Cardiovascular Disorders Part 1 & 2 PDF (SN 300 Fall 2024)

Summary

These are lecture notes for a Fall 2024 Cardiovascular Disorders course. The document covers various cardiovascular diseases, their pathophysiology, and diagnostic tests.

Full Transcript

Cardiovascular Disorders Part 1
SN 300 – Pathophysiology I
Kara Morriseau MN, BScN, RN
Fall 2024
 Content & Required Readings
Week 10 Cardiac Diseases Part 1 Quiz 4 in Class (5%) – Week 9 Content
Nov 11
(CLO 5.0 – 5.3, 8.0 – 8.2) Chapter 23 – Structure and function of
the Cardiovascular and Lymphatic
System
Chapter 24 – Alterations of
Cardiovascular Function
 Specific Diseases
Diseases of the arteries and veins: varicose veins,
chronic venous insufficiency, thrombus formation in
veins, superior vena cava syndrome, hypertension,
hypotension, aneurysm, thrombus formation,
embolism, thromboangiitis obliterans (Buerger’s
disease), raynaud’s phenomenon, arteriosclerosis,
peripheral arterial disease, shock
Review of Cardiovascular System
Heart Structure
Right heart
Pulmonary circulation → Pumps
blood through the lungs
Left heart
Systemic circulation → Pumps
blood through the body
The Heart
Heart wall
Three layers enclosed in the pericardium
Epicardium
Outer layer
Myocardium
Composed of cardiac muscle
Endocardium
Inner lining
Pericardium
Pericardial sac
Pericardial cavity
Pericardial fluid
Structure of the
Heart
Right atrium
Left atrium
Right ventricle
Left ventricle
Atrioventricular valves:
Tricuspid valve
Mitral valve
Semilunar valves:
Pulmonic semilunar valve
Aortic semilunar valve
Valves of the Heart
 Great Vessels
Superior and inferior venae
cavae

Pulmonary artery

Right and left pulmonary
arteries

Pulmonary veins

Aorta
 Blood Flow and Cardiac Cycle

Cardiac cycle

Diastole

Systole

Phases of the

cardiac cycle
 Coronary Vessels
Right coronary artery
Conus
Right marginal branch
Posterior descending branch
Left coronary artery
Left anterior descending artery
Circumflex artery
Collateral arteries
Coronary capillaries
Coronary veins:
Coronary sinus
Great cardiac vein
Posterior vein of the left ventricle
Lymphatic vessels
Structures That
Control Heart Action
Cardiac action potentials
Conduction system
Sinoatrial node (SA)
Atrioventricular node (AV)
Bundle of His (AV bundle)
Right and left bundle
branches
Purkinje fibres
 Structures That Control Heart Action
Propagation of cardiac
action potentials
Resting membrane potential
Depolarization
Repolarization
Hyperpolarization
Refractory period
Electrocardiogram
Automaticity
Rhythmicity
 Myocardial Cells
Nearly identical to skeletal muscle cells
Differences important for cardiac function
Sarcomeres
Intercalated discs
Actin, myosin, and the troponin–tropomyosin complex
A band, I bands, Z line, M line
Troponin T, I, and C
Myocardial metabolism
Myocardial oxygen consumption
 Myocardial Contraction and Relaxation
Cross-bridge theory of muscle

contraction

Excitation-contraction coupling

Calcium channel

L-type (calcium channel blocker

medications)

T-type
Myocardial Contraction and Relaxation
Myocardial Contraction and Relaxation
Cardiac Performance
Cardiac output
Preload
Volume/pressure inside ventricle at end of diastole
Left ventricular end-diastolic volume
Laplace’s law
Starling’s law of the heart
Afterload
Resistance to ejection of blood from left ventricle
Load muscle must move after it starts to contract
Determined by system vascular resistance in aorta
Cardiac Performance
Myocardial contractility

Stroke volume and preload
Inotropic agents

Oxygen and carbon dioxide levels

Cardiac output

Volume of blood flowing through either the systemic or pulmonary circuit in litres per
minute

Ejection fraction
Cardiac Output
Cardiac Performance
Heart rate
Cardiovascular vasomotor control centre
Excitatory and inhibitory centres
Neural reflexes
Baroreceptor reflexes
Atrial receptors
Brainbridge reflex
Hormones and biochemicals
Systemic Circulation
Arteries

Arterioles

Capillaries

Venules

Veins
Structure of
Blood Vessels

Lumen

Tunica intima

Tunica media

Tunica externa
(adventitia)
Structure of Blood Vessels (Cont.)
Factors Affecting Blood Flow
Pressure
Force exerted on a liquid per unit area
Resistance
Opposition to force
Diameter and length of the blood vessels contribute to resistance
Poiseuille’s law
Neural control of total peripheral resistance
Change in diameter of the vessels
Baroreceptors
Arterial chemoreceptors
Baroreceptor and Chemoreceptors

Modified from Patton, K.T. (2019). Anatomy & physiology (10th ed.). Elsevier.
Baroreceptor and Chemoreceptors

Modified from Patton, K.T. (2019). Anatomy & physiology (10th ed.). Elsevier.
 Regulation of Blood Pressure
Arterial pressure
Mean arterial pressure (MAP)
Effects of cardiac output
Effects of total peripheral resistance
Effects of hormones
Epinephrine and norepinephrine
Antidiuretic hormone, renin-angiotensin-aldosterone system, and atrial natriuretic
peptides
Effects of other mediators
Nitric oxide
Adrenomedullin
Venous pressure
Regulation of Blood Pressure
Cardiovascular Disease
Cardiac Diseases
Diseases of the arteries and veins: varicose veins, chronic venous
insufficiency, thrombus formation in veins, superior vena cava
syndrome, hypertension, hypotension, aneurysm, thrombus
formation, embolism, Thromboangiitis obliterans (Buerger’s
disease), Raynaud's phenomenon, arteriosclerosis, peripheral
arterial disease, shock
 Varicose Veins
A vein in which blood has pooled

Pathophysiology: Caused by trauma or gradual venous distension (typically

saphenous vein)

Clinical Manifestations: → Distended, tortuous, and palpable veins →

edema of surrounding tissue (due to increased hydrostatic pressure that

pushes plasma through the vessel wall)

Risk factors: Age, Female gender, Family history, Obesity, Pregnancy, Deep

vein thrombosis, Prior leg injury

This can lead to chronic venous insufficiency
 Chronic Venous Insufficiency

Inadequate venous return over a long period due to varicose veins or valvular incompetence

Pathophysiology: Venous hypertension, circulatory stasis, and tissue hypoxia cause an inflammatory

reaction in vessels and skin ulcerations. Circulation to the extremities can be so sluggish that metabolic

demands of the cells to obtain O2 & nutrients and remove waste are barely met → venous stasis ulcers

Venous stasis ulcers→ trauma or pressure can therefore lower the O2 supply and cause cell death and

necrosis

Clinical Manifestations: Edema of lower extremities (can extend to knees), hyperpigmentation of the

skin of feet and ankles.
 Venous Thrombus Formation
Thrombus formation in veins → thrombus is a blood clot that remains attached to a vessel wall
Thromboembolism: detached thrombus
Venus is more common than arterial (flow & pressure of veins are lower)
Pathophysiology: Obstruction of venous flow leading to increased venous pressure → accumulation
of clotting factors and platelets leads to thrombus formation near venous valve → inflammation
around thrombus promotes further platelet aggregation → obstructs
Three Factors promote it (Triad of Virchow)
1. Venous stasis → immobility, age, heart failure
2. Venous endothelial damage → trauma, intravenous medications
3. Hypercoagulable states → inherited disorders, malignancy, pregnancy, use of oral
contraceptives, or hormone replacement therapy
Other (cancer, orthopedic surgery/trauma, heart failure, immobility) increased the likleyhood
of DVT → Deep vein thrombosis primarily in lower extremities
Clinical manifestations: can be asymptomatic, or pain, redness, edema
Can break off and cause pulmonary embolism
 Superior Vena Cava Syndrome
Progressive occlusion of the superior vena cava that leads to venous distension of upper
extremities and head
Causes: Cancer (bronchogenic cancer (75%), lymphoma, and metastases of other
cancers), TB, mediastinal fibrosis, and cystic fibrosis, pacemaker wires, central venous
catheters, and pulmonary artery catheters with associated thrombosis can cause SVCS
Pathophysiology: SVC is a low-pressure vessel within a closed thoracic compartment
susceptible to compression by tissue expansion. Onset slow
Clinical Manifestations: edema and venous distension in upper extremities and face, c/o
of fullness in head or tightness in shirt collars, necklaces, and rings → cerebral edema can
cause visual disturbances, headaches, and impaired consciousness → skin may be
purple, taut, and prolonged cap refill → respiratory distress due to edema of bronchial
structures
Diagnostics: Chest Xray, CT Thorax, MRI, Doppler studies
 Hypertension
Consistent elevation of systemic arterial blood pressure
Sustained systolic blood pressure of 140 mm Hg or greater or a diastolic pressure of 90 mm Hg or
greater (nonautomated office BP measurement) – out of office measurements preferred
Risk Factors: Age, DM, CKD, diet, sedentary lifestyle, ancestry
White coated 140
mm Hg, Life-threatening organ damage
 Hypertension
Pathophysiology: sustained increase in peripheral resistance (arteriolar vasoconstriction), an increase in circulating blood volume or
both. Inflammation, endothelial dysfunction, obesity-related hormones, and insulin resistance contribute to increased peripheral
resistance and increased blood volume
Increased vascular volume is due to a decrease in renal excretion of salt shifting pressure-natriuresis relationship (less salt in urine)
Increased SNS leads to increased HR and systemic vasoconstriction → increased BP: causes changes in blood vessels (vascular
remodelling), renal sodium retention, insulin resistance, increased renin and angiotensin levels, and procoag effect
RAAS System → Salt and water retention & increased vascular resistance
1) Damage: Release of renin, Synthesis of angio II through ACE, the section of aldosterone.
Angio II and aldosterone contribute to hypertension hypertrophy, fibrosis of heart muscle, decreased contractibility,
increased arrhythmias and HR, systemic vasoconstriction, renal salt and water retention, stimulate tissue growth and
inflammation
Angio II contributes to endothelial dysfunction, insulin resistance, remodelling of blood vessels, and platelet aggregation
2) Protection: ACE synthesizes angiotensin I from Angio II which stimulates receptors in the brain, blood vessels, heart, kidneys,
gut, pancreas, and inflammatory cells and has vasodilatory, antiproliferative, antifibrotic, and antithrombic effects to lower
blood pressure, limit vascular inflammation and clotting, and decrease tissue remodelling and damage to main organs
Inflammation → activation of innate and adaptive immunity damages endothelial cells → endothelial injury and tissue ischemia
resulting in the release of vasoactive inflammatory cytokines (acute inflammation protective but chronic bad) → chronic
decreased vasodilators, vascular remodeling, and smooth muscle contraction
 Hypertension
Clinical Manifestations

Silent disease: early stages no CM other than elevated BP

Complications that damage organizes and tissues outside of the vascular system

Heart disease, renal insufficiency, CNS dysfunction, impaired vision, impaired mobility, vascular

occlusion, or edema

Diagnostic Tests/Labs

24h BP monitoring

CBC, UA, lytes, extended lytes, glucose, cholesterol, triglycerides, ECG
 Orthostatic (postural) Hypotension
Decrease in both systolic (20mm Hg) and diastolic blood pressure upon standing (10mm Hg) within 3 minutes of standing.

Primary (idiopathic): No known cause often related to neurogenic or autonomic function

Pathophysiology: Lack of normal blood pressure compensation in response to gravitational changes in the circulation (ie.

Baroreceptors do not mediate reflex of arteriolar and venous constriction and increase HR compensation for gravity changes )

Acute orthostatic hypotension → altered body chemistry, medication action (anti-hypertensives, anti-depressants), prolonged

immobility, starvation, physical exhaustion, volume depletion (dehydration, diuresis), or venous pooling (pregnancy, VV)

Chronic orthostatic hypotension → endocrine disorders, metabolic disorders, diseases of CNS or PNS, cardiovascular

autonomic neuropathy

Clinical manifestations → Dizziness, blurring, loss of vision, syncope, fainting
 Aneurysm
Local dilation or outpouching of a vessel wall or cardiac chamber
True aneurysms (all three layers) of arterial wall and weakening of vessel wall
Types: Fusiform, Circumferential, Saccular, False aneurysms (Extravascular
hematoma that communicates with the intravascular space)
Occur usually in thoracic or abdominal aorta. Can lead to aortic dissection or
rupture
Risk Factors: Genetics, smoking, diet (atherosclerosis)
Clinical Manifestations: aortic (asymptomatic → rupture → severe
pain/hypotension), thoracic → dysphagia and dyspnea, cerebral → increased ICP or
stroke if leaking, heart → dysrhythmias, HR, clots
Diagnostics/Labs: CT, MRI, US, or angiography
Aneurysm
 Arterial Thrombi
Thrombus formation → Blood clot that remains attached to the vessel wall
Thromboembolic → clot circulating
Arterial thrombi → clot in artery
Risk factors: intimal injury/inflammation, obstruction of flow, pooling (stasis)
Pathophysiology → inflammation of endothelium leads to activation of clotting cascade causing
platelets to adhere readily
Changes to anatomy like an aneurysm can lead to thrombus formation
Valves of heart – if calcified or bacterial vegetation can lead to thrombi
Septic Shock → systematic inflammation activates intrinsic and extrinsic pathways leaving
microvascular thrombi
Thrombus can 1) occlude artery causing ischemia and/or 2) dislodge becoming
thromboembolism
Diagnostics: US doppler or angiography
 Embolism
Bolus of matter that is circulating in the bloodstream that can obstruct a
vessel
Types: Dislodged thrombus, Air bubble, Amniotic fluid, Aggregate of fat,
Bacteria, Cancer cells, Foreign substance
Travels until it cant pass → eventually lodges in systemic or pulmonary
vessel
Pulmonary emboli (venous side) of systemic circulation or in right heart
Arterial emboli → left heart, thrombi after MI, valvular disease, LV failure,
endocarditis, or dysthymias
Can cause ischemia or infarction in the tissues distal to the obstruction,
organ dysfunction, or pain → can lead to necrosis
Thromboangiitis obliterans (Buerger’s disease)

Inflammatory disease of the peripheral arteries (Strongly associated with smoking)

Autoimmune

Characterized by the formation of thrombi filled with inflammatory and immune cells

Thrombi become organized and fibrotic and result in permanent occlusion and obliteration
of portions of small- and medium-sized arteries in feet and sometimes hands

Clinical Manifestations: pain and tenderness of affect part, rubor and cyanosis (sluggish
blood flow), chronic ischemia → thin and shiny skin, nails thickened and malformed.
 Raynaud’s phenomenon
Episodic vasospasm in arteries and arterioles of the fingers, less commonly the toes

Primary → Vasospastic disorder of unknown origin

Secondary → Secondary to other systemic diseases or conditions: Collagen vascular disease,
Smoking, Pulmonary hypertension, Myxedema, Cold environment

Pathophysiology: endothelial dysfunction with an imbalance of endothelium-derived vasodilators
and vasoconstrictors leads to vasospastic attacks as a result of ischemia change sto skin color
and sensation.

Clinical Manifestations: pallor, cyanosis, cold, pain, numbness, tends to be bilateral, tips of
digits to proximal phalanges, paresthesia until blood flow returns
 Arteriosclerosis
Chronic disease of the arterial system
Abnormal thickening and hardening of the
vessel walls
Risk factors: diabetes, smoking, increased LDL
and decreased HDL, and autoimmunity
Atherosclerosis( Form of arteriosclerosis) →
Thickening and hardening caused by
accumulation of lipid-laden macrophages in the
arterial wall leading to the formation of a lesion
called a plaque
Clinical Manifestations → inadequate tissue
perfusion can cause transient ischemic events,
tissue infarction, ishcemia, obstruction of
arteries can lead to pain, coronary artery
disease, stroke
 Arteriosclerosis
Pathophysiology
Injury to endothelial cells (see risk ractors) of artery walls causing lesions that develop to fatty
streak to the fibrotic plaque to complicated lesion
Inflammation of endothelium – atherogenesis (cannot make normal cytokines)
Cellular proliferation – expires adhesion molecules that bind to macrophages and other
inflammatory/immune cells
Macrophage migration and adherence (from the release of inflammatory cytokines including
CRP)
LDL oxidation (foam cell formation) – toxic free radicals cause oxidation of LDL (lipid-laden
macrophages)
Fatty streak (lesion formed by lipid-laden macrophages) - (fatty streak produces more free
radicals, recruits T cells leading to autoimmunity, secretion of more anti-inflammatory mediators)
Fibrous plaque - is caused by macrophages releasing growth factors that stimulate smooth
muscle growth, producing collagen and migrating over fatty streaks leading to fibrous plaque.
Plaque calcifies, protruding vessel lumen, and obstructs blood flow to distant tissues
Complicated plaque- ruptured plaques resulting in platelet adhesion, clotting cascade, and
thrombus formation.
 Lipid Transport
Lipids are transported in combination with
proteins.
Low-density lipoprotein (LDL)
Transports cholesterol from liver to cells
Major factor contributing to atheroma
formation
High-density lipoprotein (HDL)
Transports cholesterol away from the
peripheral cells to liver—“good” lipoprotein
Catabolism in liver and excretion
Atherosclerosis

Modified from Crawford, M.H., et al. (2010). Cardiology (3rd ed.). Mosby.
 Peripheral Arterial Disease
Atherosclerotic disease of arteries that perfuse limbs

Lower extremity ischemia resulting from artery obstruction - gradual or acute

Intermittent claudication – pain with ambulation from gradually increased obstruction to arterial
blood flow to less from atherosclerosis in iliofemoral vessels

If a thrombus forms over an atherosclerotic lesion, complete obstruction of blood flow can occur
acutely causing severe pain, loss of pulses, and skin color changes

Symptoms are caused by slow, sluggish blood flow. Causes pain, tenderness in the affected area

Can often lead to gangrenous lesions and amputations
Peripheral Arterial Disease
Most common sites
Abdominal aorta
Carotid arteries
Femoral and iliac arteries

Diagnostic tests
Blood flow assessed by Doppler studies and
arteriography
Shock
The cardiovascular system fails to perfuse the tissues adequately leading to widespread impairment of
cellular metabolism.
Impaired oxygen use
Cell is not able to use O2 or not receiving adequate O2
Cells go from aerobic or anaerobic (use stores of ATP faster than can be replaced) → cannot operate NA/K pump → Na & Cl
accumulate in cell, K goes out of cell → impacts NS and myocardium → decreased resting potential and action potential
As Na moved into cell H2O followed (cells swell – cellular edema – injure cells → H20 pulled from vascular space into cell →
decreased circulatory volume → inflammatory and clotting cascade activated → acute tubular necrosis, DIC
An anaerobic state impacts pH leading to metabolic acidosis → cardiac and skeletal muscles use lactic acid as a fuel sore →
acidotic state impacts cell function, repair, and division, reducing O2 carrying capacity of blood
Impaired glucose use
Impaired glucose delivery or impacted glucose uptake of cells
High cortisol levels, thyroid hormone, and catecholamines account for hyperglycemia, insulin resistance, tachycardia,
increased cardiac contractility → cells shift to glycogenolysis, gluconeogenesis, and lipolysis to generate fuel to survive →
energy costs required for glycogenlysis and lipolysis contribute to cell failure
Depletion of protein → gluconeogenesis causes proteins to be used for fuel and protein no longer available for cell structure,
function, repair, or replication → protein broken down into alamine (which is converted to pyrvic acid), ammonia, and urea.
Protein breakdown weakness skeletal muscle and cardiac muscle leading to muscle wasting
Clinical Manifestations: vary based on stage but often include hypotension, tachycardia,
increased respiratory rate
 Shock
The cardiovascular system fails to perfuse the tissues adequately leading to widespread impairment of cellular
metabolism.
Impaired oxygen use
Cell is not able to use O2 or not receiving adequate O2
Cells go from aerobic or anaerobic (use stores of ATP faster than can be replaced) → cannot operate NA/K pump
→ Na & Cl accumulate in cell, K goes out of cell → impacts NS and myocardium → decreased resting potential
and action potential
As Na moved into cell H2O followed (cells swell – cellular edema – injure cells → H20 pulled from vascular space
into cell → decreased circulatory volume → inflammatory and clotting cascade activated → acute tubular
necrosis, DIC
An anaerobic state impacts pH leading to metabolic acidosis → cardiac and skeletal muscles use lactic acid as
a fuel sore → acidotic state impacts cell function, repair, and division, reducing O2 carrying capacity of blood
Impaired glucose use
Impaired glucose delivery or impacted glucose uptake of cells
High cortisol levels, thyroid hormone, and catecholamines account for hyperglycemia, insulin resistance,
tachycardia, increased cardiac contractility → cells shift to glycogenolysis, gluconeogenesis, and lipolysis to
generate fuel to survive → energy costs required for glycogenlysis and lipolysis contribute to cell failure
Depletion of protein → gluconeogenesis causes proteins to be used for fuel and protein no longer available for
cell structure, function, repair, or replication → protein broken down into alamine (which is converted to pyrvic
acid), ammonia, and urea. Protein breakdown weakness skeletal muscle and cardiac muscle leads to muscle
wasting → decreased immune system, decreased circulatory volume, decreased O2 and glucose delivery, and
decreased waste removal
Types of Shock
Cardiogenic →
Inability of heart to Hypovolemic → loss Neurogenic → Neural
maintain cardiac of circulating blood alterations of vascular
output to circulation volume smooth muscle tone
(HF)

Anaphylactic →
Immunological Septic → Infection
process
Cardiogenic Shock

Dyspnea,
tachypnea,
systemic venous
and pulmonary
edema, dusky
skin, hypotension,
oliguria)
Hypovolemic Shock

High systemic vascular
resistance, poor skin turgor,
thirst, oliguria, low systemic
and pulmonary preloads,
rapid HR, thready pulse, and
deteriorating mental status
Neurogenic Shock

Relative hypovolemia, SVR
decreases, bradycardia, decrease
CO, under perfusion of tissues,
Anaphylactic Shock
 Anaphylactic Shock
Hypersensitivity Reactions – Type I
Type I hypersensitivity—allergic reactions (Humoral)
Common
Caused by allergen
Skin rashes
Hay fever
Causative mechanism
Exposure to allergen
Development of IgEs
Mast cells
Complications
Anaphylaxis
Anaphylactic Shock
Generalized itching or tingling,
especially in oral cavity
Coughing
Difficulty breathing
Feeling of weakness
Dizziness or fainting
Sense of fear and panic
Edema around eyes, lips, tongue,
hands, feet
Hives
Collapse with loss of
consciousness
 Septic Shock
SIRS – Systemic
Inflammatory Sepsis can lead to
Response Multiple Organ
Syndrome Dysfunction
Syndrome (MODS)
Diagnostic Tests & Lab Tests
Electrocardiography
Useful in the initial diagnosis and monitoring of dysrhythmias, myocardial infarction, infection, pericarditis
Holter Monitor
Auscultation
Determination of valvular abnormalities or abnormal shunts of blood that cause murmurs
Detected by listening through a stethoscope
Dobutamine Stress Echocardiography
Transesophageal Echocardiogram (TEE)
Probe is inserted into the esophagus
Uses ultrasound to look closely for blood clots
Clear pictures of heart
Echocardiography
Used to record heart valve movements, blood flow, and cardiac output
Diagnostic Tests & Lab Tests
Exercise stress tests
Used to assess general cardiovascular function
Perstantine-Thallium Imaging,
Chest x-ray films
Used to show shape and size of the heart
Nuclear imaging
Tomographic studies
CT Thorax or MRI
Cardiac catheterization
Measures pressure and assesses valve and heart function
Determines central venous pressure and pulmonary capillary
wedge pressure
Angiography - Visualization of blood flow in the coronary
arteries
Can result in a Percutaneous Coronary Intervention
 Diagnostic Tests & Lab
Tests

US Doppler studies
Assess blood flow in peripheral vessels
Record sounds of blood flow or obstruction
Blood tests
Assess levels of serum triglycerides,
cholesterol, A1C, sodium, potassium,
calcium, electrolytes, PTT, PT, D-Dimer
Arterial blood gas determination
Checks the current oxygen level and acid-
base balance
 Case Study
Ms. Smith is a 75 year old woman presenting with PAD, HTN, DM2.
She has smoked for the last 40 years, 1 pack per day. BP 175/92 95
bpm 95% RA 36.8 18R. The patient has a c/o of R leg pain. The
physician orders CBC, Lytes, Extended Lytes, CRP, ESR, A1C, ABG,
Random glucose, Cholesterol, and Triglycerides.
1. Can you explain the pathophysiology of HTN and PAD.
2. Describe the pathophysiology of Arteriosclerosis and
Atherosclerosis.
3. Explain the two laboratory tests of Cholesterol and Triglycerides
and their impact on PAD and HTN.