Hemodynamics PDF

Summary

This document covers various types of embolisms, including pulmonary, systemic, fat, air, and amniotic fluid embolisms. It also describes infarction and hemostasis. The document uses diagrams and illustrations to explain these concepts in detail, providing a comprehensive overview of these processes.

Full Transcript

 EMBOLISM

An embolus is a detached intravascular solid, liquid, or gaseous mass that
is carried by the blood from its point of origin to a distant site, where it
often causes tissue dysfunction or infarction. The vast majority of emboli
are dislodged thrombi, hence the term thromboembolism. Other rare
emboli are composed of fat droplets, nitrogen bubbles, atherosclerotic
debris (cholesterol emboli), tumor fragments, bone marrow, or even foreign
bodies. Emboli travel through the blood until they encounter vessels too
small to permit further passage, causing partial or complete vascular
occlusion.
Pulmonary Embolism (PE)

Pulmonary emboli originate from DVT and are
the most common form of thromboembolic
disease. Fragmented thrombi from DVT are
carried through progressively larger veins and
the right side of the heart before slamming into
the pulmonary arterial vasculature. Depending
on the size of the embolus, it can occlude the
main pulmonary artery, straddle the pulmonary
artery bifurcation (saddle embolus), or pass
out into the smaller, branching arteries.
 Pulmonary Embolism (PE)
Sudden death, acute right heart failure (cor pulmonale), or cardiovascular
collapse occurs when emboli obstruct 60% or more of the pulmonary circulation.
Embolic obstruction of medium-sized arteries with subsequent vascular rupture
can result in pulmonary hemorrhage but usually does not cause pulmonary
infarction. This is because the lung is supplied by both the pulmonary arteries
and the bronchial arteries, and the intact bronchial circulation is usually
sufficient to perfuse the affected area. Understandably, if the bronchial arterial
flow is compromised (e.g.,by left-sided cardiac failure), infarction may occur.
Embolic obstruction of small end-arteriolar pulmonary branches often does
produce hemorrhage or infarction.
Multiple emboli over time may cause pulmonary hypertension and right
ventricular failure.
 Systemic Thromboembolism
Most systemic emboli (80%) arise from intracardiac mural thrombi, two-thirds of
which are associated with left ventricular wall infarcts and another one-fourth with
left atrial dilation and fibrillation. The remainder originates from aortic aneurysms,
atherosclerotic plaques, valvular vegetations, or venous thrombi (paradoxical
emboli); 10% to 15% are of unknown origin. In contrast to venous emboli, the vast
majority of which lodge in the lung, arterial emboli can travel to a wide variety of
sites; the point of arrest depends on the source and the relative amount of blood
flow that downstream tissues receive.
 Systemic Thromboembolism

Most come to rest in the lower extremities (75%) or the brain
(10%), but other tissues, including the intestines, kidneys,
spleen, and upper extremities, may be involved. The
consequences of systemic emboli depend on the vulnerability of
the affected tissues to ischemia, the caliber of the occluded
vessel, and whether a collateral blood supply exists; in general,
however, the outcome is tissue infarction.
 Fat Embolism

Trauma Vascular Fat globules

After fracture of long Rupture vascular sinusoid Fat travel to the lung
bones, soft tissue trauma, in the marrow allowing
burns marrow or adipose tissue
to herniate into the
vascular space
 Fat Embolism syndrom

tacypneu
Pulmonary Insufficiency dyspneu
Tachycardia

Irritability
Neurologic symptom Restlessness
Delirium or coma

Anemia and Diffuse petechial rasht
Thrombocytopenia

Fatal in 5%-15% cases t
Fat Embolism
Fat microemboli and associated
red cell and platelet aggregates
and occlude and the pulmonary
and cerebral microvasculature.
release of free fatty acids from the
fat globules exacerbates the
situation by causing local toxic
injury to endothelium, and platelet
activation and granulocyte
recruitment (with free radical,
protease, and eicosanoid release)
complete the vascular assault.
Air Embolism
Gas bubbles within the circulation can coalesce to form frothy masses that
obstruct vascular flow and cause distal ischemic injury

Mechanism → intense inflammatory
response with release of cytokines that
may injure the alveoli
300-500 ml of air
100 ml at 100 mL/ sec
Bubbles in the central nervous system can
cause mental impairment/ sudden onset of
coma.

Kumar V, Abbas AK, Aster JC, Turner JR. Robbins & Cotran Pathologic Basis of Disease. 10th ed. Philadelphia: Elsevier; 2021.
p.132-134​
Decompression Sickness
Bends, chokes,
air is breathed at high pressure
stagger

increased amounts of gas

dissolved in the blood and tissues

ascends too rapidly Caisson disease

nitrogen comes out of solution in
the tissues and the blood

Kumar V, Abbas AK, Aster JC, Turner JR. Robbins & Cotran Pathologic Basis of Disease. 10th ed. Philadelphia: Elsevier; 2021.
p.132-134​
Amniotic Fluid Embolism
Amniotic fluid and its content enters the uterine veins and embolize
5th cause of maternal mortality worldwide

Characterized:
Severe dyspnea
Cyanosis
Shock
Neurologic impairment → headache to seizures and coma

Kumar V, Abbas AK, Aster JC, Turner JR. Robbins & Cotran Pathologic Basis of Disease. 10th ed. Philadelphia: Elsevier; 2021.
p.132-134​
 Tear in the placental membranes or rupture of uterine veins

Biochemical activation of coagulation factors, components of the innate immune
system, and release of vasoactive substances

Acute pulmonary hypertension and right heart failure, which causes hypoxia, left
heart failure, pulmonary edema, and diffuse alveolar damage

Autopsy and microscopic examination may
show hair, mucin, and fetal squames in
maternal pulmonary microvasculature

Kumar V, Abbas AK, Aster JC, Turner JR. Robbins & Cotran Pathologic Basis of Disease. 10th ed. Philadelphia: Elsevier; 2021.
p.132-134​
INFARCTION → an area of ischemic necrois caused by occlusion of either the arterial supply or the venous
drainage.

Red Infarction White Infarct

Venous occlusions Arterial occlusions in solid
organs with end-arterial
circulation

Loose, spongy tissues Tissue density limits the
seepage of blood from
adjoining capillary beds into
Tissues with dual circulations the necrotic area.

Tissues previously congested
by sluggish venous outflow

Flow is reestablished to a site
of previous arterial occlusion
and necrosis

Kumar V, Abbas AK, Aster JC, Turner JR. Robbins & Cotran Pathologic Basis of Disease. 10th ed. Philadelphia: Elsevier; 2021.
p.132-134​
Kidney – Infarct – NUS Pathweb :: NUS Pathweb
Factors That Influence Development of an Infarct
Anatomy of the vascular supply Rate of occlusion
(alternative blood supply)

Meier, P., Schirmer, S.H., Lansky, A.J. et al. The collateral
circulation of the heart. BMC Med 11, 143 (2013).
https://doi.org/10.1186/1741-7015-11-143

Tissue vulnerability to hypoxia Hypoxemia
(low blood oxygen content)

Kumar V, Abbas AK, Aster JC, Turner JR. Robbins & Cotran Pathologic Basis of Disease. 10th ed. Philadelphia: Elsevier; 2021.
p.132-134​
 Normal Hemostasis

Essential for life.
Orchestrated process involving platelets, clotting
factors, and endothelium that occurs at the site of
vascular injury and culminates in the formation of a
blood clot, which serves to prevent or limit the
extent of bleeding.

Kumar V, Abbas AK, Aster JC, Turner JR. Robbins & Cotran Pathologic Basis of Disease. 10th ed. Philadelphia: Elsevier; 2021.
p.118-120​
General sequence of hemostasis
Arteriolar
vasoconstriction.
Reduces blood flow to the
injured area
Mediated by reflex
neurogenic mechanism
may be augmented by the
local secretion of factors
such as endothelin
Having transient effect.
Kumar V, Abbas AK, Aster JC, Turner JR. Robbins & Cotran Pathologic Basis of Disease. 10th ed. Philadelphia: Elsevier; 2021.
p.118-120​
General sequence of hemostasis
The formation of the platelet
plug.
Disruption of the endothelium 🡪
exposes subendothelial von
Willebrand factor (vWF) and
collagen🡪 platelet adherence
and activation.
Activation of platelet results in a
dramatic shape change, as well
as the release of secretory
granules.
Within a few minutes, the secreted
products recruit additional
platelets
Kumar V, Abbas AK, Aster JC, Turner JR. Robbins & Cotran Pathologic that
Basis of Disease. undergo
10th ed. Philadelphia: Elsevier; 2021.
aggregation to form a primary
p.118-120​
General sequence of hemostasis
2. Deposition of fibrin.
Vascular injury 🡪 exposes tissue
factor 🡪 Tissue factor binds and
activates factor VII 🡪 cascade of
reactions that culminates in
thrombin generation.
Thrombin cleaves circulating
fibrinogen into insoluble
fibrin, creating a fibrin
meshwork, and also is a potent
activator of platelets, leading to
additional platelet
aggregation at the site of
injury.
Kumar V, Abbas AK, Aster JC, Turner JR. Robbins & Cotran Pathologic Basis of Disease. 10th ed. Philadelphia: Elsevier; 2021.
p.118-120​
General sequence of hemostasis
Clot stabilization and
resorption
Polymerized fibrin and platelet
aggregates form a solid,
permanent plug that prevents
further hemorrhage.
Counterregulatory
mechanisms (e.g., tissue
plasminogen activator [t-PA]
made by endothelial cells) are
set into motion that limit clotting
to the site of injury and lead to
clot resorption and tissue repair.

Kumar V, Abbas AK, Aster JC, Turner JR. Robbins & Cotran Pathologic Basis of Disease. 10th ed. Philadelphia: Elsevier; 2021.
p.118-120​
Normal Hemostasis
Endothelial cells are central regulators of
hemostasis → the balance between the antithrombic
and prothrombotic activities of endothelium
determines whether thrombus formation,
propagation, or dissolution occur.

Kumar V, Abbas AK, Aster JC, Turner JR. Robbins & Cotran Pathologic Basis of Disease. 10th ed. Philadelphia: Elsevier; 2021.
p.118-120​
Platelets
- Disc-shaped anucleate cell fragments from
megakaryocytes in the bone marrow into the
bloodstream.
- Critical role in hemostasis by forming the primary
plug that initially seals vascular defects and by
providing a surface that binds and concentrates
activated coagulation factors.
- Their function depends on several glycoprotein
receptors, a contractile cytoskeleton, and two
types of cytoplasmic granules.

Kumar V, Abbas AK, Aster JC, Turner JR. Robbins & Cotran Pathologic Basis of Disease. 10th ed. Philadelphia: Elsevier; 2021.
p.118-120​
Platelets adhesion and aggregation

Kumar V, Abbas AK, Aster JC, Turner JR. Robbins & Cotran Pathologic Basis of Disease. 10th ed. Philadelphia: Elsevier; 2021.
p.118-120​
Coagulation Cascade
Coagulation Cascade
Definition: A series of amplifying enzymatic reactions that
lead to the deposition of an insoluble fibrin clot.
Part of secondary hemostasis.
Leads to deposition of fibrin & consolidates the initial
platelet plug.
Based on assay performed in clinical laboratories: divided
into extrinsic and intrinsic pathway.

Kumar V, Abbas AK, Aster JC, Turner JR. Robbins & Cotran Pathologic Basis of Disease. 10th ed. Philadelphia: Elsevier; 2021.
p.120-124​
 Clotting in Laboratory vs In Vivo
Prothrombin time
(PT) assay:
assesses the
function of the
proteins in the
extrinsic pathway
(factors VII, X, V, II
(prothrombin), and
fibrinogen).

Partial thromboplastin
time (PTT) assay:
* vit. K-dependent screens the function
of the proteins in the
intrinsic pathway
(factors XII, XI, IX, VIII,
X, V, II, and
fibrinogen).
Coagulation Cascade
Important initiator → tissue factor.
Most important anticoagulant factor
→ thrombin. Its most important
activities are the following:
○ Conversion of fibrinogen into cross-
linked fibrin
○ Platelet activation
○ Pro-inflammatory effects → to mediate
pro-inflammatory effects that contribute
to tissue repair and angiogenesis.
○ Anticoagulant effects (reversal in
function prevents clots from extending
beyond the site of the vascular injury.
Kumar V, Abbas AK, Aster JC, Turner JR. Robbins & Cotran Pathologic Basis of Disease. 10th ed. Philadelphia: Elsevier; 2021.
p.120-124​
 Factors that Limit
Coagulation
Coagulation must be restricted to the Expression of thrombomodulin on
site of vascular injury to prevent normal endothelial cells, which binds
& convert thrombin to an
deleterious consequences. anticoagulant.
Coagulation normally is restricted to Activation of fibrinolytic pathways
sites of vascular injury by: (by association of tissue
Limiting enzymatic activation to plasminogen activator [t-PA] with
fibrin).
phospholipid surfaces provided by
activated platelets or endothelium.
Circulating inhibitors of coagulation
factors, such as antithrombin III,
whose activity is augmented by
heparin-like molecules expressed
on endothelial cells.

Kumar V, Abbas AK, Aster JC, Turner JR. Robbins & Cotran Pathologic Basis
of Disease. 10th ed. Philadelphia: Elsevier; 2021. p.120-124​
Endothelium
Antithrombotic properties of endothelium:

Anticoagulan
Platelet inhibitory effects
Procoagulant
t As a barrier of platelets from
subendothelial vWF and collagen.
Release factors → prostacyclin (PGI2), nitric
oxide (NO), and adenosine diphosphatase
→ inhibit platelet activation and
aggregation.
The balance often determines → clot formation /
Anticoagulant effects
propagation / dissolution.
Shields coagulation factors from tissue
Normal endothelial cells express: factor → in vessel walls.
Anticoagulant factors (inhibit the platelet Expresses multiple factors →
aggregation & coagulation process) → prevent thrombomodulin, endothelial protein C
thrombosis, limit clotting to sites of vascular receptor, heparin-like molecules, tissue
factor pathway inhibitor → bind thrombin →
damage.
thrombin lose its procoagulation function.
In injury or exposed to pro-inflammatory factors:
Fibrinolytic effects
Endothelium lose many of their antithrombotic Synthesize t-PA (a key component of
properties.
fibrinolytic pathway).
Endothelium
Anticoagulant
activities of
normal
endothelium

Procoagulant
properties of
injured or activated
endothelium

Kumar V, Abbas AK, Aster JC, Turner JR. Robbins & Cotran Pathologic Basis of Disease. 10th ed. Philadelphia: Elsevier; 2021.
Endothelial Injury Alterations in Hypercoagulabilit Fate of the
Normal Blood y Thrombus
Flow

Endothelial injury leading to Turbulence contributes to Hypercoagulability refers to Thrombus development
platelet activation almost arterial and cardiac an abnormally high tendency usually is related to one or
more components of the
inevitably underlies thrombus thrombosis by causing of the blood to clot, and is
Virchow triad
formation in the heart and the endothelial injury or typically caused by
arterial circulation, where the dysfunction as well as by alterations in coagulation
high rates of blood flow forming countercurrents that factors
impede clot formation contribute to local pockets of
stasis, whereas stasis is a
major contributor to the
development of venous
thrombi

Here it suffices to mention Turbulence and stasis Hypercoagulability has a If a patient survives the initial
several of the major therefore: particularly important role in thrombosis, in the ensuing
prothrombotic alterations: Promote endothelial venous thrombosis and can days to weeks thrombi
Procoagulant changes. activation be divided into primary undergo some combination of
Antifibrinolytic effects. Disrupt laminar flow (genetic) and secondary the following four events:
Prevent washout and (acquired) disorders. Propagation
dilution of activated clotting Embolization.
factors Dissolution.
Organization and
Morphology of Thrombosis
1. Arterial Thrombosis
- Turbulence / Endothelial Injury
- Grow retrograde
- Frequently Occlusive
- These are usually happened on a
ruptured atherosclerotic plaque /
Source picts: Thrombosis (An Over
other vascular injuries view): Causes, Symptoms & Diagno
1. Venous Thrombosis sis (myhematology.com)
- Stasis
- Extend in direction of blood flow
- Occlusive
- Consist of lines of Zahn
- 90% involved at lower extremities

Kumar V,Abbas AK,Aster JC,Turner JR. Robbins & Cotran Pathologic Basis of Disease. 10th.ed.
Philadelphia: Elsevier;2021. p.128-129
Kumar V,Abbas AK,Aster JC,Turner JR. Robbins & Cotran Pathologic Basis of Disease. 10th.ed. Lines of Zahn:
Philadelphia: Elsevier;2021. p.128-129
- Platelet, fibrin (pucat)
- Tumpukan sel darah
merah (merah gelap)

Source pict: JaypeeDigital | Obstructive Circulatory Dis
Dissaminated Intravascular
Coagulation (DIC)

Gando, S., Levi, M. & Toh, CH. Disseminated intravascular coagulation. Nat Rev Dis Primers 2, 16037 (2016).
https://doi.org/10.1038/nrdp.2016.37
Dissaminated Intravascular Coagulation (DIC)

Merupakan suatu keadaan dimana terjadinya
trombosis yang tersebar pada seluruh pembuluh
darah kecil
Secara bersamaan terjadi proses fibrinolisis
Menyebabkan penyumbatan pada pembuluh
darah kecil dan berkurangnya faktor pembekuan
yang diperlukan untuk mengendalikan
perdarahan
DIC bukanlah suatu penyakit primer, melainkan
suatu komplikasi berbahaya dari berbagai
keadaan yang berkaitan dengan aktivasi trombin
Akibat yang Ditimbulkan oleh DIC

Terjadi pengendapan fibrin
yang tersebar luas dalam Terjadi diatesis perdarahan
mikrosirkulasi
Contoh Kondisi yang Memicu DIC

Komplikasi
Sepsis Trauma Kanker
Kehamilan

Infeksi berat, Cedera berat dapat Sel-sel tumor, Emboli cairan
terutama yang menyebabkan terutama kanker ketuban, solusio
disebabkan oleh pelepasan zat-zat pankreas dan plasenta, atau
bakteri gram prokoagulan dari leukimia eklampsia, di
negatif dan gram jaringan yang promyelositik mana produk-
positif rusak akut, dapat produk janin atau
melepaskan faktor plasenta masuk
jaringan (TF) dan ke sirkulasi ibu
zat prokoagulan dan memicu DIC
lainnya
SHOCK
What is shock?
Shock is a state of circulatory failure that impairs tissue perfusion and
leads to cellular hypoxia.
 3 General Categories
of shock

Cardiogenic:
Myocardial pump Hypovolemic Sepsis. Septic
failure🡪low shock: shock, and the
cardiac output. Low blood volume🡪 inflammatory
low cardiac output. response
syndrome.
Et causa: intrinsic
myocardial damage Et causa: massive
(infarction), hemorrhage, fluid
ventricular loss from severe
arrhytmias, extrinsic burns.
compression.
Septic shocks🡪 a subset of sepsis in which particularly profound
circulatory, cellular, and metabolic abnormalities🡪 greater risk of
mortality.

Systemic inflammatory response syndrome (SIRS)🡪 sepsis-like condition
associated with systemic inflammation that may be triggered by variety
of nonmicrobial insults🡪 burn, trauma.

Sepsis🡪 life-threatening organ dysfunction et causa a dysregulated host
response to infection.
Major factors contributing to the pathophysiology of septic shock are
following :
1. Inflammatory mediators.
2. Endothelial cell activation and injury.
-Has 3 major sequele-thrombosis,increase vascular permiability,vasodilation
3. Metabolic abnormalities.
-Septis patient exhibit insulin resistance and hyperglycemia.
-Cytokines such as TNF & IL-1,stress induced
hormone(glucagon,catecholamines)🡪gluconeogenesis.
-At the same time the pro-inflammatory cytokines🡪suppress insulin
🡪resistance in the liver & other tissue🡪Hyperglycemia🡪reduced neutrophil
function & bactericidal activity.
4. Organ disfunction.
-Systemic hypotension, interstitialedema, microvascular dysfunction, and small vessel
thrombosis🡪 the delivery of oxygen and nutrients to the tissues that, because of cellular
hypoxia, fail to properly use those nutrients that are delivered🡪 failure of multiple organs.
 STAGES OF SHOCK

An initial non progressive stage
In this phage a varieties of neuro-hormonal &
haemostatic mechanism helps to maintain cardiac out-
put & blood pressure.

A progressive stage
tissue hypoperfusion and onset of worsening
circulatory and metabolic derangement, including
acidosis.

An irreversible stage
in which cellular and tissue injury is
so severe that even if the hemodynamic defects
are corrected,
survival is not possible.
CLINICAL PRESENTATION
OF SHOCK
⚫ Altered mental status-Restless,confusion,stupor,coma,agitation
⚫ Patient may unconscious or semi-conscious
⚫ Pallor
⚫ Increase sweating
⚫ Cold clammy skin. Warm in septic shock
⚫ Pulse-Tachycardia, rapid weak thready pulse
⚫ Respiration-Tachypnia, slow and regular
⚫ Blood pressure-low blood pressure
⚫ Temperature may or may not be raised
⚫ Dehydration
⚫ Reduce urine output