Medical Surgical Nursing Lecture: Emergency Nursing PDF

Summary

This document is a lecture on emergency nursing, focusing on critical care nursing in an ICU setting. It details the philosophy, organization, and equipment of an ICU, providing an overview of the field.

Full Transcript

CRITICAL CARE NURSING (CCN)

is a specialized field of nursing focused on
caring for patients with life-threatening
(actual or potential) problems.
These patients require comprehensive care
and constant close monitoring.
ICU (Intensive Care Unit): A designated unit
in a hospital where high-dependency,
critically ill, and hemodynamically unstable
patients are housed.
ICU Nurse: A nurse trained with specialized
BASIC EQUIPMENT IN THE ICU
knowledge to deal with ICU patients.
Patient Areas:
PHILOSOPHY OF CRITICAL CARE NURSING
(CCNAPI) Oxygen Outlets: 3 outlets per bed.
Suction Outlets: 3 outlets (gastric, tracheal,
Holistic Care Approach:
and underwater seal).
Focuses on the bio-psycho-social-spiritual Compressed Air Outlets: 2 outlets per bed.
nature of human beings and their responses Power Outlets: 16 outlets per bed.
to illnesses rather than just the disease
Storage:
process.
Helps maintain the individual patient's Bedside storage for personal belongings
identity and dignity. care supplies
Emphasizes preventive care, risk factor linen and toiletries
modification, and education to reduce includes locking drawers and cabinets if
future patient admissions to acute care syringes or pharmaceuticals are stored at
facilities. the bedside.

Organizational Commitment: Additional Equipment:

The Critical Care Nurses of the Philippines, Hooks and devices for hanging
Inc. (CCNAPI) is dedicated to promoting infusions/blood bags
health and welfare for national multi-channel invasive monitors
development. ventilators
Supports professional and personal growth infusion pumps
and development. portable X-ray unit
Committed to ideals of service, equality, fluid and bed warmers
justice, and social progress. portable lights
defibrillators
PRINCIPLES OF CRITICAL CARE NURSING
anesthesia machines
Anticipatory Nursing Care difficult airway management equipment
Early Detection and Prompt Action
Emergency Alarm:
Expertise Supportive Care
Communication and Collaborative A cardiac arrest/emergency alarm button
Practice at every bedside, with automatic alerts to
Preservation of Patient’s Physiological the hospital telecommunications center,
Defenses central nursing station, ICU conference
Prevention of Infection room, staff lounge, and on-call rooms.
Crisis Intervention
Stress Reduction ADMITTING PATIENT IN THE ICU:
Ethical Principles PREARRIVAL AND ADMISSION QUICK CHECK
ORGANIZATION OF ICU ASSESSMENTS

Prearrival Assessment:

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1. Abbreviated Report on Patient: ✓ General communication, coping styles,
✓ Age anxiety and stress, expectations of
✓ Gender critical care unit, current stresses, family
✓ chief complaint needs.
✓ diagnosis 4. Spirituality:
✓ pertinent history ✓ Faith/spiritual preference, healing
✓ physiological status practices.
✓ invasive devices 5. Physical Assessment:
✓ equipment ✓ Nervous system, cardiovascular system,
✓ status of laboratory/diagnostic tests. respiratory system, renal system,
2. Room Setup: gastrointestinal system, endocrine,
✓ Complete room setup hematologic, and immune systems,
✓ including verification of proper integumentary system.
equipment functioning.
ONGOING ASSESSMENT TEMPLATE (BODY
Admission Quick Check Assessment: SYSTEMS AND ASSESSMENT PARAMETERS)

1. General Appearance: Consciousness level. 1. Nervous System:
2. Airway: Patency and position of artificial - LOC, pupils, motor strength, blood
airway (if present). pressure, heart rate and rhythm, heart
3. Breathing: Quantity and quality of sounds, capillary refill, peripheral pulse,
respirations, breath sounds, presence of patency of IVs, hemodynamic pressures
spontaneous breathing. and waveforms, respiratory rate, breath
4. Circulation and Cerebral Perfusion: ECG sounds, etc.
(rate, rhythm, and ectopy), blood pressure, 2. Cardiovascular System:
peripheral pulses, capillary refill, skin color, - Heart rate, rhythm, ECG, blood
temperature, moisture, presence of pressure, cardiac output data, etc.
bleeding, level of consciousness, 3. Respiratory System:
responsiveness. - Respiratory rate and rhythm, breath
5. Chief Complaint: Primary body system and sounds, color and amount of secretions,
associated symptoms. etc.
6. Drugs and Diagnostic Tests: Prior drugs, 4. Renal System:
current medications, review of diagnostic - Intake and output, color and amount of
test results. urinary output, BUN/creatinine values,
7. Equipment: Patency of vascular and etc.
drainage systems, functioning and labeling 5. Gastrointestinal System:
of all connected equipment, and allergies. - Bowel sounds, contour of abdomen,
color and amount of secretions, etc.
Comprehensive Admission Assessment: 6. Endocrine, Hematologic, and Immunologic
1. Past Medical History: Systems:
✓ Medical conditions and surgical - Electrolyte and glucose values, CBC
procedures. and coagulation values, WBC with
✓ Psychiatric/emotional problems, differential count, etc.
hospitalizations. 7. Integumentary System:
✓ Medications (prescription, over-the- - Color and temperature of skin,
counter, illicit drugs) and time of last intactness of skin, areas of redness, etc.
dose. 8. Pain/Discomfort:
✓ Allergies, review of body systems. - Assessed in each system.
2. Social History: 9. Psychosocial System:
✓ Age, gender, ethnic origin, height, - Response to interventions, mental status
weight, highest educational level, and behavioral responses, ability to
occupation, marital status, primary communicate needs and participate in
family members/significant others, care, sleep patterns, etc.
religious affiliation. PHYSIOLOGIC EFFECTS OF AGING (BODY
✓ Advance Directive and Durable Power SYSTEMS AND EFFECTS)
of Attorney for Health Care.
✓ Substance use (alcohol, drugs, 1. Nervous System:
caffeine, tobacco), domestic abuse, or - Diminished hearing and vision, short-
vulnerable adult screen. term memory loss, altered motor
3. Psychosocial Assessment: coordination, decreased muscle tone
and strength, slower response to verbal

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 and motor stimuli, increased sensitivity
to sedation, etc.
2. Cardiovascular System:
- Increased effects of atherosclerosis,
decreased stroke volume, decreased
myocardial compliance, increased
workload of heart, etc.
3. Respiratory System:
- Decreased compliance and elasticity,
decreased vital capacity, increased
residual volume, etc. CLASSIFICATION OF SHOCK
4. Renal System:
- Decreased glomerular filtration rate, 1. Primary (Initial Shock)
increased risk of fluid and electrolyte 2. Secondary (True Shock)
imbalances, etc. ✓ True Shock (Circulatory Shock): A
5. Gastrointestinal System: circulatory imbalance between oxygen
- Increased presence of dentition supply and oxygen requirements at the
problems, decreased intestinal mobility, cellular level.
altered nutritional states, etc. 3. Anaphylactic Shock: Type I immunologic
6. Endocrine, Hematologic, and Immunologic reaction.
Systems:
ETIOLOGICAL CLASSIFICATION
- Increased incidence of diabetes,
thyroid disorders, anemia, decreased 1. Hypovolemic Shock
antibody response, etc. 2. Cardiogenic Shock
7. Integumentary System: 3. Septic Shock
- Decreased skin turgor, increased
capillary fragility, decreased elasticity, Other Types:
etc.
1. Traumatic Shock
8. Miscellaneous:
2. Neurogenic Shock
- Altered pharmacokinetics and
3. Hypoadrenal Shock
pharmacodynamics, decreased range
of motion of joints and extremities, etc. TYPES OF SHOCK
9. Psychosocial System:
- Difficulty falling asleep, fragmented 1. Cardiogenic Shock
sleep patterns, increased incidence of ✓ Intracardiac Causes: Related to issues
depression and anxiety, cognitive within the heart itself, such as
impairment, etc myocardial infarction or valvular heart
disease.
SHOCK OVERVIEW ✓ Extracardiac Causes: Related to
conditions outside the heart, like
Shock is a life-threatening situation due to poor
pulmonary embolism or tension
tissue perfusion with impaired cellular
pneumothorax.
metabolism, leading to serious
2. Hypovolemic Shock
pathophysiological abnormalities. If untreated,
✓ Caused by a significant loss of blood
shock has a mortality rate of 20%.
volume due to hemorrhage,
Bailey and Love: Shock results from poor dehydration, or burns.
tissue perfusion with impaired cellular 3. Distributive Shock
metabolism. ✓ Characterized by severe peripheral
Davidson's: Shock is a clinical syndrome that vasodilation leading to inadequate
develops from critical impairment of tissue tissue perfusion despite normal or
perfusion due to acute circulatory failure. increased cardiac output.
Schwartz's: Shock is defined as the a. Sepsis: A systemic infection causing
inadequate delivery of oxygen and widespread inflammation and
nutrients necessary to maintain normal vasodilation.
tissue and cellular function. b. Neurogenic (Spinal Shock): Caused
Kumar and Parrillo (1995): Shock is a state by spinal cord injury leading to loss
where profound and widespread reduction of sympathetic tone and
of effective tissue perfusion leads to vasodilation.
reversible, and if prolonged, irreversible c. Adrenal Insufficiency: Inadequate
cellular injury. production of cortisol and

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 aldosterone, leading to
hypotension and shock.
d. Anaphylaxis: A severe allergic
reaction causing widespread
vasodilation and increased
capillary permeability.

Blood Pressure (BP) Regulation in Shock

BP = CO × SVR

BP: Blood Pressure

CO: Cardiac Output

SVR: Systemic (Peripheral) Vascular Resistance

If blood pressure is low in a shock state, it
indicates that either:

✓ CO is low: The heart is not pumping
enough blood, leading to decreased
cardiac output.
✓ SVR is low: There is reduced vascular
resistance, often seen in distributive
shock types like sepsis or anaphylaxis.

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 SHOCK - Orthostatic vital signs may be normal in
hypovolemic individuals, or normal
The common denominator in all forms of
individuals may exhibit orthostatic
shock is inadequate capillary perfusion.
changes; so use clinical judgment and
Shock is characterized by inadequate tissue
base treatment on symptoms. Alcohol
perfusion and cellular
ingestion, a meal, increased age,
hypofunction/hypoxia.
antihypertensives, etc., may cause
Total body cellular metabolism is
orthostatic changes in BP and pulse in
malfunctional, usually by inadequate
the absence of hypovolemia.
delivery of oxygen to meet cellular needs
Tachycardia: Usually present but may not
and occasionally of inability of cells to utilize
be, especially in the presence of
oxygen (methemoglobinemia, carbon
diaphragmatic irritation, which causes
monoxide poisoning).
vagal stimulation in neurogenic shock.
Shock has been recognized for over 100 Hypoperfusion: Including decreased urine
years, yet a clear definition is still not output, decreased mentation, cool
established. The definition of shock varies extremities, mottling, etc.
over time and has different meanings - Goal of resuscitation is to maintain urine
depending on the etiological and output between 30 and 60 ml/hr.
pathogenetic factors that caused it.
HYPOVOLEMIC SHOCK

CLASSIFIED BY ETIOLOGY is present when a marked reduction in
oxygen delivery results from diminished
(BY MARK A. GRABER, MD) cardiac output secondary to inadequate
volume of whole blood.
Departments of Family Medicine and
Emergency Medicine, University of Iowa Pathophysiology:
College of Medicine. Peer Review Status:
Externally Peer Reviewed by Mosby. When our body loses a lot of blood or fluids,
like from heavy bleeding, burns, or severe
1. Hypovolemic shock: from volume loss (e.g., vomiting or diarrhea.
dehydration, blood loss, burns). Since there is a lot of blood or fluids loss
2. Distributive shock: based on loss of vascular happens in our body, the heart can’t pump
tone (e.g., anaphylactic, septic, out enough blood throughout our body
bacteremic, toxic, neurogenic shock). organs
3. Cardiogenic shock: based on pump failure Since our body organs can’t get enough
(e.g., acute myocardial infarction, blood, our body’s organs don’t get enough
ventricular septal defect rupture, papillary oxygen, which is like running out of fuel.
muscle rupture, ventricular aneurysm, Without oxygen, your organs can’t work
severe aortic stenosis, arrhythmias, properly, and your body starts to struggle to
trauma—tension pneumothorax, keep things running smoothly.
pericardial tamponade, cardiac
contusion). To compensate, your body tries to adjust by:
4. Dissociative shock: based on the inability of
a. Speeding up your heart rate to try to
RBCs to deliver oxygen (e.g.,
pump what little blood is left.
methemoglobinemia, carbon monoxide
b. Narrowing your blood vessels to direct
poisoning).
blood to the most important organs, like
Most common clinical signs: the brain and heart, which is why your
skin might turn pale and cool.
Hypotension: Blood pressure drop is a late c. Breathing faster to get more oxygen
finding. into your system.
- An orthostatic systolic decrease of 10 to d. Decreasing your urine output, because
20 mm Hg or an increase in pulse of 15 your body tries to hold onto as much
beats/min is considered "significant." fluid as possible.
- Take orthostatic vital signs recumbent
and after standing for 1 to 2 minutes. Causes

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 ✓ External bleeding. especially when the host's defenses are
✓ Internal bleeding. weakened due to prolonged and severe
✓ The loss of a large amount of plasma due infections.
to extensive burns. Septic shock is sepsis with hypoperfusion
✓ The loss of fluids and electrolytes after and hypotension that are refractory to fluid
prolonged and severe diarrhea, therapy. When bacteremia causes critical
vomiting. reductions in tissue perfusion, septic shock
✓ An internal loss of fluids due to pleuritis or ensues.
peritonitis, acute pancreatitis.
Pathophysiology:
Note: The last three causes are sometimes
Happens when the blood vessels in your
named oligemic shock.
body lose their normal tone and become
Clinical signs: too relaxed or leaky. This leads to a problem
where blood can’t effectively circulate to
✓ Hypotension your organs and tissues, causing them to be
✓ Tachycardia deprived of oxygen and nutrients.
✓ Tachypnea Normally, your blood vessels stay slightly
✓ Oliguria tight to keep blood moving where it’s
✓ Anxious needed. In distributive shock, something
✓ Skin is pale and cool (like an infection) causes these vessels to
✓ Often, the patient may experience suddenly relax too much.
nausea and vomiting Because the blood vessels are too relaxed,
✓ Can be restless or comatose blood starts pooling in certain parts of your
body instead of being pumped evenly to
Laboratory determination:
important areas like the brain, heart, and
Arterial blood gases: pH is considered kidneys. This means your organs don’t get
normal (7.35-7.45), PaCO2 is 35-45 mm Hg. If enough blood to function properly.
pH < 7.35, this is associated with a normal or With blood not circulating properly, your
lower PaCO2 (metabolic acidosis). blood pressure drops.
In vomiting caused by stenosis of the pyloric When your organs (like the brain and
part of the stomach: alkalosis. kidneys) don’t get enough oxygen-rich
Serum electrolytes: In hemorrhagic shock, blood, they start to suffer. Over time, this
they are near normal; in diarrhea, potassium can cause serious damage, and multiple
(K) decreases; in vomiting, sodium (Na) organs can start to fail if the shock isn’t
decreases; in pancreatitis, calcium (Ca) treated quickly.
and potassium (K) decrease. In cases like septic shock (a type of
Creatinine: Useful as an indicator of renal distributive shock caused by an infection),
function. bacteria release toxins that further mess up
your blood circulation. Your immune
Treatment and management of hypovolemic system’s response to these toxins can also
shock principles: make things worse, causing inflammation
and more blood vessel problems.
Monitoring of blood pressure, urination,
Distributive shock is like a problem with the
breathing function, and heart rate (HR).
plumbing in your body. Blood isn’t flowing
Replacement of blood volume (e.g.,
where it should, which causes your organs
Ringer's lactate, solutions similar to plasma
to struggle and eventually leads to serious
in electrolyte composition, starch or gelatin
damage if not corrected.
solution, erythrocyte mass in cases of
bleeding). Causes:
Supplemental oxygen.
After resuscitation: surgical manipulations, Septic shock is often caused by hospital-
interventional radiology, endoscopy, and acquired gram-negative bacilli and
drug therapy. typically occurs in immunocompromised
patients or those with chronic diseases.
DISTRIBUTIVE SHOCK In about 1/3 of patients, it is caused by
gram-positive cocci and Candida
Septic, bacteremic shock is based on the
organisms.
loss of vascular tone. Bacteremia and septic
Shock caused by staphylococcal toxins is
shock are closely related conditions.
called toxic shock, a condition more
Bacteremic shock develops when high
frequently occurring in young women.
levels of bacteremia or fungus and its toxic
agents penetrate the bloodstream, Predisposing Factors:
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 Diabetes mellitus, cirrhosis, leukopenic ✓ oliguria
states, especially those related to
underlying neoplasms or cytotoxic Late signs
treatment. ✓ Cool and pale extremities with
Antecedent infections in the urinary, biliary, peripheral cyanosis and mottling.
or GI tracts.
Invasive devices like catheters, drainage As the condition progresses
tubes, and other foreign materials.
✓ multiorgan failure involving the kidneys,
Prior treatment with antibiotics,
lungs, and liver occurs, along with
corticosteroids, or ventilators.
disseminated intravascular coagulation
SEPTIC SHOCK (DIC) and heart failure.

occurs more often in newborns, patients over 35 Laboratory Findings:
years of age, pregnant women, and those who
Leukocytosis with a marked shift to the left,
are severely immunocompromised due to
associated with a sharp decrease in
underlying diseases or iatrogenic complications
platelet count to ≤ 50,000/µL
from treatment.
respiratory alkalosis
Pathogenesis: metabolic acidosis
toxic anemia
The bacterial toxins generated by infecting positive blood cultures.
organisms trigger complex immunologic
reactions. Various mediators, including TNF, Management of Distributive Shock
leukotrienes, lipoxygenase, histamine,
Patients should be treated in an ICU, with
bradykinin, serotonin, and IL-2, along with
frequent monitoring of:
endotoxin (from the lipopolysaccharide
component of gram-negative bacilli cell systemic pressure
walls), play a role. arterial and venous blood Ph
arterial blood gas levels, blood lactate
WARM SHOCK
levels
Initially, vasodilation of arteries and renal function, electrolyte levels
arterioles occurs, decreasing peripheral possibly tissue PCO2
arterial resistance with normal or increased Urine output should be measured (usually
cardiac output, even though the ejection with an indwelling catheter) as an
fraction may decrease when heart rate indication of splanchnic blood flow and
increases. visceral perfusion.
The CVP or pulmonary artery pressure
COLD SHOCK should be measured, and fluid
Later, cardiac output may decrease, and replacement should be given until the CVP
peripheral resistance may increase. reaches 10-12 cm H2O or until the
Despite increased cardiac output, blood pulmonary wedge pressure reaches 12-15
flow to capillary exchange vessels is mmHg.
impaired, reducing oxygen delivery and Respiration should be supported with nasal
waste removal. O2, tracheal intubation or tracheostomy,
This decreased organ perfusion particularly and mechanical ventilation as necessary.
affects the kidneys and brain, eventually Parenteral antibiotics should be given after
causing failure of one or more visceral specimens of blood, body fluids, and
organs. wound sites have been taken for Gram stain
Ultimately, cardiac output declines, and and culture. Prompt empiric therapy is
the typical features of shock appear. essential.
The choice of an antibiotic requires an
Clinical Signs: educated guess based on previous culture
results from the primary infection site or the
✓ Altered mental alertness clinical setting where the infection
✓ shaking chills occurred.
✓ rapid rise in body temperature
✓ blood pressure decreased to < 80 RARE CASES OF SHOCK
mmHg
✓ warm skin (paradoxically warm Shock Due to Hormonal Insufficiency:
extremities) ✓ This type of distributive shock occurs
✓ tachycardia due to insufficiency in hormones such as
✓ tachypnea those from the thyroid gland (thyroid) or
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 pituitary gland (hypophysis), among
others.
Neurogenic Shock:
✓ This type of distributive shock is
characterized by hypotension
secondary to central nervous system
dysfunction, resulting from the
disruption of the sympathetic nervous
system.
✓ The main causes include trauma or
lumbar anesthesia, which lead to
vasomotor dysfunction and paralysis.
✓ This causes vasodilation and decreased
vascular resistance, resulting in blood
insufficiency in the circulatory system.
Shock Due to Hyperergic Reactions:
✓ This type of distributive shock develops
as a result of allergic reactions in
patients who are hypersensitive to
various antigens.

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 ECG READING & INTERPRETATION - This means that for every second of
heart activity being recorded, the
Electrocardiography (ECG) is a precise paper moves 25 millimeters horizontally.
method used to measure and monitor the 2. Horizontal Measurements:
electrical activities of the heart - Large Box: On the ECG paper, one
It is captured via external electrodes— large box (which is 5 mm wide)
conductive pads attached to the patient’s represents 0.2 seconds (or 200
chest and limbs. milliseconds).
The electrical signals are transcribed onto - Small Box: Each small box (which is 1
graph paper, which is marked with a grid of mm wide) within the large box
small and large squares. represents 0.04 seconds (or 40
Small square: Represents 40 milliseconds). This helps in accurately
milliseconds (ms) along the horizontal measuring the time intervals between
axis. different parts of the heart's electrical
Large square: Contains 5 small squares, activity.
representing 200 ms. 3. Vertical Measurements:
The standard paper speeds and square - Vertically, the large box represents 0.5
markings facilitate the measurement of Mv (millivolts). This measurement is
cardiac timing intervals, enabling the important for assessing the amplitude
calculation of heart rates and the (height) of the electrical signals, which
identification of abnormal electrical corresponds to the strength of the
conduction within the heart. heart's electrical impulses.
Any disturbances in the heart's electrical
activity can result in various types of
arrhythmias, which may lead to serious
consequences, including death.

MAJOR COMPONENTS OF THE ELECTRICAL
ACTIVITIES OF THE HEART:

4. Grid Layout:
- The grid on the ECG paper is designed
to allow easy and accurate
measurement of both time
(horizontally) and voltage (vertically).
The image shows a 3-second interval
represented by 15 large boxes, each
marking 0.2 seconds.

The grid and the standard measurements make
it easier for healthcare professionals to analyze
the ECG tracing, identify heart rates, and
detect abnormalities in the heart's electrical
conduction.

THE ECG PAPER

1. ECG Machine Speed:
- The ECG machine operates at a
standard speed of 25 mm/second.
scale of voltage, measured on the vertical

axis, against on time the horizontal axis

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 THE ECG LEADS

ECG leads are the graphical representation of
the depolarization of the heart.

6 PRECORDIAL LEADS

These leads capture the electrical activity of the
heart in a horizontal plane.

V1: 4th intercostal space, right parasternal
region
V2: 4th intercostal space, left parasternal
region
V3: Midway between V2 and V4
V4: 5th intercostal space, left midclavicular
line
V5: 5th intercostal space, left anterior
axillary line A wave is a deflection of the ECG line
V6: 5th intercostal space, left midaxillary line resulting from a change in the electrical
activity of the heart.
Waves can be categorized based on the
direction and characteristics of their
deflection:
Positive Deflection (Upward): The
electrical impulse is moving toward the
electrodes.
Negative Deflection (Downward): The
electrical impulse is moving away from
the electrode.
Equiphasic (Equally Upward and
Downward): The electrical impulse is
1. Limb Leads moving perpendicular to the electrode.
I, II, III: These leads capture the Other Waves: Waves can form
electrical activity of the heart in a complexes, such as the QRS complex.
vertical plane.
aVL, aVF, aVR: These are augmented
limb leads that also capture the heart's
electrical activity in a vertical plane.

ANATOMICAL RELATIONSHIP OF LEADS
LIMB PRECORDIA CORRESPONDIN
LEADS L G
HEART THE P WAVE
STRUCTURE
INFERIOR II N/A Inferior
LEADS III surface of
The P wave represents atrial depolarization.
Avf the heart It occurs when the sinus node, also known
LATERAL I V5 Left
LEADS aV V6 ventricle,
as the sinoatrial (SA) node, creates an
L lateral wall action potential that depolarizes the atria.
ANTEROSEPTA N/ V1-V4 Anterior
L LEADS A wall of
Appearance in Lead II: The P wave appears
both upright in lead II if the action potential is
ventricles
Posterior
originating from the SA node.
wall of the Sequence: Each P wave should be followed
left
ventricle by a QRS complex

ECG COMPONENTS

WAVE, SEGMENT, INTERVAL

WAVE

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 THE QRS COMPLEX ✓ There are no specific disease conditions
that elevate or depress the T-P segment.
The QRS complex, which includes the Q Tachycardia Effects:
wave, R wave, and S wave, represents ✓ During tachycardia, the T-P segment is
ventricular depolarization. shortened and may become difficult to
The normal duration (interval) of the QRS visualize.
complex is between 0.08 and 0.10 seconds ✓ It is important to examine the T-P
(80 to 100 milliseconds). segment closely for the presence of U
When the QRS duration between 0.10 and waves or atrial activity, as these could
0.12 seconds is considered intermediate or indicate pathology.
slightly prolonged.
A QRS duration greater than 0.12 seconds is QT INTERVAL
considered abnormal.
Lengthening of QRS Duration: QRS duration The QT interval is the time span from the
lengthens when electrical activity takes beginning of the QRS complex
longer to travel through the ventricular (representing ventricular depolarization) to
myocardium. the end of the T wave (resulting from
Normal Conduction System: ventricular repolarization).
✓ The normal conduction system in the Assessing Prolongation:
ventricles is called the His-Purkinje ✓ To determine if the QT interval is
system, which consists of cells that prolonged, check if the T wave ends
conduct electricity rapidly. beyond the halfway point between two
✓ Normal conduction of an electrical R waves (the RR interval).
impulse through the atrioventricular ✓ If the T wave ends past this halfway
(AV) node and then to the ventricles via point, the QT interval is considered
the His-Purkinje system is fast, resulting in prolonged.
a normal QRS duration.
Widened QRS Duration:
✓ When electrical activity bypasses the
His-Purkinje system and instead travels
from myocyte to myocyte, more time is
needed, leading to a widened QRS
duration.
S WAVE
THE T WAVE
The S wave is the first downward deflection
The T wave occurs after the QRS complex of the QRS complex that occurs after the R
and is the result of ventricular repolarization. wave. However, an S wave may not be
Appearance: T waves should be upright in present in all ECG leads for a given patient.
most leads, with exceptions in aVR and V1. Normal ECG Appearance:
T waves should be asymmetric, with the ✓ In a normal ECG, a large S wave is
second portion having a steeper decline typically seen in lead V1, which
compared to the incline of the first portion. progressively becomes smaller, with
Symmetry and Pathology: If the T wave almost no S wave present in lead V6.
appears symmetric, it may indicate cardiac Pathological Changes:
pathology, such as ischemia. ✓ A large, slurred S wave is seen in leads I
and V6 in the presence of a right bundle
branch block.

THE T-P SEGMENT

The T-P segment is the portion of the ECG
that runs from the end of the T wave to the
beginning of the P wave.
Baseline Reference:
✓ This segment should always be at S-T SEGMENT
baseline and is used as a reference to
The S-T segment represents the interval
determine whether the ST segment is
between ventricular depolarization and
elevated or depressed.
repolarization.
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 Appearance: It typically appears as a ✓ Idiopathic Ventricular Fibrillation
horizontal isoelectric line but may slope ✓ Hypercalcemia
upward slightly before the onset of the T ✓ Hypothermia
wave.
Extent: The S-T segment extends from the J
point (the end of the QRS complex) to the
start of the T wave.

ETIOLOGY

Normal Findings: Small, concave elevation
U WAVE
seen in young, healthy adults, often due to
early repolarization. The U wave is a small deflection that occurs
STEMI (ST-Elevation Myocardial Infarction): after the T wave.
Significant S-T elevation associated with The polarity of the U wave is the same as
myocardial infarction (MI). that of the T wave.
LBBB (Left Bundle Branch Block): S-T Best seen in leads V2 to V4, but it is not
elevation can be seen in the presence of a always visible.
left bundle branch block. A normal finding in athletes.
Pericarditis: Widespread S-T elevations
throughout the ECG. ETIOLOGY
Pulmonary Embolism: S-T elevation may
The exact cause of the U wave is unknown,
occur as a result of a pulmonary embolism
but it is thought to be due to delayed
Brugada Pattern: A specific ECG pattern
repolarization of myocardial cells or the His-
that includes S-T elevation, often associated
Purkinje system.
with a risk of sudden cardiac death.
Most prominent in patients with:
Left Ventricular Aneurysm: Persistent S-T
✓ Hypokalemia
elevation may indicate a left ventricular
✓ Hypercalcemia
aneurysm.
✓ Bradycardia

COUNTING THE HEART RATE

Heart Rate

The standard ECG paper speed is 25
mm/sec, equivalent to 5 large squares per
second.
S-T DEPRESSION ETIOLOGY If the interval between two beats (R-R
interval) is 5 large squares, the heart rate
Down sloping ST depression Subendocardial
or horizontal ST depression myocardial ischemia (HR) is 60 beats per minute.
Stress-induced The HR can be quickly estimated by dividing
myocardial Ischemia
Reciprocal change from
300 by the number of large squares
myocardial Infarction between two heartbeats (R-R interval).
Upsloping of s-t depression Normal during
✓ 1 large square → HR = 300 beats/min
tachycardia
May indicate ✓ 2 large squares → HR = 150 beats/min
myocardial ischemia if ✓ 3 large squares → HR = 100 beats/min
the clinical feature
suggests acute coronary ✓ 4 large squares → HR = 75 beats/min
syndrome ✓ 5 large squares → HR = 60 beats/min
Sagging of s-t segment Digoxin
depression ✓ 6 large squares → HR = 50 beats/min
Secondary repolarization Ventricular hypertrophy
abnormalities LBBB
Non-specific s-t segment Hypokalemia
depression

J WAVE The R-R interval in this illustration is between 2-3
squares so then the HR is between 150-100 or
The J wave is a positive deflection that
+/- 120
occurs between the QRS complex and the
S-T segment. Irregular Heart Rhythm
It marks the point where depolarization
ends and repolarization begins. When a patient’s heart rhythm is irregular,
Conditions Associated with J Waves: the standard method of heart rate
✓ Brugada Syndrome calculation (using the R-R interval) is

4|E M E R G E N C Y N U R S I N G | LESSON 3 JADE B.BURI
 ineffective because the R-R interval varies Uniform P Waves: All P waves should be
significantly throughout the ECG. uniform in shape.
Alternative Calculation Method: Normal P Wave Axis:
✓ Count the Number of Complexes: ✓ The P wave axis should be in the left
Count the total number of QRS lower quadrant (0-90 degrees).
complexes on the rhythm strip. ✓ This typically means the P wave is
✓ Calculate Heart Rate: upright in both lead I and lead aVF,
- For an irregular QRS rhythm, use the except in cases of dextrocardia.
formula:
R-R INTERVAL AND SINUS ARRHYTHMIA:
HR = 6 × Total Number of QRS
Complexes The R-R interval in NSR does not have to be
identical and may vary with breathing, a
- This gives the average heart rate in phenomenon known as sinus arrhythmia.
beats per minute by estimating the Sinus arrhythmia is more noticeable at
number of complexes over 1 slower heart rates.
minute. 1. Heart rate increases during inspiration
✓ Example: due to:
- 10 complexes on a rhythm strip - Increased venous return
- 10 x 6 = 60 beats per minute - Increased sympathetic tone
2. Heart rate increases during expiration
DETERMINE THE HEART RYTHM due to:
HEART RHYTHM - Decreased venous return
- Increased parasympathetic tone

ATRIAL RHYTHM

Characterized by narrow QRS complexes
are preceded by P waves that do not meet
one or more of the normal sinus rhythm
Irregularly Irregular (NSR) criteria.
If P wave morphology changes, it may
(Atrial Fibrillation)
suggest a multifocal origin, a condition
Cardiac muscle cells (myocytes) possess known as a "wandering pacemaker."
inherent automaticity, meaning they can
AV NODAL OR JUNCTIONAL RHYTHM
generate an electrical impulse on their
own. Characterized by narrow QRS complexes
The sinoatrial (SA) nodal cells have the that are not preceded by P waves.
fastest automaticity, acting as the heart's An inverted P wave may appear after the
natural pacemaker, and therefore control QRS complex due to retrograde
the heart rate and rhythm. conduction.
There are four levels of conduction and
potential pacemakers in the heart, VENTRICULAR RHYTHM
arranged from fastest to slowest:
Characterized by wide QRS complexes that
✓ SA Node rhythm
are not preceded by P waves.
✓ Atria rhythm
✓ AV Node or junctional rhythm HIERARCHY OF PACEMAKER CONTROL
✓ Ventricles rhythm
If the heart rhythm is not sinus (originating If the sinus node fails to initiate the impulse,
from the SA node), it is important to an atrial focus will take over as the
determine the origin of the pacemaker and pacemaker, usually resulting in a slower
identify where the impulse is initiated. heart rate than NSR.
If the atrial focus fails, the AV node assumes
SA NODAL RHYTHM (NORMAL SINUS RHYTHM) control as the pacemaker.
If the AV node fails, the ventricular focus,
The sinus node is located at the junction of
the slowest of all, will take over as the
the superior vena cava (SVC) and the right
pacemaker.
atrium.
Each time the pacemaker focus is
CRITERIA FOR SINUS RHYTHM: downgraded (from sinus node to atrial, AV
node, or ventricular focus), the heart rate
P Wave Before Each QRS Complex: There becomes slower due to the inherent
must be one P wave preceding each QRS automaticity of the pacemaker cells at
complex. each level.
5|E M E R G E N C Y N U R S I N G | LESSON 3 JADE B.BURI
 HEART BLOCKS In adults, the normal cardiac axis ranges
between -30° and +90° (from
FIRST-DEGREE HEART BLOCK approximately 11:00 o'clock to 5:00 o'clock
Sinus rhythm with first-degree heart block is on a clock face).
characterized by a sinus rhythm with a
prolonged PR interval greater than 0.20 If electrical activity is travelling towards
seconds. an ECG lead, there will be a positive
deflection
The prolonged PR interval is due to a delay
If the electrical activity is travelling away
in the transmission of electrical impulses
from an ECG lead, there will be a
from the atria to the ventricles
negative deflection

Determining the Cardiac Axis:

The cardiac axis can be determined by
analyzing leads I, II, and III on the ECG.
SECOND-DEGREE AV BLOCK
✓ The overall direction of electrical
Mobitz Type I (Wenckebach): Progressive activity is toward these leads (I, II, III)
lengthening of the PR interval until a QRS ✓ This results in a positive deflection in all
complex is eventually dropped. three leads, with lead II typically
Mobitz Type II: Intermittent dropping of QRS showing the most positive deflection
complexes without the progressive PR since it is most closely aligned with the
interval lengthening seen in Mobitz Type I. overall direction of electrical spread
Mobitz Type II must be carefully evaluated, ✓ The lead aVR typically shows the most
as it can rapidly progress to a complete negative deflection because it views
heart block. the heart in the opposite direction of
the normal electrical activity.

THIRD-DEGREE HEART BLOCK (COMPLETE HEART
BLOCK)

Third-degree heart block, also known as
complete heart block, is a rhythm in which
there is no relationship between the P METHODS OF DETERMINING CARDIAC AXIS
waves and the QRS complexes.
Characteristics: 1. Isoelectric (Equiphasic) QRS Method
✓ The P to P intervals are regular. Identify the lead in which the QRS
✓ However, the P waves have no complex is isoelectric (equal positive
consistent relationship with the QRS and negative deflections).
complexes on the ECG. Determine the two leads that are
perpendicular to the identified
isoelectric lead on the Cabrera circle.
The cardiac axis corresponds to the
lead that is perpendicular to the
isoelectric lead.
This method is generally more accurate
than the Lead I and aVF method.
CARDIAC AXIS 2. Lead I and aVF Method
Determine the polarity of the QRS
The cardiac axis represents the overall
complex in leads I and aVF.
direction of electrical spread within the
✓ Positive QRS Complex: The area
heart
above the isoelectric line and under
The cardiac axis represents the mean
the curve is larger than the area
direction of ventricular depolarization in the
below the isoelectric line.
frontal plane.
6|E M E R G E N C Y N U R S I N G | LESSON 3 JADE B.BURI
 ✓ Negative QRS Complex: The area Antithrombotic therapy is recommended
below the isoelectric line and for all patients with AF except those with
above the curve is larger than the lone AF or contraindications (Level A).
area above the isoelectric line. Chronic oral anticoagulant therapy with a
Approximate the cardiac axis by vitamin K antagonist is recommended in a
evaluating the combinations of QRS dose to achieve the target INR of 2.0 to 3.0
complex polarities in leads I and aVF: unless contraindicated (Level A). This is for
✓ Positive in both leads I and aVF: patients without mechanical heart valves
Normal axis. at high risk of stroke (prior stroke, TIA, or
✓ Positive in lead I and negative in systemic embolism; rheumatic mitral
aVF: Left axis deviation. stenosis),
✓ Negative in lead I and positive in Anticoagulation with a vitamin K antagonist
aVF: Right axis deviation. is recommended for patients with more
✓ Negative in both leads I and aVF: than one moderate risk factor (age >75,
Extreme right axis deviation. hypertension, HF, LVEF