Bleeding and Shock Chapter 21 PDF

Summary

This chapter details the significance of recognizing bleeding and its consequences on the body, particularly in emergency medical settings. It discusses the cardiovascular system and its critical role in maintaining blood circulation, stressing the urgency of prompt treatment to avoid severe organ damage and potential fatality during medical emergencies. The chapter also highlights compensatory mechanisms and the interplay among the heart, blood, body fluids and blood vessels for proper blood circulation and perfusion.

Full Transcript

CHAPTER 21

Bleeding and Shock

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Introduction (1 of 2)

▪Recognizing bleeding and its effects on

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the body
▪Paradigm shift away from focus on
managing the airway as most important
skills of a paramedic; bleeding now
recognized as one of most time-sensitive
conditions paramedics face
▪Any kind of bleeding is potentially
dangerous.
▪May eventually lead to shock
▪Shock Explained in 120 Seconds | Treatmen
t, Symptoms, Causes | Video – YouTube
Introduction (2 of 2)

▪Shock

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▪Bleeding is the most common cause.
▪State of collapse and failure of the cardiovascular system that causes
inadequate tissue perfusion
▪Normal compensatory mechanism used by the body to maintain systolic
blood pressure and brain perfusion during times of distress
▪If not treated promptly, shock will injure the body’s vital organs and
ultimately lead to death.
▪https://www.youtube.com/watch?v=9a7N9AU1GiQ
Anatomy and Physiology
of the Cardiovascular System (1 of 3)

▪One crucial function:

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▪Keep blood flowing via the lungs to the peripheral tissues
▪In the lungs
▪Blood dumps gaseous waste products of metabolism.
▪Blood picks up life-sustaining oxygen.
https://ed.ted.com/lessons/oxygen-s-surprisingly-complex-journey-through-
your-body-enda-butler
Anatomy and Physiology
of the Cardiovascular System (2 of 3)

▪In peripheral tissues

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▪Blood unloads oxygen and picks up wastes.
▪If blood flow stops or slows
significantly
▪Oxygen delivery would be disrupted.
▪Anaerobic metabolism: emergency
metabolic system that does not require
oxygen; produces even more acids and toxic
wastes
Anatomy and Physiology
of the Cardiovascular System (3 of 3)

▪Three intact components:

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▪Heart
▪Blood and body fluids
▪Blood vessels
▪ All three must interact effectively to maintain life.
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The Circulatory System
Structures of the Heart (1 of 2)

▪Muscular cone-shaped organ

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▪Function is to pump blood throughout the
body
▪Located behind the sternum
▪About the size of a closed fist
▪Weighs 280 to 350 g in men and 225 to 280
g in women
Structures of the Heart (2 of 2)

▪Four chambers

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▪Two atria and two ventricles
▪Each atrium receives blood that is returned
to the heart from other parts of the body.
▪Each ventricle pumps blood out of the
heart.
▪Atrioventricular valves
▪Semilunar valves
Blood Flow Within the Heart (1 of 4)

▪Starts in the right atrium

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▪Superior vena cava and inferior vena cava
return deoxygenated blood from the body to
the right atrium.
▪From the right atrium, blood passes through
the tricuspid valve into the right ventricle.
▪Right ventricle pumps blood through the
pulmonic valve into the pulmonary artery
and then to the lungs.
Blood Flow Within the Heart (2 of 4)

▪In the lungs

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▪Oxygen is returned to the blood.
▪Carbon dioxide and other waste products
are removed.
▪Freshly oxygenated blood returns to the left
atrium through the pulmonary veins.
Blood Flow Within the Heart (3 of 4)

▪After return

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▪Blood flows through the mitral valve into the
left ventricle.
▪Left ventricle pumps the oxygenated blood
through the aortic valve, into the aorta.
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Blood Flow Within the Heart (4 of 4)

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The Cardiac Cycle (1 of 4)

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hui

▪Repetitive pumping process
▪Begins with the onset of cardiac muscle contraction
▪Ends just before the beginning of the next contraction
▪Myocardial contraction
▪Afterload
▪Stroke volume
The Cardiac Cycle (2 of 4)

▪Cardiac output

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▪Amount of blood pumped through the circulatory system in 1 minute
▪Expressed in litres per minute (L/min)
▪Equals pulse rate multiplied by the stroke volume
▪Factors that influence the pulse rate, the stroke volume, or both will affect
cardiac output and, therefore, oxygen delivery to the tissues.
The Cardiac Cycle (3 of 4)

▪Increased venous return

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▪Stretches the ventricles
▪Results in increased cardiac contractility
▪First described by Ernest Henry Starling
▪ British physiologist
▪ Known as the Starling law of the heart
The Cardiac Cycle (4 of 4)

▪Ejection fraction

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▪A normal heart continues to pump the same
percentage of blood returned.
▪EF is the % of blood that the heart pumps per
contraction*
▪Amount of blood returning to the right
atrium varies.
▪If more blood returns to the heart, the
stretched heart pumps harder.
▪Maintains normal cardiac function
Blood and Its Components (1 of 4)

▪Blood

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▪Consists of plasma and formed elements, or cells that are suspended
in the plasma
▪Red blood cells
▪White blood cells
▪Platelets
▪Purpose is to carry oxygen and nutrients to the tissues and cellular
waste products away from the tissues
▪Formed elements serve as the mainstay of numerous other body
functions, such as fighting infections and controlling bleeding.
Blood and Its Components (2 of 4)

▪Plasma

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▪Watery, straw-coloured fluid
▪More than half of the total blood volume
▪Consists of 92% water and 8% dissolved substances
▪Water enters the plasma:
▪ From the digestive tract
▪ From fluids between cells
▪ As a by-product of metabolism
Blood and Its Components (3 of 4)

▪Red blood cells (erythrocytes)

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▪Disc-shaped
▪Most numerous of the formed elements
▪Unable to move on their own
▪Contain hemoglobin
▪ Protein that gives them their largely red
colour
▪ Binds oxygen absorbed in the lungs and
transports it to the tissues*
Blood and Its Components (4 of 4)

▪White blood cells (leukocytes)

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▪Several types exist
▪Primary function is to fight infection.
▪Platelets
▪Small cells in the blood
▪Essential for clot formation
▪The process is a complex series of events
involving platelets, clotting proteins in the
plasma, other proteins, and calcium.
▪Aggregate in a clump and form much of the
foundation of a blood clot
Blood Circulation and Perfusion (1 of 2)

▪Blood vessels

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▪Arteries
▪Veins
▪Arterioles and capillaries
▪ Diffusion
▪Venules
▪ Venules merge together
Blood Circulation and Perfusion (2 of 2)

▪Perfusion

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▪Circulation of blood within an organ or
tissue in adequate amounts to meet the
cells’ current needs for oxygen, nutrients,
and waste removal*
▪ Blood must pass through the system at a
speed that is fast enough to maintain
adequate circulation, yet slow enough to
allow each cell time to exchange oxygen and
nutrients for carbon dioxide and other waste
products.
▪ Most tissues require circulating blood only
intermittently.
Autonomic Nervous System (1 of 2)

▪Monitors the body’s needs from

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moment to moment
▪During emergencies:
▪ Automatically redirects blood away from other
organs and toward the heart, brain, lungs, and
kidneys
▪ Sometimes fails to provide sufficient
circulation for every body part to perform its
function
Autonomic Nervous System (2 of 2)

▪Perfusion needs

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▪The heart requires constant perfusion.
▪Brain and spinal cord cannot go for more than 4 to 6 minutes without
perfusion.
▪Kidneys will be permanently damaged after 45 minutes of inadequate
perfusion.
▪Skeletal muscles cannot tolerate more than 2 hours of inadequate perfusion.
▪The GI tract can exist with limited (but not absent) perfusion for several
hours.
▪Times based on a normal body temperature of 37.0°C
▪An organ or a tissue that is considerably colder is better able to resist
damage from hypoperfusion because of slowing metabolism.*
▪You are called to a shooting at a local gas station. The dispatcher alerts you that

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police on the scene are requesting “a rush on the bus.”
▪A detective informs you, “There was a robbery; the clerk was shot and the
perpetrator has left the scene.” You observe a 22-year-old man sitting on the
floor holding his left upper quadrant with his bloody hand. The patient appears
to weigh about 80 kg. Although he is conscious, alert, and in obvious pain, he
tells you that the shooting occurred just as the clock struck 23:00. It is now
23:10, and you hit the elapsed time counter on your digital watch as you don
your PPE. As you begin to talk to the patient, you reach down to palpate his
radial pulse but cannot feel it.

▪Does the lack of significant visible bleeding and the fact that he is alert indicate that
this patient is not bleeding seriously?
▪What is the significance of time in this type of incident?
Pathophysiology of Hemorrhage

▪Hemorrhage

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▪Simply means bleeding
▪Can range from a “nick,” to a severely
spurting artery, to a ruptured spleen
▪*External bleeding (visible hemorrhage)
▪*Internal bleeding
External Hemorrhage (1 of 2)

▪External bleeding

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▪Occurs due to a break in the skin
▪Extent or severity is often a function of the
type of wound and the types of blood
vessels that have been injured.
▪Bleeding from a capillary usually oozes.
▪Bleeding from a vein flows.
▪Bleeding from an artery spurts.
External Hemorrhage (2 of 2)

▪Injuries

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▪Do not always have serious hemorrhaging
▪Other injuries may cause more bleeding
than expected.
Internal Hemorrhage (1 of 3)

▪Internal bleeding

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▪As a result of trauma
▪The smaller the space, the less the bleeding.
▪Nontraumatic usually occurs in cases of:
▪ GI bleeding from the upper or lower GI tract
▪ Ruptured ectopic pregnancies
▪ Ruptured aneurysms
▪ Other conditions
Internal Hemorrhage (2 of 3)

▪Must be treated promptly

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▪Signs do not always develop quickly.
▪Rely on other signs and symptoms and an
evaluation of the MOI to make this
diagnosis.
▪Pay close attention to patient complaints of
pain or tenderness, development of
tachycardia, and pallor.
▪Be alert for the development of shock.
Internal Hemorrhage (3 of 3)

▪Management

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▪Focuses on:
▪ Treatment of shock
▪ Minimizing movement of the injured or
bleeding part or region
▪ Rapid transport
▪Patient will need a surgical procedure to
stop the bleeding.
Controlled Versus Uncontrolled Hemorrhage (1 of 3)

▪Serious emergency

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▪Initial assessment of the patient always
includes a search for life-threatening
bleeding.
▪If found, the hemorrhage must be
controlled.
▪If the hemorrhage cannot be controlled in
the prehospital environment:
▪ Concentrate on attempting to control the
bleeding as you rapidly transport the patient.
Controlled Versus Uncontrolled Hemorrhage (2 of 3)

▪External bleeding

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▪Most can be managed with direct pressure
▪Arterial bleeding may take 5 or more
minutes of direct pressure to form a clot.
▪Military experience has shown that the use
of pressure points is not as effective as
previously thought.
▪Use of a tourniquet for external bleeding of
an extremity that cannot be controlled with
direct pressure and a pressure bandage
Controlled Versus Uncontrolled Hemorrhage (3 of 3)

▪Internal bleeding

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▪Most cases are rarely fully controlled in the
prehospital setting.
▪Rapid transport needed
▪External circumferential pressure of a pelvic
binder may help control the massive
bleeding that accompanies a pelvic fracture.
The Significance of Bleeding (1 of 5)

▪Blood loss

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▪Often difficult to determine
▪Looks different on different surfaces
▪Patient’s presentation and your assessment
direct your care and treatment plan.
The Significance of Bleeding (2 of 5)

▪Averages

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▪Human adult male bodies contain
approximately 70 mL of blood per
kilogram of body weight.
▪Adult female bodies contain
approximately 65 mL/kg.
▪Body cannot tolerate an acute loss of
more than 20% of this total blood
volume.

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The Significance of Bleeding (3 of 5)

▪Averages (continued)

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▪If a typical adult loses more than 1 litre of
blood:
▪ Significant changes in vital signs will occur.
▪ Increasing heart and respiratory rates
▪ Decreasing blood pressure
▪Infants and children have less blood volume.
▪ May experience the same effect with smaller
amounts of blood loss.
The Significance of Bleeding (4 of 5)

▪Compensation

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▪Depends on the rate of bleeding
▪A healthy adult can donate one unit (500
mL) of blood in a period of 15 to 20 minutes
without having ill effects.
▪If a similar blood loss occurs in a much
shorter period, hypovolemic shock may
rapidly develop.
The Significance of Bleeding (5 of 5)

▪Serious if any of the following

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conditions are present:
▪*A significant MOI
▪Poor general appearance of the patient
▪Signs and symptoms of shock
▪Significant amount of blood loss
▪Blood loss causing hemodynamic instability
▪Uncontrollable bleeding
Physiologic Response to Hemorrhage (1 of 5)

▪https://ed.ted.com/lessons/how-blood-pressure-works-wilfred-manzano

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▪Bleeding from an artery
▪Bright red
▪Spurts in time with the pulse
▪Difficult to control
▪As the amount of blood circulating in the body drops, so does the patient’s BP, and
eventually the arterial spurting diminishes.
▪Bleeding from an open vein
▪Much darker
▪Flows steadily
▪Easier to manage
Physiologic Response to Hemorrhage (2 of 5)

▪Bleeding from damaged capillary

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vessels
▪Dark red
▪Oozes slowly
▪Venous and capillary bleeding are more
likely to clot spontaneously than arterial
bleeding.
▪On its own
▪Bleeding tends to stop rather quickly (within
about 10 minutes).
▪Response to internal clotting mechanisms
and exposure to air
Physiologic Response to Hemorrhage (3 of 5)

▪On its own (continued)

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▪When vessels are lacerated, blood flows
rapidly.
▪Open ends of the vessel begin to narrow.
▪Platelets aggregate at the site, plugging the
hole and sealing the injured portions of the
vessel (hemostasis).
▪Bleeding will not stop if a clot does not form.
▪Direct contact with body tissues and fluids
or the external environment commonly
triggers the blood’s clotting factors.
Physiologic Response to Hemorrhage (4 of 5)

▪The hemostatic system may fail in

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certain situations.
▪*Medications - anticoagulants (aspirin and
prescription blood thinners) interfere with
normal clotting.*
▪*Severe injury
▪*Only part of the vessel wall is cut
▪Acute blood loss may result in death
before vasoconstriction and clotting
can help.
Physiologic Response to Hemorrhage (5 of 5)

▪Trauma triad of death

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▪Combination of hypothermia, coagulopathy (poor
blood clotting), and acidosis that significantly
increases mortality in trauma patients
▪Important to:
▪Aggressively control bleeding.
▪Keep patients warm. as low body temperature
hinders the clotting process.
▪Minimize volume of acidic IV fluid
administered.
▪If possible, monitor end-tidal carbon dioxide
and ventilations to prevent respiratory acidosis.
▪Consider administering tranexamic acid to help
control internal bleeding.
Assessment of a Bleeding Patient (1 of 5)

▪Scene assessment

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▪Begins assessment of any patient
▪General impression and initial assessment
once the scene is deemed safe to enter
▪PPE entails:
▪ Gloves
▪ Mask
▪ Eyeshield
▪ Gown

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Assessment of a Bleeding Patient (2 of 5)

▪Initial assessment

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▪Determine the patient’s mental status.
▪Locate and manage immediate life threats
involving the airway, breathing, and
circulation.
▪Ensure that the patient has a patent airway.
▪If the patient has minor external bleeding,
note it and move on.
▪If major external bleeding is present, deal
with it immediately.
▪If internal bleeding is suspected, keep
patient warm and administer supplemental
oxygen, but remember rapid transport to
hospital is necessary.
Assessment of a Bleeding Patient (3 of 5)

▪MOI

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▪Trauma patients
▪May be best indicator of internal injury or
bleeding
Assessment of a Bleeding Patient (4 of 5)

▪Focused history

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▪Elaborate on the patient’s chief complaint
using the OPQRST mnemonic.
▪Obtain a history of the present illness using
SAMPLE.
▪Look for signs of shock.
▪Ask the patient about medications and about
any history of clotting insufficiency.
 Assessment of a Bleeding Patient (5 of 5)

▪Physical examination

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▪Note the colour of bleeding.
▪Try to determine its source.
▪Bright red blood from a wound or the mouth,
rectum, or other orifice indicates fresh
arterial bleeding.
▪*Coffee-ground emesis *
▪*Melena*
▪*Hematochezia* - passage of stool with
bright red blood*
▪*Hematuria
▪*Nonmenstrual vaginal bleeding
Treatment of a Bleeding Patient (1 of 3)

▪Managing external hemorrhage

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▪Steps to control hemorrhaging
▪ Apply direct pressure over the wound.
▪ Elevate the injury above the level of the heart
if no fracture is suspected.
▪ Apply a pressure dressing.
▪ A tourniquet is generally a last resort.
Treatment of a Bleeding Patient (2 of 3)

▪Bleeding from the nose, ears, and mouth

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▪ Epistaxis (non-traumatic) Standard pg 85
▪ https://www.health.gov.on.ca/en/pro/programs/emergency_health/edu/docs/
bls_pcs_v3.4.pdf

▪ May indicate a skull fracture
▪ Cover the bleeding site loosely with sterile gauze pad.
▪ May contain cerebrospinal fluid
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To control nosebleed, have the patient sit
leaning forward
Pinch the fleshy part of the patient’s nostrils firmly for at
least 5 minutes (non trauma) or 10 min (traumatic)

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Treatment of a Bleeding Patient (3 of 3)

▪Bleeding from other areas

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▪ Control bleeding through use of direct
pressure and elevation.
▪ Apply pressure dressings.
▪ Use splints as necessary.
▪ Pack large, gaping wounds with sterile
dressings.
▪ Keep the patient warm and in the appropriate
position.
Special Management Techniques (1 of 6)

▪Fractures

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▪Most bleeding occurs because the sharp
ends lacerate vessels, muscles, and other
tissues.
▪As long as the fracture remains unstable,
the bone end will move and continue to
damage tissues and vessels.
▪Immobilizing is a priority in the prompt
control of bleeding.
Special Management Techniques (2 of 6)

▪Air splints

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▪Can control the bleeding associated with
severe soft-tissue injuries or fractures
▪Stabilize fractures
▪Act like a pressure dressing applied to an
entire extremity rather than to a small, local
area
▪Monitor circulation
▪Not appropriate for use on arterial bleeding
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Special Management Techniques (3 of 6)

▪Rigid splints

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▪Can stabilize fractures
▪Reduce pain
▪Prevent further soft-tissue injury

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Special Management Techniques (4 of 6)

▪Traction splints

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▪Particularly useful in stabilizing femur
fractures
▪Reduces thigh muscle spasms
▪Prevents one end of fracture from
impacting or overriding the other

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 Special Management Techniques (5 of 6)

▪Hemostatic agents

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▪Work by causing enhanced clot formation at wound
site
▪Wound packing
▪Has been successfully used by military for many
years, now moving into civilian EMS
▪Particularly helpful for bleeding in junctional areas
(such as groin).
▪Involves pushing gauze into wound to completely and
tightly pack the wound cavity
▪Goal is to contact the source of bleeding and fill the
cavity if possible.
▪https://www.youtube.com/watch?v=RSxl2K65YVs
Courtesy of SAM Medical.
Special Management Techniques (6 of 6)

▪Tourniquets

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▪Used with partial or complete amputation or
when other methods of bleeding control
have proved ineffective
▪Can cause permanent damage to nerves,
muscles, and blood vessels
▪Do not apply directly over a joint.
▪Use the widest bandage possible.
▪Never use wire, rope, a belt, or any other
narrow material.
▪Use wide padding under the tourniquet.
▪Never cover with a bandage.
▪Do not loosen the tourniquet after you have
applied it.
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(1 of 2)
Skill Drill 21-1: Managing External Hemorrhage

Step 2
Step 1
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(2 of 2)
Skill Drill 21-1: Managing External Hemorrhage

Step 4
Step 3
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Pelvic Trauma (1 of 4)

▪Use a pelvic binder to reduce a pelvic fracture and provide mechanical

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stability.
▪Reduces blood loss and helps maintain BP
▪Indications for application of pelvic binder include trauma patients with:
▪Signs of pelvic fracture, including pain in pelvis, hip, groin, or lower back
▪Signs of hypovolemic shock
▪Suspicious mechanism of injury, even if currently hemodynamically stable
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Pelvic Trauma (2 of 4)
Pelvic Trauma (3 of 4)

▪Applying pelvic sheeting

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▪https://www.youtube.com/watch?v=Om
g79Ced6s0

▪Step 1: Align—bring legs together and
remove outer clothing. Place narrow folded
sheet on stretcher.
▪Step 2: Place padding between the knees
and ankles, and secure the legs together.
▪Step 3: Scoop patient onto folded sheet on
stretcher.
▪Step 4: The top of the sheet should be at the
level of the iliac crest.
Pelvic Trauma (4 of 4)

▪Applying pelvic sheeting (continued)

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▪Step 5: Apply tension, by holding one side
of the sheet while passing the other to your
partner on the other side and pulling tight.
Sheeting is ineffective if loose.
▪Step 6: Clamp sheet to prevent loss of
tension. Position the clamps laterally to
avoid obstructing X-ray views.
▪Step 7: Reassess tension and clamps
periodically.
Managing Internal Hemorrhage (1 of 2)

▪Definitive management

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▪Occurs in the hospital
▪Prehospital management involves
treating for shock and splinting injured
extremities:
▪Keep the patient supine.
▪Open the airway.
▪Check breathing and pulse.
▪Administer high-flow supplemental oxygen.
▪Assist ventilation if needed.
Managing Internal Hemorrhage (2 of 2)

▪Prehospital management (continued)

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▪Splint broken bones or joint injuries
▪If a pelvic fracture is suspected, apply a pelvic
binder.
▪Keep the patient warm.
▪While en route to the ED, insert a large-bore
IV catheter, and administer a fluid challenge
of 250 mL of a crystalloid if evidence of
hypoperfusion is present.
▪ Insert an IV line at the scene only if transport is
delayed (such as if the patient is entrapped).
▪ Whenever possible, use warm IV fluids to
maintain the patient temperature.
▪Consider giving pain medication.
▪Monitor the serial vital signs.
 Copyright © 2021 by Jones & Bartlett Learning, LLC an Ascend Learning Company. www.jblearning.com
Step 3
Skill Drill 21-2: Managing Internal Hemorrhage

Step 2
Step 1
© Jones & Bartlett Learning.
Transportation of Patients With Hemorrhage (1 of 2)

▪In case of hemorrhage

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▪The issue is not whether the patient will be transported.
▪Depends on:
▪ How fast the decision should be made
▪ Where the patient should be taken
Transportation of Patients With Hemorrhage (2 of 2)

▪In case of hemorrhage (continued)

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▪Exceptions: minor wounds
▪Consideration for the priority of the patient
and the availability of a regional trauma
centre
▪Severe internal or external bleeding will be
candidates for surgical interventions and
should be transported to a facility with those
capabilities.
▪May be appropriate for helicopter transport
 (continued
)

▪Your partner has brought in the stretcher and is beginning to administer supplemental

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oxygen via a nonrebreathing mask at 15 L/min. Police inform you that the robber’s
weapon may have been a “sawed-off shotgun” that was fired at a fairly close range.
▪You give the patient some gauze and tell him to hold it firmly against the wound. When
you complete your initial assessment, you decide to perform the rapid physical
examination in the back of the ambulance and the SAMPLE history as you have time,
given the higher priorities and need for rapid transport.

▪ On the basis of the information you have so far, and remembering that the patient weighs
approximately 80 kg, how much blood did he have before the incident? How much could he
have lost so far?
▪ What phase or stage of shock is this patient in?
▪ Which BLS (basic life support) and ALS (advanced life support) interventions would be most
appropriate for this patient at this time? Should you insert an intravenous (IV) line at the scene?
Pathophysiology of Shock (1 of 3)

▪Hypoperfusion

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▪Occurs when the level of tissue perfusion
decreases below normal
▪Early decreased tissue perfusion may result
in subtle changes before a patient’s vital
signs appear abnormal.
Pathophysiology of Shock (2 of 3)

▪Shock

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▪ State of collapse and failure of the
cardiovascular system
▪ Creates inadequate circulation and tissue
perfusion
▪ Cannot be seen
▪ Not a specific disease or injury
▪ Inadequate flow of blood to the body’s cells
and failure to rid the body of metabolic
wastes
Pathophysiology of Shock (3 of 3)

▪Diagnosing shock

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▪Evaluation of a patient’s level of organ
perfusion is important.
▪Severity of the disease or injury overwhelms
the normal compensatory mechanisms,
leading to progressive deterioration in the
patient’s condition.
▪If conditions causing shock are not promptly
addressed, the patient will rapidly
deteriorate.
Mechanisms of Shock (1 of 6)

▪Normal tissue perfusion

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▪Requires three intact mechanisms:
▪ Heart
▪ Blood and body fluids
▪ Blood vessels
▪If any one of those mechanisms is damaged, tissue perfusion may be disrupted, and
shock will ensue.
▪Mechanisms of shock
▪https://www.youtube.com/watch?v=WueGqL58tlo
Mechanisms of Shock (2 of 6)

▪Cardiogenic shock

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▪Arises because of failure of the heart’s ability to pump effectively due to muscle
dysfunction
▪Cardiac arrest is the most drastic form.
▪May occur secondary to:
▪ Myocardial infarction
▪ Cardiac arrhythmias
▪ Pulmonary embolism
▪ Severe acidosis
▪ A variety of other conditions
▪https://ed.ted.com/lessons/how-does-heart-transplant-surgery-work-roni-shanoada
Mechanisms of Shock (3 of 6)

▪Hypovolemic shock

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▪Occurs because of a loss of fluid volume
▪Lost as blood (hemorrhagic shock), plasma,
or electrolyte solution
▪Suspect in any patient with unexplained
shock.
▪Treat the patient for hypovolemia first.
Mechanisms of Shock (4 of 6)

▪Neurogenic shock

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▪Failure of vasoconstriction
▪Sympathetic nervous system ordinarily
controls the dilation and constriction of
blood vessels.
▪In a healthy person, the calibre of the blood
vessels constantly changes in response to
signals from the nervous system, allowing
the body to adapt to changes in position,
fluid volume, and so forth.
▪In certain situations, nervous system control
over the calibre of blood vessels becomes
deranged (spinal cord injury).
Mechanisms of Shock (5 of 6)

▪More than one cause

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▪More than one component of the circulatory
system may be affected in case of shock.
▪Some types of shock always result from
combined deficits from both fluid leakage
into the interstitial space and vasodilation.
Mechanisms of Shock (6 of 6)

▪High risk

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▪Certain categories of patients are at a high
risk to develop shock:
▪ Patients known to have had trauma or
bleeding
▪ Older people
▪ Patients with massive myocardial infarction
▪ Pregnant women
▪ Patients with a possible source for septic
shock (patients with burns, diabetes, or
cancer)
Compensation for Decreased Perfusion (1 of 6)

▪Maintaining blood pressure

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▪Central homeostatic mechanism for
regulating cardiovascular dynamics
▪*Baroreceptors
▪Stimulation typically occurs when the
systolic pressure is between 60 and 80 mm
Hg in adults (lower in children).
▪The drop in arterial pressure decreases the
stretching of the arterial walls, thereby
decreasing baroreceptor firing, stimulating
the vasoconstrictor centre of the medulla.
▪Sympathetic nervous system is also
stimulated as the body recognizes a
potential catastrophic event.
 Compensation for Decreased Perfusion (2 of 6)

▪In response to hypoperfusion

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▪Renin–angiotensin–aldosterone system is
activated and antidiuretic hormone is
released from the pituitary gland.
▪ Triggers salt and water retention and
peripheral vasoconstriction
▪Increase in blood pressure and cardiac
output
▪Spleen releases RBCs that are normally
sequestered.
▪The overall response of the initial
compensatory mechanisms is to increase
the preload, stroke volume, and pulse rate,
which usually results in an increase in
cardiac output.
 Copyright © 2021 by Jones & Bartlett Learning, LLC an Ascend Learning Company. www.jblearning.com
📂🖲📫85
Renin-Angiotensin-Aldosterone
Mechanism*
 Renin-Angiotensin-Aldosterone System*
▪Renin

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▪Aldosterone
▪Angiotensin II
▪Angiotensin I
▪Angiotensinogen
▪JGA
▪Angiotensin Converting Enzyme
▪ADH (vasopressin)
▪Liver
▪Lungs
▪Vasoconstriction
▪Thirst
▪Adrenal cortex
Compensation for Decreased Perfusion (3 of 6)

▪The body’s own “medicines”

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▪Epinephrine and norepinephrine released
by adrenal glands in response to
hypoperfusion
▪Released by the body as part of the global
compensatory state
▪Administered by caregivers in cases of
anaphylaxis, severe airway disease, and
cardiac arrest
Compensation for Decreased Perfusion (4 of 6)

▪The body’s “medicines” (continued)

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▪Release of epinephrine improves cardiac
output by increasing the pulse rate and
strength.
▪Alpha-1 response to release of epinephrine
includes:
▪ Vasoconstriction
▪ Increased peripheral vascular resistance
▪ Increased afterload from the arteriolar
constriction
Compensation for Decreased Perfusion (5 of 6)

▪The body’s “medicines” (continued)

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▪Alpha-2 effects ensure a regulated release of alpha-1.
▪Effects of norepinephrine are primarily alpha-1 and alpha-2:
▪ Centre on vasoconstriction and increasing PVR *
▪**“Golden hour of trauma”
Compensation for Decreased Perfusion (6 of 6)

▪As hypoperfusion persists

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▪Myocardial oxygen demand continues to increase.
▪*Compensatory mechanisms fail.
▪Myocardial function worsens.
▪**Tissue perfusion decreases.
▪***Fluid may leak from the blood vessels.
Types of Shock (1 of 4)

▪Impairment of cellular metabolism

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▪Inadequate oxygen and nutrient delivery to
the metabolic apparatus of the cell
▪Results in the inability to properly use
oxygen and glucose at the cellular level
Types of Shock (2 of 4)

▪Impairment of cellular metabolism

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(continued)
▪Cell converts to anaerobic metabolism.
▪ Increased lactic acid production and metabolic
acidosis
▪ Decreased oxygen affinity for hemoglobin
▪ Decreased adenosine triphosphate production
▪ Changes in cellular electrolytes
▪ Cellular edema
▪ Release of lysosomal enzymes
▪Elevated blood glucose level due to release
of catecholamines and cortisol
▪Fat breakdown (lipolysis) with ketone
formation may occur.
 Copyright © 2021 by Jones & Bartlett Learning, LLC an Ascend Learning Company. www.jblearning.com
Aerobic MetabolismAerobic Metabolism

HEAT (417
H2O

ATP
36
6

kcal)
CO2
6

METABOLI
SM
GLUCO
O2

SE
6
 Copyright © 2021 by Jones & Bartlett Learning, LLC an Ascend Learning Company. www.jblearning.com
HEAT (32
2 LACTIC

ATP
ACID

kcal)
2
METABOLI
Anaerobic Metabolism

SM
GLUCO
SE
Types of Shock (3 of 4)

▪Weil-Shubin classification

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▪Shock from a mechanistic point of view
▪Central shock
▪ Cardiogenic shock
▪ Obstructive shock
▪Peripheral shock
▪ Hypovolemic shock
▪ Distributive shock
Types of Shock (4 of 4)

▪Regardless of type

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▪Characterized by:
▪ Reduced cardiac output
▪ Circulatory insufficiency
▪ Tachycardia
▪Most types also include pallor.
▪Patient’s mental status may be altered.
▪Low blood pressure is a late sign,
especially in children.
Cardiogenic Shock (1 of 2)

▪Cardiogenic shock

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▪Heart is unable to circulate sufficient blood to maintain adequate peripheral
oxygen delivery
▪*Circulation requires constant pumping of the heart.
▪Many diseases can cause the heart to stop pumping adequately.
▪If too much muscular damage occurs, the heart no longer functions
effectively.
▪Filling is impaired because of a lack of pressure to return blood to the
heart.
▪Outflow is reduced by a lack of pumping function.
Cardiogenic Shock (2 of 2)

▪Most common causes

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▪Extensive infarction of the left ventricle
▪Diffuse ischemia
▪Decompensated heart failure resulting in primary pump failure
▪May be due to a single massive event or from cumulative damage
▪Patients have a poor prognosis when more than 40% of the left ventricle
does not function.
▪Mortality rates range as high as 80%, even with appropriate therapy
▪LVAD video
▪.https://www.youtube.com/watch?v=Fh7E2G4-Rlk
Obstructive Shock

▪Blood flow in the heart or great vessels

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becomes blocked.
▪Pericardial tamponade
▪Obstruction of the superior or inferior vena
cava
▪Large pulmonary embolus or tension
pneumothorax
Hypovolemic Shock (1 of 6)

▪Circulating blood volume is not

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sufficient to maintain adequate
perfusion
▪Exogenous or endogenous, depending on
where fluid loss occurs
▪Most common cause of exogenous is
external bleeding due to:
▪ Blunt or penetrating injuries
▪ Long bone or pelvic fractures
▪ Major vascular injuries
▪ Multisystem injury
Hypovolemic Shock (2 of 6)

▪Organs and organ systems with a high

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incidence of exsanguination from
penetrating injuries include:
▪ Heart
▪ Liver
▪ Spleen
▪ Thoracic vascular system
▪ Abdominal vascular system
▪ Venous system
Hypovolemic Shock (3 of 6)

▪Endogenous occurs when the fluid loss is

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contained within the body.
▪ Dehydration
▪ Burn injury
▪ Crush injury
▪ Anaphylaxis
Hypovolemic Shock (4 of 6)

▪Abnormal losses of fluids and electrolytes

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▪ *GI losses
▪ Fever, hyperventilation, or high environmental
temperatures
▪ Increased sweating
▪ Internal losses
▪ Plasma losses
Hypovolemic Shock (5 of 6)

▪Other causes include ascites, diabetes

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insipidus, acute renal failure, and osmotic
diuresis secondary to hyperosmolar states
▪*Fluid loss
▪ Therapy aims to restore deficient chemicals.
▪Symptoms of dehydration
▪ Loss of appetite
▪ Nausea
▪ Vomiting
▪ Fainting when standing up
Hypovolemic Shock (6 of 6)

▪Physical examination reveals:

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▪ Poor skin turgor
▪ Shrunken, furrowed tongue
▪ Sunken eyes
▪Pulse will be weak and rapid.
▪Dehydrated patients need replacement of fluid and electrolytes;
IV infusion of normal saline or lactated Ringer solution at a rate
of 100 to 200 mL/h for an adult.
Distributive Shock (1 of 5)

▪Distributive shock

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▪Widespread dilation of the resistance
vessels, the capacitance vessels, or both.
▪Circulating blood volume pools in the
expanded vascular beds and tissue
perfusion decreases
▪Three most common types:
▪ Septic
▪ Neurogenic
▪ Anaphylactic
Distributive Shock (2 of 5)

▪Septic shock

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▪ Presence of sepsis syndrome and a systolic blood pressure of less than 90 mm Hg
or a decrease from the baseline blood pressure of more than 40 mm Hg
▪ Sepsis: result of widespread infection
▪ Complex interactions between pathogen and body’s defence systems
▪ Uncontrolled and unregulated inflammatory-immune response
▪ Result: hypoperfusion to cells, tissue destruction, organ death
▪ Left untreated: multiple-organ dysfunction syndrome and, often, death.
▪ Complex problem: insufficient volume of fluid; fluid that leaks out often collects in
the respiratory system; larger-than-normal vascular bed is asked to contain the
smaller-than-normal volume of intravascular fluid
Distributive Shock (3 of 5)

▪Neurogenic shock

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▪Usually results from spinal cord injury
▪Loss of normal sympathetic nervous system
tone and vasodilation
▪Muscles in the walls of the blood vessels
▪All vessels below the level of spinal injury
dilate widely.
▪Perfusion becomes inadequate.
▪Relative hypovolemia leading to hypotension
▪Skin is pink, warm, and dry.
▪No release of epinephrine and
norepinephrine
▪Absence of sweating below the level of injury
Distributive Shock (4 of 5)

▪Spinal shock

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▪*Local neurologic condition after a spinal
injury produces motor and sensory losses
▪Characterized by flaccid paralysis, flaccid
sphincters, and absent reflexes
▪Absence of all pain, temperature, touch,
proprioception, and pressure below the level
of the lesion
▪Absent or impaired thermoregulation
▪Absent somatic and visceral sensations
below the lesion
▪Bowel distension
▪Loss of peristalsis
Distributive Shock (5 of 5)

▪Anaphylactic shock

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▪Severe reaction to a foreign substance
▪Patient experiences widespread vascular
dilation*, resulting in relative hypovolemia.
▪Immune system chemicals are released,
causing severe bronchoconstriction.
▪Fluid leaks out of the blood vessels and into
the interstitial spaces.
▪Swelling may occlude the upper airway.
▪Angioedema*
 (continued
)

▪You decide that the patient does not have spinal involvement. He reports that he was not

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blown to the ground, but rather felt dizzy and sat down on his own. You and your partner
decide to quickly pick the patient up and load him onto the stretcher, rather than
spending the time for spinal immobilization to a backboard. You also decide to insert the
IV line en route to the regional trauma centre.
▪The patient is starting to become confused as you place him into Trendelenburg position
and head out the door. He states that he is nauseated and thirsty and asks your partner,
“Am I going to die?” When closing the back of the ambulance, you note on your watch
that 7 minutes have elapsed on the scene. Your plan for the next few minutes is to redo
the initial assessment, get IV fluids running, do the rapid trauma assessment and
SAMPLE history, and notify the ED.

▪ For this patient, is the SpO2 a helpful indicator?
▪ Why were the baseline vital signs not taken on the scene?
Shock-Related Events (1 of 4)

▪At the capillary and microcirculatory

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levels
▪As perfusion decreases
▪ Cellular ischemia occurs.
▪ Minimal blood flow passes through the
capillaries.
▪ Cells switch from aerobic metabolism to
anaerobic metabolism.
Shock-Related Events (2 of 4)

▪Anaerobic metabolism

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▪Body can tolerate for only a limited time
▪Much less efficient
▪Systemic acidosis and depletion of the
body’s high energy reserves
▪Accumulation of pyruvic acid
▪Increased carbon dioxide production*
▪Sodium
Shock-Related Events (3 of 4)

▪Intracellular enzymes

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▪Digest and neutralize bacteria
▪Bound in a relatively impermeable
membrane
▪Cellular flooding damages the membrane
and releases these enzymes.
▪Autodigest the cell
▪If enough cells are destroyed in this way,
organ failure will become evident.
▪Opens the floodgates for the onset of the
last phase of shock
Shock-Related Events (4 of 4)

▪Accumulating acids and waste products

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▪Act as potent vasodilators
▪Decrease venous return and diminish blood flow to the vital organs and
tissues
▪*When aortic pressures fall below a MAP of 60 mm Hg, the coronary
arteries no longer fill, the heart is weakened, and the cardiac output
falls.
▪**Cessation of sympathetic nervous system activity
▪***Metabolic wastes are released.
▪Accumulated hydrogen, potassium, carbon dioxide, and thrombosed
RBCs wash out into the venous circulation.
▪Ischemia and necrosis ultimately lead to multiple-organ dysfunction
syndrome.
Systemic Inflammatory Response Syndrome (1 of 10)

▪SIRS - https://www.youtube.com/watch?v=90LnNDOSjjA

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▪Systemic inflammatory response to a variety of severe clinical insults
▪Does not confirm a diagnosis of infection or sepsis because the features in SIRS
can be seen in many other conditions, including trauma, burns, and pancreatitis.
▪SIRS + infection = sepsis
▪Not a diagnosis itself, nor a good indicator of outcome
▪Definition proposed in 1991 by the American College of Chest Physicians
and the Society of Critical Care
Systemic Inflammatory Response Syndrome (2 of 10)

▪Manifested by two or more of the

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following conditions:
▪Temperature greater than 38°C or less than
36°C
▪Heart rate greater than 90 beats/min
▪Respiratory rate greater than 20
breaths/min or PCO2 less than 32 mm Hg
▪White blood cell count greater than 12 × 109
cells/L or less than 4 × 109 cells/L
Systemic Inflammatory Response Syndrome (3 of 10)

▪Release of cytokines in severe sepsis

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and injury
▪Central to the development of SIRS
▪Central mediator is activated and released
Systemic Inflammatory Response Syndrome (4 of 10)

▪Specific organs and organ systems

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▪Cardiovascular
▪ Tachycardia and hypotension
▪ Myocardial depression and ischemia
▪ Peripheral pulses are weak or absent
▪ Extremities become cyanotic and cold
Systemic Inflammatory Response Syndrome (5 of 10)

▪Respiratory

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▪ Tachypnea and increased minute ventilation
▪ Impaired gas exchange*
▪ Alveolar cells become ischemic
▪ Respiratory failure, severe hypoxemia, and
respiratory acidosis
Systemic Inflammatory Response Syndrome (6 of 10)

▪Central nervous system

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▪ Decreased cerebral perfusion pressure and
cerebral blood flow result in confusion,
reduced responses to verbal and painful
stimuli, and unresponsiveness.
Systemic Inflammatory Response Syndrome (7 of 10)

▪Renal system

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▪ Reduction in renal blood flow produces acute
tubular necrosis leading to oliguria.
▪ Toxic waste products cannot be excreted.
▪ Metabolic acidosis worsens.
Systemic Inflammatory Response Syndrome (8 of 10)

▪Liver and gastrointestinal tract

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▪ Hypoperfusion results in ischemic gut.
▪ Failure to metabolize waste products
▪ Cell death evidenced by an increase in
enzyme levels.
Systemic Inflammatory Response Syndrome (9 of 10)

▪Metabolic

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▪ Respiratory alkalosis is the first acid–base
abnormality.
▪ Shock progresses with metabolic acidosis.
Systemic Inflammatory Response Syndrome (10 of 10)

▪Uncontrolled SIRS

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▪Can lead to hypotension, inadequate
perfusion, death
▪SIRS and sepsis can progress to multiple-
organ dysfunction syndrome (MODS).
 Copyright © 2021 by Jones & Bartlett Learning, LLC an Ascend Learning Company. www.jblearning.com
Phases of Shock (1 of 5)

▪Three successive phases

▪Decompensated
▪Compensated

▪Irreversible*
 Copyright © 2021 by Jones & Bartlett Learning, LLC an Ascend Learning Company. www.jblearning.com
I
D
Blood Pressure
Changes*

C

Diastolic
Children
Systolic
 Copyright © 2021 by Jones & Bartlett Learning, LLC an Ascend Learning Company. www.jblearning.com
© Jones & Bartlett Learning.
Phases of Shock (2 of 5)
Phases of Shock (3 of 5)

▪Compensated phase of shock

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▪Earliest stage
▪Body can still compensate for blood loss.
▪Level of responsiveness is best indicator of
tissue perfusion (better than the other
signs).
▪Blood pressure is maintained.
Phases of Shock (4 of 5)

▪Compensated phase of shock

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(continued)
▪Blood loss in hemorrhagic shock can be
estimated at 15% to 30%.
▪*Narrowing of the pulse pressure occurs.
▪Positive orthostatic tilt test result
▪Treatment will typically result in recovery.
 Phases of Shock (5 of 5)

▪Decompensated phase of shock

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▪Blood pressure is falling.
▪Blood volume drops by more than 30%.
▪Compensatory measures begin to fail.
▪Signs and symptoms are more obvious - ie the skin becomes mottled and pupils dilate.*
▪Cardiac output falls dramatically.*
▪Treatment will sometimes result in recovery.**
▪IV and fluid therapy medical directive pg 183
▪https://www.health.gov.on.ca/en/pro/programs/emergency_health/docs/
advanced_life_support_patientcare_v5_2_en.pdf
The Clinical Picture of Hypovolemic Shock (1 of 5)

▪Typical signs and symptoms

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▪*Inadequate tissue oxygenation and the
attempt to compensate
▪Earliest signs of shock are restlessness and
anxiety…pt looks scared
▪Decline in tissue perfusion sets off alarms all
over the body.
The Clinical Picture of Hypovolemic Shock (2 of 5)

▪Typical signs and symptoms

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(continued)
▪If conscious, the patient may complain of
thirst and feel nauseated.
▪Skin becomes pale, cool, and clammy.
▪Heart speeds up to circulate the remaining
RBCs more rapidly.
The Clinical Picture of Hypovolemic Shock (3 of 5)

▪While arteries constrict and heart

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speeds up
▪Brain signals the respiratory muscles to
speed up their activity.
▪As bleeding continues
▪*The blood pressure falls.
▪Falling blood pressure is a late sign in
shock.
The Clinical Picture of Hypovolemic Shock (4 of 5)

▪Treatment goal

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▪Save the brain and kidneys.*
▪Best indication of brain perfusion is the
state of consciousness.
▪ If the patient is conscious and alert, the brain
is being perfused adequately.
▪ If the patient is confused, disoriented, or
unconscious, perfusion of the brain is likely
inadequate.
The Clinical Picture of Hypovolemic Shock (5 of 5)

▪Treatment goal (continued)

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▪Kidney perfusion can be gauged by urine
output.
▪ *Adequately perfused kidneys
▪ Poorly perfused kidneys shut down.
▪ Test for kidney perfusion in the prehospital
setting with capillary refill.**
 (continued
)

▪ You and your partner can focus on the patient for the entire 15-minute trip to the hospital. You

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insert a large-bore IV catheter and give normal saline. You have just enough time to repeat the
initial assessment before you call the ED to report the patient’s condition. The physician advises
you to insert a second IV line. Meanwhile, your partner prepares to begin ventilatory assistance
with a bag-mask device. The patient’s mental status has diminished, signaling he is truly fighting
for his life.
▪ When you return to the ED about 4 hours later, the patient is still holding on after a few hours of
intensive surgery. He had major internal bleeding and damage to his stomach and spleen and
major vessel damage from a bullet fragment. The ED physician states that in this case, the
patient’s best chance was the operating room. Because of your quick judgment about how to save
time on the scene and your willingness to call ahead so the ED was ready, the patient made it to
the operating room about 35 minutes after the shooting.

▪ Without interventions in the prehospital setting, how long would this patient have lived?
▪ What is the benefit of calling ahead and focusing on the time factor?
General Assessment of a Patient
With Suspected Shock (1 of 6)

▪Assessment plan

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▪Scene assessment for hazards
▪Standard precautions
▪Address the need for additional help
▪Initial assessment
▪Scene assessment
▪Also includes a quick assessment of the MOI
▪For a patient with suspected shock, this
information can give you clues about the
cause and the extent of any bleeding.
General Assessment of a Patient
With Suspected Shock (2 of 6)

▪Initial assessment

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▪Form an initial diagnosis.
▪Assess mental status.
▪Manage life threats to airway, breathing, and
circulation.
▪In conscious patients, assess the pulse at
the radius.
▪In unconscious patients, assess the carotid
pulse in the neck.
▪Radial pulse*
General Assessment of a Patient
With Suspected Shock (3 of 6)

▪Priority

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▪Patients with shock will usually be
prioritized as “high.”
▪*If the shock originates from a medical
problem
▪*If the shock originates from trauma
General Assessment of a Patient
With Suspected Shock (4 of 6)

▪SAMPLE history and baseline vital signs

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▪Can be done en route to the ED
▪Time is of the essence in shock cases.
▪Keep the on-scene care to essential items.
▪Delay inserting IV lines until en route.
▪Considered hypovolemic or hemorrhagic until ruled out
 Copyright © 2021 by Jones & Bartlett Learning, LLC an Ascend Learning Company. www.jblearning.com
General Assessment of a Patient
With Suspected Shock (5 of 6)

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General Assessment of a Patient
With Suspected Shock (6 of 6)

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Treatment of a Patient With Suspected Shock (1 of 4)

▪Airway and ventilation support

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▪Take top priority as with any patient.
▪Maintain an open airway, and suction as
needed.
▪Give high-flow supplemental oxygen.
▪Consider early definitive management in
patients who are unable to maintain their
own airway.
▪Control any external hemorrhage.
▪Try to estimate the amount of blood loss.
▪Look for signs of internal hemorrhage.
Treatment of a Patient With Suspected Shock (2 of 4)

▪IV fluid therapy

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▪ Two large-bore catheters
▪ Administer IV fluid to maintain perfusion.*
▪ Solutions of dextrose in water are not effective.
▪ Presence of radial pulses equates to systolic blood pressure of 80 to 90 mm Hg.
▪ Growing evidence suggests titration of systolic blood pressure to 80 to 90
mm Hg is preferred for hemorrhagic shock.
▪ This low pressure (permis­sive hypotension) may allow the body to clot better and not dis­-
lodge clots already formed.
▪ Consider the entire patient before using permissive hypotension.**
▪ Even a single episode of hypotension (systolic blood pressure