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TACO: Transfusion Associated Circulatory Overload

TRALI: Transfusion Related Acute Lung Injury

Transfusion debate:
Risks of transfusion:
Increased mortality
Increased length of stay
Increased cost of stay
Increased infection
Increased in ammation
Increased mechanical ventilation
Decreased survival

Transfusion Overuse:
Modi able Risks
Correctable anemia
Excessive surgical blood loss
Excessive blood loss due to unnecessary testing
Poor transfusion practice

Process Techniques
Ultra ltration
Acute Normovolemic hemodilution
Perioperative Cell Salvage
Miniaturized Corporeal Circuits
Retrograde Autologous Priming
Techniques help reduce hemodilution, excess plasma, water removal, red cell recovery.

Normal Values:
Adult HCT: male: 41.4% - 51.6% ; female: 36.3%- 45.3%
RBC: male: 4.5 -5.9 x10^6/microliter ; female: 4.1 -5.1 x10^6/microliter
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 Platelets: 150,000 - 400,000 /microliter
WBC: 4,500 - 10,000 /microliter
Newborn HCT: 42 - 72 ; Infant HCT: 28.5 - 39
Hemoglobin: male: 14 - 17; female: 12 - 15; newborn: 14 -24; infant: 10 - 13

History:
Landsteiner: 1900s, de ned A, B, AB, O

Composition of whole blood:
Functions of blood:
Transportation: free in plasma, bound to plasma protein, bound to blood
cells.
Regulation: electrolyte balance, pH regulation.
Protection: clotting, immunity
Plasma: 55% - proteins 7% (albumin, globulin, brinogen); water 91%; other
solutes 2% (ions, nutrients, waste products, gas, regulatory substances).
Formed elements: 45% - WBC (neutrophils, leukocytes, monocytes,
eosinophils, basophils), RBC, Platelets.

Blood Smears
Examines morphology; indicates percent of each cell type present.
Fixated by methanol - stabilize the cell
Stained with Romanowsky stains
Anisocytosis: varying RBC sizes
Poikilocytosis: abnormal shapes

Hematopoisesis: formation of blood cells and blood plasma.
Occurs in the bone marrow, liver, spleen, thymus, lymph nodes.
Across di erent phases of life: Adults: mainly bone marrow; infancy-
childhood: long bones; gestation: 2 months: yoke sac, 2-7 months liver and
spleen, late stages of fetus and birth - bone marrow, fat shi s to long bones
at 4.
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 Asymmetric division: some are self renewing so they don’t become depleted.
Development of each cell type:

Basic family tree of cells
Pluripotent -> progenitors (2) -> blast cells (4) -> mature cells
Iron
Located: in heme, circulation - attached to transferrin, stored in liver and
reticuloendothelial system - ferritin and hemosiderin.
3500-4000 mg, 2/3 is hemoglobin iron, 1/3 is tissue iron (90% of tissue iron
is made up of ferritin / hemosiderin).
1 - 3 mg is metabolized.
Movement: absorption (regulated by intestines), reuptake (transferrin, iron is
released from hemoglobin and back into plasma), storage (liver, spleen,
reticuloendothelial cells), transportation (transferrin- from cells to tissues).

Erythrocytes (RBC)
Bioconcave, central portion is thinnest, no nucleus, 120 day lifespan - ruptures
in spleen and macrophages take them. Volume = 90

Erythropoietin (EPO)
Released in kidney, peptide hormone.
A release of EPO is released in bone marrow.
Signals growth factors in bone marrow to release stem cells for RBC
formation.
Takes about 5 days to develop mature erythrocytes.
Requires: Globin, Iron, Protoporphyrin (combines with iron and heme,
binds O2 with CO2).

Hemoglobin A 95%: 2 alpha / 2 beta
Hemoglobin A2 3.95%: 2 alpha / 2 delta
Hemoglobin F 1-2%: 2 alpha / 2 gamma

Reticulocytes: immature RBCs
No nucleus, contain RNA and loose it a er reaching blood stream.
Anemia will increase reticulocytes and bone marrow activity.
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 Erythrocyte:
No nucleus, can carry oxygen and carbon dioxide due to having hemoglobin.
Eventually rupture in spleen.

WBC Formation
Lymphopoiesis: formation of lymphocytes
Lymphocytes - 20-44% of adult white blood cells, 2nd most numerous cell in
the blood.
T cells - thymus
B cells - bone marrow (antibodies)
Natural Killer Cells - toxicity

Monopoiesis: formation of monocytes
Monocytes: commit to myeloid and monocyte stage. In response to
macrophages stimulating factor - monoblast.
Lifespan = 12 hours

Granulopoiesis: formation of granulocytes
Neutrophils: rst in line of defense of innate immune system, kill and digest
bacteria and fungi.
Lifespan = 10 hours, turns into pus and dies
Secretes products to attract monocytes

Eosinophils: granules, 0-4% in blood, destruction of tumor cells.

Basophils: 0-2% in blood, release histamine, helps reduce prostaglandin.

Megakaryocytopoisesis: formation of platelets
Megakaryocytes: rst in line of defense for clotting, 7-10 day life span.

How are platelets formed?
Descend from same stem cell.
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 TPO = Thrombopoietin
Produced in liver; signal bone marrow to start production of platelets.
Responsible for platelet development from megakaryocytes.

Interleukins: cause stem cells to produce precursors to mature blood cells,
respond to tissue injury and foreign matter in in ammatory response.

Colony Stimulating Factors: glycoproteins that produce white blood cells
(granules) for infections. Binds to receptor proteins of hemopoietic stem cells.

Lab measurements
Complete Blood Count (CBC)
WBC (leukocytes) = infection
RBC (erythrocytes) = oxygen transport
MCH - mean corpuscular hemoglobin (content and weight of hemoglobin)
MCV - mean corpuscular volume (average size of hemoglobin)
MCHC - MHC Concentration (amount of hemoglobin per unit volume,
%Hgb)
MCV: normal: normocytic (80-100), < normal: microcytic (72-79), > normal:
macrocytic (95-160).
MCH & MCHC: normal: normochromic, < normal: hypochromic, > normal:
hyperchromic.

Fishbone diagram
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 Automated methods for RBC and HCT measurement
Electrical impedance (Coutler Principle) - produces cell count and measure
of volume. Split into three: Hemoglobinometry, RBC counting, Plasma carries
a charge, RBC is insulator.
Light Scatter (Co-oximetry) - newer, low-angle light scatter

Lab evaluations of Iron
Serum: amount of iron in blood
Serum ferritin: how much of body’s stored iron has been used
Transferrin: total iron binding capacity

Anemia
WHO grades of anemia
Grade 0: > 11 g/dl
Grade 1 (mild): 9.5-10.9 g/dl
Grade 2 (moderate): 8.0-9.4 g/dl
Grade 3 (serious): 6.5-7.9
Grade 4 (life threatening): < 6.5 g/dl

Causes of anemia:
Blood loss
Accelerated destruction of RBCs
Nutritional de ciency
Infection
Toxicity
Hematopoietic stem cell de ciency
Heredity vs acquired

Hemoglobinopathy
Qualitative disorders: structure - sickle cell
Quantitative disorders: numbers - thalassemia
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 Microcytic anemias: iron overload, sideroblastic, iron overload
Iron de cient: most common, decreased in hemoglobin, MCV, and HCT;
decreased in total body stores of iron.
Depletion of iron stores, iron-de cient erythropoiesis, iron-de cient
anemia.
Sideroblastic: ine ective erythropoiesis; increased level of tissue and serum
iron.
Normal hemoglobin; can be congenital or acquired.
Iron overload: increased iron absorption, transfusion overload.
3rd and 4th stage lead to cirrhosis and organ damage; there is no mechanism
to reverse it.

Macrocytic anemias: Megaloblastic
Megaloblastic: mega (large) , plastic (immature cells)
Causes: folic acid, B12
Increased hemolysis, increased EPO

Normocytic anemias: aplastic, hemolytic, immune mediated hemolytic
Aplastic: loss of bone marrow cellularity; decreased in production or
erythrocytes, leukocytes, and platelets.
Hemolytic: hemolysis, increased in reticulocytes, increased red blood cell
destruction, increased EPO, decreased oxygen, and decreased life span.
Can be inherited or acquired, intrinsic or extrinsic, acute or chronic.
Autoimmune: body loses recognition of it’s own RBC antigens; patient
produces antibodies against its own RBCs.
Cold agglutinins: reactivity at 4-22 C; IgM activates complement; hemolysis
occurs.
Alloimune: Transfusion: IgM and ABO incompatibility; Pregnancy: maternal
fetal blood group incompatibility, hemolytic disease of newborns; Organ
transplants: antibodies produced.
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Sickle cell anemia
Point mutation: Hemoglobin S in the mutation for the 6th amino acid in Beta
chain; Valine is substituted for glutamic acid.
Sickle cell disease: homozygous; 0.15% African Americans; 80-98%
hemoglobin S present; Sickle starts at oxygen saturation 85% with complete
sickling at 38%.
Sickle cell trait: heterozygous; 8% African Americans; 20-45% hemoglobin S
present; Sickle starts at oxygenation of 40%.
Degree of Sickling depends on: dehydration, pH, oxygenation, irreversible/
reversible.

Coagulation
Hemostasis involves which major systems?
Vascular system, fybrinolytic system, platelets, coagulation system.

Stages of Hemostasis
Primary: platelet plug forms; platelet adhesion.
Secondary: enzyme activation of coagulation proteins to produce brin.
Fibrinolysis: clot dissolves; plasmin digests brinogen and brin.

How does the endothelium activate thrombus formation?
Coagulation cascade

Intrinsic Pathway: X, VIII, IX, XI, XII
Extrinsic Pathway: III, VII, X
Common Pathway: X, V, II, I
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 Primary hemostasis
Platelets characteristics: 150,000-400,000; originates in bone marrow;
develops 5-7 days a er release of thrombopoietin.
70% circulating and 30% in microvasculature of spleen
Survives 7-0 days in circulation and active for hemostasis.
For adequate hemostasis, >50,000 platelet count.
3 zones: peripheral, sol-gel, organelle
Peripheral: platelet membrane, glycocalyx; exterior glycoprotein coat,
phospholipid plasma membrane.
Sol-Gel: cytoskeleton, responsible for metabolic activity, allow for shape
change.
Consists of microtubules, micro laments (actin and myosin), sub-
membranous laments.
Organelle: responsible for metabolic activity, contains granules/
Contains dense granules (ADP, ATP, ionic calcium, serotonin, and
phosphate), alpha granules, and lysosomes.

Platelet plug formation: Vasoconstriction, platelet shape change, platelet
aggregation, platelet secretion, stabilization.
Vasoconstriction: regulates blood ow to damaged cells; adhesion.
3 components: Von Willebrand factor: links platelet to sub endothelial
binding sites; GP1B; Collagen: collagen is released, binds to Von W. Factor,
then to GP1B receptor sites bind to GP1B bridge to start forming platelet
plug.
Shape change: interaction of platelet and agonist (collagen, ADP, thrombi,
thromboxane II) alter cytosolic calcium and change shape of platelet.
Both TXA2 and ADP bind to membrane receptor surface and expose it to
platelet membrane phospholipids, which cause aggregation.
Aggregation: Platelet to platelet interaction
Usually begins 10-20 sec following vascular injury and platelet adhesion;
Requires 4 elements: ATP - energy, lonized calcium, Fibrinogen, GPIlb/
Illa complex.
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 The brinogen binds to the activated platelet membrane
GPIlb/Illa complex. Calcium/ brinogen bridges form and promote
platelet aggregation. Will not produce clot without brinogen
Secretion: Liberate ADP and calcium from the dense granules
Release of ADP makes other platelets sticky; Stickiness of platelets
causes them to adhere to the originally activated platelets
Serotonin and thromboxane A2 function as vasoconstrictors
Contracts vascular smooth muscle; Decreases blood ow through
then injured vessel.
Stabilization: last stage in arresting bleeding
Activation of coagulation cascade and brin on platelet aggregates.
Fibrin interweaves through initial platelet, compressing into site
of injury.

Secondary hemostasis
Clotting factors: roman numerals and name; listed in order of discovery; a
means it is activated.
I to Ia: brinogen to brin
II to IIa: prothrombin to thrombin

Clotting factors:
I - brinogen
II - prothrombin
III - Tissue factor
IV - Calcium
V - Labile factor
VI - doesn’t exist anymore
VII - Proconvertin, stable factor
VIII - AHF, AHG
IX - PTC, AHB, Christmas
X - Stuart-Prower factor, autoprothrombin III
XI - PTA
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 XII - Hageman
XIII - brin stabilizing factor

Intrinsic: exposure to negatively charged foreign substances or activation of
factor XII involving, initiates the intrinsic pathway. Requires factors: YII, IX, XI,
XII; Prekallikrein and HMWK; Calcium and PF3.

Extrinsic: Initiated when factor III, enters the vascular system; Factor VII is
activated to VIIa in the presence of calcium and tissue factor (factor III); Only
VIIa, Ca+, and Factor Ill are needed to activate Factor X to Xa.

Common: composed of factors X, II, V, and I; thrombin activates VII and V,
converting brinogen to brin; factor XII.

Know clotting cascade:

Fibrinogen/thrombin interaction to form crosslinked brin clot: brinogen
is a protein produced by the liver; Thrombin cleaves brinogen into short
fragments of brin -> Fibrin monomer links to form insoluble brin polymer.

What is the Cell Model Theory for coagulation?
How is it di erent than the coagulation cascade: A er injury, tissue factor
(TF) becomes exposed to blood and combines with free circulating FVII. This
complex activates FX, Which with FV can form small amounts of thrombin,
enough to activate local platelets; The surface of the activated platlet becomes
the catalytic center for a larger amount of thrombin production which produces

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 enough brin to stabilize the clot; Thrombin has both pro-coagulatory as well as
anti brinolytic e ects; Tissue factor pathway inhibitor (TFPI); Protein C and S
will inactivate FVa and FVIlla Antithrombin will inactivate thrombin as well as
FXa, FIXa, FXIa, FXIla.

Stages: Initiation, Ampli cation, Propagation.

Natural anticoagulants in blood: Antithrombin (ATIII), Protein C
Antithrombin (ATIII): main physiologic inhibitor of thrombin; In presence of
heparin → ATIll consumed and inhibits thrombin.
Protein C: Activated Protein C exerts an anticoagulant e ect by inactivating
factors Va and VIlla and slowing thrombin formation.

Fibrinolysis
How does clot breakdown: Activation of coagulation also activates
brinolytic system; Re-establishes blood ow in vessels a er thrombus and
facilitates healing; Plasminogen is activated by t-PA.

Plasmin: Has very strong a nity for brin; breaks down brin.

Thrombopoiesis: platelet production; 30% in spleen; liver: coagulation
factors.
Thrombocytopenia: < 100,000; De cient platelet production; Increased
destruction.
Thrombocytosis/Thrombocythemia: >400,000; High platelet number;
Bone marrow overproduces megakaryocytes.
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