EMCrit.org

Disorders of Hemostasis

ITP

Autoimmune thrombocytopenia, other cell lines not effected

Seen in kids as a acute, usually post-viral disease.  In adults, chronic form often seen in women.

Mucosal or skin bleeding, ptechiae, purpura

May See spherocytes but no fraged cells

Steroids (Solumedrol 1 gm over 30 minutes), IgG (1 gm/kg over 6 hours), plasmapheresis, splenectomy.  Can administer platelets if bleeding (6 to 8 units Q8 if CNS/GI bleeds), but usually patients can tolerate levels as low as 1000 without needing transfusion

Thrombocytopenia-Associated Multiple Organ Failure (TAMOF)

group of three disorders with low platelets and organ failure

endotheliopathy caused by infection, CP bypass, transplant, radiation, chemotherapy, auto-immune disease, or medications

Review Article (Crit Care 2006;10:235)

Thrombotic Thrombocytopenic Purpura

In differential:  DIC (coag path affected,) SLE, Ehrlichiosis, Hemolytic Uremic Syndrome (HUS)

think TTP whenver there is a combination of renal insufficiency, thrombocytopenia and CNS dysfunction

●Fever, thrombocytopenia, microangiopathic hemolysis (elevated LDH), renal dysfunction

Acute form from antibody against vWF cleaving protein; pts have <10% ADAMTS 13 activity

large vWF multimers can not be cleaved so cause massive amounts of PLT aggregation. SHear stress is greatest in brain and kidney, so largest amounts of thrombi deposition occurs there. 

Thrombotic Microangiopathy

Always associated c hemolysis, Coag path is spared

Fever, signs of hemolysis

PENTAD:  fever, Microangiopathic Hemolytic Anemia (MAHA), Thrombocytopenia,  Renal Dysfunction, Neuro Sx.  (present in less than 50%)

Reticulocytosis, Shistocytes/Helmut Cells

Increased LDH, BUN and Cr, Indirect hyperbillirubinemia,

Treatment

Steroids-b/c vWF problems can be antibody mediated

Emergent Plasmapheresis (FFP 2 units Q6) and continued daily

Vincristine as a last resort medication 

No rapid platelet infusion

Resolution when PLT>150,000

Not in the beginning - only when the process has already triggered a certain degree of fibrinolysis. D-dimers are much higher in DIC than in TTP. FDP too.
Neoplasia more often causes DIC than TTP...I BET her protein C activity is low...these coagulopathies seen in cancer usually respond well to heparin in small and carefully titrated dosage and antithrombin III reposition.
Perhaps some corticosteroids could be a good idea in this case, after you proper address the diagnosis of the lesions...corticosteroids do control some paraneoplastic syndromes and can ameliorate coagulopathies in neoplasic patients for a limited time. If plasma exchange does not improve it, I would try corticosteroids and vincristine...but would try to obtain a biopsy specimen before doing it...


Do you think it can be breast cancer??
Plasmacytoma?? Uterus/ovary??

VERY interesting case.

I have seen a similar one two years ago that was the first manifestation of an uterine carcinoma. The patient had predominantly thrombosis and low platelet numbers with microangiopathy...we started LMWH and antithrombin and it improved...she was discharged from the ICU. The assistant internist started coumadin to the patient, and it precipitated skin necrosis and finger ischemia - for the protein C levels were too low, and he called me. I asked him to stop coumadin immediately and restart LMWH - we don´t have thrombin inhibitors easily available here... The patient had to live on enoxaparin since then. One month later, transvaginal US detected endometrial inspissation, and they diagnosed the carcinoma. She received radiotherapy and the coagulation disturbance greatly improved for some time.
 

Micro-angiopathic Hemolytic Anemia (MAHA) thrombocytopenia and neuro findings are often present
Low grade temp maybe kidney rare
Inhibitor of protease of veg
FFP ok
Plasma exchange is much better
Protease in that is missing is present in FFP
Exchange gets rid of inhibitor and multimers
Cryosupperent FTP???????
Steroids inhibit inhibitor
No evidence ofr IVIG
No platelets
HUS plt fibrin clots
HUS shiga urine test

July 2000

Closure Time Platelet Function Screening

Andrea Cortese Hassett, Ph.D. and
Franklin A. Bontempo, M.D.



BACKGROUND

Platelet dysfunction may be acquired, inherited, or induced by platelet inhibiting agents. It is clinically important to assess platelet function as a potential cause of a bleeding diathesis, especially in critically ill patients who may develop life-threatening hemorrhages. The most common causes of platelet dysfunction are related to uremia, liver disease, von Willebrand’s disease (vWD) and exposure to agents such as acetyl salicylic acid (ASA, aspirin). Current methods to assess platelet function include bleeding time (BT), aggregation studies and whole blood in vitro test systems such as the closure time (CT).


CLOSURE TIME TESTING

Closure times are performed on a PFA-100, an instrument and test cartridge system in which the process of platelet adhesion and aggregation following a vascular injury is simulated in vitro. This system allows for rapid evaluation of platelet function on samples of anticoagulated whole blood. Membranes consisting of Collagen/Epinephrine (CEPI) and Collagen/Adenosine-5’-diphosphate CADP and the high shear rates generated under standardized flow conditions, result in platelet attachment, activation and aggregation, building a stable platelet plug at the aperture. The time required to obtain full occlusion of the aperture is reported as the closure time (CT) in seconds. The test is sensitive to platelet adherence and aggregation abnormalities and allows the discrimination of aspirin-like defects and intrinsic platelet disorder. The CEPI membrane is used to detect platelet dysfunction induced by intrinsic platelet defects (vWD, drug effects etc.). Abnormalities result in prolongations of CT >175 seconds. Follow-up testing using the CADP membrane enables the discrimination of aspirin effects. The following table shows expected patterns observed with CT on normal subjects and subjects with various disorders.




Normal
ASA
vWD
Glanzmann's Thrombasthenia

CEPI
normal
abnormal
abnormal
abnormal

CADP
normal
normal
abnormal
abnormal




CLOSURE TIMES vs. BLEEDING TIMES

While thrombocytopenias are accurately assessed by automated platelet counters, qualitative platelet defects are presently difficult to diagnose. The only global screening test for platelet and vascular functions is the BT. BT is a bedside procedure, is labor intensive, expensive and its accuracy is heavily dependent on operator skills. A critical review of BT concluded that the utility of BT is not enhanced by recent standardization attempts; that in individual patients there is no relationship between BT and platelet counts; that the BT is not a specific indicator of platelet function and that the BT is a poor indicator of surgical bleeding risk. As a consequence many clinicians no longer use BT. The noted deficiencies of BT lead to the development of an in vitro device that globally measures platelet-related primary hemostasis. Closure time is sensitive to platelet adherence and aggregation abnormalities and therefore has increased sensitivity for von Willebrand’s screening when compared to bleeding time. Comparative studies at our facility support these findings: CT was abnormal in 64% of patients diagnosed with vWD as compared to 43% by BT.


INDICATIONS

Closure times are indicated when a disorder of platelet function is suspected by a personal or family history of easy bruising, nose bleeds, menorrhagia, or post-operative bleeding, especially following dental extractions or tonsillectomy. It is not recommended as a screen for potential bleeding risk. Closure times may be prolonged when the platelet count is < 100,000/mm3 even if platelet function is normal. In addition the CT will be prolonged when hematocrit levels are < 35%, due to the contributory effect of red blood cells on platelet behavior. These restrictions should be considered prior to performing a closure time.

Suspected von Willebrand’s disease, inherited platelet disorders and evaluation of acquired disorders of platelet function (hepatic disease, renal disease, drug effects) are appropriate clinical reasons for closure time screening. It may also be useful to monitor the response of therapeutics, such as DDAVP infusions, renal dialysis, platelet and antiplatelet drug therapy. Abnormal closure times, indicating possible defective platelet function, should be further investigated with standard platelet aggregation tests.


SUMMARY

Closure time is a test system to assess platelet-related primary hemostasis with improved accuracy and reliability in comparison to bleeding time. This assay is an important aid in the assessment of platelet dysfunction and bleeding risk caused by uremia, von Willebrand’s disease, congenital platelet disorders and exposure to agents such as aspirin.



REFERENCES

1. Rogers, RPC., Levin J., “A critical reappraisal of the bleeding time.” Semin. Thromb. Hemost. 1990; 16: 1-20.

2. Cattaneo, M., Federici, AB., et. al. “Evaluation of the PFA-100 system in the diagnosis and therapeutic monitoring of patients with von Willebrand’s disease.” Thromb. Hemost. 1999; 82: 35-39.

3. Mammen, EF., Comp, PC., et. al. “PFA-100 System: A new method for assessment of platelet dysfunction. Semin. Thromb. Hemost. 1998; 24: 195-202.

4. Fressinaud, E., Veyradier, A., et. al. “Screening for von Willebrand’s disease with a new analyzer using high shear stress: a study of 60 cases.” Blood 1998; 91: 1325-1331.
 

TTP

Systemic inflammation results in systemic coagulation. Thrombotic thrombocytopenuc purpura (TTP) is a microangiopathy phenotype characterized by ADAMTS 13 deficiency. Left: Platelets attach to ultra large vWF multimers. Because vWF-CP (ADAMTS 13) is inhibited this leads to massive vWF:platelet thrombosis (right). Ab, antibody; CP, cleaving protease; vWF, von Willebrand factor.

TMA

Secondary thrombotic microangiopathy (TMA) has a phenotype characterized by decreased ADAMTS 13, and increased plasminogen activator inhibitor type I (PAI-1) and von Willebrand factor (vWF) levels with normal or high fibrinogen levels. Platelets attach to increased large vWF multimers and form thrombi in the presence of decreased PAI-I activity (left), leading to systemic platelet thrombi with delayed fibrinolysis (right). CP, cleaving protease; TF, tissue factor; TFPI, tissue factor pathway inhibitor; vWF-CP, ADAMTS 13.

DIC

Disseminated intravascular coagulation (DIC) is a microangiopathy phenotype characterized by increased tissue factor (TF) and plasminogen activator inhibitor type I (PAI-1), unopposed by the anticoagulant proteins TFPI, protein C, antithrombin III, and prostacyclin. The severest forms also have an ADAMTS 13 deficiency. Tissue factor activates factor VII (left), leading to massive consumptive fibrin thrombosis (right). VII, factor VII; vWF, von Willebrand factor.

Specific therapies used to reverse or promote thrombosis and promote or stop fibrinolysis. Therapies used to reverse thrombosis include protein C concentrate (prot C), activated protein C (APC), tissue factor pathway inhibitor (TFPI), antithrombin III, heparin, and thrombin inhibitors such as argatroban and hyarudin. Therapies used to promote thrombosis include activated factor VII. Therapies used to promote fibrinolysis include tissue plasminogen activator (TPA), streptokinase, urokinase, and defibrinopeptide. Therapies used to stop fibrinolysis include aminocaproic acid, tranexamine, and aprotinin. PAI, plasminogen activator inhibitor type I.

DIC

thrombocytopenia with decreased fibrinogen and increased d-dimer. Depletion of factors V and X causes increased pt/ptt. Increased intravascular coagulation despite increasing pt/ptt

hits CNS and kidney hardest. 

Dx

1.      Risk assessment:  Does the pt have an underlying disorder known to be associated with DIC?  If yes, proceed

2.     Order global coag tests (CBC, PT, fibrinogen, FDP, D-Dimer)

3.     Score by test results

·        Platelets (>100=0, <100=1, <50=2)

·        Elevated FDP (no icrease=0, mod. Increase=1, strong increase=2)

·        Prolonged PT (<3 sec=0, >3 sec but <6 sec=1, >6 sec=2)

·        Fibrinogen (>1 gram/l=0, <1 gram/l=1)

4.     Greater than or equal to 5 is DIC, <5 may be non-overt DIC or another diagnosis

Validated in Crit Care Med (Volume 32(12) December 2004 pp 2416-2421)

Treatment

Replace plasma until pt/ptt is corrected, but only if infusing heparin as well

In places where ATIII or Protein C concentrate are available, these may be used instead or in combination with plasma

May be a role for xigris at some point

May be a role for infusions of prostacyclin (nitroglycerin or nitroprusside as well) all for microcirculatory flow

Bleeding

give plts

prbcs

ffp

if fibrinogen is <100, give cryoprecipitate

may need low dose heparin to block consumptive coagulopathy

20-30 units/kg then 5-10 units/kg/hour

Fibrin deposition-heparin.  Treat underlying cause.

Rarely will fibrinogen get to cutoff in crit care patients, consider ATIII instead

The activity of plasma antithrombin is reduced in sepsis and DIC, indicating defective anticoagulation [12, 21]. In this study the lowest plasma antithrombin activity distinguished well the patients with overt DIC, as did the lowest platelet count and the highest plasma D-dimer. Antithrombin has been suggested to be included as a part of the score for nonovert DIC [6]. Our results suggest that antithrombin could have a role in the diagnosis of overt DIC as well. Furthermore, in an earlier study on septic patients we found higher levels of plasma antithrombin in survivors than in nonsurvivors, although antithrombin did not independently affect mortality [22]. Availability of the plasma antithrombin test may limit its use, however. (Inten Care Med Intensive Care Medicine 2005;31(9))

Non-Consumptive secondary thrombotic micro-angiopathy (TMA)

secondary TTP or Hemolytic Uremic Syndrome

normal or mildly elevated pt/ptt

only small amounts of hemolysis

increased d-dimer, but increased  fibrinogen

Probably benefit from same plasma-exchange therapies as TTP

Coagulation Pathway Disorders

Bleeding Time

Test of vascular integrity and platelet function; independent of the clotting cascade

Increase is seen in thrombocytopenia, qualitative platelet dysfunction, vWD, Vascular disorders

Ask about ASA and NSAIDs as they cause platelet dysfunction

Platelet Count

Spontaneous hemorrhage when count falls below 10-20,000

Prothrombin Time (PT)

test of the extrinisic pathway (VII) and common pathway (X,V,II, and I)

Normally 10-12 seconds

Deficiencies of Factor VII can be seen with Vit K deficiency, Coumadin, Liver Disease

Partial Thromboplastin Time (PTT)

Test of all factors except VII and XIII, used to evaluate the intrinsic pathway

Normally 25-35 seconds

Increase seen with Factor VIII, IX, or XI and Heparin

Heparin and Coumadin can raise both PT and PTT

Thrombin Time

Tests fibrinogen to fibrin

Increased with Heparin, LMH, DIC, Liver disease

D-Dimer

Increase seen with increased clot burden or consumptive coagulopathy

Hemophilia

Hemophilia A

x linked recessive causing defective VIII:c,

Abnormal ptt. 

Replace c cryoprecipitate of factor VIII 1 unit=100 units VIII

1 cc of FFP=1 unit VIII and less of IX

dDAVP raises factor VIII by causing release from endothelial cells, It has ADH-like effects.  Dose:  0.3 mcg/kg.

Number of units=0.5 x (Desired Factor Level) x (Weight in Kg)      (1/2 life of 12 hours)  (Each unit of factor/kg raises levels by 2%)

Raise to 100% in head injury, mult. Trauma, neck/tongue/throat hematoma, ABD pn/GI bleed, eye trauma.

VIII-plasma or recombinant 

Levels for Hem A/B 

• Joint/Tissue-50% A, 30% B impending joint will present with bubbly feeling, tingling, warmth

• Mouth-correct 50/30%,   Amicor 100 mg/kg (max 24 g/day) Q6 x 1 week

• Epistaxis-local measures the factor 50/30

• Iliopsoas hemorrhage-100/80% then maintain above 40

• Muscle-50/30

• Neck/Retropharyngeal-100/80

• Urinary-vigorous hydration, if still bleeding, replace factor.  Prednisone 2mg/kg divided TID x 2 days

• Suturing-replace factor first

• Trauma-100% replacement

• Fractures-100/80 prior to splinting

• Abd Pain-100/80

10 minute post transfusion, get PTT and factor level

Hemophilia B (Christmas)

Factor IX, replace c factor  

1 x Factor Level x Kg (1/2 life of 24 hours)

(Benefix is only 80% factor IX so multiply by 1.25 instead of 1)

IX-older plasma derived can be thrombogenic, use recombinant

von Willebrand's Disease

Autosomal (usually dominant)

Presents with mucocutaneous  bleeding, commonly epistaxis, gi bleeds, and prolonged menorrhagia.

Patients will have prolonged PTT, increased bleeding time, Normal PT and Platelet count.

1 bag cryo per 10 kg or FFP in emergency

Consider if prolonged vaginal bleeding in menarche or in women in the perimenopausal period.  Estrogen and progesterone raise vWF level.  When Anovulatory cycles are present, may see prolonged bleeding.

Treat with dDAVP, Factor VIII concentrates with high vWF levels (Humate-P or Koate-HS), Cryoprecipitate (10 units/kg), FFP

Purpura Fulminans

DIC in association with symmetric limb ecchymosis and necrosis of the skin

seen after viral syndromes or secondarily from meningococcal infections or most other severe infections.

there may be a role for activated protein c.

Thrombolytics

To reverse, use 6 units FFP and 10 units cryoprecipitate

Obtain CBC, fibrinogen level, thrombin time, PT/APTT, Type and Screen
Most cases need no further care.
Goal FBG is 100 mg/dL.
If life-threatening bleeding, transfuse 10 units of CRYO (FBG source), 2 FFP
(procoagulant source), and PLAT if thrombocytopenic.
Protamine sulfate 1 mg/100 units of heparin may be used if heparin given
within the previous 4 hours.
Anti-fibrinolytic, e.g., EACA can be given if life-threatening bleeding
continues after CRYO/FFP.

Hematologic Emergencies:

Bleeding Diatheses

Mild forms can remain undiagnosed until adulthood

Hemostasis is reliant on three mechanisms:  platelet activation, coagulation activation, and fibrinolysis

The platelets form a plug at the site of a vascular defect which is then stabilized by fibrin, plasmin then breaks down the fibrin.

Defects in plt adhesion cause immediate bleeding of the mucosal surfaces.  Caused by vWF deficiency, NSAIDS, ASA, and Ganzman's thrombasthenia (IIbIIIa deficiency)

Impaired coagulation causes immediate bleeding in the soft tissue and joints.  Caused by VIII, IX deficiency or warfarin/heparin.

Accelerated fibrinolysis causes delayed, mucosal or GU bleeding.  Caused by liver dysfunction, Factor VIII deficiency or thrombolytics.

The intrinsic pathway is so named b/c everything needed for activation is already in the plasma.  The extrinsic needs inflammatory cytokines.  PT=extrinsic, PTT=intrinsic.  If both are altered then consider X, V, Fibrinogen, or Thrombin defects.

Get history of minor/major surgeries, dental work, hepatic, kidney, cancer, drugs

Type of bleeding:  Purpura=decreased platelets, Mucosal or Soft Tissue=Coag, hemarthroses=hemophilia

Labs:  CBC, Coag, DIC Panel (Fibrinogen, FSP/D-Dimer, Thrombin Reptilase)

Rx:

Liver-FFP, if fibrinogen<100 give cryoprecipitate

Uremia-dDAVP .3 mcg/kg IVPB over 15-30 minutes QD, Estrogens 3mg/kg IV, Blood transfusion

PT/PTT may be inaccurate with crits<20 or >50 b/c of imbalance between plasma and sodium citrate.

Severe Thrombocytopenia

If patient is clinically normal, look at smear for platelet clumps and giant platelets

Bleeding secondary to anti-thrombotics

Bleeding and thromboses

Acute Leukemia

Sickle Cell Chest Syndrome

Thromboelastography (TEG)

Br J Anesthaes 1992;69:307

Figure 1. A normal thromboelastograph tracing. R = reaction time (the time from placing the sample in the cuvette until the tracing amplitude reaches 2 mm (normal range = 19–28 mm). R denotes the rate of initial fibrin formation and is functionally related to plasma clotting factors. K = clot formation time (normal range = 8–13 mm). K measured from R to the point where the amplitude of the tracing reaches 20 mm. K represents the time it takes for a fixed degree of viscoelasticity to be achieved by the forming clot. It is effected by the activity of the intrinsic clotting factors, fibrinogen, and platelets. Alpha angle ([alpha]°) (normal range = 29–43°) is the angle formed by the slope of the thromboelastograph tracing from the R to the K value. It denotes the rate at which a clot is formed. Maximum amplitude (MA) (normal range = 48–60 mm) is the greatest amplitude on the thromboelastograph tracing. MA is a reflection of the absolute strength of the fibrin clot and can be altered by both qualitative and quantitative platelet abnormalities (11).

TEG does not monitor platelet adhesion/release in abnormalities such as low dose aspiring use or renal failure

Clotting time (CT) or reaction time( R time)

The time from the start of the curve until it reaches 1 mm wide
This is the time taken to form fibrin. Prolonged with clotting factor deficiencies, anticoagulants and thrombocytopaenia.
 

Clot formation time (CFT) or K time

The time taken for the graph to widen from 1 mm to 20 mm. This is dependent on fibrinogen and platelets.
 

Maximum clot firmness (MCF )or maximum amplitude

This is the width of the curve at the widest point. This is affected by platelet function and number and fibrinogen.
 

Alpha angle

This is the angle measured between the midline of the tracing and a line drawn from the 1 mm point tangential to the curve.

The alpha value and CFT indicate the rate of increase of elastic shear modulus in the sample – i.e. how fast the clot structure is forming.

This is abnormal in the presence of clotting factor deficiencies, platelet dysfunction, thrombocytopenia and hypofibrinogenaemia.

Fibrinolysis

This is measured as a decrease in amplitude from the maximum. If there is a substantial decrease – i.e. more than 15% – then this is an indication of fibrinolysis taking place.

Dr Mattox,


Two hours ago I was called by the hospital´s
transfusional team to discuss an interesting clinical
case.


A 78 yo patient with abdominal sepsis (an infected
gastrostomy) on the vent. Yesterday his platelets,
antithrombin and protein C levels dropped, and
thrombin-antithrombin (TAT) complexes , PF 1+2,
plasminogen activator inhibitor (PAI) raised, with low
fibrinogen and low levels of all coag factors except
VIII (which is an acute phase protein...). Some hours
later he developed a purpuric rash. He was in norepi
and terlipressin, and received antithrombin to
compensate for extremely low ATIII plama levels. ANti
PF 4 test was performed to exclude HIT too, since the
patient has received lots of heparin before.
They performed a ROTEM in him with reagents for the
intrinsic pathway (INTEM), extrinsic pathway tissue
factor- activated (EXTEM), fibrinogen polymerization
&fibrin formation pathway (FIBTEM) and a test with a
fibrinolysis inhibitor (APTEM. EXTEM curve was not
that bad.... INTEM curve had a reduced maximum
amplitude and all the signs of fibrinolysis, and the
same with FIBTEM curve which was flat.HEPTEM
demonstrated there was no reversal of the problem with
heparin neutralization.
Fibrinogen levels were 280, platelets were 20000.
Aprotinin was administrated. Despite improvement of
fibrinolysis in the APTEM (EXTEM with an in-vitro
fibrinolysis inhibitor) the INTEM and FIBTEM worsened.
So we decided to administer platelets, cryo and FFP
together with aprotinin and later perform another
TEG.Why not to use r VIIa? Low coag factor and
fibrinogen levels. Fibrinolysis on course. Bad timing
for VIIa but good timing for factor concentrates...why
we didn´t do it? their protein C content is not enough
to make sure thrombosis won´t happen. This patient had
previously a prothrombotic state in his complex coag
profile.So we decide to treat the guy conventionally,
blocking fibrinolysis and administrating coag factors
and platelets first. Later another ROTEM will be
performed with the same reagents.


Coagulation complex tests interact with ROTEM to
provide a better bedside decision-making tool. There
is already literature on these tests, written mainly
by French authors (DHAINAUT, RUGERI, LEVRAT). I think
ROTEM does not substitute the tests, but rather, they
go together very well.


This is a wonderful way of DIC management, and there
is some literature coming on TRAUMA too.ROTEM cannot
make the specific diagnosis among the several platelet
disorders, acquired or congenital, nor several kinds
of acquired dysfibrinogenemia - like abnormal
fibrinogens, lack of factor XIII, etc.ROTEM is also
not accurate for platelet function. For this purpose,
PFA-100 and Accumetrics are
better. Also, it cannot address prognosis and phase of
endothelitis and microvasculature coagulation status
in sepsis like the complex tests like TAT, PAP, PAI,
PF 1+2, etc.
Common sense and deep knowledge of the pathophysiology
of coagulation derangements are important to address
properly the indicated tests according to the
patient´s moment.


My 2 brazilian cents, since Dr Rubens Costa, once
more, decided to shut up.



claudia


Usefulness of Thromboelastography (ROTEM®) in
Coagulation Management in Trauma Patient


Abstract number: P0696


Rugeri1 L, Levrat2 A, Gros2 A, Floccard2 B, Scherrer1
F, Delecroix1 E, Allaouchiche2 B, Negrier1 C


11Laboratoire Hémostase, Hôpital E. Herriot, Chu-lyon,
France 11Laboratoire Hémostase, Hôpital E. Herriot,
Chu-lyon, France 22Service Réanimation Chirurgicale,
Hôpital E. Herriot, Chu-lyon, France


The purpose of this study was to investigate
thromboelastography in assessment of trauma patient
coagulation. ROTEM® was performed on 268 samples from
71 men and 20 women with a mean of age 34 ± 16 years
(mean ± SD) admitted to our intensive care. Normal
values were established on 42 male and 18 female
controls with a mean age of 39±12 years. The ROTEM®
parameters were performed for EXTEM (tissue factor
activated test), FIBTEM (assessment of fibrinogen
status) and APTEM (in-vitro fibrinolysis inhibition)
at H0, 6, 12 and H24 comparatively to standard assays.
Results:
EXTEM parameters FIBTEM N PT Fibrinogen Platelets
CT normal (56 ± 7) A15 normal (55 ± 5) A10 normal (12
± 4) 181 72 ± 12 2.8 ± 0.9 197 ± 61
CT increased (85 ± 18) A15 normal (55 ± 5) A10 normal
(11 ± 4) 27 71 ± 11 2.4 ± 0.9 196 ± 69
CT normal (56 ± 7) A15 decreased (39 ± 5) A10
decreased (7 ± 2) 28 55 ± 13 1.7 ± 0.6 110 ± 65
CT increased (120 ± 69) A15 decreased (33 ± 13) A10
decreased (4 ± 3) 32 46 ± 22 1 ± 0.6 123 ± 53
Subgroup (219 ± 91) (15 ± 12) (0 ± 0) 8 18 ± 12 0.2 ±
0.2 112 ± 62


Mean ± SD, CT = Clotting Time (sec), A15 or A10 = Clot
firmness in mm at 10 or 15 min. In 1 case, we observed
a correction of APTEM parameters evocating a
hyperfibrinolysis. These results showed that a normal
A15 of EXTEM was always associated with normal A10 of
FIBTEM and coagulation parameters over transfusional
threshold. When abnormal A15 of EXTEM was found, A10
of FIBTEM would be studied to be helpful for
monitoring of hemostatic therapy. In the last 8
samples, the results indicated a very severe
hypocoagulability requiring rapid therapy management.
In conclusion, ROTEM® is a rapid test that could be
helpful in coagulation monitoring in trauma patients.


To cite this abstract use the following format:


Journal of Thrombosis and Haemostasis 2005; Volume 3,
Supplement 1: abstract number


Session Details

ROTEG is involved in some transfusion algorhythms and it´s supposed
to reduce excessive blood transfusions. Dr Plinio Gomes, Dr João Luiz,
Dr Rubens Costa, Dr Edimilson Silva and Dr Erica Tavora are starting
to validate this method in Procardiaco Hospital ICU, Rio de Janeiro.
There are several algorhythms involving TEG-guided blood transfusions
published, and it seems a very good application of the method.
Hyperfibrinolysis is much more common in general ICU than one might
suppose.


Despite many papers advocating it, and one DBMC showing benefit in
blunt trauma, I seriously fear administering rVIIa in trauma without
the help of a TEG or a fast TEG or a ROTEM at bedside. Many of these
patients are hypercoagulable and a disaster might happen. In others
hyperfibrinolysis will just "eat" r VII a, unless you administer some
antifibrinolytic that helps to stop the fibrin degradation. while you
start factor reposition with factor concentrates and rVII a.


My 2 cents.
 

An increased CFT or MA in thromboelastography, is by no means a rare
finding - those who are used to this method can endorse my words. And
many patients who are supposed to have bleeding tendencies because of
aspirin use before CABG procedures are actually HYPERCOAGULABLE when
you check their MA in TEG and test their coagulation profile. I BET
that if you administer aprotinin to this kind of patient the drug
will probably be detrimental to the microvascular coagulation status.
Only for curiosity, aprotinin use during CABG causes PAI-1 to increase
in plasma and there was a trend to a greater incidence of Non-Q wave
myocardial infarction in the people who received this drug, as shown
by an RCT done with 54 patients.PAI-1 is a predictor of bad prognosis
in septic patients with acute renal failure. Take a good look in the
two papers which abstracts I send below, and take your own
conclusions.


That means that WE ARE YET to discover who will benefit from these
drugs, and the way to discover it is through complex coagulation
monitoring.



All of this said, and apologizing for the BIG post, I leave the
scenario wondering what the OTHER coagulation buffs in the list are
thinking about all that.

claudia

Clotting and Bleeding: Ouchie, Mommy!

We know that when Johnnie or Susie cut their finger on the playground, that they bleed, get a bandage, and then clot. But why, when a child is in the ICU, does he or she clot and then bleed. The secrets of the paradox have now been revealed. When vasculature is focally injured by a laceration on the playground, the focal endothelium at the point of injury, normally antithrombotic and profibrinolytic, becomes prothrombotic and antifibrinolytic, allowing the bandage to get all the credit. In critical illness, systemic inflammation–induced endotheliopathy causes all the endothelium to become prothrombotic and antifibrinolytic. Systemic antithrombotic factors (protein C and antithrombin III) are consumed until they become low enough that prothrombotic factors take over and are systemically consumed in clots. When enough prothrombotic factors are consumed in this manner, then spontaneous hemorrhage occurs. An armamentarium of anticoagulants (e.g., heparin, antithrombin III, protein C, argatroban), procoagulants (e.g., activated factor VII), fibrinolytics (e.g., tissue plasminogen activator, activated protein C), and antifibrinolytics (e.g., Amicar, tranexamic acid) are now available to the physician. Unfortunately, clinical tests that might guide the clinician as to which specific therapy to use are not readily available in most clinical laboratories. One can sometimes see bleeding, but how does one know if the patient may have systemic thrombosis precedent to bleeding? You should think about it in any patient who develops new-onset thrombocytopenia and multiple organ failure. These patients are likely to be consuming platelets in microvascular fibrin or platelet clots. If the child has a prolonged prothrombin time/partial thromboplastin time and low fibrinogen, then it is likely to be disseminated intravascular coagulation pathophysiology, and if the child has a normal or high fibrinogen, then it is likely to be thrombotic thrombocytopenic purpura pathophysiology. Plasma exchange is an effective therapy for reversal of coagulopathy from either condition because it corrects any and all abnormalities (21).

Coag Abnormalities in the Crit Ill (Crit Care 2006;10:222)