Consistent
blood flow
anastomosis
Variable
blood flow
a A typical capillary bed. Solid arrows
indicate consistent blood flow;
dashed arrows indicate variable or
pulsating blood flow. 20
 Structure and Function of Veins

Veins
Collect blood from capillaries in tissues and organs
Return blood to heart
Are larger in diameter than arteries
Have thinner walls than arteries
Have lower blood pressure

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 Structure and Function of Veins
Venules
Very small veins
Collect blood from capillaries
Some venules lack a tunica media
Medium-sized veins
Thin tunica media and few smooth muscle cells
Tunica externa with longitudinal bundles of elastic fibers
Large Veins
Have all three tunica layers
Thick tunica externa
Thin tunica media

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 Structure and Function of Veins

Venous Valves
Folds of tunica intima
Prevent blood from flowing backward
Compression pushes blood toward heart

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Figure 21-5 The Function of Valves in the Venous System.

Valve
closed

Valve opens superior
to contracting muscle

Valve
closed

Valve closes inferior
to contracting muscle 24
Figure 21-2 Histological Structure of Blood Vessels.

Veins Arteries
Large Vein Elastic Artery

Tunica externa Internal elastic
membrane Tunica
Tunica media
Endothelium intima
Endothelium
Tunica media
Tunica intima
Tunica externa

Medium-sized Vein Muscular Artery

Tunica externa
Tunica externa
Tunica media
Tunica media
Endothelium
Endothelium
Tunica intima Tunica
intima

Venule Arteriole

Smooth muscle cells (tunica media)
Tunica externa
Endothelium Endothelium
Basement membrane

Fenestrated Capillary Capillaries Continuous Capillary

Pores
Endothelial
Endothelial cells cells

Basement membrane Basement membrane
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Figure 21-6 The Distribution of Blood in the Cardiovascular System.

Large veins
18%

Large venous
networks (liver,
bone marrow, skin)
21%

Venules and
medium-sized veins
25%

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The role of the blood vessels and blood circulation
in maintaining adequate tissue perfusion

Learning objectives
❖ Explain the role of pressure and resistance in ensuring
blood flow through the circulatory system.
❖ Describe how pressure and resistance is created and
regulated.

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 Pressure and Resistance
Total Capillary Blood Flow
Equals cardiac output (CO)
Amount of blood (mL) pumped by the left ventricle in
one min.
Indication of blood flow through the peripheral tissues
If CO ↑, blood flow through capillary beds ↑
If CO ↓, blood flow through capillary beds ↓
CO=HR x SV
(mL/min)= (beats/min) x (mL/beat)

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 Pressure and Resistance

Total Capillary Blood Flow
Is determined by:
Pressure (P) and resistance (R) in the
cardiovascular system
To keep blood moving, the heart must generate
enough pressure to overcome the resistance in the
pulmonary and systemic circuits

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 Pressure and Resistance
Generally flow is directly proportional to the pressure
↑ pressure = ↑ flow
And inversely proportional to resistance
↑ resistance = ↓ flow
However the absolute pressure is less important than the
pressure gradient, therefore flow (F) is proportional to the
pressure gradient (∆P) divided by resistance (R)
Equation: F α ∆P/R

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 Pressure and Resistance

The Pressure Gradient ( P)
The difference in pressure from one end of a vessel
to the other

The difference between:
E.g.
Largest Pressure at the heart (base of aorta)
pressure
gradient And pressure at peripheral capillary beds

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 Pressure and Resistance

F α P/R
↑ pressure, ↑ flow
↑ resistance, ↓ flow

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 Pressure and Resistance

Measuring Pressure
1. Blood pressure (BP)
Arterial pressure (mm Hg)
2. Capillary hydrostatic pressure (CHP)
Pressure within the capillary beds
3. Venous pressure
Pressure in the venous system

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 Pressure and Resistance

Circulatory Pressure
∆P across the systemic circuit (about 100 mm Hg)
Circulatory pressure must overcome total peripheral
resistance (resistance of entire cardiovascular system)

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 Pressure and Resistance

Total Peripheral Resistance
Vascular resistance
Forces that oppose blood flow in blood vessels
Blood viscosity
Resistance to flow caused by interactions among
molecules and suspended materials in liquid
Turbulence
Eddies and swirls due to irregular surfaces, high flow
rates

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 Pressure and Resistance

Vascular Resistance
Due to friction between blood and vessel walls
Depends on vessel length and vessel diameter
Length: Longer the vessel the greater the friction
Diameter: Vessel diameter varies by vasodilation
and vasoconstriction
Resistance increases exponentially as vessel
diameter decreases

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Figure 21-7 Factors Affecting Friction and Vascular Resistance.

Factors Affecting Vascular Resistance
Friction and Vessel Length

Resistance to flow = 1
Internal surface
Flow = 1
area = 1

Resistance
to flow = 2
Internal surface area = 2 Flow = 12

Friction and Vessel Diameter

Greatest resistance near
surfaces, slowest flow

Least
resistance
at center
greatest flow

Vessel Length versus Vessel Diameter

Diameter = 2 cm

Resistance to
flow = 1

Diameter = 1 cm
Resistance to
flow = 16

Turbulence
Plaque
deposit Turbulence

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 Pressure and Resistance

Viscosity
Resistance caused by molecules and suspended
materials in a liquid
Whole blood viscosity is about four to five times that of
water
↑ viscosity = ↑ resistance

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 Pressure and Resistance

Turbulence
Swirling action that disturbs smooth flow of liquid
Occurs in heart chambers and great vessels
Atherosclerotic plaques cause abnormal turbulence

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Table 21-1 Key Terms and Relationships Pertaining to Blood Circulation.

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 Summary

↑ vessel length, ↑ friction = ↑ resistance
↑ friction at the zone closest to vessel wall = ↑ resistance
↓ diameter of blood vessel = ↑ resistance
↑ blood viscosity = ↑ resistance
↑ turbulence = ↑ resistance

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 Pressure and Resistance

An Overview of Cardiovascular Pressures
Vessel diameters
Total cross-sectional areas
Pressures
Velocity of blood flow

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Figure 21-8a Relationships among Vessel Diameter, Cross-Sectional Area, Blood Pressure, and Blood Velocity within the Systemic Circuit.

3

2

Vessel
diameter 1
(cm)

0
Elastic Muscular Arterioles Capillaries Venules Veins Venae
arteries arteries cavae
Aorta a Vessel diameter

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Figure 21-8b Relationships among Vessel Diameter, Cross-Sectional Area, Blood Pressure, and Blood Velocity within the Systemic Circuit.

5000

4000
Cross-
3000
sectional
area
2000
(cm2)
1000

0
Elastic Muscular ArteriolesCapillaries Venules Veins Venae
arteries arteries cavae
Aorta b Total cross-sectional area of vessels

44
Figure 21-8c Relationships among Vessel Diameter, Cross-Sectional Area, Blood Pressure, and Blood Velocity within the Systemic Circuit.

120
100

80
Average
blood 60
pressure
(mm Hg) 40

20
0
Elastic Muscular Arterioles Capillaries Venules Veins Venae
arteries arteries cavae

Aorta
c Average blood pressure

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Figure 21-8d Relationships among Vessel Diameter, Cross-Sectional Area, Blood Pressure, and Blood Velocity within the Systemic Circuit.

35

28
Velocity
of blood 21
flow
(cm/sec) 14

7

0
Elastic Muscular Arterioles Capillaries Venules Veins Venae
arteries arteries cavae

Aorta
d Velocity of blood flow

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 The role of the blood vessels and blood
circulation in maintaining adequate tissue
perfusion

Learning objectives
❖ Differentiate between mean arterial pressure, pulse
pressure, capillary pressure and venous pressure
and explain how each of these pressures is
sustained.
❖ Describe the process of capillary exchange.

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 Pressure and Resistance

Arterial Blood Pressure
Systolic pressure
Peak blood pressure during ventricular systole
Diastolic pressure
Minimum blood pressure during ventricular
diastole
160/100

160 = systolic pressure
100 = diastolic pressure

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 Pressure and Resistance
Arterial Blood Pressure
Pulse: rhythmic fluctuation in pressure that accompanies
each heartbeat
Pulse pressure
Difference between systolic pressure and diastolic
pressure

Mean arterial pressure (MAP)
MAP = diastolic pressure + pulse pressure/3

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 Pressure and Resistance

Abnormal Blood Pressure
Normal = 120/80
Hypertension
Abnormally high blood pressure
Greater than 140/90
Hypotension
Abnormally low blood pressure

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 Pressure and Resistance

Elastic rebound
As systolic pressure ↑, arterial walls stretch
When diastole begins, blood pressure falls and arteries
recoil to their original dimensions

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 Pressure and Resistance
Pressures in Small Arteries and
Arterioles
Pressure and distance
MAP and pulse pressure
decrease with distance from
heart
Blood pressure decreases
as it overcomes friction

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 Pressure and Resistance

Venous Pressure and Venous Return

Low pressure in venous system

Venous pressure determines venous return - the
amount of blood arriving at right atrium each minute

Venous return directly impacts cardiac output

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 Pressure and Resistance

Venous Pressure and Venous Return
Two factors assist low venous pressures in propelling
blood towards the heart:
Muscular compression (“muscular pump”) of
peripheral veins
Compression of skeletal muscles pushes blood
toward heart (one-way valves)

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 Pressure and Resistance

Venous Pressure and Venous Return
Two factors assist low venous pressures in propelling
blood towards the heart:
The respiratory pump
Thoracic cavity action
Inhaling decreases thoracic pressure
Pulls blood into inferior vena cava and right
atrium
Exhaling raises thoracic pressure
Pushes the venous blood into the right atrium

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 Pressure and Resistance

Capillary Pressures and Capillary Exchange
Vital to homeostasis
Moves materials across capillary walls by:
Diffusion, Filtration and Reabsorption

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 Pressure and Resistance
Diffusion
Movement of ions or molecules from high concentration to lower
concentration along the concentration gradient
Diffusion Routes
1. Water, ions, and small molecules such as glucose diffuse
between adjacent endothelial cells or through fenestrated
capillaries
2. Some ions (Na+, K+, Ca2+, Cl−) diffuse through channels in
plasma membranes
3. Large, water-soluble compounds pass through fenestrated
capillaries
4. Lipids and lipid-soluble materials such as O2 and CO2 diffuse
through endothelial plasma membranes
5. Plasma proteins cross endothelial lining in sinusoids
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 Pressure and Resistance
Filtration
Removal of solutes as a solution flows across a porous
membrane
Driven by hydrostatic pressure (HP)
HP= force exerted against a liquid (fluid pressure)
Pushes water from an area of higher pressure to
an area of lower pressure
Water and small solutes forced through capillary wall
Leaves larger solutes in bloodstream
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Figure 21-10 Capillary Filtration.

Capillary
hydrostatic
pressure
(CHP) Amino acid
Blood protein
Glucose
Ions

Interstitial
fluid

Small solutes

Hydrogen
bond

Water
molecule

Endothelial Endothelial
cell 1 cell 2

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 Pressure and Resistance

Reabsorption
Occurs as the result of osmosis
water molecules diffuse across a membrane
towards the solution containing a higher solute
concentration
Osmotic pressure (OP)
pressure that must be applied to prevent osmosis

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 Pressure and Resistance

Reabsorption
Blood colloid osmotic pressure (BCOP)
Caused by suspended blood proteins that are too
large to cross capillary walls
Equals pressure required to prevent osmosis
Also called “oncotic pressure”

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 Pressure and Resistance

Interplay between Filtration and Reabsorption
1. Ensures that plasma and interstitial fluid are in constant
communication and mutual exchange
2. Accelerates distribution of nutrients, hormones, and dissolved
gases throughout tissues
3. Assists in the transport of insoluble lipids and tissue proteins
that cannot enter bloodstream by crossing capillary walls
4. Has a flushing action that carries bacterial toxins and other
chemical stimuli to lymphatic tissues and organs responsible
for providing immunity to disease

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 Pressure and Resistance

Interplay between Filtration and Reabsorption
Net hydrostatic pressure (NHP)
Forces water out of solution
Net osmotic pressure (NCOP)
Forces water into solution
Both control filtration and reabsorption through capillaries

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 Pressure and Resistance

Factors that Contribute to the Net Hydrostatic Pressure (NHP)
Capillary hydrostatic pressure (CHP)
Interstitial fluid hydrostatic pressure (IHP)
Net capillary hydrostatic pressure tends to push water and
solutes out of capillaries and into interstitial fluid
NHP = CHP – IHP
Under normal circumstances IHP = 0
Therefore: NHP = CHP

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 Pressure and Resistance

Factors that Contribute to the Net Capillary Colloid Osmotic
Pressure (NCOP)
Is the difference between:
Blood colloid osmotic pressure (BCOP)
Interstitial fluid colloid osmotic pressure (ICOP)
Pulls water and solutes into a capillary from interstitial fluid
NCOP = BCOP- ICOP
Under normal circumstances ICOP = 0
Therefore: NCOP = BCOP

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 Pressure and Resistance

Interplay between Filtration and Reabsorption
Important to remember
Net hydrostatic pressure (NHP) = CHP
Forces water out of solution
Net osmotic pressure (NCOP) = BCOP
Forces water into solution
Both control filtration and reabsorption through capillaries

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 Pressure and Resistance

Net Filtration Pressure (NFP)
The difference between:
Net hydrostatic pressure
Net osmotic pressure
NFP = (CHP – IHP) – (BCOP – ICOP)

NFP = CHP - BCOP

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 Pressure and Resistance

Capillary Exchange
At arterial end of capillary:
Fluid moves out of capillary into interstitial fluid
At venous end of capillary:
Fluid moves into capillary out of interstitial fluid
Capillaries filter more than they reabsorb
Excess fluid enters lymphatic vessels

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Figure 21-11 Forces Acting across Capillary Walls.

NFP = CHP - BCOP
Return to
circulation
3.6 L/day flows
into lymphatic
vessels

Arteriole KEY
Venule
CHP (Capillary
hydrostatic pressure)
Filtration Reabsorption
BOP (Blood
No net fluid
movement 20.4 L/day
osmotic pressure)
24 L/day
35 25 25 25 18 25
mm mm mm mm mm mm NFP (Net filtration
Hg Hg Hg Hg Hg Hg pressure)

NFP = +10 mm Hg NFP = 0 NFP = −7 mm Hg

CHP > BCOP CHP = BCOP BCOP > CHP
Fluid forced No net Fluid moves
out of capillary movement into capillary
of fluid

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 Reference

Martini (FH), Nath (JL) and Bartholomew (EF) (2015).
Fundamentals of Anatomy and Physiology. 10th Edition.

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