Hypertension Lecture 8 PDF

Summary

This document covers the systemic circulation, blood flow characteristics, and the properties of blood vessels. It details the roles of blood, pulmonary and systemic circulation, emphasizing the role of blood vessel properties and vascular resistance in maintaining blood pressure. The document also includes questions about hypertension.

Full Transcript

Calli Cook, DNP, APRN, FNP-C, FAANP
Clinical Associate Professor
NHWSON

Objectives: Part 1

Describe the general
organization and function
of the systemic circulation

Briefly describe the
characteristics of each
segment of the vascular
system from arteries to
veins

The primary roles of blood:

Homeostatic
Function of
the
Circulator
System

• Carry oxygen from the lungs to the tissues and
carbon dioxide from the tissues for elimination
from the lungs
• Nutrients from the digestive tract to the tissues
• Metabolic waste products from the tissues to their
point of elimination
• Hormones from their point of production to the
site of action
• Immune system components

Blood Flow

Pulmonary Circulation
• The pulmonary circulation originates from the
right ventricle with the pulmonary artery.
• The primary goal of the pulmonary circulation is
to oxygenate blood and remove carbon dioxide
• Oxygenated blood is returned to the left atrium
by means of the pulmonary veins.
• Despite the same amount of total blood flow,
pressure and vascular resistance are about
five- to ten-fold lower in the pulmonary
circulation compared with that in the
systemic circuit.

Systemic Circulation
• Systemic circulation starts with the aorta, which receives output
from the left ventricle, and branches into numerous parallel
vascular circuits, each receiving a fraction of the cardiac output.
• Each circuit dynamically adapts to the tissues’ metabolic needs
• During exercise and rest cardiac output varies.
• Redistribution of blood flow is an adaptive mechanism that
ensures that blood is being directed to areas with greater
metabolic need during times of increased activity.
• Vital organs such as the brain are always active and receive
similar blood flow under both conditions.

Question 1

Which of the following best describes blood flow during exercise?
• Redistribution of blood flow is an adaptive mechanism that ensures that blood is being
directed to areas with greater metabolic need during times of increased activity
• Redistribution of blood flow ensures that blood is directed to areas with decreased
metabolic need during times of increased activity
• Blood flow does not change with activity
• Blood flow only changes in relationship to wall tension

Structure and Properties of
Blood Vessels

General
Structure
• Most vessels have three layers (from inner to
outer):
1. Tunica intima:
• single layer of endothelial cells forming
the vessel lining, basement membrane
• and a layer of elastic fibers (internal
elastic lamina)
2. Tunica media:
• Concentric layers of smooth muscle cells
3. Tunica externa:
• Strong connective tissue
• Capillaries:
• Have uniquely thin walls composed of only
endothelial cells and basement membrane (no
elastic fibers or VSM).

Comparative Structure of Blood Vessels

• The size and ratio of wall components in blood vessels vary greatly
• Blood flow in the systemic circulation is driven by the pumping action of the left ventricle
• The pressure is highest in the aorta and falls throughout the circuit because of vascular
resistance
• Arteries have much thicker walls compared with veins and thus can withstand higher
pressures
• Arteries branch into arterioles
• Representing the primary site (70% to 80%) of systemic vascular resistance
• Consider diameter

Endothelial Cells
• The endothelial cells form a barrier that contains blood within the lumen of the vessel and
controls the passage of solutes and cells from the circulation into the subendothelial
space.
• Endothelial cells secrete substances that modulate contraction of SMCs in the underlying
medial layer.
• These substances include vasodilators (e.g., NO and prostacyclin) and
vasoconstrictors (e.g., endothelin)
• Endothelial cells can also modulate the immune response.
• In the absence of pathologic stimulation, healthy arterial endothelial cells resist
leukocyte adhesion and thereby oppose local inflammation.
• However, endothelial cells respond to local injury or infection by expressing cell
surface adhesion molecules, which attach monocytes to the endothelium and
chemokines
• The normal endothelium provides a protective, nonthrombogenic surface with
homeostatic vasodilatory and anti-inflammatory properties

Vascular Smooth Muscle Cells

• SMCs within the medial layer of normal muscular arteries have both contractile and
synthetic capabilities.
• SMCs produce vasoactive and inflammatory mediators, including interleukin (IL)-1 and IL6, and tumor necrosis factor (TNF).
• In normal arteries, most SMCs reside in the medial layer
• During atherogenesis, medial SMCs can migrate into the intima, proliferate, and augment
synthesis of extracellular matrix macromolecules while they dampen contractile protein
content. (makes SMC pathologic)

Properties and
Disorders of Large
Arteries

Objectives: Part 2

• Describe the relationship between vascular pressure and the development of tension in
the blood vessel wall.
• Apply the law of Laplace to the development of vascular wall hypertrophy or an aneurysm
in a patient with poorly controlled hypertension.
• Identify the role of large artery elastic recoil in maintaining diastolic pressure
• Describe the steps, processes, cells, and mediators involved in atherosclerotic plaque
development and progression
• Distinguish between the long-term processes of plaque formation and the rapid process
of vessel occlusion upon erosion or rupture of the atherosclerotic plaque.

Biophysics of Wall Tension
• Blood pumped into the aorta by the left ventricle
generates a push on the vessel wall (hydrostatic
pressure)
• This pressure is highest in the aorta and large arteries
• Large arteries must withstand high pressure at a
relatively large radius
• To reduce wall tension and avoid rupture, large
arteries have much thicker walls compared with
walls of veins of similar size.
• Wall tension (T) is increased by both pressure (P) and
radius (r), but decreased by wall thickness (h).

Clinical
Examples of
Vascular Wall
Tension

• Vascular Hypertrophy:
• Increase in wall thickness helps to offset the effect of
increased pressure and decrease wall tension.
• However, if elevated blood pressure is sustained over
time, the thicker vascular walls become fibrotic and
can lead to secondary problems
• Vascular Aneurysm:
• Sustained high arterial pressure can cause a
progressive increase in vascular radius
• This sets up a vicious cycle in which the vessel begins
to dilate, further increasing its radius, and therefore
wall tension.
• This forms a vascular aneurysm

Case courtesy of The Radswiki, Radiopaedia.org, rID: 11534

Question 2

• High arterial pressure has consequences for
blood vessels, according to the Law of
Laplace. Which of the following occurs when
the arterial wall weakens in response to the
increased pressure, causing a viscous cycle
of dilation, increased radius, increased
tension, and ultimately a weakened wall?
•
•
•
•

Hypertrophy
Atherosclerosis
Aneurysm
Heart failure

Biophysics of Vascular
Compliance
• All blood vessels stretch under pressure
• Arteries are less compliant than veins but are subjected to greater
pressure changes as they receive the stroke volume of the heart during
systole.
• The aorta and large arteries contain an abundance of elastic fibers that
stretch during systole and return to their original shape and size during
diastole.
• This elastic recoil of the large arteries helps to maintain diastolic
blood pressure and thus tissue perfusion between heart beats.
• When arterial walls become less compliant, patients may present with
an increase in systolic blood pressure and a decrease in diastolic
pressure and blood flow
• Veins are much more compliant than arteries
• 60% to 68% of the circulating blood volume is typically stored at
relatively low pressures in the systemic veins and venules

Elastic Recoil

Biophysics of Flow
Velocity
• Blood flow velocity and cross-sectional area are
inversely related
• Blood velocity is highest in the aorta and large arteries
and lowest in the capillaries.
• Flow velocity is directly related to shear stress (friction
of the blood sliding past and pulling on the
endothelial cell surface parallel to the direction of
flow)
• Slow blood velocity is also the foundation for capillary
function
• Allows for exchange of water and blood-borne
substances between blood and interstitial fluid

Biophysics of Shear Stress
• Laminar flow and high velocity in large arteries cause shear
stress
• Hydrostatic pressure further acts on the vessel wall by
maintaining a perpendicular distending force that
contributes to wall tension
• Endothelial cell and smooth muscle layers generate and
respond to a variety of biochemical mediators
• Most important is the production of nitric oxide
• NO promotes vasodilation, maintaining vessel patency
and vascular wall health and lowering blood pressure

Pathology of Flow
• In turbulent flow, such as downstream from an
atherosclerotic plaque and in areas of vascular
branching, endothelial shear stress is reduced,
leading to decreased nitric oxide production.
• Decreased endothelial nitric oxide production is
a hallmark of endothelial dysfunction that
contributes to and accompanies atherosclerosis.
• Elevated sheer stress cannot increase nitric
oxide production, but rather contributes to
endothelial damage and exacerbates
atherosclerosis (HTN).

Properties of Arterioles

Objectives: Part 3
• List the factors controlling vascular resistance
• Provide an overview of factors regulating blood pressure
• Identify the major role played by vascular smooth muscle cells and the sympathetic
nervous system in blood pressure regulation
• Describe the cellular mechanisms that cause contraction of vascular smooth muscle
(VSM) and give examples of mediators that stimulate VSM contraction
• Describe the cellular mechanisms that cause VSM relaxation and give examples of
mediators that stimulate VSM relaxation
• Review the steps of baroreflex responses to states of acute hypotension and acute
hypertension
• Recognize the hypotheses regarding the pathogenesis of primary hypertension
• Identify the consequences of poorly managed hypertension and the strategies used to
improve blood pressure management.
• Compare and contrast the pathophysiology of the different forms of shock.

Structure and
Function

• Help maintain the systemic vascular resistance (SVR)
• Abundance of sympathetic NS activity
• Stimulation of α-adrenergic receptors results in
vasoconstriction, whereas stimulation of β2-receptors
promotes vasodilatation.
• Major pathophysiological changes:
• Hypertension
• Shock

Biophysical
Determinants of
Blood Pressure

• Mean arterial pressure (MAP) is the average driving
pressure in the circulatory system.
• MAP = DBP + ((SBP-DBP) ÷ 3)

Biophysical Determinants
of Blood Pressure
• Vascular resistance refers to the tendency of the
branching and narrowing blood vessels to hinder
blood flow, MAP drives this gradient
• MAP is influenced by cardiac output and systemic
vascular resistance, each of which is influenced by
several variables.

Determinates of Vascular
Resistance
• Length of the blood vessel
• Viscosity of blood: An increase in hematocrit will
increase blood viscosity and increase systemic
vascular resistance
• Radius of the vessel: This is the main factor
controlling vascular resistance on a minute-tominute basis. Decreasing the radius of the vessels
increases vascular resistance. Increasing the radius
of the vessels would have the opposite effect
• Radius affects the vascular resistance the most

Distribution of Vascular
Resistance
• Pressure is highest in the left ventricle
during systole and drops throughout the
cardiovascular circuit as vascular resistance
opposes the flow of blood.
• Flow will only occur from an area of higher
pressure to an area of lower pressure.
• The greatest drop in MAP occurs at the
arterioles, as the arterioles represent the
greatest amount (~70%) of resistance in the
systemic circulation.

Dual Role of Arterioles
• Increasing arteriolar resistance by arteriolar constriction will
increase pressure in the arteries; however, decrease
pressure in the capillaries following those arterioles
• In contrast, vasodilation reduces the arteriolar resistance.
Decreased total peripheral resistance reduces arterial
pressure while increasing pressure reaching the capillaries
• In hypertension, arteriolar resistance may be too high,
causing an elevation in blood pressure and the potential for
reduced tissue perfusion due to decreased capillary
pressure and flow.
• In contrast, in shock, there is dangerous decrease in arterial
blood pressure and the potential for loss of fluid into the
tissues due to increased capillary pressure and flow

Regulation of
Blood Pressure

Four Sites of BP Regulation

Resistance arterioles

• Arterioles represent the primary site of vascular resistance maintaining
normal blood pressure

Capacitance venules

• Veins and venules can alter cardiac output and blood pressure by
regulating venous return (preload)

Cardiac Output

• Cardiac output = heart rate × stroke volume
• An increase in HR or SV will increase CO and thus blood pressure

Kidneys

• Site of blood volume regulation

BP Regulation

Regulation of Blood Pressure
Short Term
• Neural
• Baroreceptor reflex
• Hormonal
• Angiotensin II
• Vasopressin
• Local
• Nitric Oxide
• Bradykinin
• Endothelin
• Prostaglandins
• Goal: Alter vascular resistance

Long Term
• Hormonal
• Aldosterone
• Vasopressin
• Natriuretic peptides
• Goal: alter blood volume by modulating fluid
output

Smooth Muscle
Contractile Cells
• Action potentials open voltage-gated
calcium channels, initiating smooth muscle
cell contraction.
• Once contracted, the actin–myosin crossbridges do not completely relax; rather,
they stay in a state of moderate
contraction.
• This state is supported by low levels of tonic
firing of sympathetic vasoconstrictor fibers.
• These mechanisms are important for
overall blood pressure maintenance.

Endothelial Factors
• Nitric oxide is essential for maintaining normal blood flow during
physiological conditions. Nitric oxide diffuses out of the endothelial
cells to the underlying smooth muscle and causes relaxation by
increasing cGMP production.
• Endothelial dysfunction is common in diabetes, hypertension,
and atherosclerosis, causing decreased nitric oxide production
and contributing to vascular pathology.
• Prostacyclin (PGI2) is an endothelium-derived vasodilator. In
endothelial cells, PGI2 is produced from arachidonic acid by
cyclooxygenase-2 (COX-2) and other enzymes.
• ET1 is an endothelium-derived vasoconstrictor peptide. ET1
activates ETA receptors on VSM to cause vasoconstriction. Under
healthy physiological conditions, ET1 production is minimal.
• Increased ET1 production has been implicated in the
pathogenesis of primary pulmonary arterial hypertension

Endothelial
Factors

Cellular vs. Extrinsic
VSM regulation
• Cellular: As electrically excitable cells, smooth muscle
cells can have action potentials that open voltagegated calcium channels and cause contraction.
•
Vascular calcium channels are the target of one
class of antihypertensive medications: calcium
channel blockers.
• Extrinsic: Vasoconstriction is linked to Gq and
phospholipase C activation. This leads to IP3
generation and release of calcium from intracellular
stores.
• Extrinsic: Vasodilation occurs through inhibition of
MLCK and activation of myosin light-chain phosphatase
(MLCP). Gs-coupled receptors increase intracellular
cAMP, which inhibits MLCK.

Cellular

Extrinsic

EC and
VSMC

Vascular Autoregulation
• Maintain constant local blood flow despite changes in MAP
• Very important to the brain and kidneys
• Two hypotheses:
1. Myogenic hypothesis suggest that acute pressureinduced stretch of the arterial and arteriolar walls
stimulates immediate constriction, while a rapid pressure
drop elicits vasodilation
2. Metabolic hypothesis of autoregulation suggests that
decreased pressure and flow result in buildup of
vasodilator metabolites that produce vasodilation, while
increased pressure and flow wash out vasodilator
metabolites, producing vasoconstriction

RAAS
• Low blood pressure is detected by the juxtaglomerular apparatus
of the nephrons of the kidney, and renin is secreted.
• Renin is an enzyme that catalyzes the conversion angiotensinogen
to angiotensin I.
• Angiotensin I circulates through vasculature and is converted to
angiotensin II by angiotensin-converting enzyme (ACE)
• Angiotensin II is a potent vasoconstrictor and is also the key
regulator of adrenal aldosterone secretion.
• Aldosterone, the final mediator of the RAAS, stimulates
sodium conservation through its actions on the distal
nephron.
• Angiotensin II acts within the hypothalamus to stimulate
thirst, further promoting fluid acquisition and retention to
support blood volume. (can further worsen HF since they are
already fluid overload)

Mediators
that
Regulate
Resistance

Vascular Effect

Mediator

Receptor

Constriction/
increased
resistance

NE

α1

Dilation/
decreased
resistance

G Protein

Epinephrine
Angiotensin II
(ATII)

AT1

Vasopressin
(AVP)

V1

Endothelin-1
(ET1)

ETA

Thromboxane
A2 (TXA2)

TP

Epinephrine

β2

Adenosine

A2

Prostacyclin
(PGI2)

IP

Second
Messenger

Type of
Regulation

IP3—calcium
release

Neural
Endocrine

Gq
Paracrine

cAMP ↑

Paracrine

Gs

Nitric oxide (NO) sGC

None

Atrial natriuretic NPR (pGC)
peptide (ANP)

None

Endocrine

cGMP ↑

Paracrine
Endocrine

Summary of
Vascular
Resistance

• Arteriolar resistance is determined by the
balance of local and systemic vasodilator
and vasoconstrictor influences in health
and disease.
• Changes in arteriolar resistance elicit
opposite changes in arterial pressure
(MAP) and capillary pressure.
• Vasoconstrictor dominance can cause
tissue ischemia and hypertension, whereas
vasodilation can cause potentially lifethreatening hypotension and tissue
edema.

Mediator

Source

Major Function in Resistance, Regulation
in Health or Disease

NE

Sympathetic vasoconstrictor fibers

Blood levels show circadian rhythm, highest
when awake at upright posture
Tonic activity at a1 receptors is the primary
factor in normal blood pressure
maintenance
Prevents orthostatic hypotension

Mediators
and
Mechanisms
of VSM
Contraction

Epinephrine

Adrenal medulla

Blood levels lower than NE, highest when
awake at upright posture
Some activity at a1 receptors
Levels increase with exercise contributing
to β2-mediated vasodilation supplying
skeletal muscles

Angiotensin II (ATII)

Renin, ACE generated

Blood levels low at rest
Primary effects are on sodium and blood
volume regulation
Vasoconstricting activity at AT1 receptors
Major target of antihypertensive drugs

Mediator

Source

Major Function in Resistance,
Regulation in Health or Disease

Vasopressin (AVP)

Posterior pituitary hormone

Major role in water conservation by the
kidneys
Increased secretion stimulated by
hypotension and hypovolemia augments
sympathetic vasoconstriction

Mediators
and
Mechanisms
of VSM
Contraction

AVP and its analogues can be used
pharmacologically to support blood
pressure during hypotensive/shock
states
Atrial natriuretic
peptide/BNP

Released from cardiac
atria/ventricles in response to
stretch

Normally low circulating
levels; BNP increases in heart failure
Primary action is on the kidneys,
reducing circulating volume by
stimulating natriuresis and diuresis
Secondary action is vascular smooth
muscle relaxation
Breakdown by the enzyme neprilysin is
targeted by the heart failure drug
sacubitril

Mediators
and
Mechanisms
of VSM
Contraction

Mediator

Source

Major Function in Resistance,
Regulation in Health or Disease

Prostacyclin (PGI2)

Normal endothelial cells

Tonically produced; inhibits platelet
aggregation and promotes
vasodilation

Nitric oxide (NO)

Normal endothelial cells

Tonically produced; diffuses to
smooth muscle layer and promotes
vasodilation
Mechanism of vasodilation produced
by acetylcholine and bradykinin
Target of nitrate vasodilator drugs

Endothelin (ET)

Damaged endothelial cells

Potent vasoconstrictor
Mediates trauma-induced
vasoconstriction, limiting blood loss
Endothelin antagonism is effective at
reducing pulmonary arterial
hypertension

Mediators
and
Mechanisms
of VSM
Contraction

Mediator

Source

Major Function in Resistance,
Regulation in Health or Disease

CO2, H+, K+,
adenosine

Local tissues with high
metabolic activity

Mediators of local flow increase in
response to high metabolic
demand, producing vasodilation
This is proposed as the mechanism
of metabolic autoregulation

Bradykinin

Produced locally in areas of
tissue inflammation

Contributes to cardinal signs of
inflammation: redness, swelling,
heat, and pain, through vasodilation

Histamine

Released by mast cells in
areas of trauma or allergic
responses

Contributes to inflammatory and
allergic vasodilation and increased
vascular permeability
Can cause severe tissue swelling and
contribute to anaphylactic shock

Mediators
and
Mechanisms
of VSM
Contraction

Mediator

Source

Major Function in
Resistance, Regulation in
Health or Disease

PGD2 and PGE2

Released by white
blood cells in the
process of
inflammatory
responses

Contribute to
inflammatory and allergic
vasodilation

Released by platelets
in conditions of
vascular and tissue
trauma

Contributes to
vasoconstriction that
reduces blood loss after
vascular trauma

TXA2

PGE2 and PGI2 increase
vasodilation and blood
flow in the renal medulla

VSM
Signaling:
Putting it all
together

• Rapid adaption for short term changes

Baroreflexes

• Stretch-sensitive sensors in the carotid sinus and the aortic
arch respond to increases or decreases in vessel
distention.
• Increased stretch increases the action potential firing
rates.
• Decreased pressure relaxes the stretch on the sensory
endings, thus decreasing their action potential firing rates.

• Increases in arterial pressure (stretch) increase
baroreceptor sensory fiber activity to the medulla
(parasympathetic).
• NTS (medulla) neurons also project to
cardioinhibitory center, resulting in decreased
heart rate (which decreases cardiac output) and
decreased sympathetic vasoconstriction (which
decreases peripheral resistance) returning the
blood pressure to normal.

Baroreflex Pathway

• Decreased arterial pressures reduce action potential
firing rate of baroreceptors.
• Medullary responses include decreased vagal
flow and increased sympathetic stimulation.
• Sympathetic stimulation of the sinoatrial node
increases heart rate, and stimulation of the
cardiac ventricles stimulates contractility,
increasing cardiac output.
• At the same time, sympathetic vasoconstrictor
activity increases, resulting in VSM contraction
and increased peripheral resistance. The effect
of these alterations is to restore normal arterial
pressure.

Response to Hypotension

Clinical
Vignette 2
• 32-year-old female admitted to an
acute psychiatric unit is found
sitting down in the floor of her
room. She reports fainting.
• PMHx: Depression and HTN
(recently started on amlodipine
5mg)
• Physical Exam: Blood pressure:
130/75 (sitting) 105/64
(standing), Pulse: 79bpm (no
change), Respiratory rate: 18
breaths per minute. Lungs: CTAB.
CV RRR, no MGR
• What is the most likely cause of
her spell?

Vasovagal Syncope
• The afferent limb of the reflex arc begins with a trigger. It is thought that this trigger,
usually in combination with central hypovolemia results in increased cardiac
contractility in the setting of a relatively underfilled left ventricle. This may trigger
mechanoreceptors in the ventricle that signal via vagal afferents to the central
nervous system. (poorly understood).
• The efferent limb of the reflex arc is better understood. Increased vagal firing
(increased parasympathetic activity) at the sinus node and the atrioventricular node
causes a decrease in heart rate.
• At the same time, decreased sympathetic activity results in decreased vascular tone
in both arterioles and venules. The results in decreased preload, venous return, and
ventricular volume.
• This results in a drop in the patient's mean arterial pressure.
• Cerebral autoregulation results in constant cerebral blood flow over a wide range of
mean arterial pressures, but when the mean arterial pressure falls below the body's
ability to autoregulate, the patient loses consciousness.

Question 6

• An acute drop in blood pressure will not cause which of these baroreflex compensatory
responses?
• Increased firing of parasympathetic fibers to the heart
• Increased firing of sympathetic nerves to the kidney stimulating renin release
• Increased firing of sympathetic fibers to vascular smooth muscle
• Increased firing of sympathetic fibers to the heart to increase cardiac output

Hypertension

Pathophysiology of
HTN
• Hypertension: >130 mm Hg systolic or >80 mm Hg diastolic
pressure (per book)
• Two hypotheses of origin:
• Initial defect in sodium and water retention that increases
vascular volume and cardiac output. This is predicted to
result in vasoconstriction by generalized autoregulation.
• Chronically increased sympathetic tone that leads to
vasoconstriction and RAAS activity.
• These hypotheses are not mutually exclusive, and data also
support a role for increased sodium intake, obesity, and a state
of chronic inflammation as contributing factors to the
hypertension seen as a component of the metabolic syndrome

Other Possible
Theories of
HTN

Causes of HTN

• Primary HTN:
• 95% of cases
• Uncommon before the age of 20 (but growing!)
• Secondary HTN:
• Underlying cause present: Renal disease, Primary
hyperaldosteronism, Cushing’s
syndrome, Pheochromocytoma, Coarctation of the
aorta, Pregnancy, OSA, thyroid disease
• 10-15% of cases

HTN and End Organ Damage

Complications

Contributing Factors

Atherosclerosis

Shear stress, endothelial injury, and inflammation

Coronary heart disease

Atherosclerosis, left ventricular hypertrophy, increased oxygen demand

Heart failure

Increased afterload, myocardial remodeling

Stroke

Atherosclerosis, inflammation/hypercoagulability, aneurysm rupture

Kidney disease

Vascular wall hypertrophy and hyaline arteriosclerosis

Retinopathy

Endothelial damage, leakiness and rupture, vessel narrowing

Aneurysm formation and rupture

Turbulent flow, high pressure, vascular wall thickening and ischemia

Peripheral arterial disease

Atherosclerosis, endothelial injury, inflammation

HTN and End Organ Damage

• 45% of adults in the United States have a blood pressure
greater than 140/90 mm Hg or are being treated for
hypertension
• About 80% of people with hypertension are aware of the
diagnosis and 75% are receiving treatment

Epidemiology

• Hypertension is controlled in only 52% of those affected
• Adequate blood pressure control reduces the incidence of:
• acute coronary syndrome by 20–25%
• stroke by 30–35%
• heart failure by 50%.

HTN Diagnosis
• A single elevated blood pressure reading is not sufficient to establish the
diagnosis of hypertension.
• The major exceptions to this rule are hypertension presenting with unequivocal
evidence of life-threatening end-organ damage or blood pressure is greater
than 220/125 mm Hg but life-threatening end-organ damage is absent.
• 3-month delay in treatment of hypertension in high-risk patients is associated
with a twofold increase in cardiovascular morbidity and mortality
• The 2017 guidelines from the American College of Cardiology and American
Heart Association (ACC/AHA) define normal blood pressure as less than 120/80
mm Hg, elevated blood pressure as 120–129/less than 80 mm Hg, stage 1
hypertension as 130–139/80–89 mm Hg, and stage 2 hypertension as
greater than or equal to 140/90 mm Hg.

Guideline
Differences in
Management

Guidelines1

Cardiovascular
Risk

Threshold for
Pharmacotherapy
(mm Hg)

ACC/AHA

Not increased

> 140/90

< 130/80
(reasonable)

Hypertension
Canada

Not increased

> 160/100

< 140/90 (< 130/80
for diabetes)

ESH/ESC

Not increased

> 140/90

All < 140/90, most <
130/80, not < 120

ACC/AHA

Increased

< 130/80

< 130/80
(recommended)

Hypertension
Canada

Increased

> 140 systolic

ESH/ESC

Increased

> 130/80

120–130/< 80

ACC/AHA > 65 yr

Risk due to
advanced age

> 130/80

< 130 systolic

Hypertension
4
Canada

Increased

Not specified

ESH/ESC > 65 yr

Not increased

> 140/90

2

3

3

4

5

Target (mm Hg)

< 120 systolic

4

Not specified

130–140/> 80

6

Nonpharmacologic Therapy
Modification

Intervention

Resulting Decrease in Blood Pressure

Weight loss

Target BMI 18.5–24.9

5–20 mm Hg/10-kg loss

DASH diet

Fruit, vegetables, low fat dairy

8–14 mm Hg

Sodium intake

< 100 mmol/day (< 6 g salt)

2–8 mm Hg

Alcohol intake

Male ≤ 2 drinks/day
Female ≤ 1 drink/day

4 mm Hg

Exercise

Aerobic 30 min/day
Dynamic 90-150 min/week
Isometric (hand grip 4 repetitions
3 times/week)

5–10 mm Hg

Mindfulness

Meditation and breathing control

5 mm Hg

BP thresholds and recommendations for treatment and follow-up

Normal BP
(BP<120/80
mm Hg)

Promote optimal
lifestyle habits

Elevated BP
(BP 120-129/<80
mm Hg)

Stage 1 hypertension
(BP 130-139/80-89
mm Hg)

Nonpharmacologic
therapy
(Class I)

Clinical ASCVD
or estimated 10-y CVD risk
≥10%
No

Management
of HTN

Reassess in
1 year
(Class IIa)

Reassess in
3-6 mo.
(Class I)

Nonpharmacologic
therapy
(Class I)

Reassess in
3-6 mo.
(Class I)

Optimal lifestyle
habits

Nonpharmacologic
therapy

• Healthy diet

• Weight loss for
patients who are
overweight or obese

• Weight loss,
if needed
• Physical activity
• Tobacco cessation,
if needed
• Moderation of
alcohol consumption

REASSESSMENT
CHECKLIST
Measure BP

Yes
Nonpharmacologic
therapy and
BP-lowering medication
(Class I)

Nonpharmacologic
therapy and
BP-lowering medication
(Class I)

Reassess in
1 mo.
(Class I)

BP Goal Met

• Heart-healthy diet
(such as DASH)

No

• Sodium restriction
• Potassium
supplementation
(preferably
in dietary
modification)a

Assess and
optimize
adherence to
therapy

• Increased physical
activity with
structured exercise
program

Consider
intensification
of therapy

• Limitation of alcohol
to 1 (women) or
2 (men) standard
drinks per dayb

Stage 2 hypertension
(BP ≥140/90
mm Hg)

a
b

Yes
Reassess in
3-6 mo.
(Class I)

Unless contraindicated by the presence of chronic kidney disease or use of drugs that reduce potassium excretion.
In the United States, one standard drink is equivalent to 12 oz of regular beer (usually about 5% alcohol), 5 oz of
wine (usually about 12% alcohol), or 1.5 oz of distilled spirits (usually about 40% alcohol).

Identify white-coat
hypertension or a
white-coat effect
Document adherence
to treatment
Reinforce importance
of treatment
Assist with treatment
to achieve BP target
Evaluate for orthostatic
hypotension in select
patients (eg, older
or with postural
symptoms)
Talk to your patients
about substances that
should be avoided,
limited or stopped
to help maintain a
healthy BP.

Recommended Treatment Based on Coexisting Condition

Antihypertensive Medication
Indication
Heart failure

Diuretic

Beta-blocker

ACE Inhibitor

ARB

√

√

√

√

√

√

Following MI
√

√

√

Diabetes

√

√

√

√

√

√

Recurrent stroke prevention

√

√

Aldosterone antagonist
√
√

High coronary disease risk

Chronic kidney disease

Calcium channel blocker

√
√

Clinical Vignette 3

• A 49-year-old female with a history of type 2 diabetes, obesity,
hypertension, and migraine headaches presents for follow-up.
• DM is treated with an oral sulfonylurea and metformin. Her
diabetes has been under fair control with a most recent
hemoglobin A1c of 7.4%.
• Hypertension was diagnosed 5 years ago when blood pressure (BP)
measured in the office was noted to be consistently elevated in the
range of 160/90 mmHg on three occasions. L.N. was initially treated
with lisinopril, starting at 10 mg daily and increasing to 20 mg daily,
yet her BP control has fluctuated.
• Microalbuminuria was detected on an annual urine screen
• Physical examination reveals an obese woman with a BP of 154/86
mmHg and a pulse of 78 bpm.

Clinical Vignette 3

• What are the effects of controlling BP in
people with diabetes?
• What is the target BP for patients with
diabetes and hypertension? Less than
130/80
• Which antihypertensive agents are
recommended for patients with
diabetes? Add a beta blocker or calcium
blocker, consider weight loss

The Initiation and Titration of Anti-hypertensive Medications

Step 1

ACE inhibitor/ARB or
Calcium channel blocker or
Thiazide diuretic

Step 2

ACE inhibitor/ARB plus
Calcium channel blocker or thiazide diuretic5

Step 3

ACE inhibitor/ARB plus calcium channel
blocker plus thiazide diuretic

Step 4

ACE inhibitor/ARB plus calcium channel
blocker plus thiazide diuretic plus spironolactone

Physiologic effects of antihypertensive
medications

Question 3
• Which organ system shows the largest impact of
chronically, poorly managed hypertension?
A. Gastrointestinal
B.

Renal

C.

Respiratory

D. Dermatologic

Shock

Shock
• Shock is a clinical state of severely decreased blood
pressure and blood flow that greatly reduces tissue
perfusion and oxygenation. If this state is not
quickly corrected, irreversible tissue damage occurs
and can lead to death
• Three stages of shock:
• Compensated (fixable)
• Decompensated (reduced fixable)
• Irreversible (impending doom)

Stages of Shock

Compensated Shock

Decompensated Shock

Irreversible shock

Arterial pressures may not reflect
the full magnitude of the insult.

A transitional phase of shock that
reduces the likelihood for recovery.

Vascular damage is extreme, and
death is imminent.

Baroreceptors and RAAS are
activated

Tissue damage becomes widespread,
and severely ischemic tissues release
inflammatory markers

CO2 accumulates and lactic acid
levels rise, along with other products
of tissue hypoxia

Severe hypoxia promotes anaerobic
metabolism, resulting in widespread
lactic acidosis, leading to loss of
sympathetic tone and rapid
circulatory collapse.

Shock Types
Type of Shock

Examples

Primary Problem

Initial Hemodynamic Change

Hypovolemic

Blood loss

Low circulating volume

↓ Preload, ↓ CO, ↑ TPR (trying to
compensate)

Generalized decrease of peripheral
resistance

↓ TPR, blood pooling in periphery, ↓
venous return, ↓ preload, ↓ CO

Neurogenic shock (spinal cord injury,
drug overdose)

Loss of sympathetic tone

↓ TPR, blood pooling in periphery, lack of
cardiac compensation, ↓ CO

Myocardial infarction

Impaired cardiac contractility

↓ CO, ↑ TPR

Papillary muscle rupture

Acute mitral regurgitation

Cardiac tamponade, pulmonary
embolism, tension pneumothorax

Physical block of vasculature or of
cardiac filling

Dehydration
Distributive

Anaphylactic reaction (type 1
hypersensitivity)
Systemic infection (septic shock)

Cardiogenic

Obstructive

↓ CO, ↑ TPR

Shock
Treatment
• All forms of shock are
managed with urgent,
invasive support measures
with close monitoring, fluid
replacement, and
administration of pressor
agents.
• Ventilate
• Infuse (fluid resuscitation)
• Pump (admin. Vasoactive
agents)

Question 8

• A patient with a tree-nut allergy presents to the
Emergency Department after accidently
ingesting peanuts. The patient has shortness of
breath, decreased blood pressure, and
swelling. Which clinical diagnosis and type of
shock are you most concerned about?
A.Anaphylaxis; Distributive
B.Myocardial infraction; Cardiogenic
C.Septic; Distributive
D.Pulmonary embolism; Obstruction

Properties and Disorders
of Capillaries

Objectives: Part 4

• Identify the four pressures (Starling forces) that influence
capillary filtration and reabsorption, and predict the effect on
these capillary fluid movements as each factor increases or
decrease, while all other factors are held constant
• Describe the factors that promote edema formation and relate
those factors to the mechanisms and mediators of local acute
inflammation

Capillaries
• Capillaries are a collection of narrow branching blood vessels that are located between the arterioles and
venules.
• Capillary walls are a single endothelial cell thick with a small amount of basement membrane, perfect for
nutrient exchange
• Three types:
1. Continuous
• Most abundant
• Allow for some nutrient exchange; however, the do NOT permit movement of plasma proteins. This
allow the capillary to exert a force called colloid osmotic pressure retaining fluid within the capillary
lumen
2. Fenestrated
• Found in the intestines, kidneys, and endocrine organs
• Have higher rates of fluid exchange, including small proteins
3. Sinusoids
• Found in spleen, liver, and bone marrow
• Have large gaps between endothelial cells, and discontinuous basement membranes

Capillaries
Continuous (most common)

Fenestrated

Sinusoids

Capillary Fluid Exchange

• Net fluid exchange across capillary walls is influenced by a summation of capillary and
interstitial pressures.
• Hydrostatic pressures that push water and small dissolved molecules away from the
source across the capillary walls.
• Hydrostatic net pressure gradient favors filtration- fluid movement outward across
the wall
• Colloid osmotic pressure pulls water and small dissolved molecules toward the source
across the capillary walls
• Net colloid osmotic pressure favors reabsorption- inward fluid movement across the
wall

Capillary Fluid Exchange
• As the capillary hydrostatic pressure gradually drops
from the arteriole end to the venous end, the rate of
fluid movement across the wall changes accordingly.
• Consequently, capillary filtration is relatively high in
the arteriolar end of the capillary, but a substantial
portion is reabsorbed in the venous end of the
capillary.
• This aids in nutrient delivery and waste removal

Lymphatics
• Interstitial fluid arising from capillary filtration
forms lymph.
• Lymph vessels become lined with smooth muscle
that slowly contracts when filled with lymph.
• Lymph vessels eventually converge at lymph nodes
that filter fluid proteins and are active in immune
responses.
• The lymph then proceeds back into the circulation,
primarily through the subclavian vein.

Conditions Associated
with Edema Formation:
Vasodilation
• Arteriolar vasodilation allows higher hydrostatic
pressure to be sustained to the level of the
capillaries, in turn, increase the rate of lymph
formation
• Vasodilatory edema is a hallmark of local
inflammation. When tissue trauma triggers an
innate immune response, histamine is released into
the region.
• Histamine promotes vasodilation and
increased capillary permeability, both of which
favor filtration over reabsorption and produce
the cardinal inflammatory sign of swelling.

Conditions Associated with
Edema Formation:
Increased Venous Pressure
• Deep venous thromboses increases venous pressures in the
affected region. This pressure greatly increases capillary
hydrostatic pressure (venule) and promotes filtration along the
capillary length.
• This is manifested by edema and pain in the affected
limb.
• Right-sided heart failure is also known to cause fluid retention
and increase systemic venous pressures, promoting peripheral
edema.
• Main signs include peripheral edema.
• Venous hypertension can occur in the legs, particularly in older
adults, due to incompetence of venous valves and decreased
effectiveness of leg muscle activity to compress the leg veins.
• Main signs of this syndrome of venous insufficiency is
ankle edema.

Conditions
Associated with Edema
Formation: Hemodilution
• Liver disease, malnutrition, and some kidney
diseases can lead to reductions of circulating
albumin reducing the colloid osmotic
pressure.
• This reduction in osmotic pressure
promotes widespread edema
• Hemodilution that reduces colloid osmotic
pressure is also a prevalent scenario in EDs,
where patients are volume expanded with
intravenous fluids containing glucose and
electrolytes, but no proteins, after major
hemorrhagic losses.

Conditions Associated with
Altered Lymph Clearance:
Vasoconstriction
• Baroreflexes promote intense sympathetic
vasoconstriction that maintains arterial
pressure but greatly reduces capillary
hydrostatic pressure. This promotes
reabsorption of fluid along the length of the
capillaries, a phenomenon sometimes termed
autotransfusion.
• Loss of skin turgor is a physical manifestation
of this fluid shift, particularly in children and
youth.
• Capillary refill is also slowed due to the
generalized vasoconstriction.

Question 9
• A patient presents with a venous thrombosis. How
would you interpret the illustration describing the
clinical situation?
A.Increased capillary filtration due to increased
capillary hydrostatic pressure
B.Decreased reabsorption due to reduced colloid
osmotic pressure
C.Obstruction of lymph flow causing edema due to
changes in tissue pressures

Lifespan considerations

Objectives: Part 6

• Explain how the vascular changes associated with aging impact
the systolic and diastolic blood pressure
• Describe the effect of age-related vascular changes on the heart

Pediatric HTN
•

At age of 13, the current ranges for adults
apply.

•

In 2017, normative tables were revised and
adjust for age, sex, and height.

•

Elevated blood pressure should be
confirmed with three separate
measurements and should be measured by
auscultation

Ashraf, M., Irshad, M., & Parry, N. A. (2020).
Pediatric hypertension: an updated
review. Clinical hypertension, 26(1), 22.
https://doi.org/10.1186/s40885-020-00156w

BP/HTN

Age 1–< 13 Years

Age > 13 Years

Normal BP

<90th percentile

< 120/< 80 mmHg

Elevated BP

≥90th percentile to
<95th percentile or
120/80 mmHg to <95th
percentile (whichever is
lower)

120/< 80–
129/< 80 mmHg

Stage 1HTN

≥95th percentile to
<95th
percentile+ 12 mmHg or
130/80–139/89 mmHg
(whichever is lower)

130/80–
139/89 mmHg

≥95th percentile
+ 12 mmHg
Stage 2 HTN
or ≥ 140/90 mmHg
(whichever is lower)

≥140/90 mmHg

Age (Years)

Pediatric HTN:
BP requiring
further
investigation

Ashraf, M., Irshad, M., & Parry, N. A. (2020).
Pediatric hypertension: an updated
review. Clinical hypertension, 26(1), 22.
https://doi.org/10.1186/s40885-020-00156w

Boys

Girls

SBP (mmHg)

DBP (mmHg)

SBP (mmHg)

DBP (mmHg

1

98

52

98

54

2

100

55

101

58

3

101

58

102

60

4

102

60

103

62

5

103

63

104

64

6

105

66

105

67

7

106

68

106

68

8

107

69

107

69

9

107

70

108

71

10

108

72

109

72

11

110

74

111

74

12

113

75

114

75

≥13

120

80

120

80

Endothelial
Changes with
Aging
• Endothelial dysfunction as
we age is signaled by
changes in balance of the
vasodilators nitric oxide and
PGI2 and the
vasoconstrictors ET1, TXA2,
and angiotensin II.
• ROS increase with aging and
further deplete NO
• This creates a net reduced
ability of the vessel to dilate
and a reduction of
antithrombotic properties.

Arterial Stiffness