Advanced Skill Theory - Final Exam Review PDF

Summary

This document provides a review of advanced skill theory, focusing on topics like respiration, ventilation, oxygenation, and related concepts. It includes definitions, descriptions, and an overview of the various physiological processes involved. The document also explains terms like ETCO2 and Capnography.

Full Transcript

Advanced Skill Theory – Final Exam Review

EtCO2
Respirations:
The process by which oxygen and carbon dioxide diffuse in and out of the blood.
Also referred to as gas exchange that occurs in two areas of the body – external and
internal.
External Respiration: refers to gas exchange across the respiratory membrane in the lungs.
Internal Respiration: refers to gas exchange across the respiratory membrane in the
metabolizing tissues (ie. Skeletal muscles).
Ventilation:
Pulmonary Ventilation: the process by which oxygen enters, and carbon dioxide exits
the alveoli. Ventilation is the act or process of inhaling and exhaling – the movement of
air.
Oxygenation: Refers to the process of adding oxygen to the body system – how we get O2 to the
tissues.
SPO2: Saturation of peripheral capillary oxygenation. Pulse oximetry measures oxygen
saturation levels.
Noninvasive measurement – finger probe
% of oxygen bound to red blood cells
Issue: changes in ventilation can take minutes to be detected/artifact secondary to
motion/circulatory status/nail polish.
EtCO2: Measures ventilation status. Is the CO2 in the airway at the end of exhalation.
Noninvasive measurement – “snapshot” of patients’ ventilatory status.
Provides reading for every breath – so results are within seconds.
Not affected by motion/circulatory status.
100% sensitive/100% specific.
Ventilation + Circulation + Metabolism = Gas Exchange
Dead Air Space:
Ventilated areas that do not participate in gas exchange.
 Total physiological dead air space = Anatomic Dead Space (airways leading to the
alveoli) + Alveolar Dead Space (ventilated areas in the lungs without blood flow) +
Mechanical Dead Space (artificial airways – including ventilator circuits)
Capnography:
Represents the amount of CO2 in exhaled air.
Partial pressure of CO2 at the end of exhalation.
Normal: 35-45mmHg
Nasal prongs or attachment on BVM
Respiratory Effort:
Healthy lungs – brain responds to changes in CO2 levels in the blood, controlling
ventilation, this is assessed by chest rise and fall, respiratory effort, breath sounds, and
counting respiratory rate.
As CO2 rises, respiratory rate should increase because the body wants to blow off some
CO2.
As CO2 falls, respiratory rate should decrease in order to retain CO2.
Generally:
ETCO2 less than 35mmHg (hyperventilation/hypocapnia) – you should hypoventilate the
patient to increase their CO2 levels.
ETCO2 greater than 45mmHg (hypoventilation/hypercapnia) – you should hyperventilate
the patient to increase their CO2 levels.
Why Use Capnography?
To assess when patient is ventilated (SGA/ETT) – two primary and one secondary
Primary Secondary
Visualization ETCO2
Auscultation EDD
Chest rise Other

How is ETCO2 Measured?
Quantitative – an actual numeric value usually associated with an electronic device (35-
45mmHg)
Semi-Quantitative (Qualitative) – devices that give a range vs an actual number (low,
medium, high)
Wave Form Capnography
Blood Gasses:
 PaCO2 – partial pressure of carbon dioxide in arterial blood gasses. The PaCO2 is
measured by drawing the ABGs, which also measures the arterial PH.
If ventilation and perfusion are stable, PaCO2 should correlate with PetCO2.
The Waveform:
Capnogram waveform begins before exhalation and ends with inspiration.
Phase 1 (A-B) – inspiratory baseline (low CO2 as it is inspired air)
B – the start of alveolar exhalation
Phase 2 (B-C) – exhalation upstroke (dead space gas mixes with lung gas)
Phase 3 (C-D) – continuation of exhalation (gas is all alveolar now, rich in CO2)
D – end tidal value, peak concentration
Phase 4 (0) (D-E) – start of inspiration
Abnormal Values and Wave Forms:
Sudden Loss of Waveform:
Tube disconnected, dislodged, kinked, or obstructed
Loss of circulatory function
Decreasing ETCO2:
Tube cuff leak
Tube in hypopharynx
Partial obstruction
CPR Assessment:
Attempt to maintain a minimum value of 10mmHg
Sudden Increase in ETCO2:
Return of spontaneous circulation (ROSC)
Bronchospasm (Shark Fin Appearance):
Asthma
COPD
Why the slope – because movement of air at the alveoli is delayed, the rise to the plateau
is more gradual and the plateau itself becomes sloped.
Hypoventilation:
Long/wide, stretched out
Hyperventilation:
Short and quick
Decreased ETCO2:
Apnea
Sedation
Hyperventilation - Low CO2 Levels:
When a person hyperventilates, their CO2 levels go down. They are blowing off large
amounts because of the increased rate of breathing.
Can be caused by many factors - anxiety, bronchospasm, pulmonary embolus.
Other reasons ETCO2 may be low – cardiac arrest, hypotension, decreased cardiac
output, cold.
Hypoventilation – High CO2 Levels:
When a person hypoventilates, their CO2 levels go up. They are retaining CO2 due to the
slow rate of breathing.
Can be caused by – overdose, sedation, intoxication, postictal states, head trauma, stroke,
tiring CHF.
Other reasons ETCO2 may be high – fever, sepsis.
ETCO2 and Cardiac Output:
When cardiac output (blood flow) is normal – ETCO2 measures ventilation.
When cardiac output (blood flow) is decreased – ETCO2 measures cardiac output.
ETCO2 in Cardiac Arrest:
Cardiac arrest is the ultimate shock state – there is no circulation, no metabolism, and no
CO2 production unless effective CPR is being done.
Capnography provides feedback on the quality of CPR.
ETCO2 of 18
The longer the shaft, the slower the flow (friction loss)
16 Gauge – adolescents & adults only, critical trauma/burns, patients requiring large
amounts of fluids
18 Gauge – adolescents & adults only, fluid resuscitation, colloid infusion
20 Gauge – children, adults, & adolescents, most infusions requiring medication, TKVO
lines, smallest size for colloid infusion
22 Gauge – infants, toddlers, children, adolescents & adults (especially elderly patients),
TKVO infusions, minor medication needs
Flow Rate Complications:
Venous pressure – position of patients’ extremity (arm bent)
Vein spasm – irritating, or chilled fluids = reflex to occur
Phlebitis & Thrombi – initial decrease in flow rate due to spasm = inflammation to vein
or clot formation
Viscosity – thickness of fluid (high concentrations of dextrose tend to flow at a slower
rate)
Amount of fluid in the bag – approx. 150cc if flow is affected
Needle or gauge size – the smaller the needle, the slower the flow
Height of fluid container – approx. 3’ above the site
Needle/cannula position – cannula may be making contact at the valve/vein wall
Tubing occlusions – kinking/pinched in the stretcher
Infiltration – cannula actually slips out of vein = edema at interstitial site
Local Complications:
Infiltration – dislodgement of catheter or needle cannula, puncture of distal vein wall,
leakage of solution/medication into surrounding tissue, poorly secured IV, poor vein site
selection, irritating solution, improper cannula size, high delivery rate/pressure of
solution/medication. Causes coolness of skin around IV site, swelling, sluggish or absent
flow rate, infusion continues to infuse when pressure is applied to the vein, and no
backflow of blood into IV tubing when clamp is fully opened.
Hematoma – when amounts of blood collect outside of the vessel after catheter passes
through the vein. Causes redness, tenderness, pain, and swelling.
 Phlebitis – inflammation of the vein caused by injury to the vessel wall. Causes pain,
swelling, redness, and tenderness.
Local Infection – infection only present at or around the IV site, present after the IV
initiation. Signs and symptoms occur usually 3-4 days after IV; redness, foul discharge or
odor at site.
Systemic Complications:
Contamination and infection
Hypersensitivity reactions
Sepsis
Emboli (blood clot, air, and catheter)
Air Embolism – caused by air entering the bloodstream via the catheter tubing, risk is
greatest when catheter is passed into central circulation (ie. Jugular vein). Signs and
symptoms include hypotension, cyanosis, weak and rapid pulse, and loss of
consciousness.
Peripheral IV Procedure:
Apply gloves
Select puncture site
Apply tourniquet
Prepare puncture site – cleanse
Remove protective cover from catheter
Avoid puncture sites where there is injury or disease to an extremity
Stabilize vein by applying distal pressure and tension to the point of entry
With the bevel of the needle up, pass through the skin directly into the vein (from the side
or directly on top)
Advance the needle and catheter about 2mm beyond the point where blood returned in
the hub
Slide catheter over needle and into the vein
Release tourniquet
Secure hub with opsite
Apply pressure on proximal end of catheter to stop escaping blood
Withdraw needle while stabilizing catheter
Attach IV tubing
Open tubing clamp and allow fluid infusion to begin
Anchor tubing
Secure catheter
Document procedure
 Fluid Bolus Vs TKVO

Bolus – Rapid infusion of fluid, rate is as fast as it can go. Macro drip sets.
TKVO – to keep the vein open. Infusions that are set to a slow rate because the sole purpose
is to keep the line patent.

Cardiac Diseases

Atherosclerosis:
Thickening of the artery wall from accumulation of fatty material.
Chronic disease
Affects all the arteries, but primarily coronary, renal, aortic, femoral, carotid, and
cerebral.
Causes the majority of heart attacks.
Creates issues as it leads to narrowing of the vessels and reduction of blood flow through
them.
2 Mechanisms – chronic gradual narrowing and acute infarction (MI)
Angina Pectoris:
Also known as chest pain
Occurs when there is a deficiency of O2 for the heart muscle
Can occur when the heart is working harder than normal
Stable Angina:
Typically follows the same pattern for the patient – predictable pain, location, severity.
Insufficient O2 supply – anerobic metabolism and accumulation of lactic acid and CO2
(typically lasts 1-5 minutes and is relieved by rest)
Unstable Angina:
Same etiology as stable, however, the pain is more severe, different feeling as it is not as
easily relieved by rest or meds.
Plaque build up is bigger or ruptured.
Typically lasts longer than 15 minutes.
Often indicative of pre-MI angina
Does not follow the same pattern as their usual angina.
Greater degree of obstruction of the coronary arteries
High risk of imminent MI
Signs and symptoms of Angina:
Recurrent, intermittent episodes of substernal chest pain, usually triggered by physical or
emotional stress
Tightness or pressure in the chest that often radiates into the neck or left arm
Pallor, diaphoresis, and nausea
Acute Coronary Syndrome:
Results from a prolonged cardiac disorder causing myocardial ischemia or infarction
STEMI, Non-STEMI, and unstable angina
Typically caused by a rupture of the plaque in the arteries and subsequent thrombosis or
the coronary artery
Acute Myocardial Infarction (AMI):
Part of the coronary muscle is deprived of blood flow until that part subsequently dies
(infarcts)
Most common cause is plaque ruptured and thrombus formation (can also occur from
spasm of coronary artery)
Classified as either STEMI or Non-STEMI
Location and size of the MI depends on which coronary artery is blocked
Infarcted tissue area is inevitably surrounded by a ring of ischemic tissue, this is
relatively deprived of O2 but still viable
Ischemic tissue often is electrically unstable, this causes cardiac arrhythmias
Most deaths from MI are from arrythmias
Signs and Symptoms – CHEST PAIN, pain usually felt just beneath the sternum or the
left side of the chest, described as heavy, squeezing, crushing or tight, patient
unconsciously clenches fist when describing the pain (levine sign), may also describe as
pressure or discomfort, may mistake the pain for indigestion.
Signs and symptoms or silent MI – sudden dyspnea, pulmonary edema, hypotension,
confusion, profound fatigue, or feeling weak.
Sign and symptoms of MI in women – nausea, lightheadedness, epigastric burning,
sudden onset of weakness or unexplained tiredness
Other Signs of an MI – pain (sudden, substernal chest pain that can radiate into the jaw,
neck, and left arm, usually described as severe, steady, and crushing – no relief with
vasodilators), non pain (silent MI – gastric discomfort described as indigestion), pallor,
diaphoresis, dizziness, weakness, anxiety and fear, hypotension, rapid and weak pulse,
dyspnea.
Dissecting Aortic Aneurysm:
Aorta is subjected to massive hemodynamic forces, leads to degenerative changes in the
middle layer of the aorta
Over time, these changes in the middle layer lead to a tearing of the inner layer
 Once this is torn, dissection begins
Blood gets pumped into the unnatural layer between the inner and middle layer, this then
chronically stretches and weakens the vessel
Signs and symptoms – middle aged or older (chronic hypertension), main complaint is
chest pain (often described as the worst pain they have ever felt, ripping or tearing), pain
usually comes on suddenly, located in the anterior chest or the back (between the
shoulder blades) and can radiate into the back or abdomen, difference in BP between the
two arms (disruption of blood flow through the brachiocephalic or left subclavian artery)
Signs and symptoms depend on the site of the tear and the extent of the dissection
Hypertensive Emergencies (Hypertension):
Major cause of many cases of MI, heart failure, and stroke
Most often a result of advanced atherosclerosis or arteriosclerosis
Most common complications include renal damage, stroke, and heart failure
Blood pressure at rest consistently greater than 130/80mmHg
By the time symptoms start to occur, hypertension is already in a more advanced stage
and has probably produced at least some damage to organs such as the heart, kidneys, and
brain.
Common signs and symptoms – headache, blurred vision, buzzing in the ears, chest pain,
and altered LOC

Respiratory Diseases

Dyspnea:
Subjective feeling of discomfort that occurs when a person is unable to inhale enough air
Orthopnea:
SOB that occurs when a person is lying down, results as blood pools in the lungs with
gravity
Cyanosis:
Bluish discoloring of the skin resulting from large amounts of deoxygenated hemoglobin
in the blood
Upper Respiratory Tract Infection (URTI):
Common cold caused by viral infection of the URT
Spread through respiratory droplets either inhaled or touched
 Signs and symptoms – red mucous membranes of the nose and pharynx, copious watery
discharge, mouth breathing, changes in voice, and cough may develop from irritation of
discharge
Sinusitis:
Bacterial infection secondary to a cold or allergy that has obstructed drainage of one or
more sinuses
Croup:
Layrngotracheobronchitis
Common viral infection in children
Begins as an upper respiratory condition with nasal congestion and cough
The larynx and subglottic area become inflamed with swelling and exudate which leads
to characteristics such as barking cough, horse voice, and inspiratory stridor
Often more severe at night
Epiglottitis:
Acute infection from a bacterial organism
Most common in children aged 3-7
Infection causes swelling of the larynx, supraglottic area, and epiglottis
Onset is rapid, fever and sore throat develop, and inability to swallow
Excessive drooling is present
Child will appear anxious, mouth open, struggling to breathe
Pneumonia:
May develop as a primary acute infection in the lungs or secondary to another respiratory
or systemic condition
Always risk following aspiration or inflammation in the lung, when fluids pool or cilia
are reduced
Most cases, the organism enters the lungs directly via inhalation or aspiration
Can be classified as viral, bacterial, or fungal
Tuberculosis:
Infection that affects the lungs primarily, but may also invade the other organs
Transmitted by oral droplets released from a person with active infection, and then
inhaled into the lungs
Primary infection – occurs when the microorganisms enter the lungs (fought off by your
body’s immune system), creates a small area of necrotic tissues in the lungs, stays
dormant for years.
Secondary infection – active stage of infection
 Signs and symptoms – malaise, fatigue, weight loss, low grade fevers, night sweats,
cough that is prolonged and gets increasingly severe and often contains blood.
Cystic Fibrosis:
Genetic disorder that results in a thick, sticky mucous secretion in the lungs.
Mucous obstructs airflow in the bronchioles causing air trapping and permanent damage
to the alveoli
Signs and symptoms – chronic cough, frequent respiratory infections, chest may appear
overinflated, audible rhonchi, dyspnea, tachypnea, accessory muscle use, cyanosis,
diminished breath sounds
Aspiration:
Passage of food or fluid, vomit or drugs, or any other foreign material into the trachea or
lungs.
Right lower lung is most commonly affected
Signs and symptoms – coughing with dyspnea, stridor and hoarseness, wheezes,
tachycardia, tachypnea, or with a complete obstruction – no sound
COPD:
Chronic obstructive pulmonary disease
Group of chronic respiratory disorders that are characterized by progressive tissue
degeneration and obstruction of the airways
Causes irreversible damage to the lungs
Debilitating conditions
Emphysema, bronchitis, and asthma
Asthma:
Disease that involves periodic episodes of severe but reversible bronchial obstruction in
persons with hypersensitive/hyper responsive airways
May be acute or chronic
Can be triggered by inhaled antigen or respiratory infections, exposure to cold, exercise,
drugs, or stress
Bronchi and bronchioles respond to stimuli in 3 ways – inflammation of the mucosa with
edema, constriction of the smooth muscles (bronchoconstriction), or increased secretions
of thick mucous in the passages.
Partial obstruction of the bronchioles results in air trapping and hyperinflation of the
lungs
Air passes into the areas distal to the obstruction and is only partially expired
Air builds up and the patient tries to force expiration which leads to collapse of the
bronchial walls
Residual volume increases – becomes more difficult to breathe fresh air and cough to
remove the mucous (hyperinflation analogy)
 Total obstruction of the bronchioles results when mucus plugs completely block flow or
the already narrowed passages
This leads to non aeration of the tissue distal
Air in the distal area diffuse out and is not replaced, resulting in collapse of that section
of the lung
O2 demands increase as the body senses stress response to hypoxia as the patient fights
for air
Signs and symptoms – cough, dyspnea, tightness in chest, agitation as obstruction
increases, wheezes as air passes through narrowed bronchioles, rapid, laboured breathing
with accessory muscle use, thick tenacious mucus coughed up, tachycardia, decreased
LOC, and respiratory failure.
Status Asthmaticus – persistent severe asthma attack that does not respond to therapy, fatal
secondary to hypoxia and cardia arrythmias
Asthma Exacerbation – severe narrowing of the airways in an asthma attack to the point that no
air is able to pass through, results in no respiratory rate and no breath sounds (silent chest)
Emphysema:
Destruction of the alveolar walls which leads to large, permanently inflated alveolar air
spaces
“pink puffers”
Breakdown of alveolar walls results in loss of surface area for gas exchange, loss of
elastic fibers affecting lung recoil, altered V/Q ratios, decreased support for bronchial
structures leading to obstruction of airflow in expiration, thickening of bronchial walls
leads to narrowed airways, difficult expiration leads to air trapping and increased residual
volumes and over inflation, fixation of ribs in inspiratory position (barrel chest),
hypercapnia, and hypoxic drive as the patient’s respiratory center adapts to high CO2
levels and fails to be the respiratory centers regulatory mechanism, the large air spaces
(bleb) can create the tissues and pleural membranes around the bleb to rupture (causing
pneumothorax), frequent infections as secretions are difficult to remove, pulmonary
hypertension and cor pulmonale develop as pulmonary blood vessels are destroyed,
causing increases in pressure in the pulmonary circulation.
Signs and symptoms – dyspnea (initially on exertion, eventually on rest),
hyperventilation with prolonged expiratory phases and accessory muscle use, barrel chest
from hyperinflation, tripod positioning to facilitate breathing, fatigue (contributes to
weight loss), clubbed fingers, polycythemia
Chronic Bronchitis:
Significant changes to the bronchi resulting from constant irritation from smoking or
exposure to pollutants
Effects are irreversible and progressive
 Results in inflammation and obstruction to the bronchi, repeated infections, and chronic
coughing
Patho – mucosa are inflamed and swollen, hypertrophy of mucous glands and increased
secretions are produced, chronic irritation and inflammation lead to thickening of
bronchial walls and further obstruction, secretions pool and are difficult to remove, low
O2 levels (cyanosis will be evident), “blue bloaters” (edema, cyanosis, and low O2
levels), severe dyspnea and fatigue interfere with nutrition, pulmonary hypertension
results.
Signs and symptoms – constant productive cough, tachypnea, shortness of breath,
frequent secretions that are thick, rhonchi (usually more prevalent when secretions have
pooled), cyanosis and hypoxia.
Pulmonary Embolus:
Blood clot or mass of other material that obstructs the pulmonary artery or branch of it,
blocking blood flow through the lung tissue
Signs and symptoms – transient chest pain that often increases with coughing or deep
breathing, cough, SOB, tachypnea, hypoxia, anxiety, restlessness, tachycardia, Massive
emboli can cause – crushing chest pain, low BP
Atelectasis:
Non aeration or collapse of a lung or part of a lung, leading to decreased gas exchange or
hypoxia
When alveoli become airless, they shrivel up
This interferes with blood flow through the lungs and alters both ventilation and
perfusion
Signs and symptoms (of large areas) – dyspnea, tachycardia, tachypnea, chest expansion
may appear abnormal or asymmetrical
Pleural Effusion:
Presence of excessive fluid in the pleural cavity
Pleurisy may follow – inflammation/swelling of the pleural membranes
The fluid creates higher pressure which prevents normal lung expansion, leading to
atelectasis
Signs and symptoms – dyspnea, chest pain, tachycardia, tachypnea, absence of breath
sounds over affected area, tracheal deviation, hypotension
Adult Respiratory Distress Syndrome (ARDS):
Restrictive disorder
Secondary to an injury
Usually occurs 1-2 days after an injury
Often associated with multiple organ dysfunction
 Changes in the lungs results from injury to the alveolar wall and capillary membranes,
this leads to increased alveolar permeability, increased fluid in the alveolar and interstitial
areas of the lungs. This results in decreased diffusion of O2, reduced blood flow to the
lungs, difficulty in expanding the lungs, reductions in tidal volumes.
Signs and symptoms – dyspnea, restlessness, rapid shallow respirations, tachycardia,
accessory muscle use as lung congestion increases, crackles, productive cough with
frothy sputum
Acute Respiratory Failure:
End result of many pulmonary disorders
Happens when there are inadequate O2 and CO2 levels for the body’s needs at rest
CNS including the respiratory control center is affected
Ends in respiratory arrest

SGA – When to Place and Procedure

Supraglottic Airways:
King LT and Igel are most common
Inserted to pharynx to allow oxygenation and ventilation
Blind/quick insertion
Patient must be GCS 3
Max number of attempts = 2
When to Insert:
BLS airways are ineffective, or definitive need for advanced airway
Prolonged extrication
Ineffective management with other devices
Ensure insertion does not compromise the quality of other interventions
Confirmation of Placement:
ETCO2 waveform
Chest auscultation
Chest rise and fall
Non waveform ETCO2
Tube misting
King LT Airway:
 How does it work – has a distal and proximal balloon to occlude the esophagus and
oropharynx, which prevents gastric inflation and aspiration. Creates a direct route for
oxygen/ventilation to the trachea and lungs.
Contraindications – does not eliminate the risk of vomiting/aspiration, high airway
pressures can cause air to leak into stomach or out of mouth, do not use in patients with
intact gag reflexes, esophageal disease or who has ingested caustic substances, or airway
obstructions.
Complications – laryngospasm, vomiting, hypoventilation, trauma (from insertion),
ventilation may be difficult if pharyngeal balloon pushes the epiglottis over the glottic
opening.
Sizing – Yellow (3) = adults 4-5ft, cuff volume 50mL, Red (4) = 5-6ft, cuff volume
70mL, Purple (5) = adults >6ft, cuff volume 80ml
Igel Airway:
Does not require inflation
3 adult and 4 pediatric sizes (2-90+kg)
High seal pressures, resulting in reduced trauma to airway upon insertion
Tip is designed to fit into the proximal esophagus
Sizing – 1 Pink (2-5kg Neonate), 1.5 Blue (5-12kg Infant), 2 Black (10-25kg Small
pediatric), 2.5 White (25-35kg Large pediatric), 3 Yellow (30-60kg Small adult), 4 Green
(50-90kg Medium adult), 5 Orange (90+kg Large adult)
Complications – trauma to the pharyngo-laryngeal framework, downfolding epiglottis,
gastric insufflation, regurgitation, and inhalation of gastric contents, nerve injuries, vocal
cord paralysis, lingual or hypoglossal nerve injuries, if placed too high in pharynx may
result in poor seal and cause excessive leakage, laryngospasm
SGA Medical Directive:
Indications – need for ventilatory assistance or airway control AND other airway
management is ineffective
Conditions – absent gag reflex
Contraindications – airway obstructed by foreign object, known esophageal disease,
trauma to the oropharynx, and caustic ingestion
Treatment – consider supraglottic airway insertion, the maximum number of SGA
insertion attempts is 2
Confirmation of SGA Placement:
Primary – ETCO2 waveform capnography
Secondary – ETCO2 (non waveform device), auscultation, and chest rise

Cardiac Arrest
Causes of Cardiac Arrest:
Atherosclerosis (#1 cause)
Genetic disorders
Cardiomyopathies
Electrocution, drowning, trauma, overdose
Management of Cardiac Arrest:
Scene safety
Additional crew, fire, police
Ensure patient is on flat, hard surface
C-A-B to ensure patient is in cardiac arrest
Check carotid and radial pulses in 24 hours old to < 8yeares old = initial: 2j/kg, subsequent: 4j/kg, interval: 2 mins
> 8 years old, Zoll = 120, 150, 200, Lifepack = 200, 300, 360
Shockable – Vtach and Vfib
Non Shockable – asystole and PEA
Medical TOR:
Age greater than or equal to 16 years of age
Altered LOA
Arrest not witnessed by EMS and no ROSC after 20 mins of resuscitation, and no defib
delivered
When to Transport Early
After 1 analysis (and shock if needed) – pregnancy presumed to be greater than 20 weeks,
hypothermia, airway obstruction, non-opioid drug overdose/toxicology, and other known
reversible cause of arrest not addressed
For patients in refractory Vtach or Vfibb, transport of the patient should begin after the
third consecutive shock
Trauma Cardiac Arrest:
Cardiac arrest secondary to severe blunt or penetrating trauma
Manual defib – 1 shock/analysis maximum prior to transport (and total)
Trauma TOR:
Greater than or equal to 16 years of age
No palpable pulses AND
No defib delivered AND
Rhythm asystole AND
No signs of life at anytime since fully extricated OR
Signs of life when fully extricated with the closest ED greater than or equal to 30 mins
transport time away OR
Rhythm PEA with the closest ED greater than or equal to 30 mins transport time away
Trama TOR Contraindications:
Age less than 16 years
Defib delivered
Signs of life at anytime since fully extricated medical contact
Rhythm PEA and closest ED is less than 30 minutes away
Patients with penetrating trauma to the torso/neck and lead trauma hospital is less than 30
minutes away
Manual Defib – don’t need to pull over ambulance to shock
SAED – must pull over ambulance to defibrillate
Hypothermia:
Must be cardiac arrest secondary to hypothermia
1 analysis. Then transport
Cold waxy skin/core
Blanching
Rigid extremities
Passive/gentle rewarming
Limit movement – can cause lethal arrythmias
ROSC:
Fluid bolus: 10mL/kg, reassess every 100mL (2-12) and 250mL (12+), BP, auscultation,
vitals
Target ETCO2 30-40mmHg
Titrate SPO2 94-98%
12 lead
Supine or head elevated slightly
Oxygen

Medical Math and Drug Conversion

Syringe Formula – how much you are drawing up in a syringe
(Desired dose/dose on hand) x volume on hand = volume to deliver
Iv Infusion Formula – how much fluid to give your patient over an amount of time
(amount to be infused(mL)/time(mins)) x drop factor (gtts/mL) = drops/min
Drug Conversion:
Concentration Ratio – amount of drug (x) in 1 mL, xmg:1mL
Serial Dilution – the constant is 1gram in various amounts of fluid, 1g/xmL
% Dilution or % Concentration – the constant is amount of grams of drug in 100mLs,
%xdrug: 100mL

STEMI Bypass
Indications under the STEMI Hospital Bypass Protocol
Transport to a PCI center will be considered for all patients who meet ALL of the following:
Greater than or equal to 18 years of age
Chest pain or equivalent consistent with cardiac ischemia/myocardial infarction
Time from onset of current episode of pain is less than 12 hours
12-Lead ECG indicates and acute AMI/STEMI: atleast 2mm of ST elevation in leads V1-
V3 in at least two contiguous leads AND/OR at least 1mm of ST elevation in at least 2
other anatomically contiguous leads OR 12 lead ECG computer interpretation of STEMI
and paramedic agrees
Once activated, continue to follow the STEMI hospital bypass protocol, even if ECG normalizes
Contraindications under the STEMI hospital bypass protocol:
ANY of the following exclude the patient from being transported under the STEMI hospital
bypass protocol:
CTAS 1 and the paramedic is unable to secure patient’s airway or ventilate
12 Lead ECG is consistent with LBBB, ventricular paced rhythm, or any other STEMI
imitator
Transport to a PCI is greater than or equal to 60 minutes from patient contact
Patient is experiencing complication requiring PCP diversion – moderate to severe
respiratory distress or use of CPAP, hemodynamic instability or symptomatic SBP