Venous Thromboembolism

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Venous Thromboembolism

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Title: Venous Thromboembolism

1
Venous Thromboembolism

Core Rounds
April 10, 2003
A.F. Chad, MD, CCFP

2
DVT Objectives

Epidemiology
Natural History
Risk Factors
Hx PHx Pre-test Probability
Wells Perrier
Tests (D-dimer, Doppler, IPG, Venography)
Upper Extremity DVT (Dx, RF, Rx, risk PE)
Rx

3
DVT Submission move by Jake The Snake
Roberts OR Badness in the Veins?
4
Epidemiology

Lifetime incidence VTE 2-5
PE 0.5/1,000/year
DVT 1/1,100/year
Prospective studies of DVT
10-13 medical pts on bed rest 1 week
29-33 pts in ICU
20-26 pts pulmonary diseases given bed rest gt3d
27-33 CCU pts
48 pts post CABG

5
History

1550 BC Ebers papyrus documented peripheral
venous disease
1644 Schenk observed venous thrombosis with
occlusion in the IVC
1846 Virchow -gt association b/n venous thrombosis
in legs PE
1937 Heparin comes into practice

6
Natural History

19th C Virchows triad venous stasis, injury to
intima, hypercoagulability
Thrombosis platelet nidus near venous
valves-gtplatelets and fibrin -gt thrombus -gt
occlusion, embolism
Endogenous thrombolytic system -gt partial
dissolution-gt organized into venous wall

7
Natural History

Most go away w/o Rx
20 propagate proximally
Organize into vein by day 5-10
Biggest risk of propagation, embolization is
before this

8
Natural History

Debate whether isolated calf thrombi are
important
Some said to have low risk PE
Others said just as bad

9
Risk Factors General

Age
Immobilization longer than 3 days
Pregnancy and the postpartum period
Major surgery in previous 4 weeks
Long plane or car trips (gt4-6 h) in previous 4
weeks
Wrestling Jake The Snake Roberts

10
Risk Factors Specific

Medical
Cancer,Previous DVT, stroke, MI, CHF, sepsis,
nephrotic, UC
Trauma
Multiple trauma, CHI, SCI, Burn, LE
Vasculitis
SLE / LAC, Bechet, Homocystinuria
Hematologic
PRV, Thrombocytosis

Clotting D/O
Antithrombin III , Protein C, Protein S, Factor V
Leiden, Dysfibrinogenemias and disorders of
plasminogen activation
Drugs/medications
IV drug abuse
Oral contraceptives
Estrogens
HIT

11
Risk Factors

50 without risk factors
OCP/HRT 3x baseline risk
0.3/10,000/yr 15/10,000/yr
higher in 3rd gen progesterones
pregnancy 5x baseline risk
75 DVT antepartum, 66 PE postpartum

12
PathophysiologySource of VTE

most start in calf, extend proximally
70 PE have DVT evidence at autopsy
70-90 known source IVC, ileofemoral or pelvic
veins, 10-20 SVC
incidence of PE from DVT
calf 46
thigh 67
pelvic 77
other UE, jugular, mesenteric, cerebral

13
History

Many No Sx
Edema (unilateral) specific
Leg pain in 50 -gt nonspecific
Tenderness in 75, but also in 50 w/o DVT
10 Sx PE
Amount pain / tenderness do not correlate to
severity
Warmth, erythema

14
Physical

No ONE reliable history / physical finding
Sensitivity 60-96, Specificity 20-72
Need to look _at_ combination of factors
Anand SS, Wells PS, Hunt D, Brill-Edwards P, Cook
D, Ginsberg JS. Does this patient have deep vein
thrombosis? JAMA. 1998 Dec 2280(21)1828-9.

15
Physical

Edema (unilateral) (gt 3cm)
Homans (50 sens)
Superficial thrombophlebitis (up to 40 can have)
Fever (gt39.5, something else)
Phlegmasia cerulea dolens
Swollen purple leg re venous engorgement
Cyanosis re massive venous obstruction
Phlegmasia alba dolens
Whitish inflammation associated with arterial
spasm 2nd to massive venous obstruction
Worry about arterial occlusion

16
Clinical PresentationDVT

Calf-popliteal
80-90, many asymptomatic
pain swelling
10-20 spreads proximally
Ileofemoral
pain in buttock, groin
thigh swelling
10-20 cases
Do not adhere to vessel walls until 5-10d post
formation -gt high risk to propagate / embolize

17
Clinical Prediction Model for DVTWells et al.
Ann Int Med, 1997
18
Clinical Model for DVT
19
Incidence of DVT by Clinical Probability
20
Algorithm for Suspected first DVTPerrier.
Lancet, 1999
21
Tests

D-dimer
Doppler U/S
IPG
Venography

22
D-Dimer

Not Clot specific
recent surgery, trauma, MI, pregnancy, CA can all
give false

23
D-dimer AssaysVan der Graaf. Thromb Haemost,
2000.
24
Diagnostic Imaging for DVT

Duplex / compression U/S
non-invasive, portable
direct visualization of veins and flow
loss of compression DVT
97 sensitive specific for symptomatic
proximal/popliteal DVT
62 sensitive for asymptomatic DVT
ve in 30-50 PE 5 non-dx V/Q scans

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Serial Venous U/S

2 protocols Wells Hull
may avoid angiography in ?PE
2 ve in 2 weeks (?PE)
if U/S -ve 2 weeks apart, lt2 have VTE in next 6
mos

29
Diagnostic Imaging for DVT

IPG
detects changes in flow before and after cuff
inflated
sensitivity 60

30
IPG vs. Doppler

N985
PPV U/S94 (CI 87-98)
PPV IPG 83 (CI 75-90)
P0.02
Harriet Heijboer, Harry R. Buller, Anthonie
Lensing, Alexander Turpie, Louisa P. Colly, and
Jan Wouter ten Cate. A Comparison of Real-Time
Compression Ultrasonography with Impedance
Plethysmography for the Diagnosis of Deep-Vein
Thrombosis in Symptomatic Outpatients NEJM Volume
3291365-1369November 4, 1993Number 19.

31
Venography

?Gold Standard?
Invasive
Contrast
Need experienced readers
Non-diagnostic up to 25

32
Upper Extremity DVT

8 of all DVT
75 are related to hypercoag, CVC
25 Paget-von Schroetter syndrome
Exertional DVT
Caused by underlying MSK deformities (Thoracic
outlet, extra rib)

33
Upper Extremity DVT

Prandoni P, Polistena P, Bernardi E, Cogo A,
Casara D, Verlato F, Angelini F, Simioni P,
Signorini GP, Benedetti L, Girolami A.
Upper-extremity deep vein thrombosis. Risk
factors, diagnosis, and complications. Arch
Intern Med. 1998 Sep 28158(17)1950-2.

34
Upper Extremity DVT

N58 Sx UEDVT
IPG, Doppler, venography
27 (47) UEDVT
Test Sens Spec
compression ultrasonography (96 and 93.5)
color flow Doppler imaging (100 and 93)

35
Upper Extremity DVT

PE Objectively found in 36
2 yr F/U 2 recurrent VTE
RF
CVC
Thrombophilia
Previous VTE

36
U/S Upper Extremity DVT

The sensitivity of duplex ultrasonography ranged
from 56 to 100, and the specificity ranged from
94 to 100
Unsure if Helpful
Bisher O. Mustafa, MD Suman W. Rathbun, MD
Thomas L. Whitsett, MD Gary E. Raskob, PhD
Sensitivity and Specificity of Ultrasonography in
the Diagnosis of Upper Extremity Deep Vein
Thrombosis A Systematic Review Arch Int Med Vol.
162 No. 4, February 25, 2002.

37
Upper Extremity DVT

10-30 incidence PE associated
Therapy
Usual Rx
Local thrombolytics appears to be Rx of choice
with literature mainly case studies

38
Treatment of VTEGoals

reduce mortality
prevent extension/recurrence
restore pulmonary vascular resistance
prevent pulmonary hypertension

39
Treatment of VTEAnticoagulation

Out-patient LMWH
LMWH superior to UFH? (Gould 1999)
out-pt Rx safe in PE (Kovacs, 2000)
DVT start Rx, definitive test in 24hr
baseline B/W

40
Anticoagulation

Enoxaparin 1mg/kg bid or 1.5 od
Tinzaparin 175 anti-Xa u/kg od
start warfarin 5mg on day 1
d/c LMWH when INR gt2.0 x 2 days
Rx 3 mos if 1st and reversible cause
6 mos if non-reversible
indefinite if recurrent, CA, genetic
Anticoagulation Clinic

41
LMWH vs. UFH

N432
No difference in new VTE
Less died, complications in LMWH (SS)
RD Hull, GE Raskob, GF Pineo, D Green, AA
Trowbridge, CG Elliott, RG Lerner, J Hall, T
Sparling, HR Brettell, and et al Subcutaneous
low-molecular-weight heparin compared with
continuous intravenous heparin in the treatment
of proximal-vein thrombosis NEJM Volume
326975-982April 9, 1992Number 15

42
Pregnancy

V/Q safe, no breastfeed x 15hr post
D-dimer ? in pregnancy, wide Aa
angiography safer than empiric Rx
LMWH in DVT, not studied in PE
PE UFH IV x 4-5 days, then s/c
treat x 3 months or 6 weeks postpartum
switch to oral postpartum

43
PE Early Rappers OR Badness in the Veins?
44
PE Objectives

Epidemiology Natural History
Mortality Pathophysiology
Hx PHx
Pre-test Probability
Dx
Angio, Echo, CT, algorithms
Which tests / combo rules in / out
What to do if non-Dx results
Confounding Clinical Situations
Rx
Heparin, Thrombolysis (massive, submassive),
embolectomy, IVC filter

45
Epidemiology

USA 60-80 patients with DVT, gt50 Sx free
3rd in hospital mortality, 650,000 cases/yr
Autopsy studies 60 pts who die in hospital had
PE, diagnosis missed 70

46
Natural History

Most pulmonary emboli are multiple, and the lower
lobes are involved
From deep veins of lower extremities
Also pelvic, renal, upper extremity, right heart
chambers
Large thrombi lodge _at_ bifurcation of main PA or
lobar branches -gt hemodynamic compromise
Smaller thrombi occlude smaller vessels in
periphery
More likely to cause pleuritic chest pain
(inflammatory response adjacent to parietal
pleura)

47
Mortality

Approximately 10 of patients who develop PE die
within the first hour,
30 die from recurrent embolism. Anticoagulant Rx
decreases mortality lt 5

48
Pathophysiology Review

Normal RV has a narrow range over which it can
compensate for acute increases in afterload. The
pericardium has a limited ability to distend.
Increased RV afterload elevation in RV
wall pressures dilation and hypokinesis of
the RV wall
shift of intraventricular septum towards left
ventricle (tricuspid regurgitation) and decreased
LV output.

49
Respiratory Consequences

Early
Increased alveolar dead space, Pneumoconstriction,
hypoxemia, hyperventilation
Late
regional loss surfactant, pulmonary infarction
Arterial hypoxemia frequent, not universal
V/Q mismatch, shunts, reduced CO, intracardiac
shunt via PFO
Infarction uncommon re bronchial arterial
collateral circulation

50
Hemodynamic Consequences

Reduces X-sectional area of pulmonary vascular
bed -gt incr pulmonary vascular resistance -gt RV
afterload -gt RV failure
Reflex PA constriction
Prior poor cardiopulmonary status important
factor re hemodynamic collapse

51
Resolution

Anticoagulant therapy -gt resolution of emboli
rapidly 2 weeks Rx
Significant long-term nonresolution of emboli
causing pulmonary HTN or cardiopulmonary symptoms
uncommon

52
History Size Matters

DVT Risk factors, DVT
Massive
Shock, arrest (Do you have any cousins with
Factor V Leiden?)
Acute pulmonary Infarction
pleuritic CP, SOB, hemoptysis
Acute Emboli
SOB, non-specific CP
Multiple Small Emboli
Progressive SOB, SOBOE, exertional CP, Cor
Pulmonale

53
PIOPED Sx

dyspnea (73)
pleuritic chest pain (66)
cough (37)
hemoptysis (13)

54
Physical Size Matters

Massive pulmonary embolism
Shock , hypotension, poor perfusion, tachycardia,
and tachypnea.
Signs of pulmonary hypertension
palpable impulse over 2nd LICS, loud P2, RV S3
gallop, and a systolic murmur louder on
inspiration at left sternal border (TR)

55
Physical Size Matters

Acute pulmonary infarction
Decreased excursion of involved hemithorax,
palpable or audible pleural friction rub,
localized tenderness
Signs of pleural effusion

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Physical Size Matters

Acute pulmonary Embolus (no infarct)
Non-specific
Tachypnea, tachycardia, pleuritic pain, crackles
and local wheeze _at_ embolus site

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Physical Size Matters

Multiple pulmonary emboli or thrombi
Non-specific
Pulmonary HTN and cor pulmonale
High JVD, RV heave, palpable impulse 2nd LICS, RV
S3 gallop, systolic murmur over the left sternal
border that is louder during inspiration,
hepatomegaly, ascites, dependent pitting edema.

60
Physical PIOPED

Tachypnea (70)
Rales (51)
Tachycardia (30)
Fourth heart sound (24)
Accentuated P2 (23)
Fever lt 39C ( 14) of patients (gt 39.5C not
from PE)
Palpable Chest wall tenderness w/o Hx trauma

61
Diagnostic Imaging for PEPulmonary Angiography

Gold standard (imperfect)
sens 98, spec 95-98
ED physicians reluctant to use
invasive, risks, requires expertise, not readily
available, time consuming,
relative contraindications
indicated if non-invasive tests inconclusive

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Diagnostic Imaging in PEEchocardiography

useful for patients in shock/arrest
r/o DDx tamponade, Ao dissection, AMI
indirect evidence of PE
RV overload, septal shift to L, TR, ? PA
pressure, RV wall motion abn
sens 93, spec 81
sub-massive PE independent predictor of
mortality (?significance)

64
Grifoni et al. Short-Term Clinical Outcome of
Patient With Acute Pulmonary Embolism, Normal
Blood Pressure and Echocardiographic Right
Ventricular Dysfunction. Circulation, 101. 2000,

Prospective clinical outcome study
209 consecutive patients with documented PE
all patients had an TTE within 1 hr of admission
patients stratified into one of four groups
results only for in-hospital period

65
Grifoni et al, Circulation, 2000.

4 groups
Shock (N28,13.4)
SBPlt100 with signs of organ hypoperfusion
Hypotensive without signs of shock (N19, 9.1)
Normotensive with RV strain (N65, 31.1)
Normotensive without RV strain (N97, 46.4)

66
Grifoni et al, Circulation, 2000.

Patients with hypotension/shock (22, N47)
Mortality 19
Normotensive without evidence of RV strain
(46.5, n97)
0 PE-related deaths
Normotensive with RV strain (31.1, N65)
10 (n6) clinically deteriorated due to PE
recurrence
5 (n3) PE-related deaths

67
Grifoni et al, Circulation, 2000.

Positive predictive value of echocardiography was
low
NPV was 100
good tool for screening low risk patients
The detection of RV dysfunction defines a subset
of patients with short-term risk of PE-related
mortality.

68
Ribeiro et al. Echocardiography Doppler in
Pulmonary Embolism Right Ventricular Dysfunction
as a Predictor of Mortality Rate. American Heart
Journal, 134. 1997.

RV dysfunction at diagnosis of PE is a predictor
of mortality
126 consecutive PE patients assessed by TTE on
day of diagnosis
stratified into 2 groups based on severity of RV
systolic dysfunction on TTE
(A) normal to mildly hypokinetic and
(B) moderate to severely hypokinetic
Follow-up TTE within 1 year

69
Ribeiro et al. American Heart Journal, 1997.

56 patients in group A and 70 in group B
baseline characteristics similar (except over
twice as many with symptoms gt14days (sig.),
malignancy and CHF (NS)in B)
In-hospital PE mortality all in group B (n9),
p0.002
1 year overall mortality rate 15.1 (n19)
group A, 7.1 (n4) mortality, all non-PE.
group B, 27.7 (n15) mortality, 9 due to PE
(p0.04)
Group B
RR for in-hospital death 6.0 (95 CI 1.1 to
111.5)
RR for death within 1 year 2.4(95 CI 1.2 to 4.5)
(malignancy RR 3.0).

70
Ribeiro et al. American Heart Journal, 1997.

Subgroup analysis of patients without cancer
(n101)
In-hospital mortality
Group A 0
Group B 7.7 (N4/52)
1 year cumulative mortality
Group A 2, (N1)
Group B 9.8, (N5)

71
Moore, et al. Determination of Left Ventricular
Function by Emergency Physician Echocardiography
of Hypotensive Patients. Academic Emergency
Medicine, vol. 9, no. 3, 2002.

Prospective, observational study, convenience
sample of 51.
EPs with prior US training underwent focused echo
training
inclusion symptomatic hypotension
exclusion trauma, CPR, ECG of AMI
EPs estimation of EF
compared with cardiologist correlation
coefficient of 0.86
between cardiologists 0.84
EP categorization of EF,
agreement 84 (kappa 0.61)

72
Diagnostic Imaging for PEV/Q scan

PIOPED ventilation component adds little info
PISAPED criteria
normal, non-diagnostic, high probability
25, 50, 25 respectively
high prob 85-90 PPV
non-diagnostic 25 PE
interpret in context of PTP

73
Relationship between degree of RV dysfunction and
degree of perfusion scan deficits

Wolfe, 1994. N90
degree of perfusion deficit greater in patients
with RVD (54 vs 30, plt0.001)
all patients with recurrent PE in group with
initial RVD, plt0.01
Ribiero, 1998
correlation between RVD and perfusion scan
deficit but wide CI.
Miller, 1998. N64
failed to demonstrate a correlation between RVD
and perfusion deficit

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Diagnostic Imaging for PESpiral CT

IV contrast, direct visualization
subsegmental PE not well seen
more specific, underlying lung dx
sens depends on CT, experience
wide variation in studies
Rathbun. Ann Intern Med, 2000 (review)
sens 53-100, spec 81-100
poor methodology of studies

78
Spiral CT

Perrier. Ann Intern Med, 2001
sens 70, spec 91 , 4 inconclusive
good interobserver agreement
CT venography
benefit over U/S not determined
role?
no evidence to withhold Rx if CT negative
may replace angiography

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Clive Kearon. Diagnosis of pulmonary embolism.
CMAJ January 21, 2003 168 (2)
83
Non -Invasive Testing

NEED TO Dx PE as HIGH MORTALITY IN THOSE NOT Dx
or MISDIAGNOSED!
Angiography carries risk
Mortality 0.5, invasive, labour intensive
Can make Dx without P. angio

84
Standardized Clinical Assessment

Well Criteria 2 low, 19 intermediate, 50 high
Pisa-PED Sx, ECG, CXR -gt 2, 50, 100
Perrier8 clinical, blood gas or CXR -gt 10, 38,
81

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Clinical Prediction Model for PEWells. Ann Int
Med, 1998
89
Incidence of PE by Clinical Probability
90
Algorithm for suspected PEWells. Ann Int Med,
2001
91
Wells AlgorithmCriticism

Uses SimpliRED assay lower sens.
sCT not included
could replace angiography?
Low prevalence of PE (9)
not validated by other RCTs

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95
Treatment of PECriteria for admission

Hemodynamic instability
O2 requirement
surgery lt 48hr
risk of active bleeding
history of HIT
IV pain control

96
Thrombolytics Heparin

Randomised trials comparing thrombolytics to
heparin
UPET 1970 -- prospective, Randomised.
USET
PIOPED 1990
Levine et al. 1990
PAIMS 2. 1992
Goldhaber et al. 1993
Non-randomized
Dalla-Volta, 1993
Konstantanindes, 1997
Hamel, 2001

97
Thrombolytics

2 week window of opportunity!
effect ? with time
no advantage of t-PA bolus
protocols
t-PA 100mg over 2 hr
UK 4400U/kg over 10min rpt x 12-24hr
SK 250,000U over 30min 100,000 x 24h
arrest t-PA 10mg/kg bolus x 2 q 30 min

98
Treatment of massive PE

judicious fluids (500cc max)
NE, dopamine, dobutamine prn
O2, intubate if shock
positive pressure worsens RV fn
anticoagulation
if no contraindications
UFH if hypotensive
PTT 1.5-2.5 x normal

99
Treatment of massive PEThrombolytics

no evidence of mortality benefit
including in cardiac arrest (case series)
no benefit in hemodynamically stable
improves pul. perfusion (15 vs. 2), RV function
(34 vs.. 17) cf. heparin
t-PA faster hemodynamic effect
IV same as intrapulmonary
5-10 major bleed, 1-2 ICH

100
Treatment of massive PEThrombolytics

Abu-Laban, R et al. Tissue Plasminogen Activator
in Cardiac Arrest With Pulseless Electrical
Activity. NEJM, vol 346, No 20, May 16, 2002.
Reviewed _at_ J-club
N233
No Benefit
Only 1 of 42 autopsied showed PE
Not great PE, Still ????

101
Thrombolytics in Severe Shock or During CPR in
Fulminant Pulmonary Embolism?

Fulminant PE can produce CA in approx. 40 of
cases
Mortality ranges from 65 to 95
Multiple purported mechanisms
RV strain, AMI, arrhythmia.
PEA or asystole

102
Jerjes-Sanchez C. et al. Streptokinase and
Heparin versus Heparin Alone in Massive Pulmonary
Embolism A Randomised Controlled Trial. Journal
of Thrombosis and Thrombolysis. 1995.

Prospective and Randomised trial, N8
all had massive PE and in cardiogenic shock
high prob. V/Q, with abnormal RH echo or
gt9 obstructed segments on V/Q
autopsy in 3
no significant baseline differences between the
two groups, except time elapsed from onset of
symptoms to randomization (2.5 vs 34.75hrs)
100 survival in streptokinase plus heparin group
100 mortality in heparin group
no bleeding complications

103
Thrombolytics in Severe Shock or During CPR in
Fulminant Pulmonary Embolism?

Ruiz Bailen M. et al., Thrombolysis During
Cardiopulmonary Resuscitation in Fulminant
Pulmonary Embolism A Review. Critical Care
Medicine. 2001. Vol 29, No. 11.
single cases and small series demonstrate
promising outcomes when PE suspected clinically.
Kurkciyan et al. 2000
retrospective, N42 (thrombolysis 21, 21 no
treatment)
9.5 survival in thrombolysis vs 4.5 in no
treatment
ROSC in 81 vs 33.3
Survival from 9.5 to 100 (Sienblenlist, 1990
Sigmund, 1991 Hopf, 1991 Bittiger, 1991
Scheeren, 1994)

104
Treatment of Submassive PEThrombolytics

Konstantinides S et al. Heparin Plus Alteplase
Compared with Heparin Alone in Patients with
Submassive Pulmonary Embolism. NEJM, Vol 347, No
15, October 10, 2002.
Reviewed _at_ J-club
N256
10mg bolus -gt90mg over 1hr
Three times less death / Rx escalation in
Alteplase group

105
Goldhaber, S. et al. Alteplase versus Heparin
in Acute Pulmonary Embolism Randomised Trial
Assessing Right-Ventricular Function and
Pulmonary Perfusion. The Lancet. 1993, no 8844.
vol 341.
106
Goldhaber et al. The Lancet. 1993.

Thrombolysis plus heparin is better than heparin
alone in reversing echo evidence of RV
dysfunction
Prospective and randomized, non-consecutive.
99 hemodynamically stable PE patients
PE confirmed by high probability V/Q and/or
pulmonary angiogram
excluded if at high risk of adverse hemorrhage.
all had TTE assessments of right ventricular wall
motion at baseline, then repeated at 3 and 24
hours.
Angiograms were obtained at baseline and at 24h

107
Goldhaber et al. The Lancet. 1993.

46 patients randomized to rt-PA followed by
heparin and 55 to heparin alone
Endpoints mortality, recurrent PE and major
bleeding (72h)
Followed for 14 days for adverse outcomes (PE
recurrence or death), or longer if in hospital.
72 hrs for bleeding.

108
Goldhaber et al. The Lancet. 1993.

Results
follow-up echo (89 patients)
rtPA group vs heparin
3 hrs -- greater improvement in RV wall motion
(p0.01)
24 hrs -- 39 improved, 2 worse vs 17 improved
and 17 worse vs. 17 improvement and 17 worse
in heparin group (p0.005)
follow-up angiogram at 24hrs (95 patients)
rtPA vs heparin -- mean absolute improvement in
pulmonary perfusion of 14.6 vs 1.5 in heparin
(plt0.0001).

109
Goldhaber et al. The Lancet. 1993

Subgroup analysis
patients with right ventricular hypokinesis on
echo (N36)
rtPA -- 89 improvement, 6 worsened
heparin -- 44 improvement, 28 worsened (p0.03)
Deaths
2 in heparin group (1 refractory CA and 1 with CI
to tPA)
Recurrent PEs
rtPA -- none
heparin -- 5 (2 fatal)
Significant hemorrhage
heparin -- 1
rtPA -- 3

110
Goldhaber et al. The Lancet. 1993.

Conclusions
rtPA group
improved right heart function at 24 hours
improvement in pulmonary perfusion
decrease in recurrent PEs
lower rate of death
Strong points
randomization and similarities between groups
echo and angiogram readers blinded to treatment
and timing in relation to therapy
Limitations
non-blinded to clinicians and open-labeled
no long -term morbidity or mortality data

111
Konstantinides, et al. Association Between
Thrombolytic Treatment and the prognosis of
hemodynamically Stable Patients with Major
Pulmonary Embolism Results of a Multicenter
Registry. Circulation, 96. 1997

Early thrombolysis favorably affects in-hospital
clinical outcome.
Multicentred, registry study
719 consecutive patients analyzed 73 PE
confirmed by one or more imaging study
evidence of either increased right ventricular
afterload or pulmonary hypertension based on TTE
or cath.
all patients hemodynamically stable
also included patients who were hypotensive
(SBPlt90) without signs of shock and those on low
dose (lt5mcg/kg/min) dopamine.

112
Konstantinides, et al. Circulation. 1997

primary end-point -- overall 30-day mortality
secondary endpoints -- PE recurrence, major
bleeding

113
Konstantinides, et al. Circulation. 1997

Treatment decisions made at discretion of
physician
23.5 (n169) received thrombolytic therapy
within 24h of diagnosis followed by heparin
remaining patients treated with heparin alone
unless the physician thought that they required
thrombolytics after the first 24h of heparin.

114
Konstantinides, et al. Circulation. 1997

Findings
overall 30d mortality higher in heparin group
11.1 vs 4.7 (p0.016).
thrombolytic treatment was found by multivariate
analysis to be the only independent predictor of
survival (OR 0.46 for in-hospital death)
95 CI 0.21 to 1.00
thrombolytic group
lower rates of recurrent PE (7.7 vs. 18.7,
p0.001)
higher rates of major bleeding events (21.9 vs
7.8, p0.001)
ICH and deaths due to bleeding were the same in
the two groups

115
Konstantinides, et al. Circulation. 1997

Subgroup analysis
patients with a dilated right ventricle on echo
30 day mortality in (N380) 10 compared with
4.1 in those without (p0.018), a 58 reduction
in mortality.
58 reduction in mortality in patients treated
with thrombolytics (4.7 vs 11.1 heparin,
p0.16)

116
Konstantinides, et al. Circulation. 1997

Limitations
study design
non-randomised, heterogeneous thrombolytic
regimens
many patients had clinical signs of disease
severity
more with chronic lung disease in UF heparin
group
choice of treatment was at the discretion of the
physician
selection bias is likely
distribution of many clinical variables were
statistically different between the two groups
(esp. age, pre-existing CHF, higher in heparin)
major end point analyses required multivariate
regression model to account for the unequal
distribution of clinical variables

117
Konstantinides, et al. Circulation. 1997

40 of patients thrombolysed had
contraindications to lytics
25 in the heparin group crossed over and
received thrombolytics. This data was not
reported.

118
Hamel et al. Thrombolysis or Heparin Therapy in
Massive Pulmonary Embolism With Right Ventricular
Dilation. Chest, 2001. Vol. 1201.

There is a benefit to thrombolysis over heparin
in stable PE patients with RVD
Retrospective, cohort study of 153 consecutive
patients
PE confirmed by, V/Q or angiography
RV function evaluated by TT E on admission
64 patients in each treatment group were matched
on the basis of RV/LV diameter ratio
perfusion scans repeated on day 7 to 10 or
earlier if recurrent PE suspected

119
Hamel et al. Chest, 2001.

Inclusion criteria
included PIOPED criteria for high prob. V/Q
Pulmonary vascular obstruction gt40 on V/Q or
Miller index of 20/34
RV to LV ratio of gt0.6 in absence of LV or Mv
disease
Exclusion criteria
SBP lt90
contraindications to thrombolysis
inotropes
syncope prior to presentation

120
Hamel et al. Chest, 2001.

thrombolysis versus heparin
higher mean relative improvement in lung scan at
7-10 days (54 vs 42, p0.01)
gt50 relative improvement in lung scan perfusion
defect seen in 57 (vs 37)
at day 7-10 follow-up scan, average defect equal
between two groups

121
Hamel et al. Chest, 2001.

PE recurrence
rates were the same in both groups, 4.7 (N3).
Mortality
4 (6.3) in thrombolytic and 0 in heparin (NS)
Bleeding events
6 severe, 3 intracranial significantly higher in
thrombolytic group. 4 died as a result. (15.6,
N10 vs 0, p0.001)

122
Hamel et al. Chest, 2001.

Retrospective, case-controlled, consecutive
patients
small numbers
Two groups comparable at baseline for historic
factors, RV dysfunction, LS defect and all free
of signs of PE severity
LS defect, RV/LV ratio and higher PAP higher in
thrombolysis group (not significant)
heterogeneous treatment regimen in thrombolytic
group

123
Levine et al. A Randomised Trial of a Single
Bolus Dosage Regimen of Recombinant Tissue
Plasminogen Activator in Patients with Acute
Pulmonary Embolism. Chest. 1990. 981473.

rt-PA will benefit pulmonary perfusion in
patients with PE and demonstrated perfusion
deficits
Inclusion -- symptomatic patients with either
high probability V/Q or angiographically proven
PE and no contraindications to thrombolytics.
Excluded if hypotensive or hemodynamically
unstable
All patients received heparin bolus. Then
randomized to either rt-PA (0.6mg/kg, given as a
bolus over 2min) or placebo.
10 day study period

124
Levine et al. Chest. 1990

End-points were gt50 improvement in perfusion
defect over baseline and major bleeding events
intracranial, retroperitoneal, requires
transfusion gt2U or fall in Hgb gt20g/L

125
Levine et al. Chest. 1990

58 patients randomized (33 to rt-PA) and groups
were comparable for baseline characteristics.
Comparison lung scans (at 24h and 7days)
available for 57
At 24 hours
rt-PA group -- 34.4 demonstrated a greater than
50 improvement in perfusion scan (12 improved
gt50 in the placebo group (p0.017).
Mean absolute improvement of 9.7 in rt-PA (5.2
in placebo, p0.07)

126
Levine et al. Chest. 1990

At 7 days
no statistically significant difference in lung
scan resolution
No recurrent PEs in either group
No major bleeding episodes

127
Dalla-Volta, S. et al. Alteplase Combined
With Heparin Versus Heparin in the Treatment of
Acute Pulmonary Embolism. Plasminogen Activator
Italian Multicentre Study 2 (PAIMS 2). Journal
of the American College or Cardiology 1992. 20
520.

tPA will result in more rapid improvement in
angiographic and hemodynamic variables.
Open, parallel, multicenter, randomized trial,
N36.
PE confirmed by angiogram with PA pressures
recorded.
all patients hemodynamically stable
excluded if contraindications to thrombolytics
all patients received bolus UF heparin then
Randomised to rt-PA or heparin
follow-up angiogram at end of randomized
treatment (2hrs), subset had lung scans at 7 and
30d.

128
Dalla-Volta, S. et al. JACC. 1993

Interim data analyzed for first 32 patients
randomized
study terminated due to gt3 SD (plt0.01) in the
difference between the angiographic index of the
two groups
patients treated with rt-PA
decrease in Miller Score (mean 28.3 to 24.8) at 2
hours
decrease in mean PA pressure (mean of 30.2mmHg to
21.4mmHg, plt0.01).
CI increased from 2.1 to 2.4 L/min/m2, plt0.01
patients treated with heparin
no change in Miller Score or CI
increase in PA pressure, plt0.001.

129
Dalla-Volta, S. et al. JACC. 1993

Patient Subset with 7 and 30day follow-up
perfusion scans
No difference in Miller Scores (plt0.05)
Bleeding complications
14/20 in tPA had, 3 were severe (Hb decreased by
gt50g/L)
6/16 and 2 severe in heparin group (NS)
Deaths
2 in tPA group (ICH, tamponade).

130
Summary of Studies To-Date

Grifoni -- RVD increased mortality, PE
recurrence.
Ribeiro -- extent of RVD correlates with early
late death
Levine -- early improvement in scan ,no benefit
at 7 days
Goldhaber -- improved short-term hemodynamics
lower rate of short-term rec. PE and death. RCT,
non-blinded.
Konstantinides - lower mortality in submassive
Rx thrombolysis
Konstantinides -- lower rate of mortality in
subgroup of pts with RVD thrombolysis.
Non-randomized, groups sig. different at
baseline.
Dalla-Volta negative for mortality
Hammel no better survival (mortality higher in
thrombolysis group) and higher rate of serious
bleeding.