Antithrombotic therapy in children

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Antithrombotic therapy in children

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Title: Antithrombotic therapy in children

1
Antithrombotic therapy in children

Dr.K.Mahesh

2
Introduction

Rising use of Anticoagulant / Antithrombotic
drugs among pediatric patients
Thromboembolic Disease The new Epidemic of
Pediatric Tertiary Care Hospitals.
Nowhere more evident than in pediatric
cardiac/cardiac surgery patients.
In the last decade vast improvements in
surgical techniques,new drugs, new
applications,critical and supportive care-
resulted in improved survivals.
TE Disease is one the most frequent complications
in these survivors.

Majority of children on primary anticoagulant
prophylaxis have underlying CHD/acquired heart
disease
Venous thromboembolic disease in children has a
mortality of 7
Morbidity in the form of post-phlebitic syndrome
and recurrent venous thrombosis occurs in 20

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Arterial Thromboembolic Disease
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Points of discussion

Antithrombotic / Anticoagulant therapy in context
of Pediatric Cardiac morbidities.
Biochemical basis of coagulation and factors that
influence / modify it.
Specific drugs that regulate coagulation
Recommendations for anticoagulant therapy in
specific clinical situations

9
Indications for Anticoagulant / Antithrombotic
therapy in Pediatric Cardiology

Native structural cardiovascular disease
Vavular heart disease
Cardiomyopathies
Surgically altered cardiovascular architecture
BT Shunt, Glenn, Fontan, Norwood
Valve replacements
Post-op / intensive care related issues
Central line, sepsis
Cardiac catheterization and interventions
Prophylaxis
Interventional procedures

10
How are things different in children compared to
adults?
11
Epidemiolgical differences

High proportion of secondary thrombosis in
children with major underlying HD
Role of central venous access devices
Biphasic age difference highest risk in
neonates and Adolescents
Age distribution of major illnesses that require
CVA.
Small physical size of blood vessels related to
CVA in neonates
Maturation of coagulation system in adolescents

Frequency and type of intercurrent illnesses
makes administration and regulation of oral
anticoagulant therapy difficult
Vascular access impacts ability to deliver and
monitor AC
GA used in procedures more commonly in children,
affecting ability to confirm and monitor
thromboembolic disease and therefore therapeutic
decisions

13
The coagulation cascade
14
Thrombogenesis

Vasospasm
Platelet adhesion
Platelet aggregation
Viscous metamorphosis
Platelet plug
Fibrin reinforcement
Local production of thrombin
Platelet ADP
Thromboxane A2, Prostacyclin (PGI2).
Serotonin
White thrombus, Red thrombus

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Drugs that affect coagulation
17
Indirect Thrombin Inhbitors
Heparin Fondaparinux
Vitamin K Antagonists Warfarin
Coumarinsl
Antithrombotics
Direct Thrombin inhibitors Hirudin,
Bivaluridin Argatroban, Melagatran
Ximelagatran
Antiplatelet agents
Aspirin Dipyridamole , Clopidogrel
Ticlopidine
18
Indirect Thrombin Inhbitors Act
on ANTITHROMBIN
Vitamin K Antagonists Act via Vit K
dependent factors II, VII, IX, X
Direct Thrombin inhibitors Directly bind to
Thrombin
19
Adults Vs Children / Infants
20
Developmental Haemostasis

Affects frequency, natural history, and response
to agents
Global functioning of the haemostatic system is
different from adults
Plasma values of many coagulation proteins are
different
Qualitative differences in many of the
coagulation proteins, especially in neonates
Significant differences in the antithrombotic
properties of the vessel wall

21
Developmental Haemostasis

Antithrombin (AT) levels are physiologically low
at birth (0.50 U/ml)
Adult values are reached only after 3 months
Sick preterms have levels less than 0.30 U/ml
Fetal range 0.20-0.37 at 19-38 weeks
Significance Profound effect on the action of
Heparin
Following infancy, thrombin generating capacity
increases but remains 25 less than adult
capacity throughout childhood
In-vitro tests show both increased sensitivity
and resistance to Unfractionated Heparin (UFH) in
neonates

22
Developmental Haemostasis

Infants have physiologically low levels of Vit K
dependent factors and contact factors which
gradually rise to adult values nearing 6 months
Levels of Protein C and Protein S are very low at
birth
Interaction of Protein C with Protein S in
newborn plasma may be regulated by increased
concentration of alpha-2 macroglobulin
Plasma concentration of thrombomodulin is
increased in early childhood, decreasing to adult
values by teenage
Free tissue factor pathway inhibitor (TFPI)
concentrations are significantly lower in
neonates

23
Pharmacokinetic differences

Distribution, binding and clearance of AC agents
is age-dependent
Larger volume of distribution, faster clearance
of UFH, LMWH in newborns
Altered heparin binding (unproved)
Low levels AT
Result Higher initial dose of Heparin needed to
attain therapeutic levels
Maintenance doses required are highest in infants
lt 2 months
Higher patient-patient variability
Warfarin doses are also age dependent reasons
not known

24
Drug formulations

No specific pediatric formulations available

Dietary differences

Vit K concentrations in breast milk and infant
formulae differ
Breast fed babies are very sensitive to VKA
Formula-fed babies need high doses, increasing
the risk of bleeding in case of intercurrent
illnesses etc

There are numerous studies defining appropriate
strategies in adults with a range of TEs
Anticoagulation strategies are controversial and
unproven in children
Attempt to formulate a consensus 7th ACCP
Conference on Antithrombotic and Thrombolytic
Therapy Evidence based Guidelines

26
Specific DrugsHeparins
27
Heparin

A heterogenous mixture of glycosaminoglycans
ranging from 3000 to 30000 daltons in MW
Non-branching, negatively charged pentasachharide
chain
Pentasachharide sub-unit structure is
instrumental in its ability to bind to
Antithrombin

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Heparin Mechanism of Action

Indirect thrombin inhibitor
Catalysis the action of Antithrombin by over
1000-fold.
(AT inhibits Thrombin i.e IIa, IXa,and Xa)
Active Heparin molecules bind tightly to AT,
causing conformational changes, exposure of its
active site for more rapid interaction with the
activated clotting factors).
Once AT-protease complex is formed, Heparin is
released intact for binding to more AT.
Prevents additional thrombus accretion
Does not lyse a thrombus already formed

HMW fraction of Heparin inhibits all three
thrombin (Factor IIa), IXa and Xa, esplly
thrombin and Xa.
LMWH inhibits activated factor X but has less
effect on thrombin than HMW species.
Commercial heparin consists of a family of
molecules of different MW.
Commercial heparin is extracted from porcine
intestinal mucosa and bovine lung.
Usually sodium or calcium salts. Lithium salt for
in-vitro anticoagulation.
UFH dosing in in USP units/mg

31
Therapeutic range of UFH

That reflects a heparin level by protamine
titration of 0.2 0.4 U/ml or an Anti Factor Xa
level of 0.35 0.7 U/ml
aPTT therapeutic ranges are universally
calculated using adult plasma and are
extrapolated onto the pediatric population as
well. Validity yet unknown.
In pediatric patients, aPTT values correctly
predict therapeutic concentrations approx 70 of
the time

32
Pharmacokinetics and Dose

Volume of distribution is more and clearance
rapid in neonates and young infants heparin
binding may also be different.
So higher dose required to achieve adult
therapeutic range
Bolus dose of 75 100 U/Kg results in
therapeutic aPTT value in nearly 90.
Maintenance is age-dependent
Infants lt 2 mo 28U/kg/Hr
Children gt 1 yr 20U/kg/Hr
Older children 18U/kg/Hr

33
Heparin Dosing Nomogram
34
Adverse effects of Heparin

Bleeding Andrew M et al reported 1.5 incidence
in their prospective cohort study in children
treated for DVT/pulmonary embolism
Thrombocytopenia
Non-immune HAT (HIT Type I)
Immune mediated (HIT Type II)
Osteoporosis and spontaneous fractures
Allergic reactions
Reversible alopecia
Long-term usage mineralocorticoid deficiency

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Frequency of HIT
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Treatment of adverse affects

Bleeding Cessation of heparin and IV Protamine
if needed

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Treatment of thrombocytopenia

Non-Immune HAT Promptly discontinue Heparin
Suspected HIT
Discontinue all Heparin
Confirm diagnosis with alternate tests
Alternative anticoagulants
Monitor for thrombosis and platelet counts
Avoid prophylactic platelet transfusion

39
Treatment of HIT

Stop Heparin
Alternative anticoagulants
Warfarin disadvantage- takes 4-5 days for full
therapeutic effect associated with venous limb
gangrene when used alone
LMWH
Recombinant Hirudin,
Danaparoid sodium
Ancrod (isolated from Malayan Viper)
Prostacyclin analogues
IVIG
Plasmapharesis

40
Low Molecular Weight Heparins(LMWH)

Principally inhibit Factor X, less effect on
Thrombin
Enoxaparin same source as regular heparin, but
doses specified in mg
Dalteparin , Tinzaparin, Danaparoid (a mixture of
heparan sulfate, dermatan sulfate and chondroitin
sufate)doses specified in Anti Factor Xa units

Low Molecular Weight Heparins
Have rapidly become AC of choice in many
pediatric patients both for primary prophylaxis,
and treatment of TE, despite unproven efficacy
Advantages
Need for minimal monitoring
Lack of interference by other drugs or diet (as
for VKAs)
Reduced risk of HIT
Reduced risk of Osteoprosis
Disadvantages
High in-vitro cross-reactivity with Heparin
dependent antibodies
Significant risk of recurrent or progressive
thrombocytopenia and/or thrombosis
Reduced predictability of anticoagulant effect
compared to adults

42
LMWH Therapeutic range and dosage

Extrapolated from adult data, based on Anti
Factor Xa levels 0.50 1.0 U/ml in a sample
taken 4-6 hours following a subcutaneous inj
Peak occurs 2-6 hours after s/c inj
lt 2-3 months or lt5 Kg have higher requirement due
to increased volume of distribution, lower levels
of AT and or altered heparin pharmacokinetics

43
L M W H D O S A G E
44
Adverse effects of LMWH

Dix D et al reported 10.8 major bleeding
complication in infants in a prospective cohort
study
Same authors reported bleeding complication in
4.8 patients with enoxaparin
Massicotte P et al reported major bleeding
complications in 8.1 patients in a randomized
trial, with Reviparin
No data on frequency of osteoporosis, HIT,
hypersensitivity reactions in children
TREATMENT Protamine Sulfate

45
Contra-indications to Heparin

Hypersensitivity
Active bleeding
Hemophillia
Significant thrombocytopenia/purpura
Severe hypertension
ICH
IE
Active TB
Ulcerations of GI tract
Threatened abortion
Visceral Ca
Advanced hepatic or renal disease
AVOID IN Recent neuro/ophthalmic surgery, or
undergoing lumbar puncture / regional anaesthetic
block, pregnancy

46
Vitamin K Antagonists
47
Vitamin K Antagonists Warfarin and coumarin
anticoagulants

Discovery of an anticoagulant substance (
bishydroxycoumarin ) formed in spoiled sweet
clover silage which resulted in hemorrhagic
disease in cattle.
Warfarin is the most reliable member of this
group, which also comprises Dicumarol,Phenprocoumo
n,Phenindione, Diphenindione

Warfarin generally administered as a Sodium salt
100 bio-availability
99 bound to albumin, small volume of
distribution
Long plasma half life 36 hours
Racemic mixture of levorotatory S-warfarin (4
times more potent) and dextrorotatory R-warfarin

49
MOA of Warfarin

Blocks gamma carboxylation of several glutamate
residues in Prothrombin and factors VII, IX, X
and endogenous anticoagulant proteins C and S
results in biologically inactive molecules
Oxidative deactivation of Vit K. Prevents
reductive metabolism of inactive Vit K epoxide
back to its active hydroxyquinolone form

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AC effect results from a balance between
partially inhibited synthesis and unaltered
degradation of the 4 Vit K dependent factors
The effect therefore depends on their degradation
rates in circulation. Therefore there is an 8-12
hour delay in onset of anticoagulant action
Larger initial doses of upto 0.75 mg/Kg can
hasten the onset of action but there is no
benefit beyond this dose

52
VKA use in neonates and children

Vit K dependent factors are physiologically low
in newborns ( equivalent to an adult getting VKA
with target INR of 2 3)
Multiple issues
Formula feeds are fortified with Vit K, so
formula fed babies are resistant to VKAs
Breast milk is deficient in Vit K, so breast fed
babies are very sensitive to VKAs
Only oral formulations are available
Require frequent monitoring in newborns because
of rapidly changing physiological values of
Vitamin K-dependent proteins, changes in
medications and dietary changes
No data on their efficacy or safety in newborns

53
VKA Therapeutic Range

Current therapeutic INR ranges for children are
directly extra-polated from adults there are no
clinical trials for optimal INR range for
children based on clinical outcomes
Andrew M et al proposed initial dose of 0.2 mg/Kg
with dose adjustments according to nomogram
Streif W et al in the largest cohort study (319
patients) found that infants required 0.33 mg/Kg
and teenagers required 0.09 mg/kg warfarin to
maintain a target INR of 2-3

Monitoring of Efficacy -- the INR or
International Normalised Ratio. This represents
a standardised prothrombin time (PT) which is
specific for the extrinsic pathway of coagulation
(sensitive to factors I, II, V, VII, and X).
INR (PT pt / PT
ref)ISI
where PTpt patient prothrombin time, PTref
specific laboratory reference PT, and ISI
international sensitivity index.
This normalisation is approximately equal to a PT
of 1.6 for most American laboratories.
Effective warfarin therapy should produce an INR
that is 2.5-3.5 times the normal

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Monitoring and Adverse Effects

Monitoring in children is difficult and requires
close supervision and frequent dose adjustments
In contrast to adults, only 10-20 can be
monitored safely monthly
Bleeding is the main adverse effect
Monagle P et al reported serious bleeding in
lt3,2 per patient year in children receiving VKA
for mechanical prosthetic valve
Streif W et al reported bleeding rate of 0.5 per
patient year
Massicotte P et al reported bleeding in 12.2 of
patients in a randomized control trial (41
patients, target INR 2-3, for 3 months)
Non-hemorrhaegic complications tracheal
calcification, hair loss, loss of bone density -
rare

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Drug interactions of warfarin

Drugs that increase PT/INR by pharmacokinetic
mechanisms
Amiodarone, Cimetidine, Disulfiram,
Metronidazole, Fluconazole, Phenylbutazone,
Sulfinpyrazone, Cotrimoxazole
Drugs that increase PT by pharmacodynamic
mechanisms
Aspirin (high dose),third generation
Cephalosporins, Heparin
Body factors causing increase in PT
Hepatic disease, hyperthyroidism

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Drug interactions of warfarin

Drugs that cause fall in PT/INR by
pharmacokinetic mechanisms
Barbiturates, Rifamicin, Cholestyramine
Drugs that cause fall in PT/INR by
pharmacodynamic mechanisms
Diuretics, Vit K
Body factors resulting in fall in PT/INR
Heriditary resistance, hypothyroidism

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Direct Thrombin Inhibitors
62

Relatively new class of drugs
Directly binding to the active site of thrombin
Hirudin
Specific irreversible thrombin inhibitor from
leech.Bivalent DTI, ie., binds at both the active
site AND at the substrate recognition site of
thrombin
Recomb form Lepuridin Parenteral drug,
monitored by aPTT, FDA approved for HIT, short
halflife but accumulates in renal insufficiency,
has no antidote.No effect on platelets.

Bivaluridin also bivalent DTI, I/V administered,
rapid onset and offset of action, short
halflife.Inhibits platelet activation,
FDA-approved for use in PTCA.
Argatroban I/V infusion, short half life,
monitored by aPTT, FDA-approved for HIT. Requires
dose adjustment in liver disease
Melagatran and oral pro-drug Ximelagatran
predictable pharmacokinetics and
bio-availability, no need for routine monitoring,
lack of drug interaction, rapid onset and offset
No data in children on DTI

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Platelet function and Antiplatelet Drugs
65

Neonatal platelets have an intrinsic defect that
makes them hyporeactive to thrombin,
ADP/epinephrine, and thromboxane A2.But
paradoxically, BT is short due to increased RBC
size, high hematocrit and increased level of vW
Factor
BT is prolonged throughout childhood, compared to
adults Andrew M et al, Sanders J et al

66
Aspirin

Most common agent
Pediatric doses not based on studies of effect on
platelets in pediatric patients
Empirical dose 1 5 mg/kg/day
Adverse effects
Risk for bleeding in neonates exposed to maternal
aspirin ingestion
Significant bleeding rare except with underlying
bleeding disorder, or anticoagulant/thromboltyic
therapy
TREATMENT platelet transfusion / plasma products
with vW factor or des-amino-D-arginine

67
Other anti-platelet drugs

Dipyridamole 2-5mg/kg/d
Ticlopidine and clopidogrel Thienopyridines.Selec
tively inhibit ADP-induced platelet
aggregation.Effect additive to that of Aspirin.
No reported use in children
(GP)IIb-IIIa antagonists abciximab,
eptifabitide (Integrilin), tirofiban (Aggrastat)
Powerful antiplatelet agents as they block the
final common pathway of fibrinogen-mediated
platelet aggregation by binding to platelet
surface GPIIb-IIIa
Williams RV et all reported the use of abciximab
in addition to standard therapy in Kawasaki
Disease, resulting in greater regression in
coronary aneurysm at earlier follow-up

68
Surgical therapy

Venous interruption devices
Sugical thrombectomy Rare
Acute thrombosis of BT shunt
Life threatening intra-cardiac thrombosis
immediately after complex cardiac surgery
prosthetic valve thrombosis
Peripheral artery thrombosis following vascular
access in neonates
No specific guidelines

69
THROMBOLYTIC DRUGS
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Streptokinase

Synthesized from streptococcus
Binds circulating plasminogen, catalysing its
conversion to plasmin
Non-specific, generalized action

72
Urokinase

Synthesized from urine
Actually converts plasminogen to plasmin
Non-specific, generalized action

73
Tissue plasminogen Activator

Preferentially activates fibrin-bound plasminogen

74
Specific Indications for Antithrombotic Therapy
in Children
75
1).Systemic Venous Thrombosis in neonates

gt80 of venous TE in neonates are secondary to
central venous lines
Mechanism damage to vessel walls, disrupted
blood flow, TPN, thrombogenic catheter material
An international registry of symptomatic VTE in
neonates reports an incidence of 2.4/1000
admissions to NICUs

Acute problems loss of CVL patency, swelling,
pain, discoloration, SVC syndrome, respiratory
compromise, pulmonary embolism
Chronic problems development of collateral
circulations, requirement for local thrombolytic
therapy, repeated requirement for CVL
replacement,sepsis, chylothorax,
chylopericardium, recurrent VTE requiring
long-term AC therapy.
Long term sequelae portal HTN, variceal bleeds,
hypertension

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Systemic Venous Thrombosis in neonates -
Recommendations

UFH or LMWH, or radiographic monitoring and AC
therapy if extension occurs
If AC (UFH/LMWH) is administered, subsequently
give LMWH for 10d to 3 months
Adjust the dose of UFH to prolong the aPTT
corresponding to an anti-FXa level of 0.35 - 0.7
U/ml
Adjust the dose of LMWH to achieve an Anti FXa
level of 0.5-1 U/ml
If thrombus extends following discontinuation of
heparin therapy, administer VKAs or extend LMWH
therapy

DO NOT use thrombolysis unless there is a major
vessel occlusion causing critical compromise of
organ or limb. In that case, supplement with FFP
immediately prior to thrombolysis
Remove the CVL / UVL in situ or give prophylactic
LMWH therapy till its removed

80
2).Systemic venous thromboembolic disease

Estimated incidence of symptomatic VTE in
children 5.3/10000 hospital admissions
95 secondary to serious conditions like CHD /
cancer / trauma / surgery / SLE
lt1 year, teenagers at max risk
Most common risk factor CVL
Asymptomatic, radiologically detected CVL-related
VTE important because of association with
CVL-related sepsis, and pul embolism
2 major trials Reviparin in Thromboembolism
(REVIVE) and Prophylaxis of Thromboembolism in
Kids Trial (PROTEKT) both closed early,
underpowering them

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Systemic venous thromboembolic diseaseRecommendat
ions

Based on adult data
IV Heparin to prolong aPTT corresponding to Anti
FXa level of 0.35-0.7 U/ml, or LMWH to achieve
anti FXa level of 0.5-1 U/ml after 4 hours of inj
(G 1C)
Initial t/t with UFH/LMWH for 5-10 d.If
subsequent VKAs to be used, then begin oral
therapy as early as D1 and discontinue Heparin on
D6 if INR in therapeutic range on 2 consecutive
days.For massive PEs or extensive DVTs, longer
period of UFH/LMWH therapy (G1C)
Continue AC for idiopathic TE for at least 6
months using VKA to achieve target INR of 2.5
(2.0 3.0), or LMWH to maintain anti FXa level
of 0.5 1.0 U/ml (G 2C)
6 mo rather than life long, placing relatively
high value on avoidance of known bleeding
complication, and less value on unknown risk of
recurrence

4.For secondary TEs, continue ACs for at least 3
months using VKAs to achieve a target INR of 2.5
(2 -3), or LMWH to maintain anti FXa level of
0.5-1.0 U/ml
5.In presence of continuing risk factor, eg
nephrotic syndrome, ongoing asparaginase therapy,
AC therapy in either therapeutic or prophylactic
doses to continue till risk factor resolved
6.Do not use thrombolysis routinely.If used,
supplement with FFP
7.Recurrent idiopathic TEs need indefinite
therapy with therapeutic/prophylactic doses of
VKA (G1C). LMWH if VKA too difficult
8.Recurrent secondary TE, following intial 3
months, AC therapy to continue for another 3
months or till removal of precipitating factors
9.If no longer required, CVL be removed give 3-5
days of AC therapy prior to removal.If CVL
required and functioning, retain it and give AC
therapy
10.First CVL-related DVT after initial 3 months
of therapy, prophylactic dose of VKA ( INR 1.5-8)
or LMWH (anti FXa 0.1-0.3) till CVL removed
11.Recurrent CVL related TEs after initial 3
months of therapy, prophylactic VKA (INR 1.5-1.8)
or LMWH (anti FXa 0.1-0.3) till removal of CVL.
If there is recurrence during prophylactic
therapy, continue therapeutic doses until CVL
removed OR minimum of 3 months

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CVL ProphylaxisRecommendations

1.No routine primary prophylaxis
2.In long term TPN, continuous VKA therapy
(target INR 2-2.5), or alternately, for the first
three months after each CVL is inserted (G2C)

84
Primary prophylaxis for neonatal BT
ShuntRecommendations

Incidence of thrombotic complications in BT shunt
1 17
Intra-operative heparin followed by either
Aspirin (5mg/Kg/day) or no further anticoagulant
therapy

85
Glenn Shunt

Thrombotic complications are infrequently
reported.
30 year follow-up GS Kopf et al, JACC 1990
reported no long term thrombotic complications.
2 reported cases of RV thrombosis
No evidence to support need for routine
thromboprophylaxis

86
Fontan Surgery

TE is a major cause for early and late
morbidity/mortality
Venous TE 3-16
Stroke 3-19
May occur anytime, often present months or years
later
High mortality. Response to therapy in lt 50
cases.

87
Primary prophylaxis for Fontan Surgery in
childrenRecommendations

1.Aspirin (5mg/kg/day) or therapeutic heparin
followed by VKAs with target INR of 2.5 (2-3)
(G2C)
Optimal duration unknown.Whether fenestrated
fontans need more intensive therapy till
fenestration closure, is unknown

88
Primary prophylaxis for Stage 1
NorwoodRecommendations

Heparin therapy immediately after the procedure

89
Primary prophylaxis for endovascular
stentsRecommendations

Heparin perioperatively

90
Primary prophylaxis for DCMRecommendations

VKA to achieve INR of 2.5 ( 2-3) (G2C)
(awaiting transplant)

91
Thromboprophylaxis for cardiac cath in neonates
and children

For arterial punctures, IV Heparin (G1A)
100 150 U/Kg bolus dose. Further doses may be
required in prolonged procedures (G2B)
Do NOT give aspirin (G1B)

92
Femoral artery thrombosis following cardiac
cathRecommendations

Therapeutic dose of IV Heparin (G1C)
Treatment for at least 5-7 days
In limb-threatening or organ-threatening
thrombosis who fail to respond to initial heparin
therapy,and who have no contraindications,
thrombolytic therapy is recommended (G1C)
When thrombolysis is contraindicated or
organ/limb death is imminent, Surgical
intervention is recommended (G2C)

93
Peripheral artery thrombosisRecommendations

Administration of low-dose heparin through the
peripheral arterial catheters in-situ, preferably
by cont infusion
For children with peripheral arterial
catheter-related TE, immediate removal.
Subsequent AC therapy with/without thrombolysis

94
Kawasaki Disease in childrenRecommendations

Aspirin in high dose (80 100mg/kg/d) during
acute phase for upto 14 days, then 3-5 mg/kg/d
for gt7weeks
IVIG (2g/kg as a single dose) within 10 days of
onset
In GIANT CORONARY ANEURYSMS, Warfarin therapy is
recommended ( target INR 2.5 range 2.0-3.0) in
addition to low dose aspirin

95
Spontaneous aortic thrombosis in
neonatesRecommendations

In aortic thrombosis with e/o renal ischemia,
urgent, aggressive thrombolytic or surgical
therapy, supported by AC therapy with heparin /
LMWH

96
Antithrombotic therapy in Valvular Heart Diseases
97
Valvular Heart Disease

Native valves
Prosthetic Valves
Mechanical Valves
Bioprosthetic Valves
Endocarditis
Infective
Non-Bacterial Thrombotic

98
Native cardiac valvular disease

Rheumatic valvular disease
Thromboembolic complications maximum with Mitral
Valve disease
Wood (1961) 9-14 prevalence in large early
series with MS
Ellis and Harkin 27 in 1500 mitral
valvuloplasty patients
Szekely et al 1.5 /patient year
At least 1in 5 chance of clinically detectable
emboli during course of MV Disease

99
Risk factors of TE in MV Disease

MS vs MR
Wood 1.5 times more common in MS
AF vs Sinus Rhythm
Szekely 7 times higher risk in AF
Hinton et al 41 in autopsy studies of MS/AF
Coulshed et al 31.5 in MS/AF vs 8 in MS/NSR
22 in MR/AF
Age
LA thrombus / LA size
Significant AR
Chiang et al MV area, LA size
H/o previous embolism 30-65 60-65 of these
occur within 1 year

100
Mitral Valve disease with AF/ Previous Systemic
emboli
Long term OAC Non Anticoagulated
Szekely et al 3.4 per pt yr 9.4 per pt yr
Fleming et al 0.8per pt yr 25per pt yr
Roy D et al 0.75.46 per pt yr 5.46per pt yr
101

Evidence strongly tilted in favour of offering
anticoagulant therapy for all patients with
Rheumatic Mitral Valve Disease and AF, or with
h/o previous embolism
Mitral Valve Disease with sinus rhythm also
carries substantial risk
Prior AF
Antiarrhythmics
Large LA

102
RECOMMENDATIONS FOR MITRAL VALVE DISEASE
103
MVD WITH AF / PREVIOUS SE

Long term OAC therapy target INR 2.5 ( 2 3)
Do not use concomitant therapy with OAC and
antiplatelet agent
Systemic embolism while on OAC with therapeutic
INR
Add Aspirin
Add Dipyridamole or Clopidogrel- If unable to
take aspirin

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MVD IN SINUS RHYTHM

With LA diameter gt 55mm
Long term OAC target INR 2.5 ( 2 3 )
With LA diameter lt 55mm
No anticoagulant therapy

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Mitral Valvuloplasty

OAC with VKA for three weeks prior to and four
weeks after the procedure target INR 2.5 ( 2 3
)

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Mitral Valve Prolapse

No systemic embolism / unexplained TIAs / AF no
anticoagulant therpay
Documented but unexplained TIAs long term
Aspirin therapy
Documented systemic embolism or recurrent TIAs
despite Aspirin VKA with target INR of 2.5 ( 2
3 )

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Native Aortic Valve Disease
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Isolated Aortic valve disease causing
thromboembolic complications is rare among all
age groups, especially in children except if
associated with MVD or AF
Microthrombi, usually clinically undetected are
known to occur

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Recommendation for AV disease

Do not use long term VKAs unless for some other
indication
Use VKA if
Aortic plaques gt 4mm
Mobile aortic atheromas

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PROSTHETIC CARDIAC VALVES
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MECHANICAL VALVES

All types of mechanical valves need anticoagulant
therapy
Permanent therapy with VKAs

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RECOMMENDATIONS FOR MECHANICAL VALVES
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All patients to get permanent VKA therapy. UFH or
LMWH until INR is stable and at therapeutic level
for two consecutive days.
St.Jude Medical Bileaflet valve in Aortic
position, target INR 2.5 ( 2 3 )
Tilting disc valves and bileaflet mechanical
valves in Mitral position, target INR 3.0 ( 2.5
3.5 ).
CarbosMedics bileaflet valves or Medtronic Hall
tilting disk valves in aortic position with
normal LA size and SR, target INR 2.5 ( 2 3 )

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Additional risk factors such as AF, LAE,
endocardial damage, low EF, target INR 3.0 ( 2.5
3.5 ), combined with low dose aspirin.
Caged ball or caged disk valves, target INR 3.0 (
2.5 3.5 ) with aspirin.
Systemic embolism despite therapeutic INR, add
aspirin maintain INR at target 3.0 ( 2.5 3.5
).
If VKA must be discontinued, LMWH.

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RECOMMENDATIONS FOR BIOPROSTHETIC VALVES
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BIOPROSTHETIC VALVES

First three months high propensity for TE.
Higher incidence in Mitral position.
Ionescu et al 5.9 in 1st 3 months after
operation, without anti-coagulant therapy.
Orszulak et al Strokes during 1st month after
opreation _at_ 40 per patient year.

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RECOMMENDATIONS

In the Mitral position VKA with a targt INR of
2.5 ( 2 3 ) for the first 3 months.
In Aortic position VKA with a target INR of 2.5
( 2 3 ) for the first 3 months OR aspirin.
Heparin until INR is stable at therapeutic
levels for 2 consecutive days.
With h/o systemic embolism, VKA for 3-12 months.
With evidence of LA thrombus at surgery, VKA with
a target INR of 2.5 ( 2 3 ).

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Long term risks with Bioprosthetic valve