1. Heparin Induced�Thrombocytopenia David Miller, MD
Mecklenburg Medical Group
January 20, 2005
2. Objectives Define and discuss the mechanism of HIT
Review associated risks
Describe the clinical features of HIT
Present diagnostic criteria
Discuss treatment options
3. Heparin Induced Thrombocytopenia (HIT) Clinicopathologic syndrome characterized by
the formation of IgG antibodies against a Heparin/PF4 complex.
a sudden unexpected decline in platelet count 4 – 14 days after first exposure to Heparin and
a high risk for venous and arterial thrombosis
4. Pathophysiology
5. Thrombin Generation in HIT Fc mediated platelet activation
Ab/PF4/GAG complex activates endothelium cells which release Tissue Factor (TF)
PF4 released from activated platelets inactivates the antithrombotic effect of Heparin
6. Risk for Developing HIT Risk increases with
Dose of heparin (high > low)
Type of heparin (bovine > porcine)
Preparation of heparin (UFH > LMWH)
Clinical situation (surgical > medical)
Average risk is 1-3%
7. Clinical Features of HIT Modest drop in platelet count during heparin treatment
Typical timing of the drop in platelet count after first exposure
High risk for thrombosis
Confirmatory laboratory testing
8. Platelet Counts in HIT
9. Temporal Aspect of Thrombocytopenia in HIT Typical (70%):
Rapid Onset (30%): drop in platelet count within minutes to hours after re-exposure to heparin (within 100 days of exposure)
Delayed onset (Rare): Delayed thrombocytopenia days after heparin has been discontinued
10. Temporal Aspect of Thrombocytopenia in HIT Typical Onset (70%)
5 – 10 days after starting heparin
HIT-IgG usually not detectable until day 5
Risk of HIT diminishes after day 5 – 10 “window” passes
(Sometimes the clock can be “reset” with an intravascular procedure or surgical procedure)
11. Temporal Aspect of Thrombocytopenia in HIT Rapid Onset HIT
Unexpected fall in the platelet count that begins shortly after heparin is started
Invariably have had heparin exposure in the past (last 100 days)
Caused by residual circulating HIT Abs
Pts with typical HIT had no difference in median day of onset even if previously exposed to heparin.
Pts do not develop HIT on days 2-4
Pts reexposed to Heparin following disappearance of the HIT Abs do not necessarily develop HIT Abs againPts with typical HIT had no difference in median day of onset even if previously exposed to heparin.
Pts do not develop HIT on days 2-4
Pts reexposed to Heparin following disappearance of the HIT Abs do not necessarily develop HIT Abs again
12. Temporal Aspect of Thrombocytopenia in HIT Delayed Onset HIT
Previous heparin exposure was uncomplicated
Patient often discharged home, off heparin
Patient readmitted to hospital
New thrombosis (usual)
Unexpected thrombocytopenia (uncommon) Delayed-onset HIT is characterized by the following:
Previous heparin exposure that was uncomplicated
Patient often discharged, off heparin
Patient readmitted to hospital
New thrombosis (usual)
Unexpected thrombocytopenia (uncommon)
Delayed-onset HIT is characterized by the following:
Previous heparin exposure that was uncomplicated
Patient often discharged, off heparin
Patient readmitted to hospital
New thrombosis (usual)
Unexpected thrombocytopenia (uncommon)
13. Clinical Features of HIT: Temporal Aspect of Thrombocytopenia
14. Thrombotic Complications of HIT Venous
Deep vein thrombosis
Upper limb
Lower limb
Pulmonary embolism
Cerebral dural sinus thrombosis
Adrenal hemorrhagic infarction
Disseminated intravascular coagulation (DIC) Arterial
Acute limb ischemia
Acute thrombotic stroke
Myocardial infarction
Mesenteric, renal, spinal artery thrombosis
15. Clinical Features of HIT:�Thrombosis Venous thrombosis
50% develop DVT, half of whom will have a PE
Severe limb ischemia
Phlegmasia cerulea dolens
Venous limb gangrene
Adrenal thrombosis (3 – 5%)
Cerebral sinus thrombosis
16. Characteristics of Warfarin-Induced Venous Limb Gangrene Acral necrosis complicating a DVT
Palpable or Doppler-identifiable pulses
Thrombosis of large and small veins
No large artery occlusion
Supratherapeutic INR
17. Clinical Features of HIT:�Warfarin-induced Skin Necrosis May involve central tissues (breast, abdomen, thigh, flank, leg)
HIT? Thrombin
Warfarin? Low protein C
18. Heparin-induced Skin Necrosis Inflammatory, plaque-like or necrotic lesions
Begin 6 or more days after starting SQ UFH or LMWH
Most pts. do not have low platelets
Considered a marker for HIT syndrome
Thrombocytopenia and thrombosis can occur after heparin is discontinued
19. Heparin-induced Skin Necrosis Warkentin TE. Br J Haematol. 1996;92:494-497.
20. Adrenal Hemorrhagic Infarction Thrombosis of the adrenal veins leading to hemorrhagic necrosis of the glands
Abdominal pain
Hypotension
Fever
Hyponatremia
Requires corticosteroid replacement
21. Neurologic Consequences of HIT Stroke due to venous or arterial thrombosis
Cerebral Sinus Thrombosis
Headache, decreased LOC, focal neurologic defects
Lower limb paralysis due to spinal cord or lumbosacral plexus infarction
22. Cardiac Syndromes of HIT Myocardial Infarction
Intra-ventricular or intra-atrial thrombus formation
Cardiopulmonary arrest shortly after heparin bolus
23. Acute Systemic Reaction �to IV Bolus Heparin Onset within 5-30 min.
Chills, rigors, fever
Tachycardia, hypertension
Tachypnea, dyspnea
Chest pain or tightness
Diaphoresis or flushing
Nausea, vomiting, diarrhea
Sudden death
Transient global amnesia
24. Diagnosis of HIT HIT is a clinical diagnosis
Confirmed with Laboratory Testing
25. Estimating the Pre-test Probability of HIT (The 4 T’s) Thrombocytopenia
Timing of Thrombocytopenia
Thrombosis (or other sequelae of HIT)
OTher causes for platelet fall unlikely
26. Estimating the Pre-test Probability of HIT (The 4 T’s)
27. Estimating the Pre-test Probability of HIT (The 4 T’s) High probability 6-8 points
Moderate probability 4-5 points
Low probability 0-3 points
28. Laboratory Tests for HIT There are two types of laboratory tests available to confirm a diagnosis of HIT: a functional assay and an antigen assay.
Functional assays detect HIT-IgG on the basis of their ability to activate platelets. Activation can be measured in a number of different ways, including SRA, platelet aggregation, ATP release, and flow cytometry. A washed platelet system is recommended. Of the available assays, the serotonin release assay has the most advantages.
The citrated plasma assay is widely used, specifically, the platelet aggregation. This assay measures the aggregation of normal donor platelets by patient serum or plasma in the presence of heparin. However, it is not recommended because of its low sensitivity and low specificity.
Antigen assays detect the binding of antibodies to immobilized PF4-heparin complexes. The most typical of the direct antigen assay performed on serum or plasma is the heparin-PF4 ELISA.There are two types of laboratory tests available to confirm a diagnosis of HIT: a functional assay and an antigen assay.
Functional assays detect HIT-IgG on the basis of their ability to activate platelets. Activation can be measured in a number of different ways, including SRA, platelet aggregation, ATP release, and flow cytometry. A washed platelet system is recommended. Of the available assays, the serotonin release assay has the most advantages.
The citrated plasma assay is widely used, specifically, the platelet aggregation. This assay measures the aggregation of normal donor platelets by patient serum or plasma in the presence of heparin. However, it is not recommended because of its low sensitivity and low specificity.
Antigen assays detect the binding of antibodies to immobilized PF4-heparin complexes. The most typical of the direct antigen assay performed on serum or plasma is the heparin-PF4 ELISA.
29. Heparin-induced Thrombocytopenia (HIT): Consequences Heparin-Induced Thrombocytopenia (HIT): Consequences Pyramid
Key Point: Although only a subset of HIT antibody-positive patients will develop thrombosis, it is not possible to predict which ones will develop thrombosis.
This model reflects that only a portion (up to 10%) of all patients exposed to heparin develop antibodies, although antibodies may occur in approximately 50% of cardiopulmonary bypass surgery patients.1 A number of factors contribute to this, including the type of heparin used, the mode of administration and the dose, and patient-specific factors such as the clinical setting.1
As illustrated, only a portion of the patients who develop HIT antibodies will develop thrombocytopenia. Only a subset of those patients who develop thrombocytopenia will progress to thrombosis.1
Thrombotic events are more likely to develop in patients with thrombocytopenia who develop HIT antibodies as opposed to patients without thrombocytopenia.1
HIT can occur in the absence of thrombocytopenia.
1. Warkentin TE. Heparin-induced thrombocytopenia: pathogenesis, frequency, avoidance and management.
Drug Saf. 1997;17(5):325-341. 2. Francis JL, Drexler A, Moroose R, et al. Comparative effects of bovine and
porcine heparin on heparin antibody formation following cardiovascular surgery [abstract]. Blood. 2001;98(11):
60b. Abstract 3854.Heparin-Induced Thrombocytopenia (HIT): Consequences Pyramid
Key Point: Although only a subset of HIT antibody-positive patients will develop thrombosis, it is not possible to predict which ones will develop thrombosis.
This model reflects that only a portion (up to 10%) of all patients exposed to heparin develop antibodies, although antibodies may occur in approximately 50% of cardiopulmonary bypass surgery patients.1 A number of factors contribute to this, including the type of heparin used, the mode of administration and the dose, and patient-specific factors such as the clinical setting.1
As illustrated, only a portion of the patients who develop HIT antibodies will develop thrombocytopenia. Only a subset of those patients who develop thrombocytopenia will progress to thrombosis.1
Thrombotic events are more likely to develop in patients with thrombocytopenia who develop HIT antibodies as opposed to patients without thrombocytopenia.1
HIT can occur in the absence of thrombocytopenia.
1. Warkentin TE. Heparin-induced thrombocytopenia: pathogenesis, frequency, avoidance and management.
Drug Saf. 1997;17(5):325-341. 2. Francis JL, Drexler A, Moroose R, et al. Comparative effects of bovine and
porcine heparin on heparin antibody formation following cardiovascular surgery [abstract]. Blood. 2001;98(11):
60b. Abstract 3854.
31. Laboratory Tests for HIT
32. Laboratory Testing for HIT at CMC Antigen assay
Labcorp performs the ELISA test daily Monday-Friday
Esoterix performs it daily but must go through Labcorp per the hospital’s contract
Functional Assay
Serotonin Release assay is performed at Esoterix Tuesdays and Fridays
33. Differential Diagnosis: Pseudo-HIT Adenocarcinoma with DIC or Venous Limb Gangrene
Pulmonary Embolism
Diabetic Ketoacidosis
Antiphospholipid Syndrome
Thrombolytic Therapy
Septicemia-Associated Purpura Fulminans
Infective Endocarditis
Paroxysmal Nocturnal Hemoglobinuria
Posttransfusion Purpura
34. Differential Diagnosis: Other Causes of Thrombocytopenia Hemodilution after cardiac surgery
Pseudothrombocytopenia
Autoimmune Thrombocytopenia (ITP)
Drug Induced Immune Thrombocytopenia
DIC (due to sepsis or malignancy)
TTP/HUS
35. Treatment of HIT FIRST - Remove all heparin, every little bit!
Swan
Arterial lines
Indwelling catheters
And keep it away!
Cath lab
Operating room
Dialysis
36. Cumulative Frequency of Thrombosis After Heparin Discontinuation
37. Treatment of HIT Begin therapy with an alternative antithrombotic agent immediately.
Never start warfarin therapy without another form of anticoagulation.
Start warfarin therapy after platelet count has returned to normal.
38. Why Treat HIT with Thrombin Inhibitors? Thrombosis begets thrombosis!
HIT is a thrombotic storm!
39. Direct Thrombin Inhibitors Advantages
Lack of interaction with HIT antibodies
Predictable dose-response curve
Relatively short half-life
Rapid therapeutic effect
Easily monitored (?)
Inhibits clot-bound thrombin
40. Direct Thrombin Inhibitors Problems
No reversal agent
Does not affect thrombin generation
Possible hypercoagulable state after discontinuation
Use during cardiopulmonary bypass not well established
41. Direct Thrombin Inhibitors in HIT
42. Conversion of Direct Thrombin Inhibitors to Warfarin
43. Routine Order Set for HIT
44. Guidelines for Oral Anticoagulants in HIT Do not use oral anticoagulants alone
Wait for the platelet count to increase to near normal while HIT is “cooled” (100-150/µL)
Initiate modest doses, avoid overshooting the INR
Overlap minimum of 4-5 days
Be sure INR is >2.0 for 2 consecutive days
Ensure adequate levels of alternative anticoagulant during transition
45. Final Pearl The HIT Antibody is transient.
Heparin Abs fall to undetectable levels a median of 50 to 85 days after cessation of heparin depending on the assay performed.
Heparin-dependent Abs do not invariably appear with subsequent heparin use.
46. Heparin-dependent Antibodies over Time
47. Summary HIT is a clinical diagnosis.
A positive antibody test is not diagnostic.
Thrombotic complications of HIT can be devastating and have unusual presentations.
Therapy involves stopping all heparin exposure and starting a direct thrombin inhibitor.
Do not use Warfarin alone in a patient with HIT.
Conversion from a Thrombin Inhibitor to Warfarin can be tricky.
The HIT Ab is transient.
