Hemodynamics class 3.pptx

Hemodynamic
Disorders
Dr Shallo Alemu
5/28/2023 hemodynamics 1

Hemostasis and thrombosis
• Hemostasis is a precisely
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

Hemostasis and thrombosis
• Normal hemostasis – rapid and localized hemostatic plug formation at a
site of vascular injury.
• Thrombosis
• Pathologic opposite to hemostasis.
• Inappropriate activation of normal hemostatic process:
• Clot (thrombus) in uninjured vessel
• Thrombotic occlusion of a vessel after minor injury

• Both hemostasis and thrombosis depends on 3 components:
• Endothelium
• Platelet
• Coagulation cascade

Normal
hemostasis
• Sequence of events at sites of
vascular injury:
I. Arteriolar vasoconstriction
II. Primary hemostasis (platelet
plug)
III. Secondary hemostasis – fibrin
deposition
IV. Permanent plug
• Polymerized fibrin and platelet
aggregate
V. Counter regulatory response
• Restricts hemostatic plug at site of
injury
• Tissue plasminogen activator

So when does the process of
coagulation becomes pathologic?
• If body is unable to mount coagulation,  bleeding diathesis
• Platelets (number, functional abnormalities)
• Clotting factor deficiencies
• Hemophilia A,B and C
• Vascular abnormalities
• Vasculitis or amyloidosis

Hemophilia

Virchow's triads
• If thrombosis is obstinate and
excess

Endothelium
• Prothrombic properties
• vWF
• Tissue factor
• Tissue plasminogen activator
inhibitor (t-PAI)
• Antithrombotic properties
• Heparin like molecules
• Tissue factor pathway inhibitor
• Thrombin receptor and
Thrombomodulin
• Prostacyclin, NO, ADPase,
• t-PA

Endothelial injury
• Most important factor in thrombus formation
• Exposure to the highly thrombogenic sub endothelial ECM (collagen & tissue
factors)  platelet adherence & contact activation

Stasis or turbulence blood flow
• Normal blood flow is laminar.
• Stasis & turbulence brings platelets to the surface and reduce PGI2, t-PA
• Stasis is major factor in venous thrombi
• Turbulence is pathogenesis mzm for arteries and cardiac thrombosis

Hypercoagulability
• Any alteration of the coagulation
pathway that predisposes to
thrombosis
• Primary hypercoagulable states
• Mutations in factor V (Leiden factor)
• Mutation in prothrombin gene
• Antithrombin III deficiency
• Protein C or S deficiency
Secondary hypercoagulable states
• High risk
• Prolonged immobilization
• Myocardial infarction
• Tissue damage
• Cancers
• DIC
• Low risk factors
• Atrial fibrillation
• Cardiomyopathy
• Oral contraceptives
• Smoking
• Hyper estrogenic states E.g –pregnancy

Cont’d,…
• Don’t forget these terms
• Mural thrombi
• Vegetation
• The most common site of
arterial thrombi in increasing
order of frequency
• Femoral arteries
• Cerebral arteries
• Coronary arteries
• Common site venous
thromboembolism
• Leg veins
• Vena cava
• Dural venous sinuses

• Fates of thrombus
• Propagation
• Dissolution
• Embolization
• Organization & recanalization

Clinical significance
• Thrombi are clinically significant because:
• They can cause blood vessel obstruction (arterial thrombi causing myocardial
infarction) or
• Possible sources of emboli (venous thrombi causing pulmonary embolism, deadly
complication)

Venous thrombosis
(phlebothrombosis)
• Affects the lower extremity
veins~90%
• Divided in to
• superficial and
• deep venous thrombosis
• Superficial VT
• Usually occurs in saphenous venous
system
• E.g in varicosities
• Predisposes to infection after
slight trauma  Varicous Ulcer
• Rarely embolizes
• Causes local edema ,pain
,tenderness(i.e symptomatic

Deep Vein Thrombosis (DVT)
• May embolize, hence serious
• Occurs in deep veins of calf muscles
• May cause pain or edema
• Asymptomatic in ~50%, because of collateral bypass channels. Might be
noted after causing pulmonary embolism.
• Higher incidence in middle aged & elderly people ,due to increased
platelet aggregation & decreased PGI2 by endothelium

Predisposing factors to DVT
• Trauma, surgery, prolonged bed
rest
• Reduced physical activity
• Injury to vessels
• Procoagulant release from tissues
• Reduced t-PA activity (fibrinolysis)
• Pregnancy & puerperal states
• Increase coagulation factors &
decrease synthesis of antithrombic
substances
• Myocardial infarction & heart
failure  stasis in the left side

• Malnutrition, debilitating conditions (cancer)  marantic thrombosis
• Inflammation of veins (thrombophlebitis)
• Migratory thrombophlebitis- unknown etiology
• sometimes associated with cancer, especially pancreatic cancer  Trosseau
syndrome

Arterial thrombosis
• Following abnormal vessel wall & turbulence is commonest predisposing
factor
• Myocardial infarction causing dyskinetic contraction & endocardial
damage.
• May narrow or occlude the lumen of arteries such as coronary &cerebral
arteries  myocardial & cerebral infarctions respectively

Embolism
Embolus –detached intravascular solid, liquid or gaseous mass that is carried by blood to sites
distant from its point of origin.

Causes of embolism
• Thrombus (90% cases) 
thromboembolic
• Unless specified embolism 
thromboembolism
• Platelet aggregates
• fragment of a tumor
• Less commonly, emboli are
composed of fat droplets, bubbles
of air or nitrogen, atherosclerotic
debris
(cholesterol emboli), tumor
fragments, bits of bone marrow,
or amniotic fluid

• Thromboembolism, based on the
site of origin & impaction, is
divided in to:
• Pulmonary thromboembolism (PTE)
• Systemic thromboembolism
• Crossed embolism(paradoxical
embolism)

Consequences
• Systemic embolization
• Ischemic necrosis (infarction) of downstream tissues, whereas
• Embolization in the pulmonary circulation
• Hypoxia, hypotension, and right-sided heart failure

Pulmonary thromboembolism
• Embolus in the pulmonary
arteries & their branches
• Derived from thrombus in the
systemic veins or right side of
the heart.
• ~95% arise from deep leg veins and
follows venous return, pass
through heart and arrest pulmonary
arteries
a. If large thrombus  block
right ventricle out flow or
bifurcation of the main
pulmonary trunk (saddle
embolus) or both of its
branches  sudden
circulatory arrest and death
b. It may result in cor-
pulmonale or CVA collapse if
60% of blood volume is
obstructed

Very small embolus (60-80% of cases)
• Clinically silent, obstruction of medium sized arteries these embolus
may cause pulmonary hemorrhage but not infarction, because
collaterals from bronchial circulation.
• But in poor cardiorespiratory condition, medium arteries obstruction
 pulmonary infarction
• Small end-arterial vessel obstruction causes infarction.
• Recurrent thromboembolism  pulmonary hypertension in the long
run

Systemic thromboembolism
• 80% arise from intracardiac mural thrombi
• 2/3 of intramural thrombi associated with left ventricular wall infarcts & 25%
with dilated left atria (rheumatic heart diseases)
• Remainder originate from aortic aneurysms, thrombi overlying ulcerated
atherosclerotic plaques, fragmented valvular vegetations, or the venous system
(paradoxical emboli);
• 10% to 15% of systemic emboli are of unknown origin.
• Major sites of embolization: lower extremities(75%), brain(10%),
intestines, kidneys, spleen

Fat Embolism
• Fat globules in the circulation
• Commonly - fractures of long bones or,
• Rarely - soft tissue trauma and burns.
• the fat enters the circulation by rupture of the marrow vascular sinusoids
or rupture of venules.
• 90% of individuals with severe skeletal injuries
• fewer than 10% of such patients show any clinical findings.

• Fat embolism syndrome
• pulmonary insufficiency,
• neurologic symptoms,
• anemia, and
• thrombocytopenia and
• fatal in about 10% of cases.
• Typically, the symptoms appear 1 to 3 days after injury,
• sudden onset of tachypnea, dyspnea, and tachycardia.
• Neurologic symptoms - irritability and restlessness, with progression to delirium
or coma.
• The pathogenesis of this syndrome involves both mechanical obstruction and
chemical injury.

Air Embolism
• Gas bubbles within the circulation can obstruct vascular flow (and cause
distal ischemic injury) almost as readily as thrombotic masses.
• Air may enter the circulation during obstetric procedures or as a
consequence of chest wall injury.
• in excess of 100 mL of air is required to produce a clinical effect;
• bubbles -> physical obstructions and may coalesce to form frothy masses
sufficiently large to occlude major vessels.

Amniotic Fluid Embolism
• is a grave but uncommon complication of labor and the immediate
postpartum period (1 in 50,000 deliveries).
• mortality rate in excess of 80%.

• Onset –
• sudden severe dyspnea,
• cyanosis, and
• hypotensive shock,
• seizures and coma.
• If the patient survives,
• pulmonary edema ,
• DIC - release of thrombogenic substances from amniotic fluid.

Amniotic Fluid Embolism

Infarction
• Potential consequence of thromboembolic events  Ischemic necrosis 
Infarction
• Infarct – is an area of ischemic necrosis caused by occlusion of either the
arterial supply or venous drainage in a particular tissue
• ~99% of all infarction result from thrombotic or embolic events

• Other mechanisms (mostly arterial)
• Local spasm
• Atheroma expansion due to hemorrhage in to atheromatous plaque.
• External compression of vessels, e.g. trauma (compartment syndrome)
• Entrapment of vessels at hernial sacs etc….

Development and Types of infarcts
• Development and size of infarcts
• Nature of vascular supply,
collaterals
• Rate of development of occlusion
• Susceptibility of the tissue for
hypoxia
• Oxygen content of the blood
• Duration and severity of ischemia
• Types
• The basis of their color (reflecting
the amount of hemorrhage) in to:
• hemorrhagic (red) infarcts
• Anemic (white) infarcts
• Presence or absence of microbial
infection
• Septic infarcts
• Bland infarcts

Types
• Red infarcts occur in:
• Ovarian torsion-venous occlusion
• In loose tissues (lung)
• Allow blood to collect in infarct zone
• Tissue with dual circulation
• In previously congested tissues
• Areas where blood flow
reestablished(arterial occlusion &
necrosis)
• White infarcts occur in:
• Arterial occlusion - in single artery
sites
• Solid organs - heart, spleen, kidney
• Why is this so? Show off your hands

Clinical examples of infarction
• Myocardial infarction(MI)
• Following occlusion of coronary
arteries by thrombus formed on
ulcerating atheroma
• Is white infarct (why?)
• Can cause sudden death,
cardiac failure etc…
• Cerebral infarcts
• May appear as pale or hemorrhagic
• Can result in increased intracranial
pressure
• Is one type of cerebrovascular
accidents or stroke
• Lung infarcts
• Are typically dark red &conical
(wedge shaped, why?)
• Can result in hemoptysis, piercing
type chest pain

Disseminated Intravascular
Coagulation (DIC)
• Acute or chronic thrombohemorrhagic disorder occurring as a result of
progressive activation of coagulation pathway beyond physiologic set
point due to disease resulting in failure of all components of hemostasis
• Hence the name consumptive coagulopathy

Etiology and Pathogenesis
• DIC is not a primary disease
• Pathologic activation of coagulation system
• Massive or prolonged release of soluble tissue factors &/or endothelial derived
thromboplastin in to the circulation with generalized
• Two mechanisms to cause DIC
• Release of tissue factor or thromboplastin substance
• Wide spread injury to endothelial cells

• Tissue thromboplastin is derived from trauma, burns, surgery, obstetrics
procedures like placenta, dead fetus or amniotic fluid; cancers like acute
promylocytic leukemia, adenocarcinoma of the lung
• In our set up commonly from gram negative sepsis, i.e. bacterial
endotoxin

• Endothelial injury result from:-
• Ab-Ag complex deposition in lupus erythematosis
• Extreme temperature
• Hypoxia, acidosis, shock

END
THANK YOU!

Hemodynamics class 3.pptx

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