Hemostasis and Thrombosis PDF

Summary

This document discusses hemostasis and thrombosis. It explores the systems of hemostasis, including the role of blood vessels, platelets, and plasma proteins. The text covers the process of hemostasis, which includes vasoconstriction, platelet adhesion, aggregation, and coagulation enzyme activation.

Full Transcript

662 PART VI Hemostasis and Thrombosis

CASE STUDY
After studying the material in this chapter, the reader should be able to respond 1. Is this hemostatic disorder typical of an acquired or an inherited condition?
to the following case study. Answers can be found in Appendix C. 2. Are these symptoms most likely caused by a deciency of a procoagulant or
A pregnant woman developed a blood clot in her left leg (deep vein thrombosis an inhibitor?
[DVT]). Her mother reportedly had a history of thrombophlebitis. She had a brother
who was diagnosed with DVT after a ight from Los Angeles to Sydney, Australia.

Hemostasis is a complex physiologic process that keeps blood and collagen. ey subsequently become activated, which pro-
circulating in a uid state until an injury occurs, then causes motes secretion of the contents of their granules, aggregation
production of a blood clot to stop the bleeding, connes the with other platelets via brinogen, VWF, and bronectin, and
blood clot to the site of injury, and nally dissolves the blood formation of a platelet plug. Vasoconstriction and platelet plug
clot as the wound heals. When hemostasis systems are out of formation make up the initial, rapid, and short-lived response to
balance, either hemorrhage (uncontrolled bleeding) or thrombo- vessel damage. However, to control major bleeding in the long
sis (pathologic clotting) can occur, which can be life-threatening. term, the platelet plug must be reinforced by brin. Defects in
e absence of a single plasma procoagulant protein may cause primary hemostasis such as collagen abnormalities, thrombo-
the individual to experience lifelong anatomic hemorrhage and cytopenia, qualitative platelet disorders, or von Willebrand dis-
transfusion dependence. Conversely, absence of an anticoagu- ease can cause debilitating, sometimes fatal, chronic bleeding.
lant protein allows coagulation to proceed unchecked and can Secondary hemostasis (see Table 35.1) describes the activation
result in thrombosis, including myocardial infarction, stroke, of a series of coagulation proteins in the plasma, mostly serine
pulmonary embolism, and deep vein thrombosis. proteases, to form a brin clot. ese proteins circulate as inactive
Understanding the major systems of hemostasis—blood ves- zymogens (proenzymes), becoming activated during the process of
sels, platelets, and plasma proteins—is essential to interpreting coagulation and, in turn, form complexes that activate other zymo-
laboratory test results, along with being able to prevent, predict, gens. is pathway ultimately leads to the generation of thrombin,
diagnose, and manage hemostatic disease. an enzyme that converts brinogen to brin. is allows for forma-
tion of a localized brin clot, which is stabilized by factor XIII. e
OVERVIEW OF HEMOSTASIS nal event of hemostasis is brinolysis, the gradual digestion and
removal of the brin clot, which occurs as the injury heals.2
Hemostasis involves the interaction of vasoconstriction, plate- Although the various components of the coagulation sys-
let adhesion and aggregation, and coagulation enzyme activa- tem are divided between primary and secondary hemostasis for
tion to stop bleeding. e coagulation system, similar to other improved understanding and compartmentalization, they are
humoral amplication mechanisms, is complex because it associated with each other during early and late-stage hemo-
translates a diminutive physical or chemical stimulus into a pro- static events. For example, platelets and vascular ECs, which
found lifesaving event.1 e key cellular elements of hemostasis are key components of primary hemostasis, secrete coagula-
are the endothelial cells (ECs) of the vascular intima, extravas- tion factors stored in their granules and Weibel-Palade bodies,
cular tissue factor (TF)–bearing cells, and platelets. e plasma respectively. In addition, platelets provide the essential cell
components include the coagulation and brinolytic proteins membrane phospholipid on which coagulation complexes
and their inhibitors. form. Conversely, coagulation proteins, particularly VWF and
Primary hemostasis (Table 35.1) refers to the role of blood brinogen, are involved in platelet adhesion and aggregation,
vessels and platelets in the initial response to a vascular injury respectively. roughout this chapter the vascular intima, plate-
or to the commonplace desquamation of dying or damaged lets, coagulation factors, brinolysis proteins, and control pro-
ECs. Blood vessels contract to seal the wound or reduce the teins will be detailed, illustrating how they function to promote
blood ow (vasoconstriction). Platelets adhere to the damaged normal hemostasis.
vessel wall by interactions with von Willebrand factor (VWF)

TABLE 35.1 Primary and Secondary VASCULAR INTIMA IN HEMOSTASIS
Hemostasis e vasculature consists of the blood vessels, including arter-
Stage Primary Hemostasis Secondary Hemostasis ies, veins, and capillaries, carrying blood throughout the body.
Activation Desquamation and small Large injuries to blood vessels A blood vessel is structured into three layers: an inner layer
injuries to blood vessels and surrounding tissues (tunica intima), a middle layer (tunica media), and an outer
Components Vascular intima and platelets Platelets and coagulation system
layer (tunica adventitia or tunica externa). e tunica intima
provides the interface between circulating blood and body tis-
Timing Rapid, short-lived response Delayed, long-term response
sues. is innermost lining of blood vessels is a monolayer of
Mechanism Procoagulant substances Tissue factor exposed on cell metabolically active ECs (Box 35.1 and Figure 35.1; refer also
exposed or released by membranes to Figure 11.9A).3 ECs are complex and heterogeneous cells
damaged or activated that are distributed throughout the body. ey display unique
endothelial cells
structural and functional characteristics, depending on their
 CHAPTER 35 Normal Hemostasis 663

environment and physiologic requirements, not only in subsets Anticoagulant Properties of Intact Vascular Intima
of blood vessels such as arteries versus veins but also in the var- Intact vascular endothelium prevents thrombosis by numerous
ious tissues and organs of the body.4 5 ECs play essential roles in anticoagulant mechanisms, which are specied in Table 35.2
immune response, vascular permeability, proliferation, and, of and see Figure 35.1. e rst mechanism of intact ECs is their
course, hemostasis. physical presence. ECs are rhomboid and contiguous, provid-
ECs form a smooth, unbroken surface allowing for nontur- ing a smooth inner surface of the blood vessel promoting non-
bulent blood ow. e ECs are supported by a basement mem- turbulent blood ow, which prevents activation of platelets and
brane and an elastin-rich internal elastic lamina. Arteries have coagulation enzymes. ECs form a physical barrier, separating
an additional elastin-rich external lamina component. In all
blood vessels, broblasts (important for maintenance, tissue
TABLE 35.2 Anticoagulant Properties of
metabolism, and structural framework) occupy the connective
Intact Vascular Endothelium
tissue layer, where they produce collagen. Smooth muscle cells
present in the walls of all blood vessels, in much larger numbers Endothelial Cell Structure/
Substance Anticoagulant Property
in arteries than veins and only occasionally in capillaries, pro-
mote contraction when an injury occurs and primary hemosta- Composed of rhomboid cells Present a smooth, contiguous surface
sis is initiated. Secrete prostacyclin The eicosanoid platelet inhibitor
Secrete nitric oxide A vascular “relaxing” factor
Secrete the glycosaminoglycan An anticoagulant that regulates
BOX 35.1 Vascular Intima of the Blood heparan sulfate thrombin generation
Vessel Secrete TFPI A regulator of the extrinsic pathway
Innermost Vascular Lining of coagulation
Endothelial cells (endothelium) Express the protein C receptor An integral component of the protein
EPCR C control system
Supporting the Endothelial Cells
Internal elastic lamina composed of elastin and collagen Express cell membrane A protein C coagulation control
thrombomodulin system activator
Subendothelial Connective Tissue Secrete TPA Activates brinolysis
Collagen and broblasts in veins
Collagen, broblasts, and smooth muscle cells in arteries EPCR, Endothelial protein C receptor; TFPI, tissue factor pathway
inhibitor; TPA, tissue plasminogen activator.

Anticoagulant Functions of Intact Endothelial Cells

Smooth, Nitric Heparan Thrombo- TPA
EC lining oxide sulfate modulin
PGI2 TFPI EPCR

ECs Platelets Coagulation Fibrinolysis

VWF P-Selectin PAI-1
Vasocon- Collagen TF
striction ADAMTS13 exposed exposed TAFI

Procoagulant Functions of Damaged Endothelial Cells
Figure 35.1 Hemostatic Properties of Endothelial Cells that Line the Inner Surface of All Blood Vessels.
Depicted in this gure are the anticoagulant properties associated with normal intact endothelial cells (top)
and the procoagulant properties associated with damaged endothelial cells (bottom) as they relate to the
functions of the hemostatic system listed in the center. ADAMTS13, A disintegrin and metalloprotease with
a thrombospondin type 1 motif, member 13; ECs, endothelial cells; EPCR, endothelial cell protein C recep-
tor; PAI-1, plasminogen activator inhibitor-1; PGI2 prostacyclin or prostaglandin I2; TAFI, thrombin activatable
brinolysis inhibitor; TF, tissue factor; TFPI, tissue factor pathway inhibitor; TPA, tissue plasminogen activator;
VWF, von Willebrand factor.
664 PART VI Hemostasis and Thrombosis

platelets in blood from the collagen in the vascular intima that TABLE 35.3 Procoagulant Properties of
promotes platelet adhesion. e EC barrier also separates cir- Damaged Vascular Intima
culating procoagulant proteins from TF, present on underlying
Structure/Substance Procoagulant Property
broblasts and smooth muscle cells, that activates coagulation.
Smooth muscle cells in arterioles Induce vasoconstriction
e ECs are covered with carbohydrates, known as a glycocalyx,
and arteries
consisting of proteoglycans and glycoproteins that have a neg-
ative charge. e negative charge repels cellular components, Exposed subendothelial collagen Binds VWF; binds to and activates platelets
preventing binding to the adhesion molecules present on ECs.6 Damaged or activated ECs secrete Important for platelet binding to collagen
e second anticoagulant mechanism relates to the variety VWF at site of injury: platelet adhesion as a
of substances synthesized and secreted by ECs. Prostacyclin rst line of defense against bleeding
(PGI2) is synthesized through the eicosanoid pathway (Chapter Damaged or activated ECs secrete Promote platelet and leukocyte binding
11) and prevents unnecessary or undesirable platelet activa- adhesion molecules: P-selectin, and activation at site of injury
tion in intact vessels by acting as an antagonist of thrombox- ICAMs, PECAMs
ane A2 (TXA2).7 8 In addition, PGI2 promotes vasodilation Exposed smooth muscle cells and Tissue factor exposed on cell membranes
through a protein kinase A mechanism, leading to inhibition broblasts
of the myosin light chain kinase with subsequent smooth mus- ECs in inammation Tissue factor is induced by inammation
cle cell relaxation.8 Nitric oxide is synthesized in ECs, vascu-
lar smooth muscle cells, neutrophils, and macrophages. Nitric ECs, Endothelial cells; ICAMs, intercellular adhesion molecules;
PECAMs, platelet endothelial cell adhesion molecules; VWF, von
oxide induces smooth muscle relaxation with subsequent vaso- Willebrand factor.
dilation and inhibits platelet activation through a guanylate
cyclase-dependent mechanism, while also being able to pro- to binding of circulating VWF, which causes binding and
mote angiogenesis in healthy arterioles through vascular endo- activation of platelets (Figure 11.9B and 11.9C). Platelets sub-
thelial growth factor (VEGF) and basic broblast growth factor sequently bind to the collagen through their GPVI and α2β1
(bFGF).8-10 An important EC-produced anticoagulant is tissue receptors and adhere to the damaged area until new ECs grow.
factor pathway inhibitor (TFPI), which controls activation of roughout an individual’s life span, connective tissue nat-
the TF pathway, also called the extrinsic coagulation pathway. urally degenerates, which leads to an increased tendency to
TFPI limits the activation of the TF:VIIa:Xa complex, thereby bruise in the elderly.
limiting thrombin generation. ird, ECs secrete VWF from storage sites called Weibel-
Finally, ECs synthesize and express on their surfaces two Palade bodies when activated by vasoactive agents such as
known inhibitors of thrombin function, thrombomodulin and thrombin. VWF is a large multimeric glycoprotein that acts
heparan sulfate. rombomodulin promotes activation of the as the necessary bridge that binds platelets to exposed suben-
coagulation inhibitor protein C and subsequent anticoagula- dothelial collagen in arterioles and arteries where blood ows
tion. Heparan sulfate is a glycosaminoglycan that enhances the rapidly (Figure 11.9C and 11.9D).12 VWF has been described as
activity of antithrombin, a blood plasma serine protease inhib- a “carpet” on which activated platelets assemble. ADAMTS13,
itor.11 e pharmaceutical anticoagulant heparin, an important also secreted from ECs, serves an important function as it
therapeutic agent used for many clinical indications, resembles cleaves large VWF multimers into shorter chains that support
EC heparan sulfate in both its structure and its inhibitory activ- normal platelet adhesion.
ity when bound to antithrombin. Fourth, on activation, ECs secrete and coat themselves with
P-selectin, an adhesion molecule that promotes platelet and leu-
Procoagulant Properties of Damaged Vascular kocyte binding.13 ECs also secrete immunoglobulin-like adhe-
Intima sion molecules called intercellular adhesion molecules (ICAMs)
Although the intact endothelium has anticoagulant properties, and platelet EC adhesion molecules (PECAMs), which further
when damaged, the tunica intima (ECs and the subendothelial promote platelet and leukocyte binding.14
matrix) promotes coagulation through several procoagulant prop- Finally, subendothelial smooth muscle cells and broblasts
erties (Table 35.3 and see Figure 35.1). First, any harmful local support the constitutive membrane protein TF.15 EC disruption
stimulus, whether mechanical or chemical, induces vasocon- exposes TF to circulating blood, promoting activation of the
striction in arteries and arterioles where blood pressure is higher coagulation system through contact with plasma coagulation
than on the venous side (Figure 11.9B). Smooth muscle cells factor VII, which ultimately leads to brin formation (Figure
contract, leading to narrowing of the vascular lumen, followed 35.2). e formed brin surrounds the platelet plug, securing it
by decreased blood ow through the injured site. As veins and to the damaged area such that the blood ow does not dislodge
capillaries do not have as many smooth muscle cells to contribute the platelet plug.
to vasoconstriction, blood can escape into surrounding tissues, In arterioles and arteries, the larger VWF multimers form a
creating extravascular pressure on the blood vessel and causing brillar carpet on which the platelets assemble because of the
compression, which eectively minimizes the escape of blood. high blood ow; a white clot consisting of essentially platelets,
Second, the subendothelial connective tissues of arteries brin, and VWF is produced.16 In veins, because of the slower
and veins are rich in collagen, a exible, elastic structural pro- blood ow, a bulky red clot is produced, consisting of mostly red
tein. Upon injury to the vessel, collagen is exposed, leading blood cells and brin, with some platelets.16
 CHAPTER 35 Normal Hemostasis 665

Fibroblast Smooth muscle cell Endothelial cells Platelet

HS

TFPI Fib White blood cell

Blood flow
Red blood cell

TM

Collagen External elastic lamina von Willebrand factor
Figure 35.2 Secondary Hemostasis. Immediately after the initial response to vessel injury of platelet activa-
tion, adhesion, and aggregation (primary hemostasis), as detailed in Chapter 11 and Figure 11.9, the continued
response of an injured blood vessel leads to the formation of a brin clot that stabilizes the initial platelet plug,
as shown in this artist’s rendering. Primary hemostasis requires interaction of platelets with subendothelial
VWF and collagen. Secondary hemostasis requires exposure of TF from damaged endothelial cells and phos-
pholipids from activated platelets that promotes activation of the coagulation cascade, thrombin generation,
and brin formation that polymerizes around the platelet aggregate. Fib, Fibrinogen; HS, heparan sulfate; TF,
tissue factor, TFPI, tissue factor pathway inhibitor (EC bound and soluble forms exist); TM, thrombomodulin
(EC bound and soluble forms exist).

Fibrinolytic Properties of Vascular Intima Platelets serve as one of the body’s rst lines of defense
rough the secretion of tissue plasminogen activator (TPA), against blood loss. At the time of injury, platelets adhere to the
ECs support brinolysis (see Table 35.2 and see Figure 35.1), the site of injury, aggregate, and secrete the contents of their gran-
breakdown of brin, leading to thrombus degradation and res- ules (Table 35.4 and Figure 11.9).22 23 Adhesion is the property
toration of vessel patency. TPA activates brinolysis by convert- by which platelets bind to nonplatelet surfaces such as sub-
ing plasminogen to the primary brinolytic enzyme plasmin, endothelial collagen and VWF. VWF links platelets to colla-
which gradually digests brin and restores blood ow. ECs also gen through their GPIb/IX/V membrane receptors in areas of
regulate brinolysis by providing inhibitors to prevent excessive high shear stress such as arteries and arterioles.24 In damaged
plasmin generation. One of the brinolytic inhibitors secreted veins and capillaries, platelets may bind directly to collagen via
by ECs, as well as by other cells, is plasminogen activator inhib- GPVI and α2β1 receptors. e importance of platelet adhesion
itor-1 (PAI-1).17 Another inhibitor of plasmin generation is is underscored by bleeding disorders such as Bernard-Soulier
thrombin activatable brinolysis inhibitor (TAFI), which is acti- syndrome (Chapter 37), in which the platelet GPIb/IX/V recep-
vated by thrombin bound to EC membrane thrombomodulin.18 tor is absent, and von Willebrand disease (Chapter 36), in which
Although the signicance of the tunica intima in hemosta- VWF is missing or defective.
sis is well recognized, there are few valid laboratory methods Aggregation is the property by which platelets bind to one
to assess the integrity of ECs, smooth muscle cells, broblasts, another. When platelets are activated, a change in the GPIIb/
and their collagen matrix.19 Invasive blood vessel biopsies are IIIa receptor allows binding of brinogen as well as VWF and
not performed. us the diagnosis of blood vessel disorders is bronectin.25 Fibrinogen binds to GPIIb/IIIa receptors on adja-
based on clinical symptoms, family history, and indirectly by cent platelets and joins them together in the presence of ionized
laboratory tests that rule out platelet or coagulation disorders. calcium (Ca2+). Fibrinogen binding is essential for platelet aggre-
gation as evidenced by bleeding and compromised aggregation
in patients with abrinogenemia or in patients who lack the
PLATELETS GPIIb/IIIa receptor (Glanzmann thrombasthenia; Chapter 37).
Platelets are produced from the cytoplasm of bone marrow Platelets secrete the contents of their α-granules and dense
megakaryocytes.20 Although platelets are only 2 to 3 μm in granules during adhesion and aggregation, with most secretion
diameter on a xed, stained peripheral blood lm, they are occurring late in the platelet activation process. Platelets secrete
complex, metabolically active cells that interact with their envi- procoagulants (e.g., factor V, VWF, factor VIII, brinogen) as
ronment and initiate and control hemostasis.21 Chapter 11 pro- well as control proteins (e.g., protein S, TFPI, antithrombin,
vides an in-depth description of platelet structure and function. C1-inhibitor), along with Ca2+, adenosine diphosphate (ADP)
An overview of the platelet functions critical in the initial stages and other hemostatic molecules (Table 35.5).26 27 Although
of hemostatic control is given in this chapter. these substances participate in thrombosis and hemostasis, the
666 PART VI Hemostasis and Thrombosis

TABLE 35.4 Platelet Function phosphatidylserine, some procoagulant factors, and receptors.
e importance of these substances in the blood clotting pro-
Function Mechanism of Action Characteristics
cess, as well as how they serve to integrate platelet function with
Adhesion Platelets roll and cling to Reversible; seals endothelial activation of the plasma coagulation system, will be described
nonplatelet surfaces gaps, some secretion of
in this chapter.
growth factors, in arterioles
Erythrocytes, monocytes, and lymphocytes also participate
VWF is necessary for
adhesion
in hemostasis. Erythrocytes add bulk and structural integ-
Aggregation Platelets adhere to each Irreversible; platelet plugs rity to the brin clot. Interestingly, those with anemia have an
other form, platelet contents are increased tendency to bleed, likely in part because of the lack
secreted, requires brinogen of movement of platelets to the vessel wall (marginalization) by
Secretion Platelets release the Irreversible; occurs during erythrocytes and the decreased number of erythrocytes able to
contents of their granules aggregation, platelet be incorporated into the thrombus.30 In inammatory condi-
contents are secreted, tions, monocytes and lymphocytes, and possibly ECs, provide
essential to coagulation surface-borne TF that may trigger coagulation. Leukocytes also
VWF, von Willebrand factor. have a series of membrane integrins and selectins that bind
adhesion molecules on platelets and other cells and help stimu-
late the production of inammatory cytokines that promote the
TABLE 35.5 Platelet Granule Contents wound healing process and combat infection.31
Platelet α-Granules Platelet Dense Granules
(Large Molecules) (Small Molecules)
COAGULATION SYSTEM
Factors V, VIII, XI, prothrombin, Adenosine diphosphate
brinogen Adenosine triphosphate Nomenclature of Procoagulants
VWF Ionized calcium Plasma transports at least 16 procoagulants called coagulation
HMWK Serotonin factors. Nearly all are glycoproteins synthesized in the liver,
Antithrombin, TFPI, protein S Magnesium although monocytes, ECs, and megakaryocytes produce a few
C1-inhibitor (control protein of the Potassium
(Table 35.6 and Figure 35.3). Eight are enzymes that circulate in
contact system) Histamine
an inactive form called zymogens. Others are cofactors that bind,
Plasminogen
PAI-1
stabilize, and enhance the activity of their respective enzymes.
Platelet factor 4 Fibrinogen is the substrate for the enzymatic action of throm-
Platelet-derived growth factor, other bin, the primary enzyme of the coagulation system. In addition,
growth factors there are plasma glycoproteins that act as control proteins that
serve the important function of regulating the coagulation pro-
HMWK, High-molecular-weight kininogen; PAI-1, plasminogen activator
inhibitor-1; TFPI, tissue factor pathway inhibitor; VWF, von Willebrand
cess to avoid unnecessary thrombin generation, brin forma-
factor. tion, and blood clotting (see Figure 35.3). Reference intervals
can be found aer the Index at the end of the book.
role of platelets in inammation, atherosclerosis, antimicrobial Fibrinogen and prothrombin (factor II) were known in
host defense, wound healing, angiogenesis, and malignancy has 1935; factors V and VII were identied in the period 1945 to
become increasingly appreciated as the function of platelets in 1950; and factors IX and X were described in the 1950s.32 In
the pathophysiology of these processes is being better dened.27 1958 the International Committee for the Standardization
e platelet membrane consists of a phospholipid bilayer. of the Nomenclature of the Blood Clotting Factors ocially
During activation, ADP and Ca2+ activate phospholipase A2, named the plasma procoagulants and cofactors using Roman
which converts platelet membrane phospholipids into arachi- numerals in the order of their initial description or discovery.33
donic acid (Figure 11.12). Arachidonic acid is converted into the An additional convention adopted was the use of a lowercase a
endoperoxides prostaglandin G2 (PGG2) and prostaglandin H2 behind the Roman numeral to designate factors in their acti-
(PGH2) by the cyclooxygenase enzyme-1 (COX-1). In the plate- vated state—for instance, activated factor VII is VIIa.
let, thromboxane synthetase converts these prostaglandins into ere are multiple factors not usually identied by their
TXA2, which causes Ca2+ to be released from the dense tubules, Roman numerals. Factors I and II are customarily called brin-
thereby promoting platelet aggregation and vasoconstriction. ogen and prothrombin, respectively, although occasionally they
Available Ca2+ (ionized calcium) is critical for normal platelet are identied by their numerals. e numeral III was given to
function because it is involved in helping with subsequent phys- tissue thromboplastin, a crude mixture of TF and phospholipid.
ical spreading of the platelet to cover the site of injury, along Now that the precise structure of TF has been described, the
with promoting secretion of platelet granule content.26 28 numeral designation is seldom used. e numeral IV iden-
e membrane of activated platelets is the key surface for tied the plasma cation calcium (Ca2+); however, calcium is
coagulation enzyme-cofactor-substrate complex formation (see referred to by its name or chemical symbol, not by its numeral.
Figure 35.2), which is the foundation for secondary hemostasis e numeral VI was assigned to a procoagulant that later was
to occur.29 Platelets supply Ca2+, the membrane phospholipid determined to be activated factor V; VI was withdrawn from
 CHAPTER 35 Normal Hemostasis 667

TABLE 35.6 Properties of the Plasma Procoagulants
Molecular Weight Mean Plasma
Factor Name Function (Daltons) Half-Life (hr) Concentration†
I* Fibrinogen Thrombin substrate, 340,000 100–150 200–400 mg/dL
polymerizes to form brin
II* Prothrombin Serine protease 71,600 60 10 mg/dL
III* Tissue factor Cofactor 44,000 Insoluble None
IV* Ionized calcium Mineral 40 NA 8–10 mg/dL
V Cofactor 330,000 24 1 mg/dL
VII Serine protease 50,000 6 0.05 mg/dL
VIII Antihemophilic factor Cofactor 260,000 12 0.01 mg/dL
VWF von Willebrand factor Factor VIII carrier and 500,000–20,000,000 24 1 mg/dL
platelet adhesion
IX Christmas factor Serine protease 57,000 24 0.3 mg/dL
X Stuart-Prower factor Serine protease 58,800 48–52 1 mg/dL
XI Serine protease 143,000 48–84 0.5 mg/dL
XII Hageman factor Serine protease 84,000 48–70 3 mg/dL
Prekallikrein Fletcher factor, pre-K Serine protease 85,000 35 35–50μg/mL
High-molecular- Fitzgerald factor, HMWK Cofactor 120,000 156 5 mg/dL
weight kininogen
XIII Fibrin-stabilizing factor (FSF) Transglutaminase, 320,000 150 2 mg/dL
transamidase
Platelet factor 3 Phospholipids, Assembly molecule — Released by platelets —
phosphatidylserine, PF3
*These factors are customarily identied by name rather than Roman numeral.
†Clinically, plasma concentration of all coagulation factors, except brinogen, can be given as percentage of normal (%) or units/dL, where the

numeric value remains the same.

ZYMOGENS
Prekallikrein
FXII
FXI
FIX
FX
FVII
Prothrombin
FXIII
CO-FACTORS
CONTROL PROTEINS
HMWK
Antithrombin
Tissue factor
Heparin cofactor II
FVIII
TFPI
FV
Protein C
Protein Z
2
Protein S
1
Thrombomodulin
ZPI

FIBRINOGEN
SUBSTRATE

Figure 35.3 Plasma Components of the Coagulation System. Four categories of plasma-based compo-
nents of the coagulation system of blood clotting include procoagulants (zymogens), cofactors, anticoagu-
lants (regulatory or control proteins), and the nal brinogen substrate. Throughout this chapter, gures will
use the above-shaped symbols to aid in classifying each component: zymogens as circles; activated zymo-
gens or serine proteases as hexagons (not shown here); cofactors as rectangles; control proteins as stars;
other components as ovals. HMWK, High-molecular-weight kininogen; TFPI, tissue factor pathway inhibitor;
ZPI, protein Z–dependent protease inhibitor.