Hemodynamic Disorders, Thromboembolism, & Shock PDF 2024

Summary

This document provides an overview of pathophysiology and underlying mechanisms of hemodynamic disorders, thromboembolism, and shock, including edema, hemorrhage, hemostasis, thrombosis, embolism, ischemia, and infarction. The material is presented via objectives and recommended readings.

Full Transcript

HEMODYNAMIC DISORDERS, THROMBOEMBOLISM, &
SHOCK
DR. J. KUM
PATHOLOGY AND LABORATORY MEDICINE, WESTERN UNIVERSITY

OBJECTIVES:
1. Explain hyperemia and congestion and outline the differences in the underlying
mechanisms.
2. Define edema, effusion, and anasarca. Explain the various causes of edema and its
classification.
3. Define hemorrhage and describe various types of bleeds seen in tissues.
4. Explain hemostasis and the key molecules involved in the process.
5. Explain thrombosis and its cause, prognosis, and complications.
6. Differentiate between thrombus and embolus.
7. Become familiar with the types of embolism and know the effects.
8. Summarize the causes and effects of ischemia.
9. Define infarction, classify the types of infarcts, and explain the factors that influence
infarct development.
10. Explain the causes, types, and stages of shock.

Recommended readings:
"Robbins Basic Pathology" 11th Edition, 2023. Chapter 3 - Hemodynamic Disorders, Thromboembolism
and Shock (pages 57-78). Read relevant sections.

HYPEREMIA & CONGESTION

Hyperemia and congestion refer to an increase in blood volume within a tissue. However, these
have different underlying mechanisms.

Hyperemia Congestion

*This table will be discussed and may be completed during class.

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EDEMA

Edema is the accumulation of interstitial fluid within tissues. This results in the net movement of
water into extravascular spaces. Extravascular fluid can also collect in body cavities, where it is
referred to as an effusion (examples include hydrothorax; and hydroperitoneum, or ascites).

CAUSES OF EDEMA

1. Increased hydrostatic pressure (Figure 1B)
Increases in hydrostatic pressure are mainly caused by disorders that impair venous return or
increase arteriolar dilation.
Clinical examples:
o Deep venous thrombosis of the lower extremity
o Congestive heart failure:
i. Right side failure → peripheral edema
ii. Left side failure → lung edema
o Neurohumoral dysregulation

2. Reduced plasma osmotic pressure (Figure 1C)
Reduced plasma albumin is a common feature of disorders in which edema is caused by
decreases in colloid osmotic pressure.
Clinical examples:
o Liver disease (e.g., cirrhosis): decrease synthesis of albumin
o Damage to glomeruli allows albumin to pass into the urine

3. Lymphatic obstruction (Figure 1E)
Lymphatic obstruction that compromises resorption of fluid from interstitial spaces.
Clinical examples:
o Cancer
o Inflammation
o Post-surgical lymphedema

4. Sodium and water retention
Excessive salt and associated water retention can increase hydrostatic pressure and reduce
plasma osmotic pressure.
Clinical examples:
o Renal failure
o Poststreptococcal glomerulonephritis

5. Inflammation (Figure 1D)
Increased vascular permeability in inflammation can result in edema.
Clinical examples:
o Acute inflammation
o Chronic inflammation

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\
FIGURE 1:
The capillary system and
mechanisms of edema
formation.

(A) Normal. The
differential between the
hydrostatic and oncotic
pressures at the arterial
end of the capillary
system is responsible for
the filtration into the
interstitial space of
approximately 14mL of
fluid per minute. This
fluid is reabsorbed at the
venous end at the rate of
12 mL/min. It is also
drained through the
lymphatic capillaries at a
rate of 2 mL/min.
Proteins are removed by
the lymphatics from the
interstitial space.

(B) Hydrostatic
Edema. If the
hydrostatic pressure at
the venous end of the
capillary system is
elevated, reabsorption is
decreased. If the
lymphatics are able to
drain the surplus fluid,
no edema results. If their
capacity is exceeded,
however, edema fluid
accumulates.

(C) Oncotic
Edema. Edema fluid
also accumulates if reabsorption is diminished by a decrease in the oncotic pressure of
the vascular bed, owing to a loss of albumin.

(D) Inflammatory and Traumatic Edema. Edema, either local or systemic, results if the
vascular bed becomes leaky following injury to the endothelium.

(E) Lymphedema. Lymphatic obstruction causes the accumulation of interstitial fluid
because of insufficient reabsorption and deficient removal of proteins, the latter
increasing the oncotic pressure of the fluid in the interstitial space.

“Essential Pathology”, Rubin & Farber, 2nd Edition 1995, J.B. Lippincott Company, p173.

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Edema is classified into two types:
o Localized edema: occurs due to
increased hydrostatic pressure due to vascular obstruction (local)
Lymphatic obstruction: compression by tumour or inflammation (local)

o Generalized edema: occurs due to
increased hydrostatic pressure (e.g., heart failure)
decreased oncotic pressure (colloid osmotic pressure) due to:
- loss of albumin in renal failure
- decreased synthesis of albumin (liver failure)
Sodium retention → kidney disease

Other terminologies to be familiar with:
o Transudate
Edema fluid due to high hydrostatic pressure or low colloid pressure is a protein-poor
transudate.

o Exudate
Edema fluid due to increased vascular permeability, inflammatory edema fluid is a
protein-rich exudate.

HEMORRHAGE

Hemorrhage (bleeding) is the extravasation (discharge or escape) of blood from the blood vessels
into the surrounding tissues or to the exterior of the body or into a body cavity.

CAUSES OF HEMORRHAGE

Damage to the blood vessels and may be exacerbated by defects in blood clotting.
o Trauma to large blood vessels due to surgical procedures or fracture
o Weakened artery (from atherosclerosis, congenital weakness)
o Infections (e.g., pulmonary tuberculosis)
o Invasive tumours (erosion of vessel wall)
o Hypertension (increase intraluminal blood pressure)
o Hemorrhagic diatheses (spontaneous hemorrhage) affecting capillaries (small blood
vessels) including:
Thrombocytopenia
Severe decrease in the number of platelets
Deficiency of coagulation/clotting factors

Other terminologies to be familiar with:
o Hematoma: blood accumulation within a tissue.
Large bleeds into body cavities are described according to their location.
- Hemothorax: Collection of blood in the pleural cavities due to trauma or rupture
of the aorta.
- Hemopericardium: Collection of blood in the pericardial cavity around the heart
due to rupture of the heart or the aorta.
- Hemoperitoneum: Collection of blood in the abdominal cavity due to rupture of
an aortic aneurysm or trauma to the liver, spleen, or aorta.
- Hemarthrosis: Collection of blood in the joint cavity.

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 o Petechia: a pinpoint hemorrhage (1-2 mm); represents the rupture of capillaries and
mainly involves the skin, mucous membranes, and serosal surfaces. Causes include
thrombocytopenia, defective platelet function, and vitamin C deficiency (scurvy).

o Purpura: slightly larger hemorrhages (3-5 mm). Causes include those that cause
petechiae, as well as trauma, vasculitis, and increased vascular fragility.

o Ecchymosis: a larger, subcutaneous hematomas (e.g., bruises) (1-2 cm). Skin
discoloration reflects products of heme degradation from hemoglobin in the extravasated
red cells.

HEMOSTASIS & THROMBOSIS

HEMOSTASIS

Hemostasis is a precisely orchestrated process initiated by a traumatic vascular injury that leads
to the formation of a blood clot to prevent or limit the extent of bleeding. This process involves
platelets, clotting factors, and endothelium, and is broken down into four steps:
o Transient arteriolar vasoconstriction
o Primary hemostasis: formation of the platelet plug
o Secondary hemostasis: deposition of fibrin
o Clot stabilization

THROMBOSIS

Thrombosis is the pathological counterpart to hemostasis. It is the formation of a clot (a thrombus)
in the blood vessels that have been damaged by a disease process.

A thrombus consists of:
o Red blood cells
o White blood cells
o Platelets
o Fibrin

CAUSES OF THROMBOSIS: “Virchow triad”

o Endothelial injury
injury → tear
inflammation

o Abnormal blood flow
stasis (slow circulation)
- lack of activity
- decreased cardiac output
- increased blood viscosity

o Hypercoagulability
Changes in blood composition: ↑ platelets

PROGNOSIS (outcome) OF THROMBOSIS

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 o Propagation
o Embolization
o Dissolution
o Organization and recanalization

COMPLICATIONS OF THROMBI
o Fragments of thrombus may break off and result in thromboembolization/emboli.
o Reduced blood flow to a tissue/organ resulting in ischemic injury or infarction.

EMBOLISM

An embolus is a detached intravascular mass transported from its point of origin to a distant site
through the bloodstream, where it can cause tissue dysfunction or infarction.

TYPES OF EMBOLI
o Thrombi
The most common type of emboli
Thromboemboli arise from thrombi and can range in size from microscopic to those
which are large enough to occlude major arteries
Thromboemboli may occur in either arteries or veins
o Gas (bubbles of air or nitrogen)
o Fat (often fracture of large bones)
o Tumour
o Others (e.g., foreign body)

ISCHEMIA & INFARCTIONS

ISCHEMIA

Ischemia is a condition in which blood flow is restricted or reduced to an area of tissue.

CAUSES OF ISCHEMIA

o Decreased blood supply (inadequate cardiac output)
o Obstruction of blood vessel by
thrombus
embolus
pressure (outside pressure)
damage of the vessel wall (e.g., inflammation)

PROGNOSIS OF ISCHEMIA (depends on the degree of ischemia)

o If there is an alternate blood supply, no effect
o If severe and complete, infarction (necrosis)

INFARCTION

An infarct is an area of ischemic necrosis caused by occlusion of the vascular supply of the

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affected tissue. Infarction is an irreversible process, and most infarcts are ultimately replaced by
fibrosis (fibrotic scar).

CLASSIFICATION OF INFARCTS

Based on colour:
o Red (hemorrhagic) infarct
Venous or arterial occlusion
Tissues with dual blood supply (e.g., lung and small intestine)
Previously congested tissue (sluggish venous outflow)
Re-established flow after infarction has occurred (e.g., after angioplasty of an
arterial obstruction)
o White (anemic) infarct
Arterial occlusion in solid organs (e.g., heart, spleen, kidney, brain)
Wedge-shaped

Presence or absence of microbial infections:
o Septic
infarct converted into an abscess, with correspondingly greater inflammatory
response and healing by organization and fibrosis.
o Bland

INFLUENCING FACTORS ON INFARCT DEVELOPMENT

The effects of vascular occlusion range from inconsequential to tissue necrosis leading to organ
dysfunction and sometimes death. The range of outcomes is influenced by the following:

Anatomy of the vascular supply

Rate of occlusion

Tissue vulnerability to hypoxia

*This table will be discussed and may be completed during class.

SHOCK

Shock is a state in which diminished cardiac output and/or reduced effective circulating blood
volume (failure of the circulatory system to maintain an appropriate blood supply) impairs tissue
perfusion and leads to cellular hypoxia. It is a state of systemic tissue hypoperfusion.

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 Categories of shock:
o Cardiogenic shock
The inability of the heart to pump blood due to myocardial damage (myocardial
infarction), extrinsic compression (cardiac tamponade - fluid accumulation in the
pericardial sac that compresses the heart), or outflow obstruction (e.g., pulmonary
embolism).
o Hypovolemic shock
Due to loss of blood or plasma volume, resulting in low cardiac output.
- E.g., fluid loss from severe burn

Cardiogenic and hypovolemic shock result in decreased perfusion.

o Septic shock
Triggered by microbial infections and is associated with severe systemic
inflammatory response syndrome (SIRS).
Mechanism: massive outpour of inflammatory mediators from innate and adaptive
immune cells that produce arterial vasodilation, vascular leakage, and venous
blood pooling. These abnormalities result in tissue hypoperfusion, cellular hypoxia,
and metabolic derangements that lead to organ dysfunction. If severe and
persistent, it will lead to organ failure and death.

Less common:
o Neurogenic shock
Loss of vascular tone associated with anesthesia or secondary to spinal cord
injury.
o Anaphylactic shock
Triggered by IgE-mediated hypersensitivity reaction (e.g., allergic reaction to
ingested peanuts) that leads to systemic vasodilation and increased vascular
permeability.

Peripheral vasodilation is associated with anaphylaxis, neurogenic and septic
shock (due to the release of factors (cytokines, bacterial endotoxins, etc.) that cause
dilation and increased permeability of the vessels).

STAGES OF SHOCK (for hypovolemic and cardiogenic shock)

o Nonprogressive stage: reflex compensatory mechanisms are activated, and vital organ
perfusion is maintained.
o Progressive stage: tissue hypoperfusion and the onset of worsening circulatory and
metabolic derangement, including acidosis (widespread tissue hypoxia; vital organs begin
to fail).
o Irreversible stage: cellular and tissue injury is so severe that survival is not possible even
if the hemodynamic defects are corrected.

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STUDENT NOTES:

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