Chapter 1: Cardiovascular, Pulmonary & Lymphatic Systems PDF

Summary

This chapter provides an overview of the cardiovascular system, including its anatomy, physiology and function. It discusses various components of the heart, such as valves, chambers, and vessels, as well as the cardiac cycle and heart rhythm. The document also covers important aspects of heart diseases and conditions.

Full Transcript

ANATOMY & PHYSIOLOGY OF THE CARDIOVASCULAR SYSTEM

Chapter 1: Cardiovascular, Pulmonary &
Lymphatic Systems

Anatomy & Physiology of the Cardiovascular System

Topology

Pericardium: fibrous protective sac enclosing heart

Epicardium: inner layer of pericardium

Myocardium: heart muscle, the major portion of the heart

Endocardium: smooth lining of the inner surface and cavities of the heart

Apex: Lowest part of the heart that is pointy and part of the left ventricle.

o Auscultated at the 5th intercostal space (ICS) left of the midclavicular line

Base: Upper border below the second rib in the 2nd ICS

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Cardiac Valves

Atrioventricular valves: Prevent backflow of blood intro atria during ventricular
systole; anchored by chordae tendinae to papillary muscles; valves close when
ventricular walls contract

Semilunar valves: Prevent backflow of
blood from aorta and pulmonary arteries
into the ventricles during diastole

In order of blood flow:

1. Tricuspid
2. Pulmonary semilunar
3. Bicuspid (mitral)
4. Aortic semilunar
Interior view of the heart

Cardiac Chambers

Right atrium: receives deoxygenated blood from systemic circulation from the
superior and inferior vena cava

Right ventricle: receives blood from the right atrium and pumps blood via the
pulmonary artery to the lungs for oxygenation; the low-pressure pulmonary pump

Left atrium: receives oxygenated blood from the lungs and four pulmonary veins

Left Ventricle: receives blood from the left atrium and pumps blood via the aorta
throughout the entire systemic circulation; the high pressure systemic pump. The
walls of the left ventricle are thicker & stronger than the right ventricle and form
most of the left side and apex of heart.

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Cardiac Vessels

Aorta: exits left ventricle
Arch gives rise to brachiocephalic, left carotid, and left subclavian arteries, in
that order
Vena Cava: drains venous blood into right atrium
Right and Left Coronary Arteries:
Right coronary artery yields the marginal artery, and later to the post
interventricular artery
Left coronary artery immediately branches to the anterior interventricular and
circumflex artery
The right coronary and left circumflex arteries anastomose posteriorly

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Cardiac Cycle

Atrial systole: The contraction of the right and left atria pushing blood into the
ventricles
Atrial diastole: Period between atrial contractions when the atria are repolarizing
Ventricular systole: Contraction of the right and left ventricles pushing blood into
the pulmonary artery and aorta.
Ventricular diastole: Period between ventricular contractions when the ventricles
are repolarizing

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Rhythm (Abnormal)

Abnormal Appearance Notable Features
Rhythms
Ventricular P-wave: absent Occurs occasionally in majority of normal population.
(PVC)
QRS: wide (>0.10 sec) and Can occur by themselves or groups
bizarre
Originates in the ventricle. PVCs that come from
Serious PVCs: >6 per min different ectopic sites within the ventricle are multifocal
paired or in sequential runs, PVCs and are more serious than unifocal PVCs.
very early PVC (R on T
phenomenon) If PVCs increase with activity, the activity should be
stopped.
Ventricular P-wave: absent Occurs when ventricles don’t contract and instead
Fibrillation fibrillate
QRS: none
Pulseless, an emergency situation requiring emergency
Generally irregular medical treatment

Patient will die without electrical defibrillation being
used.
Ventricular P-wave: absent Run of 3 or more PVCs occurring sequentially.
Tachycardia
Rate: fast (100-250 bpm) Usually result of ischemic ventricle (3 PVC in a row)

QRS: wide (>.10 sec) and
bizarre
Atrial Flutter Saw tooth pattern
--
Rate: 250-350 bpm for atrial,
ventricular rate is often slower
Atrial P-wave: merged with T-wave Multifocal Atrial Tachycardia: p-wave often changing
Tachycardia shape and size from beat to beat (at least 3 different
Rate: 150-250 bpm forms)
Atrial P-Wave: absent or erratic Patient can usually exercise if heart rate and blood
Fibrillation waves present. pressure are stable

Rate: >350 bpm but ventricular If resting hear rate is above 115 bpm or the patient is
rate may be slow, normal or uncomfortable or responds poorly to exercise, then the
fast (irregular rhythm) patient should stop the intervention and seek medical
consultation
Atrial (PAC) An irregular rhythm Occurs with an ectopic beat that originates in the atria

These will usually not compromise cardiac output

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Pacemakers (Biological and Artificial)

Biological
A specialized conduction tissue allows rapid transmission of electrical impulses
throughout the myocardium

Pacemakers Location Function Innervation
SA Node At the junction of superior Main pacemaker of heart; Sympathetic &
vena cava & right atrium initiates impulse at rate of 60- parasympathetic (heart &
100bpm strength contraction)
AV Node At the junction of right Intrinsic firing rate of 40-60 Sympathetic &
atrium and right ventricle bpm parasympathetic innervation
Purkinje Right & left bundle Electrical impulses terminate
branches of the AV node in Purkinje fibers; specialized
are located on either side conducting tissue spread
of intraventricular septum throughout the ventricles --

Intrinsic firing rate of 20-40
bpm

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Artificial
A medical device which uses electrical impulses to regulate the heartbeat of the
patient. These are generally used if there are issues with the biological pacemakers
(not frequent enough) or the heart’s electrical system.

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 ANATOMY & PHYSIOLOGY OF THE CARDIOVASCULAR SYSTEM

Normal/Abnormal Heart Enzymes

Enzyme Normal Time Used to…
Markers Appear  Peak  Back to Normal
CK-MB 2-4 hrs.  12-24 hrs.  2-3 days May be able to detect a myocardial infraction as soon
as 2-4 hours after initial onset

Cardiac 2-4 hrs.  24-48 hrs.  14 days Sole marker for myocardial infraction; stays elevated
Troponin the longest

CK 6 hrs.  12 hrs. 2-3 days Diagnose a myocardial infraction

SGOT/AST 12 hrs.  24-48 hrs.  3-5 days Diagnose a myocardial infraction

LDH 18 hrs.  2-3 days  7 days Diagnose a myocardial infraction

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Normal Blood Gases

Normal Values
Partial pressure of oxygen (PaO2) Greater than 80 mm Hg
Partial pressure of carbon dioxide (PaCO2) 35–45 mm Hg
pH 7.35–7.45
Bicarbonate (HCO3) 22–26 mEq/L (22–26 mmol/L)
Oxygen saturation (O2Sat) 95%–100%

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Normal Blood Values and Blood Pressure

Hemostasis (Clotting/Bleeding)
Normal Time Factors for abnormal times
Prothrombin: 11-15 sec Higher in factor hemorrhagic disease, cirrhosis, hepatitis drugs
Partial thromboplastin: 25-40 sec Higher in factor VII, IX, and X deficiency
INR: 0.9-1.1 sec DVT, PE, AF
Bleeding: 2-10 min Higher in platelet disorders,

Blood Pressure
106−110
Infant:
60−65

113−116
Child:
70−75

1mm) in leads of poor perfusion (cyanosis &
J point becomes depressed without diagnostic Q waves pallor), patient requests to
terminate test, sustained
ST segment becomes sharply up Increase PR interval supraventricular or ventricular
sloping tachycardia, drop in SBP >10
Missing Q wave mmHg from baseline (despite an
Q-T interval shortens increase in workload, when
Missing P wave accompanied by other evidence of
T wave decreases in height ischemia), hypertensive response
Increase/decrease wave time

Normal and Abnormal Heart Rate Values

Age or fitness level Normal BPM
Babies to age 1 100-160
Children age 1 to 10 60-140
Children age 10+ and adults 60-100
Well-conditioned Athletes 40-60

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Abnormal Pulse What’s Happening Can Indicate
Irregular Variation in force and frequency Arrhythmias, myocarditis
Weak (Thready) Low stroke volume Cardiogenic shock
Bounding Shortened ventricular systole and decreased Aortic insufficiency
peripheral pressure

Methods for Determining Heart Rate Values
Count beats for 10 seconds x 6

Used for heart rate approximation

Count beats for 15 seconds x4

Most common and is almost as accurate

Count beats for 30 seconds x 2

Can detect rhythm changes

Count beats for 60 seconds

Most accurate for determining rhythm changes
Most accurate for determining heart rate

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Heart blocks

A heart block is a heart electrical system disease, as opposed to coronary artery
disease which is in the blood vessels.

AV Block: delay or interruption in transmission of an impulse from atria to ventricles
due to an anatomical or functional impairment in the conduction system.

AV Blocks
st
1 Degree PR interval lengthened > 0.20 sec.

Delayed conducting from atria to ventricles through AV node. (Enhanced
vagal tone: athletes, myocarditis, acute MI)
Asymptomatic. Incidental finding on ECG
Type I Progressive long PR interval dropped QRS complex
2nd degree
Asymptomatic, but in some patients, sensed irregularities of heartbeat,
presyncope, syncope may occur.

May manifest on physical exam as bradycardia
Type II Disease of distal conduction system (His-Purkinje system).
2nd degree
P-R Intervals steady, Occasional dropped QRS complex

May progress rapidly to complete heart block.
3rd degree AV block Block in the His-Purkinje system

Life threatening

Requires atropine, surgical implantation of pace maker

Associated with fatigue, dizziness, light headed, presyncope, syncope,
profound bradycardia

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Electrode placement

Lead 1 – LA – RA
Lead 2 – LL – RA
Lead 3 – LL – LA
AVL – LA – RA/LL
AVR – RA – LL/LA
AVF – LL – LA/RA
Precordial leads
1. 4th intercostal/ R sternal border
2. 4th intercostal/ L sternal border
3. midway between 2 and 4
4. 5th intercostal at L midclavicular line
5. L ant axillary line same level as V 4
6. L mid axillary line same level as V4

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Heart Diagnostic Imaging

Angiogram: x-ray of vessels after injection of a contrast medium to show plaques in
the cardiac vessels and level of occlusion

Carotid ultrasound: using real time US to visualize the structure and function of the
carotid arteries to screen for blockages and risk for stroke/evaluate stent placement

Fluoroscopy: continuous x-ray procedure to visualize the heart and lungs. Has been
largely replaced due to high radiation dose

PET scans: radioactive material is introduced that cumulates in areas of higher
chemical activity i.e. heart disease or cancer

Cardiac catheterization: a catheter inserted in a peripheral artery is advanced to the
coronary arteries and a contrast is injected to allow imaging of stenosis or occlusion
of the vessels. Also, a type of procedure in which a stent, angioplasty etc. may be
performed.

Myocardial Perfusion Imaging: used to diagnosis and evaluate ischemic heart
disease and MI Thallium is used to identify blood flow & areas of stress-induced
ischemia. Used with exercise test

Echocardiogram: noninvasive test that uses ultrasound to assess internal structures:
size of chambers, wall thickness, EF, movement of valves, septum, and abnormal wall
movement

Central Line (Swan-Ganz Catheter): inserted through vessels into right side of heart.
Measures central venous pressure, pulmonary artery pressure, and pulmonary
capillary wedge pressures

CXR: reveal abnormalities of lung fluids, overall cardiac shape and size, and
aneurysm

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Signs and symptoms of cardiac distress

Angina: chest pain described as squeezing, tightness, aching, burning or choking.
Generally substernal and may radiate to arms, jaw, neck or back.

Dyspnea: short of breath with activity or rest (note activity and time needed to
resolve). At rest with a respiratory rate over 30 may require EMS (this is also a sign of
acute CHF).

Diaphoresis: cold, clammy sweat

Orthopnea: dyspnea brought on by lying flat (count the number of pillows that
patient needs to breathe comfortably during sleep).

Blood Pressure: a drop over 10 of systolic blood pressure

Dizziness: patient is feeling faint, weak, or unsteady

Nausea/Emesis: vomiting or signs that the patient feels sick to stomach

Ataxia: patient lacks muscle control of voluntary movements

Cyanosis: skin takes on a bluish coloration due to lack of circulation or oxygenation
of the blood

Pallor: patient is pale, and generally unhealthy looking

Ventricular Tachycardia: see Rhythm for complete definition

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MET values

Intensity Endurance Promoting Activity Associated
1.5-2 Very low energy level Desk work, driving auto, washing clothes, standing,
METs strolling (1 MPH), sewing/knitting
2-3 Low in energy level unless capacity is Auto repair, riding lawnmower, level walking (2 MPH),
METs very low biking (5 MPH), bowling, canoeing
3-4 Yes, if continuous and if target HR Brick laying, plastering, machine assembly, mopping
METs reached floors, vacuuming, pushing lawnmower, walking
(3 MPH), biking (6 MPH), volleyball, golfing, archery
4-5 Recreational activities promote Painting, masonry, raking leaves, walking (3.5 MPH),
METs endurance; occupation activities must be biking (8 MPH)
continuous, lasting longer than 2 min
5-6 Yes Digging garden, walking (4 MPH), biking (10 MPH), ice
METs or roller skating
6-7 Yes Shoveling 10x/min or 10 LB, splitting wood, walking
METs (5 MPH), biking (11 MPH), skiing, swimming
7-8 Yes Carrying 80 LB, jogging (5 MPH), biking (12 MPH),
METs basketball, mountain climbing
8-9 Yes Shoveling 10x/min or 14 LB, running (6 MPH), biking
METs (13 MPH), rope skipping
10+ Yes Shoveling 10x/min or 16 LB, running (6 MPH=10 METs,
METs 7 MPH=11.5 METs, 8 MPH=13.5 METs, 9 MPH=15 METs,
10 MPH=17 METs)

Peripheral pulses

Ankle-Brachial Index: This is a ratio that compares and divides the lower extremity
(LE) pressure by the upper extremity (UE) pressure. This ratio helps determine if
there is a vascular problem. The test is performed with patients who have arterial
disease to determine if the lower extremity is getting enough blood and oxygen. This
in turn will help with determine if a wound will heal well.

Procedure: use the brachial artery for the upper extremity and the dorsal pedis or
tibial posterior artery for the lower extremity

Dorsal Pedis: located just lateral to the extensor hallucis longus tendon and is
best palpated proximal to the first metatarsal-cuneiform joint

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Tibial Posterior Artery: muscle tendon runs down behind the medial malleolus
and ends by segregating into main, plantar, and recurrent portions

ABI Significance Values
>1.2 Indicates non-compliant arteries, falsely elevated, arterial disease, diabetes
0.95-1.2 Normal
0.75-0.94 Mild arterial disease, and intermittent claudication
0.50-0.74 Moderate arterial disease, and rest pain
≤0.50 Risk for critical limb ischemia; may have pain at rest, Severe arterial disease

Circulation Tests

Doppler Ultrasound: Connected to earphones. Determines blood flow in a vessel;
used for in both venous and arterial diseases. Doppler probe placed over large vessel;
US signal given transcutaneously; movement of blood causes audible shift in signal
frequency

Venous Circulation Tests
Percussion test: determines competence of greater saphenous vein. While patient is
standing, palpate a segment of vein, at the same time percussing vein 20 cm higher.
The intervening valves are incompetent if the pulse wave is felt in lower hand.

Trendelenburg test: determines competence of communicating veins and
saphenous system. Patient is supine with legs elevated to 60°, which empties venous
blood. Tourniquet placed on proximal thigh, which blocks venous flow in superficial
veins. The patient stands, and the PT note whether veins fill in normal pattern
(should take 30 sec)

Venous Filling Time: time necessary to refill veins after emptying. When supine,
patient passively elevates lower extremity to 45° for 1 minute, then is placed in
dependent position. Note time for veins to refill. Delayed filling (>15 seconds) means
a venous insufficiency
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Air Plethysmography (APG): pneumatic device used to measure the flow (whether
obstructed or not) of venous system

Artery Circulation Tests
Rubor of dependency: changes in skin color during elevation of foot followed by
dependency (seated/ hanging position)

Intermittent claudication: exercise induced pain or cramping in legs that is absent at
rest. Have patient walk on level grade, 1 mile/ hour. Test is stopped with claudication
pain. Note time of test.

Grade I: minimal discomfort/ pain

Grade II: moderate discomfort or pain, patient’s vein can be diverted

Grade III: intense pain, patient’s vein cannot be diverted

Grade IV: Excruciating and unbearable pain

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 CARDIOVASCULAR DISEASES & CONDITIONS: DEFINITION & PROGNOSIS

Cardiovascular Diseases & Conditions: Definition &
Prognosis

Condition Definition Diagnosis Prognosis
Aneurysm Abnormal dilation in the Plaque formation erodes High mortality rates
wall of an artery, a vein or the vessel wall,
the heart (diameter at predisposing the vessel to
least 50% greater than stretching of the inner and
normal) outer layers of the artery
Angina Pectoris Chest pain or pressure Caused by an imbalance Depends on type of angina
due to ischemia between cardiac workload (stable or not); heart is
and oxygen supply to vulnerable to arrhythmias
myocardial tissue; usually and myocardial infractions
secondary to CAD which can be fatal
Aortic Stenosis Impairment of blood flow Is a result of aortic valve Once symptoms appear,
from left ventricle to disease or obstruction just prognosis is poor without
aorta above or below the valve surgery but excellent with
valve replacement
Claudication Impairment in walking, or Is often a symptom of Often, because of its
pain/discomfort in the another disorder (such as connection to another
legs when walking. PAD) disorder, outcome is poor
CHF Left Side The heart is unable to Occurs when the left Poor
pump sufficient blood for ventricle can no longer
the body maintain a normal cardiac
output
CHF Right Side The heart is unable to Is secondary to left-sided Poor
pump sufficient blood for failure, or pulmonary
the body disease
Cor Pulmonale Enlargement of the right As pulmonary HTN creates Poor, since it occurs late
ventricle; secondary to long-term pressure during the course of COPD
pulmonary HTN overload in the right and other irreversible
ventricle, cor-pulmonale diseases
develops.
Coronary Artery Narrowed arteries, which Caused by plaque build-up Is a common cause of heart
Disease reduces blood flow to along inner walls of the attacks
(CAD) heart heart arteries
Deep Vein Formation of a blood clot Caused by venous stasis, A frequent complication is
Thrombosis in a deep vein, often in changes in endothelial post-thrombotic syndrome;
the legs blood vessel linings, and death from DVT is generally
hypercoagulability rare
Hypertension A persistent elevation of Increased peripheral Treatment prolongs life and
diastolic/systolic blood resistance caused by anti-hypertensive
pressure (> 90 and 140 narrowing of the arterioles medications reduce mortality
mmHg respectively) rate

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 CARDIOVASCULAR DISEASES & CONDITIONS: DEFINITION & PROGNOSIS

Condition Definition Diagnosis Prognosis
Mitral Valve The mitral valve and Variation in the shape of Affects men and women
Prolapse related structures do not the mitral valve allows one equally; not life threatening,
function properly part to billow back into the and rarely results in
left atrium during complications
contraction of the
ventricle
Mitral Valve Mitral valve fails to open When the heart pumps, May be present for a lifetime
Stenosis as wide as it should blood pressure forces the with few or no symptoms or
mitral valve flaps open and may become severe.
allows blood to flow from
the left atrium to the left
ventricle
Myocardial Heart attack Caused by improper blood First 24 hours after symptoms
Infraction flow (often from a is highest risk for death; the
blockage), which injures elderly, those with
the muscles because lack cardiovascular/respiratory
of oxygen diseases, hypertension, and
an anterior location for the MI
are at a higher risk for death
Orthostatic A decrease of 20 mmHg< Caused by failure of the Whenever the underlying
Hypotension in systolic BP or a drop of arterial barorelfex disorder causing hypotension
10 mmHg< of both is corrected, symptoms stop
systolic/diastolic BP
Pericarditis Inflammation of the Causes are many, Excellent when there is no or
pericardium including infection, minimal myocardial
idiopathic, uremic involvement; w/out
pericarditis, etc. intervention, shock and death
can occur
Peripheral Artery Obstruction of large Caused by acute and Patients are at high risk for
Disease arteries not in the chronic ischemia cardiovascular events and
coronary/aortic diseases, which will often be
arch/brain the cause of death

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 DIFFERENTIAL DIAGNOSIS OF THE CARDIOVASCULAR SYSTEM

Differential Diagnosis of the Cardiovascular System

Condition Features
Aneurysm Substernal/back/neck/jaw pain, extreme/sharp pain felt at base of neck, acute MI, acute
chest pains, ischemia of arms/legs
Angina Pectoris Temporary pain, discomfort that starts suddenly in chest and radiates, squeezing,
burning, heartburn, indigestion, choking
Aortic Stenosis Dyspnea on exertion, fatigue, angina, palpitations, orthopnea, systolic ejection
murmurs radiating to neck
Claudication Pain in the legs, often the calves (though not always); pain is relieved by rest
CHF Left Side Dyspnea, orthopnea, productive spasmodic cough, pulmonary edema, cerebral hypoxia,
fatigue, muscular weakness, renal changes
CHF Right Side Progressive failure, dependent edema, jugular vein distention, abdominal
pain/distention, weight gain, right-upper quad pain, cardiac cirrhosis, anorexia, nausea
Cor pulmonale Chronic productive cough, wheezing, easy fatigability, sudden/severe central chest pain,
(pulmonary heart rapid pulse, sweating, hypotension, distended neck veins, clubbing
disease)
Coronary Artery Regular angina, both stable and unstable
Disease
Deep Vein Pain, swelling, redness, warmth, engorged superficial veins; symptoms are often not
Thrombosis enough to diagnose a patient since many other disorders share similar symptoms
HTN Asymptomatic in the early stages; headache, vertigo, flushed face, blurred vision, sleep
disordered breathing
Mitral Valve Most people are asymptomatic, profound fatigue (not from exercise/stress),
Prolapse palpitations, dyspnea, joint hypermobility, mild scoliosis, tremors, swelling of the
extremities, low back pain, dizziness, difficulty in concentrating
Mitral Valve Atrial fibrillation, dyspnea, orthopnea, fatigue, reduced cardiac output, Distinctive heart
Stenosis murmur and specific heart sound, swelling especially in the legs, ankles and feet,
bulging neck veins, fine crackles heard in the lungs, flushing of the cheek
Myocardial Pain is constant, lasting 30 minutes up to hours, crushing/squeezing chest pain, profuse
Infraction (Heart perspiration, skin cool and clammy, nausea/vomiting, pain spreads from chest to
Attack) neck/jaw/shoulders/arms, fast/irregular heart beat
Orthostatic Dizziness, blurring/loss of vision, fainting, unexpected/unexplained falls
Hypotension
Pericarditis Pleuritic chest pains, substernal pains, fever, joint pain, dyspnea, difficulty swallowing
Peripheral Artery Mild PAD can be asymptomatic; claudication, sores/wounds that heal slowly or never,
Disease changes in color and temp, diminished hair/nail growth on affected limbs

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 PHARMACOLOGICAL MANAGEMENT

Pharmacological Management
Cardiac pharmacology

Class Examples Action Indication Side Effects
Alpha Minipress, Reduces blood HTN, BPH Dizziness, orthostatic
Adrenergic Prazosin, pressure by dilating hypotension, drowsiness
Antagonist doxazosin, peripheral arterioles
Agents terazosin and veins
“zosin”
ACE inhibitor Lisinopril, Reduce BP by HTN, CHF Hypotension, dizziness,
(angiotensin captopril, Suppresses the dry cough, hyperkalemia
converting enalapril, enzyme that converts and natremia
enzyme) Ramipril “pril” angiotensin 1 to 2
Angiotensin II Losartan, Reduce BP by Block HTN, CHF Dizziness, back and leg
receptor candesartan, angiotensin II pain, angina
antagonist valsartan receptors to limit
Agent “sartan” vasoconstriction
Anti-arrhythmic Depend on Class 1: sodium Arrhythmia Depend on subtype
Agents subtype, look channel blockers
at respected Class 2: beta blockers
area Class 3: inhibit
potassium and
sodium
Class 4: calcium
channel blocker
Anti-coagulants Heparin, Inhibit platelet Heart valve Hemorrhage, GI distress
Coumadin, aggregation surgery,
Warfarin, angioplasty,
Lovenox bypass, etc.
Antihyperlipide Lipitor, Zocor, Break down LDL, High cholesterol, HA, GI distress, rash
mic fenofibrate, decrease triglycerides, atherosclerosis
atorvastatin, increase HDL and prevent
simvastatin CAD
“statins”
Anti-thrombotic Aspirin, Bayer, Inhibit platelet Post MI, A-Fib, Hemorrhage, thrombo -
(antiplatelet) Plavix formation prevent cytopenia, liver damage
thrombus
Beta Blocker Atenolol, Decrease HR and Tachycardia, Bradycardia, arrhythmia,
metoprolol, contractility by arrhythmia, fatigue, weakness,
propranolol blocking Beta heart failure, depression, blurred vision
adrenergic receptors essential tremor
Calcium channel Procardia, Reduce calcium entry HTN, angina, Dizziness, HA,
blocker Cardizem, reducing contractility arrhythmia, CHF hypotension, peripheral
Norvasc and O2 demands to edema
the heart

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 PHARMACOLOGICAL MANAGEMENT

Class Examples Action Indication Side Effects
Diuretics Thiazide - Increase sodium HTN, edema due Dehydration, hypotension,
diuril, Loop – excretion to reduce to CHF or polyuria, electrolyte
Lasix, plasma volume to pulmonary imbalance
Potassium reduce BP edema,
sparing - glaucoma
dyrenium
Nitrates Nitrostat, Smooth muscle Angina HA, dizzy, ortho-hypo,
nitroglycerin relaxation and reflex tachycardia,
isordil peripheral vessel
dilation
Positive Digoxin, Increase force and Heart failure, A- Arrhythmia, GI distress,
Inotropic Lanoxin velocity of fib dizziness, blurred vision
contraction, slow HR,
decrease conduction
velocity
Thrombolytic Urokinase, Convert plasmogen to Acute MI, PE, Hemorrhage, allergic
activase, linlytic plasmin to breakdown ischemia CVA, reaction, arrhythmia,
clots venous
thrombosis

Drug Management for COPD

Drug Trade Action Side Effects
Name
Anticholinergic Atrovent Bronchodilator Throat Irritation, drying of tracheal
secretions, tachycardia, palpitations
Long-acting Serevent Bronchodilator Tachycardia, palpitations, GI distress,
Beta2 agonist nervousness, tremor, headache, dizziness

Steroids Flovent Reduces the Increase blood pressure, sodium retention,
Prednisone Inflammatory muscle wasting, osteoporosis, GI irritation,
Maintenance Response atherosclerosis, hypercholesterolemia,
increased susceptibility to infection
Cromolyn Intal Prevents the Throat irritation, cough, bronchospasm
Sodium inflammatory
response
Leukotriene Singulair Blocks allergic GI distress, sore throat, upper respiratory
receptor reaction tract infection, dizziness, headaches, nasal
antagonist (blocking congestion
leukotriene’s)
Short-acting Albuterol Bronchodilator Tachycardia, palpitations, GI distress,
Rescue
Beta2 agonist Ventolin nervousness, tremor, headache, dizziness

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Cardiovascular Interventions: Types, Applications,
Responses & Potential Complications
Disease Specific Interventions and Considerations

Disease PT Intervention Affects A&P of Individual Complications
Chronic Supervised exercise Walking program; helps open Rise in diastolic BP > 110
Arterial training 30-45 min, alternative small vessels mmHg
Insufficiency 3x/week, at least 12 Minimal increase in collateral Decrease in systolic BP > 10
(PAD) weeks; needed to build up flow mmHg
tolerance Improved nitric oxide- Significant ventricular or atrial
Smoking cessation dependent vasodilation dysrhythmias
Lipid-lowering Improve mitochondrial 2nd or 3rd degree heart blocks
medications energetics
Revascularization Decrease markers of systemic
procedures inflammation
No leg elevation
Chronic Manage edema Rise in diastolic BP > 110mmHg
Venous Elevate leg at least 18 cm Decrease in systolic BP > 10
Insufficiency above heart (avoid mmHg
dependent positions) Significant ventricular or atrial
Unna Boot (4-7 days) dysrhythmias
Compression Therapy -- 2nd or 3rd degree heart blocks
Exercise
Ankle AROM (ankle
pumps, circle)
Cycling (seated)
Ambulation (3-4x/day)
Left CHF and Low level, low impact Decrease stress/load on heart Rise in diastolic BP > 110
Right CHF exercise Heart pumps more efficiently mmHg
Anticoagulants, Increase endurance and Decrease in systolic BP > 10
antihypertensives, abilities/quality of life mmHg
digitalis Significant ventricular or atrial
Restricting sodium intake dysrhythmias
Smoking cessation 2nd or 3rd degree heart blocks
Limiting alcohol and Orthostatic hypotension
fluids Dizziness
Monitor at rest & during Hypotension
activity Hyperkalemia
Low level, gradually
progressive aerobic
training
Capacities under 6 METs
not candidates for
resistance training
Cardiac Rehab stages

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Disease PT Intervention Affects A&P of Individual Complications
Acute Smoking cessation Decrease stress/load on heart Rise in diastolic BP > 110mmHg
Coronary Weight loss Heart pumps more efficiently Decrease in systolic BP > 10
Artery Heart-healthy diet Increase endurance and mmHg
Syndrome Regular exercise abilities/quality of life Significant ventricular or atrial
Antiplatelet agents, ACE dysrhythmias
inhibitors, angiotensin II 2nd or 3rd degree heart blocks
receptor blockers, statins Statins can cause liver
Percutaneous damage, rash/flushing, muscle
angioplasty, coronary cramps
artery bypass graft
surgery considered for
high risk patients
Myocardial Smoking cessation Decrease stress/load on heart Rise in diastolic BP > 110mmHg
Infarction Moderate exercise Heart pump more efficiently Decrease in systolic BP > 10
(“heart Healthy diet Increase endurance and mmHg
attack”) Weight loss abilities/quality of life Significant ventricular or atrial
Stress reduction dysrhythmias
Decrease alcohol intake 2nd or 3rd degree heart blocks
Exercise Throbbing headache
Medications: beta Flushing
blockers, calcium channel Dizziness
blockers, ACE inhibitors, Orthostatic hypotension
nitroglycerin
Deep Vein Acute bed rest with leg Decrease pain Risk for osteoporosis with
Thrombosis elevated Decrease swelling prolonged use of medications
Exercise contraindicated
during acute phase
Ambulation with
compression stockings
when tenderness and
swelling are gone
Medications: Anti-
coagulants
Peripheral Interval training with Decrease pain Beta blocker may decrease
Vascular frequent rests Decrease swelling time for claudication or make
Disease Walking program Increase endurance symptoms worse
moderate intensity Pentoxifylline, dipyridamole,
Exercise to point of pain aspirin, and warfarin may
improve time to claudication

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Cardiac rehab

Indications Contraindications
Medically stable post MI Unstable angina
Stable angina Resting systolic BP >200mmHg
Coronary artery bypass graft surgery (CABG) Resting diastolic BP>110mmHg
Percutaneous transluminal coronary angioplasty Orthostatic BP drop of >20mmHg with symptoms
(PTCA) Critical aortic stenosis
Compensated congestive heart failure Acute systemic illness or fever
Cardiomyopathy Uncontrolled atrial or ventricular dysrhythmias
Heart, or other organ transplantation Uncontrolled sinus tachycardia >120bpm
Other cardiac surgery Uncompensated CHF
Peripheral arterial disease
High risk CV disease ineligible for surgery
Sudden cardiac death syndrome
At risk for coronary artery disease with diagnosis of
DM, dyslipidemia, HTN, obesity
End stage renal disease
Allow to Initiate Cardiac Rehab If:

Medical Doctor approval/order
No chest discomfort (8 hours)
No new signs of decompensated heart failure
No abnormal EKG changes (8 hours)

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Phases
Phase I:

Patient requires 24-hour monitoring in the ICU or CCU. Patients in this phase
require monitoring at rest and during activity through telemetry or wall mounted
ECG.
Activities focus on strength with active and active assistive exercises starting with
the lower extremities and progressing to the upper extremities.
Few repetitions are used with frequent rest breaks.
Use a low target 60%-75% of maximal effort. Activities such as transfer training
and short distance ambulation are also acceptable forms of exercise for this
phase.
Initial activities are low intensity in bed (1-2 METs) by having patient sit up in bed
and then progressing to ≥ 5 METs by discharge. Post-MI: limited to 70% max HR
and/or 5 METs until 6 weeks post-MI. Lifting activities are restricted for 6 weeks.

Goals: minimal assistance levels with ADLs. Goal should be for the patient to return
home (homebound) with assistance. Ideally the patient should be able to tolerate a
stress level of 2.5-3 METs. Patients need to be stable at rest to be released to phase II.

Phase II:

The patient is home in homebound status or in a subacute unit. Length of this
phase is typically 4-6 weeks to allow the muscle of the myocardium to heal.
Exercise testing prior to starting program (submaximal treadmill testing). Cardiac
monitoring during exercise, not at rest. Vital signs are most often used to
monitor, but a pulse oximeter fix now in use as well.
Exercise of both lower and upper extremities with a concentration on strength.
Patient should be ambulating at least 200 ft. by the end of this phase.
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Goals: The patient should be able to tolerate 5-6 Mets by the end of this phase. This
will allow the patient to enter the community, get to outpatient cardiac rehab. This is
the same level that is needed for sedentary work, such as an office job.

Phase III:

Outpatient cardiac rehab facility. During exercise patient is closely monitored by
a professional. Telemetry is commonly used.
Monitoring is done prior to exercise, during exercise and after exercise to
determine recovery time.
Exercise 5 times/week including activities that challenge both upper/lower
extremities to achieve higher workload levels (elliptical).
Educate patient to monitor their own vitals.

Goals: The myocardium should be completely healed by this point. Goals should
focus on endurance to enhance patient's quality of life. The patient should tolerate
their expected maximal HR and be able to return to work. This phase is terminated
with a patient can reliably monitor their own vital signs and demonstrate that they
can increase workloads to an appropriate stress level and recognize when they are
exceeding a targeted training level.

Phase IV:

Patient is able to monitor themselves during exercise and at rest, no professional
monitoring is needed.
Patients exercise at health club. Patients can come in and use equipment or
attend program at YMCA.
Activities focus on aerobic activities that are integrated into patient's lifestyle.

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When a patient participates in the activities their heart rate should be within a
training level for at least 20 minutes.

Goals: maintain (3 times/week) or improve (5 times/week) cardiac muscle function.
Improvement may be needed if a patient cannot tolerate a workload, or stress level
that is required by either a job or recreational activity that they need to or want to
participate.

Setting Duration Initial D/C HR Exercise Duration
MET MET
Phase I Inpatient 3-5 days 2-3 3-5 10-20bpm 3-5 minutes initially
above resting progressing to 15
HR minutes, 2-3 x day
Phase II Subacute or 2-12 weeks 5 9 HR intensity 30-60 minutes, 3-4 x
outpatient 60-80% week
Phase III outpatient 6-12 months 5 9+ HR intensity 45 minutes +
50-85% 3-4 x week
Phase IV Maintenance/home lifetime >9 3x or more/week

Types of exercise
Post MI or Cardiac Surgery
Minimum 5 weeks after insult or surgery and 4 weeks of consistent participation
in a supervised CR endurance training program
Post-trans catheter procedure (PTCA)
o Minimum of 3 weeks following procedure and 2 weeks of consistent
participation in a supervised CR endurance training program
Exercise Prescription
Low resistance
o One set of 10-15 reps
Resistance can include
o Weights 50% or more of maximum weigh used to complete one rep

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o Elastic bands
o Light 1 to 5 LB cuff and hand weights
o Wall pulleys
RPE-Borg Scale
o Range from 11 to 13 (light to somewhat hard)

Congestive Heart Failure
Classes of Chronic Heart Failure
Class I No limitation to normal activity up to 6.5 METS
Class II Slight limitation to ordinary activity up to 4.5 METS
Class III Marked limitation to < ordinary activity up to 3.0 METS
Class IV Severe, unable to carry out any activity up to 1.5 METS (angina present)
Monitor at rest and during activity
o Use RPE
o Clinical signs of exertional intolerance
o HR response may be impaired
 HR limited to resting HR + 10-20 bpm
 Exercise HR > 115 bpm generally contraindicated
Use low level, gradually progressive aerobic training
o Intensities
 40%-60% VO2 max
o Interval training
Use caution exercising in supine or prone
o Due to orthopnea
AVOID breath holding and Valsalva’s maneuver
Pt’s with CHF with capacities under 6 METs not candidates for resistance training

Cardiac transplant
Heart rate alone not an appropriate measure of exercise intensity
o Use
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 RPE
 METs
 Dyspnea scale
Use longer periods of warm up and cool down
Heart is denervated and patients tend to be tachycardic

Pacemakers and automatic implantable cardioverter defibrillators (AICDs)
Fixed rate pacer: Heart rate will not change—impacts activity tolerance
ST segment changes may be common
AVOID UE aerobic or strengthening exercises initially after implant

Percutaneous transluminal coronary angioplasty (PTCA)
Exercise prescription
o Wait 2 weeks to exercise

Coronary artery bypass grafting (CABG)
Limit UE exercise while sternal incision is healing
AVOID lifting, pushing, pulling for 4-6 weeks post-surgery

Arterial Disease
Exercise training for PVD
o Interval training with frequent rests
o Walking program
 Mod intensity 40%-70% VO2 max
 Duration 2-3 times/day, 3-7 days/week
o Exercise to point of pain
o NWB exercise
 Cycle ergometry

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 Arm ergometry
o Well-fitting shoes with insensitive feet
 Proper foot inspection and care
o Beta blockers may decrease time to claudication or worsen symptoms
LE exercise
o Modified Buerger-Allen exercises
 Postural exercises plus active PF and DF of the ankle
o Resistive calf exercises

Venous Disease
Management of edema
o Positioning
 Elevate extremities
 AVOID dependent position
o Compression therapy
 Bandages
 Paste bandages (Unna boot)
Gauze impregnated with zinc oxide, gelatin and glycerin
applied for 4-7 days
 Graduated compression stockings (Jobst)
 Compression pump therapy
Used for 1-2-hour session twice daily
o DO NOT APPLY compression therapy to a limb with
an ABI < 0.8 or with evidence of active cellulitis or
infection
Exercise
o Active ankle exercises
 Muscle pump exercises

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DF/PF
Foot circles
o Cycle ergometry
o Early ambulation as soon as patient able to get out of bed

Sternal precautions
No pulling up in bed during acute care
o Pt must roll into side-lying and use the top arm to assist in pushing up while
allowing the feet to drop off the side of the bed as a pendulum
Hand held assistance may be required initially in place of AD’s
No pushing, pulling or lifting more than 10 LB for 6 weeks postop
o Some precautions list 5 LB
No driving motorized vehicles for 4 weeks postop
Full neck, shoulder and torso ROM may be permitted as long as sternum is stable
but not if a sternectomy with skin or muscle flap is present
o Presence of a flap limits ROM to 90* flexion or abduction
Avoid shoulder horizontal abduction with extreme ER
Progression is based on client tolerance and signs of wound healing
Use of more conservative precautions is advised with pts with diabetes mellitus,
severe osteoporosis, or other equally compromising morbidities

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System monitoring (including Borg RPE)
Borg RPE Approximate %MHR Revised RPE
6 nothing
7 (very, very light) Very Very weak
8 Very weak
9 (very light) Weak
10 (60-70% MHR) Moderate
11 (Fairly Light) Somewhat Strong
12 Strong
13 (Somewhat hard)
14 (70-80% MHR) Very Strong
15 (Hard)
16 (80-90% MHR)
17 (Very Hard) Very, Very Strong
18 (90-100% MHR)
19 (Very, Very, Hard) --
20 --

Complications
Adverse Responses to Inpatient Exercise Leading to Exercise Termination
Rise in diastolic BP >/=110mmHg
Decrease in systolic BP >10mmHg
Significant ventricular or atrial dysrhythmias
Second or third-degree heart block
Signs and symptoms of exercise intolerance
o Angina
o Marked dyspnea
o ECG changes suggestive of ischemia

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 ANATOMY & PHYSIOLOGY OF THE PULMONARY SYSTEM

Anatomy & Physiology of the Pulmonary System
Lung anatomy and topology

Mediastinum: compartment of the thoracic cavity that contains the heart and
vessels, esophagus, phrenic and cardiac nerves, trachea, etc. It is located behind the
lungs.

Pleural cavity: the fluid-filled space between the visceral and parietal pleurae of each
lung.

Apex: highest point on the lung, about 1 inch above the middle third of each clavicle

Base: concave and resting on the convex surface of the diaphragm

Bronchioles: branches of the bronchi, the smallest passageways in which air travels
to the alveoli. Control the amount of air in the lungs by constricting or dilating

Alveoli: air sacs, in which the
exchange of oxygen and carbon
dioxide take place. These gases
diffuse through the walls into the
capillaries

Lobes, fissures &
segments
Right Lung
o Upper Lobe
 Superior lobar bronchus
Apical, Anterior, and Posterior segmental bronchi
o Middle Lobe
 Mid lobar bronchus

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Lateral and medial segmental bronchi
o Lower Lobe
 Inferior lobar bronchus
Superior, Anterior basal, medial basal, lateral basal, post basal
segmental bronchi

Left Lung
Anterior border of left lung: cardiac notch
o Upper Lobe
 apical posterior segment
Apical, posterior, ant segmental bronchi
 Ant segment
superior and inferior lingular segmental bronchi
o Lower Lobe
 anteromedial segment
Ant and medial basal segmental bronchi
 Posterior Segment
lateral and posterior basal segmental bronchi

For a more comprehensive review, click here

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Musculature and Regions

Thorax

Covers and protects major organs of cardiopulmonary system
Conical at both superior and inferior aspects
Boundaries are the 12 thoracic vertebrae dorsally, the ribs laterally, and sternum
anteriorly

Sternum

Breast bone: manubrium, body and xiphoid process
Sternal angle “angle of Louie”: anterior angle formed by junction of manubrium
and body of sternum
Easily palpable; in level with 2nd costal cartilage anteriorly and thoracic
vertebrae T4 – T5 posteriorly
Marks bifurcation of the trachea into right and left main stem bronchi
Pectus excavatum: congenital deformity of the anterior wall of the chest, in which
several ribs and sternum grow abnormally

Ribs

Curve forward and downward from their posterior vertebral attachment toward
their costal cartilages
First 7 ribs: attach via their costal cartilage to the sternum; “true ribs”
(vertebrosternal)
Lower 5 ribs “false ribs”:
Ribs 8, 9 & 10: attach to the rib above by their costal cartilages
(vertebrocohondral ribs)
Ribs 11 & 12: end freely “floating ribs”

Muscles of ventilation

External intercostals: slope obliquely between ribs, forward and downward; the
attachment to the lower rib is farther forward from the axis of rotation,
contraction raises the lower rib more than it depresses the upper rib
Sternocleidomastoid
Scalenes
Serratus anterior
Pectoralis minor
Pectoralis major
Latissimus dorsi
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Trapezius
Erector spinae muscles
Diaphragm
o Major muscle of inspiration
o Musculotendinous dome that forms floor of thorax and separates the
thoracic and abdominal cavities
o Innervation: Phrenic Nerve (C3 – C5)
o Three major openings for various vessels to transverse the diaphragm
 Inferior vena cava, esophageal opening and aortic opening
o Resting position: arched high in thorax
 In supine: the level of the diaphragm rises (no gravity)
 In upright: dome of diaphragm is pulled down (due to gravity)
 In side lying: uppermost side drops to a lower level and has less
excursion than in a sitting position; the lowermost side rises higher
and has a greater excursion
o Quiet sitting: diaphragm normally moves 2/3 of an inch; with max
ventilator effort, the diaphragm may move 2.5 – 4 inches
o Patients with COPD:
 Compromised ability to expire which results in flattening of the
diaphragm because of the presence of hyper inflated lungs

Muscles of Expiration

Rectus abdominis,
Transversus abdominis and
Internal/external obliques

Upper and Lower Respiratory Tract

Upper respiratory tract
Nose: Primary functions of nasal cavity are air conduction, filtration, humidification,
and temperature control; also plays a role in olfactory process

Pharynx: musculomembranous tube ~ 5-6 inches long; located posterior to nasal
cavity; extends from base of skill to the esophagus. There are three parts:
nasopharynx, oropharynx, laryngopharynx

Nasopharynx: continuation of nasal cavity
Oropharynx: extends from soft palate and pharyngeal isthmus superiorly to upper
border of epiglottis inferiorly

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Laryngopharynx: extends from upper border of epiglottis to inferior border of
cricoid cartilage and the esophagus
Larynx: “voice box”, made up of several cartilages and forms a connection between
the pharynx and the trachea. Controls airflow and closes to increase intrathoracic
pressure to generate an effective cough

Two sets of laryngeal muscles play roles in swallowing, ventilation and vocalization

Lower respiratory tract
Extends from level of true vocal cords in the larynx to the alveoli within the lungs

Physiology of gas exchange

O2 and CO2 diffuse in opposite directions across the alveolar-capillary septum into
red blood cells where it combines with hemoglobin for transport

For a more comprehensive review, click here

Respiratory Rates

Infant: 30-45

Child: 20-35

Adult (10 yrs. and older): 12-20

Bradypnea: < 12 breaths/min

Tachypnea: > 20 breaths/min

Eupnea: Normal

Hyperpnea: Increased rate and depth of breathing

Hypopnea: Decreased rate and depth of breathing

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For a more comprehensive review, click here

Auscultation (normal)

Vesicular: Heard over the lungs. Soft rustling heard throughout all of inspiration and
the beginning of expiration. Is normal, unlabored breathing

Normal Vocal Sounds: Loudest near trachea & main stem bronchi. Words should be
intelligible, softer, and less clear at the more distal areas of lung

Bronchovesicular: Heard over 1st and 2nd intercostal spaces and the interscapular
region

Bronchial: Hallow, echoing. Normally found only over the right superior anterior
thorax through right main stem bronchus. All inspiration and expiration. Normally
heard over the manubrium

Tracheal: Heard right over the trachea

For a more comprehensive review, click here

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Pulmonary Tests & Measures
Abnormal blood-gas values

Abnormal Values
pH 7.45: Alkalemia
PaCO2 >45mmHG: Hypercapnia
w/ pH < 7.4: Respiratory Acidosis
< 35mmHg: Hypocapnia
w/pH > 7.4: Respiratory Alkalosis
PaO2 60-79 mmHg: Mild Hypoxemia
40-59 mmHg: Moderate Hypoxemia
< 40 mmHg: Severe Hypoxemia
HCO3 < 22 mEq/L w/ pH < 7.4: Metabolic Acidosis
>26 mEq/L w/ pH > 7.4: Metabolic Alkalosis

For a more comprehensive review, click here

FEV₁, FEV, IRV, TV, ERV, RV, VC, TLC, FEV1/FVC, etc.

Spirometry: Measures the capacity of the lungs

Tidal volume (TV): Volume of gas inhaled (or exhaled) during a normal resting breath
(10% of TLC)

Inspiratory Reserve Volume (IRV): Volume of gas that can be inhaled beyond a
normal resting tidal inhalation. Makes up 50% of total lung volume

Expiratory Reserve Volume (ERV): Volume of gas that can be exhaled beyond a
normal resting tidal exhalation, if forced. Makes up 15% of total lung volume

Residual Volume: Volume of gas that remains in the lungs after ERV has been
exhaled. Makes up 25% of total lung volume

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Inspiratory Capacity (IRV+TV): The amount of air that can be inhaled at the end of
tidal expiration. Makes up 60% of total lung volume

Vital Capacity (IRV+TV+ERV): The amount of air that is under volitional control;
conventionally measured as forced expiratory vital capacity (FVC). Makes up 75% of
total lung volume

Functional Residual Capacity (ERV+RV): The amount of air that resides in the lungs
after normal resting tidal exhalation

Total Lung Capacity (IRV+TV+ERV+RV): The total amount of air that is contained
w/in the thorax during a max inspiratory effort

FEV1/FVC = forced expiratory volume in 1 s / forced vial capacity
< 70% is the primary indicator of obstructive impairment
o 100-70= mild obstruction
o 60-70 = moderate obstruction
o 50-60 = moderate-severe obstruction

For a more comprehensive review, click here

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Auscultation (abnormal sounds)

Breathing Pattern or Sound Description

Apneustic Gasping inspiration followed by short expiration

Biot’s Respiration (ataxia) An irregular pattern of deep and shallow breaths; fast deep breaths
interspersed with abrupt pauses in breathing
Cheyne-Stokes respiration Repeated cycle of deep breathing followed by shallow breaths or cessation of
breathing
Hyperventilation Abnormally prolonged and deep breathing

Hypoventilation Reduction in the amount of air entering the pulmonary alveoli

Kussmaul’s breathing Distressing dyspnea characterized by increased respiratory rate, increased
depth of respiration, panting, and labored respiration typical or air hunger
Lateral-costal breathing Chest becomes flattened anteriorly with excessive flaring of the lower ribs;
minimal to no upper chest expansion or accessory muscle involvement with
outward flaring of the lower rib cage
Used to focus expansion in areas of the chest wall that have decreased
expansion
Paradoxical breathing All or part of the chest wall falls in during inspiration; may be abdominal
expansion during exhalation; can lead to a flattened anterior chest wall or
pectus excavatum
Crackles Rales, rattling or bubbling sounds that occur owing to secretions in the air
passages of the respiratory tract. Apparent in patients with CHF. Indicates
atelectasis (alveoli deflated), fibrosis, pulmonary edema
Sigh Is a deep inspiration followed by a prolonged, audible expiration. Occasional
sighs are ok, but frequent sighs are abnormal
Stertor Is a snoring sound owing to partial obstruction (e.g. secretions) in the upper
airway (e.g. trachea, large bronchi)
Egophony Abnormal transmission of vocal sounds, nasal or bleating sound. “E” sounds are
transmitted to sound like “A”. Fluid filled areas of consolidation, cavitation
lesions, or pleural effusions
Stridor A shrill, harsh sound heard during inspiration in the presence of laryngeal
obstruction
Bronchophony Abnormal transmission of vocal sound, intense clear sound during auscultation
even at lung bases. Heard through fluid filled areas of consolidation, cavitation
lesions or pleural effusion.
Whispered pectoriloquy Abnormal transmission of vocal sounds. Whispered sounds are heard clearly
during auscultations. Heard through fluid filled areas of consolidation,
cavitation lesions or pleural effusion
Wheezing Breathing with a rasp or whistling sound from constriction of the throat,
pharynx, trachea or bronchi. Can be heard on both inspiration and expiration.
Symptom of asthma and CHF

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Signs and symptoms of pulmonary distress

Noisy breathing: congested or wheezing in lower airway or is pitched indicates
asthma. Stridor indicates the trachea is narrowing

Using accessory muscles to breathe

Purse lip breathing

Dyspnea: difficulty breathing, always subjective

Dyspnea on exertion: classic sign of anemia

Paroxysmal nocturnal dyspnea: sign of heart failure

Kussmaul Respirations: increased depth and rate indicates hyperpnea, and is
compensatory breathing for metabolic acidosis

Labored breathing: specifically during exhalation

Cheyne-Strokes: alternating deep and shallow breathing with periods of apnea
which indicates a neurologic or brainstem dysfunction

Hypoventilation: respiratory rate of around of 8 (normal is around 12-20)

Hyperventilation: respiratory rate of around 32 (normal is around 12-20)

Cough (acute or chronic): can be productive or non-productive. If coughing up
yellow, green, brown phlegm, this indicates an infection. If coughing up blood, this is
a classic sign of tuberculosis

Cyanosis: low SaO2, hypoxemia, desaturated hemoglobin

Pain: from pleura, airways, chest wall muscles, cardiac muscles, musculoskeletal
muscles

Clubbing of nail beds: indicates chronic hypoxia
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 MOVEMENT ANALYSIS AS RELATED TO THE PULMONARY SYSTEM

Movement Analysis as Related to the Pulmonary System
Rib cage excursion (normal motion patterns for
females/males)

Rib Cage Excursion
Ribs 2-4: pump handle. Breathe in and out, ribs move up and down. Supine for assessment
Ribs 8-10: bucket handle. Flop up and down with inhaling/ exhaling. SL for assessment
Ribs 11-12: hug and expand when breathe in and out

Elastic recoil of lung parenchyma pulls the lungs and therefore, visceral pleura, parietal
pleura and bony thorax into a position of exhalation (inward pull)

Bony thorax pulls the thorax and parietal pleura, visceral pleura and lungs into position of
inspiration (outward pull)

RIBS:
Upper ribs: pump handle, then move upward and forward (increase chest
dimension in the anterior/ posterior direction)
Lower ribs: bucket handle, then move upward and lateral (increase chest
dimension in the transverse/ lateral direction)

Muscular activity during abnormal/normal breathing

Normal Breathing

Inspiration
Primary muscle used: diaphragm

Diaphragm contracts (central tendon pulled downward); flattening the dome and
results in a protrusion of abdominal wall.

Normal resting tidal volume

Expiration
When resting: passive relaxation of inspiratory muscles and elastic recoil tendency of
lung. Diaphragm returns to normal, high dome position

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 MOVEMENT ANALYSIS AS RELATED TO THE PULMONARY SYSTEM

Abnormal Breathing
Accessory muscles are used for more rapid and deeper inhalation/disease states. The
upper two ribs are raised by scalenes and sternocleidomastoid. Rest of the ribs are
raised by levator costarum and serratus. Fixing shoulder girdle, the trapezius,
pectorals and serratus can become muscles of inspiration

Muscles used: quick/full expiration desired for exercise or disease: QL, portions of
intercostals, abdomen

Without Abdominal Muscles (Ex. Spinal Cord Injury)

Lower resting position of diaphragm, decreasing inspiratory reserve.
More upright body means lowering the diaphragm and a lower inspiratory
capacity
More supine is a more advantageous position of diaphragm.
Abdominal Binder: may help support abdominal viscera assisting in ventilation

Positional effects on pulmonary perfusion and ease of
breathing

Gravity affects the distribution of ventilation and perfusion. Perfusion is gravity
dependent; more pulmonary blood is found at the base of the lung in the upright
position

Ventilation: Static point of right end-expiratory pressure. The apical alveoli are fuller
than those at the base. During inspiration, more air will be delivered to the less-filled
alveoli at the bases, causing a greater change in 𝑉𝑉𝐸𝐸 at the bases.

Upright Position

Apices: gravity independent, with the lowest blood flow or Q (still more air than
blood); high V/Q ratio (dead air space)

Bases: gravity dependent and have the most Q (blood flow). 𝑉𝑉𝐸𝐸 is relatively high
(more blood than air); relatively low V/Q ratio (shunt)

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 PULMONARY DISEASES & CONDITIONS: DEFINITION & PROGNOSIS

Pulmonary Diseases & Conditions: Definition & Prognosis
Condition Definition Diagnosis Prognosis
Asthma Reversible obstructive lung Combination of genetic and Good; mortality rates have
disease caused by increased environmental factors decreased because of
reaction of the airways to improvement in
various stimuli management
Atelectasis The collapse of normally Primary cause of atelectasis is Depends on underlying
expanded and aerated lung obstruction of the bronchus disease
tissue at any structural level serving the affected area.
involving all or part of the
lung
Bronchiectasis Dilated, inflamed, & easily May result from recurrent Good
collapsible bronchi due to pneumonia, cystic fibrosis,
destruction of the muscle and TB
and decrease in elasticity
Bronchitis Inflammation of the Caused by virus or bacteria Good if treated; better
(acute) bronchi; lasts several days breathing in warm moist air,
to weeks worse with cold damp air
Bronchitis Inflammation of the Smoking is the most common Periods where symptoms
(chronic) bronchi; lasts years cause worsen, and then get better;
often, patients have COPD
COPD A disease state Tobacco is a common cause; Usually gets progressively
characterized by airflow most people with chronic worse, which ultimately
limitation that is not fully bronchitis also have it results in death; it can be
reversible worsened if the underlying
cause is not addressed
Cystic Fibrosis Disorder of ion transport in Inherited as an autosomal Median survival age is 32
the exocrine glands recessive trait yrs., with pulmonary failure
affecting the hepatic, as a common cause of death
digestive, male
reproductive and
respiratory systems
Emphysema Pathologic accumulation of Part of COPD, with smoking Can't be cured, but
air in tissues, particularly in as the primary cause treatment will slow the
lungs progression
Lofgren’s A group of symptoms Sarcoidosis Good
Syndrome present at initial onset of
sarcoidosis
Pancoast Apical lung tumor at the It is a type of lung cancer Poor
syndrome/ superior thoracic inlet
tumor
Pleural Fluid within the pleural Underlying cause is often left Depends on underlying
effusion space ventricular failure and disease, and how well it is
cirrhosis treated
Pneumonia Inflammation affecting the Can be caused by Death more common with
parenchyma of the lungs bacterial/viral/mycoplasmal older individuals; there are
infection, inhalation of toxic many effective treatment
or caustic chemicals, smoke, methods that improve
dusts or gases, or aspiration survival rates, and prevent it
of food, fluids or vomitus

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 PULMONARY DISEASES & CONDITIONS: DEFINITION & PROGNOSIS

Condition Definition Diagnosis Prognosis
Pneumothorax Entry of air into the pleural The lung collapse is caused by Small/spontaneous ones
space with secondary lung a separation between the usually don't require
collapse visceral/parietal pleurae when treatment and will resolve
air enters the pleural cavity, themselves; not life-
destroying the negative threatening unless it
pressure of the pleural space develops into a tension
pneumothorax
Pulmonary Excessive fluid in the lungs Occurs when the pulmonary Considered a medical
Edema that may accumulate in the vasculature fills with fluid that emergency; it is reversible
interstitial tissue, in the air leaks into the alveolar spaces, with clinical management
spaces or in both decreasing the space
available for gas exchange
Pulmonary The lodging of a blood clot Often is a result of deep vein Small emboli resolve
Embolism in a pulmonary artery with thrombosis without serious morbidity,
subsequent obstruction of but large or multiple emboli
blood supply to the lung have poorer prognosis.
parenchyma.
Pulmonary Damage to alveoli cause Most common cause is The scarring is irreversible;
Fibrosis stiffening of the lung due to idiopathic; in some cases, however, some treatment
scarring of the lung tissue could be chronic exposure to can improve symptoms
dust, asbestos, grain dust, temporarily and improve
sugar cane, etc. quality of life
Pulmonary Increased blood pressure in Vasoconstriction of blood With treatment, prognosis is
Hypertension the lung vasculature vessels connected to the good
lungs
Sarcoidosis Inflammation of the body’s Granulomas (lumps) can form Many patients do not need
organs, mostly the lungs in the lungs, lymph, and skin treatment
Tuberculosis Airborne infectious disease Caused by bacillus Treatable with antibiotics,
that typically attacks the Mycobacterium tuberculosis but some strains can
lungs become resistant. Risk of
reoccurrence increases with
immunosuppression (such as
AIDS)

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 PULMONARY DISEASES & CONDITIONS: DEFINITION & PROGNOSIS

Obstructive vs. Restrictive Pulmonary Disease

Obstructive Disease Restrictive Disease
Definition Disease characterized by airflow limitation Restrictive disease due to alterations in lung
that is not fully reversible parenchyma & pleura. Difficulty expanding
lungs caused by a reduction in lung volumes
Airflow limitation is usually both progressive &
associated with abnormal inflammation Fibrotic changes within pulmonary
response of lungs to noxious particles & gases parenchyma or pleura due to idiopathic
pulmonary fibrosis, asbestos, radiation,
oxygen toxicity
Physical Cough/sputum production/ hemoptysis Dyspnea
findings Hypoxemia/hypercapnia Hypoxemia/hypocapnia
Dyspnea on exertion Crackles
Breath sounds decreased with adventitious Clubbing
sounds Cyanosis
Increased respiratory rate Shallow rapid breathing
Weight loss/anorexia Reduced cough effectiveness
Low diaphragm position May present with alterations in chest wall, or
Pursed lip breathing may present due to alteration in
Decreased elastic recoil neuromuscular apparatus
Cyanosis
Clubbing
Chest Hyperinflation Reduced lung volumes
X-ray Flattened diaphragms Diffused interstitial infiltrates
Findings Hyperlucency Pleural thickening
Atelectasis (in alterations in chest wall)
Pulmonary Decreased FEV & FVC Reduced Vital capacity
Function Increased RV & FRC Reduced FRC and TLC
Tests Decreased FEV1/FVC
Lung Decreased vital capacity Decreased vital capacity, residual volume, and
Volumes Increased residual volume & functional residual FRC
capacity
Examples Cystic Fibrosis Ankylosing spondylitis
COPD Scoliosis
Asthma Pectus excavatum
Bronchiectasis Tuberculosis
Bronchitis Pneumonia
Respiratory distress syndrome Arthrogryposis
Bronchopulmonary dysplasia Burns
Emphysema Scleroderma
Pleural Effusion
Pneumothorax
Pulmonary Edema and Hypertension
MS
MD
SCI
CVA

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 DIFFERENTIAL DIAGNOSIS OF THE PULMONARY SYSTEM

Differential Diagnosis of the Pulmonary System
Condition Features
Asthma Wheezing, chest tightness, SOB, cyanosis
Atelectasis Dyspnea, tachypnea, cyanosis, elevation of temp, drop in BP, substernal retractions, shock
Bronchiectasis Obstructive disease, difficulty clearing secretions; SOB, sputum with or without color,
hemoptysis, crackles, wheezes, loud breath sounds
Bronchitis Expectorating cough, dyspnea, wheezing, chest pains, fever, fatigue
(acute)
Bronchitis Expectorating cough, dyspnea, wheezing, chest pains, fever, fatigue
(chronic)
COPD shortness of breath, cough, sputum production, barrel chest
Cystic Fibrosis persistent cough/wheezing, sputum production, excessive appetite with poor weight gain,
salty skin and sweat, bulky/foul smelling stools
Emphysema Mostly shortness of breath, which begins gradually and worsens
Lofgren’s Fever, arthritis, enlarged lymph nodes, rash
Syndrome
Pancoast Shoulder/arm pain along distribution of 8th cervical nerve trunk and 1st/2nd thoracic nerve
syndrome/tumor trunks, weakness and atrophy of muscles of the hand, sensory loss/motor deficit in UE
Pleural effusion May be asymptomatic; dyspnea on exertion, chest discomfort, sharp/stabbing chest pains
made worse by coughing/breathing
Pneumonia Follows an upper respiratory infection, sudden/sharp chest pains, hacking/productive
cough, headache, fatigue, fever/chills, dyspnea, cyanosis, tachypnea, rust/green colored
purulent sputum. Look below to review the differences between the different types.
Pneumothorax Dyspnea, sudden/sharp pleural chest pain, fall in BP, weak/rapid pulse, normal respiratory
functions on the affected side cease, pain localized to affect side
Pulmonary Restlessness, anxiety, persistent cough, diaphoresis, slight dyspnea, problems w/ exercise,
Edema increased respirations,
Pulmonary Dyspnea, pleuritic chest pain, apprehension, persistent cough, hemoptysis, diaphoresis,
Embolism tachypnea, fever
Pulmonary Difficulty with inspiration, SOB, dry cough, unexplained weight loss, fatigue, aching
Fibrosis muscles & joints
Pulmonary Shortness of breath, fatigue, non-productive cough, angina, fainting, swelling of ankles
Hypertension and feet
Sarcoidosis No symptoms, wheezing, coughing, SOB, fatigue, night sweats
Tuberculosis fever, chills, night sweats, loss of appetite, fatigue, weight loss, chest pain, persistent
cough (sometimes blood)

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 DIFFERENTIAL DIAGNOSIS OF THE PULMONARY SYSTEM

Pneumonia

Aspiration Bacterial Viral Walking pneumonia
Foreign materials in Bacteria enters lung with Virus invades the cells From bacterial
bronchial tree (food, inhalation lining the airways and microorganism called
saliva, nasal alveoli mycoplasma pneumonia
secretions)
Incompetent Community or hospital Virus reaches lung by Spread through contact
swallowing acquired traveling in droplets with droplets from nose
mechanism through mouth and nose and throat of someone who
with inhalation has it
Generally, the right Bacteria live in upper Invade alveoli
middle and lower lung respiratory tract
lobes
CVA, MS, Alzheimer’s Infants, adults >65, long More common in children; Common in older children
disease, intoxication, term influenza and adults 3 days no
obvious cause
Pulmonary Medication for initial Prevents blood & nourishment Risk for osteoporosis (with
Embolism treatment from getting to a