Thrombin Generation Assays - PowerPoint PPT Presentation

1 / 55
About This Presentation
Title:

Thrombin Generation Assays

Description:

Describes the concentration of thrombin in clotting plasma ... Relative risk of recurrent VTE correlates with peak thrombin concentration ... – PowerPoint PPT presentation

Number of Views:3440
Avg rating:3.0/5.0
Slides: 56
Provided by: jkibl
Category:

less

Transcript and Presenter's Notes

Title: Thrombin Generation Assays


1
Thrombin Generation Assays
  • Technothrombin TGA Kit
  • By Jennifer J. Kiblinger
  • Technical Regulatory Affairs Manager
  • DiaPharma Group, Inc.

2
Technothrombin TGA Kit Thrombin Generation
AssayIntroduction
  • DiaPharma introduces the Technothrombin TGA kit,
    a global research test for investigation of
    bleeding and thrombotic tendency. This thrombin
    generation assay from Technoclone is based on
    monitoring the formation of thrombin with a
    fluorogenic substrate upon activation of the
    coagulation cascade by tissue factor (TF).
  • By providing varying amounts of TF and
    phospholipid, the Technothrombin TGA is a
    universal tool with multiple applications
  • Hemophilia during inhibitor by-passing therapy
  • Pro-coagulant microparticles
  • Anticoagulant drugs
  • Thrombophilia
  • Features of the assay
  • Reagent-complete kit includes thrombin calibrator
    and controls
  • Easy to perform User-friendly software and
    instructions are provided
  • Calibration required only once per lot number
  • Step-by-step applications available for the
    Bio-TEK FLx800 TBI, as well as many other
    fluorometers
  • Can be performed with plasma or whole blood, and
    in platelet rich plasma or platelet poor plasma

3
Thrombin Generation AssaysOutline
  • Measurement Principle / Methodology
  • Applications (General)
  • Introduction to Technoclone
  • Technothrombin TGA
  • Cevron Coagulation Analyzer
  • Publications References

4
Why Thrombin Generation Assays?
  • TGA is to clotting assay as ECG is to pulse
  • TGAs provide more info
  • The amount of thrombin that generates, as well as
    the length of time that it is active, both count
  • With routine clotting tests, only the initial
    phase of thrombin generation is measured

5
Why Thrombin Generation Assays?
  • More to come
  • Clotting times only represent lag phase before
    thrombin generation ignores amount of thrombin
    that forms and time it remains active
  • After clot formation, much of the thrombin action
    is still to come

6
Why Thrombin Generation Assays?
  • Describes the concentration of thrombin in
    clotting plasma
  • Good physiological function test of thrombotic
    hemostatic system
  • Measures thrombotic and bleeding tendency

7
History of the Thrombin Generation Assay
  • Choice of substrate
  • Chromogenic vs. Fluorogenic
  • Traditionally TG was measured with chromogenic
    substrate
  • Substrate converted slowly, did not bind too
    tightly to thrombin Clotting mechanism not
    disturbed, velocity of substrate conversion is
    proportional to concentration of thrombin during
    course of thrombin generation

8
History of the Thrombin Generation Assay
  • BUTChromogenic thrombin substrates are also
    converted by the thrombin-a2-Macroglobulin
    complex
  • Physiologically inactive must correct for this
    in order to calculate the actual free thrombin
  • Fibrinogen must be removed (defibrinated)

9
History of the Thrombin Generation Assay
  • Fluorogenic substrate fluorescence not heavily
    influenced by turbidity appearance of a clot
    will not impair signal fibrinogen does not need
    to be removed
  • Presence of platelets does not disturb
    measurement
  • Can study role of platelets in coagulation in
    large series of samples

10
History of the Thrombin Generation Assay
  • Fluorogenic assays Tappenden et al. found that
    of the substrates tested, Z-Gly-Gly-Arg-AMC,
    appears the most appropriate fluorogenic
    substrate for monitoring thrombin generation.
  • Ref Tappenden KA et al. Evaluation of
    Fluorogenic Substrates for the Monitoring of
    Thrombin Generation. ISTH Sydney 2005, P1897.

11
History of the Thrombin Generation Assay
  • Thrombin Calibrator allows calculation of molar
    concentration of thrombin

12
Measurement Principle
  • Remember coagulation starts when a vessel is
    wounded
  • A vessel is wrapped in a layer that is full of
    cells containing TF
  • After injury, this TF is exposed to blood, binds
    with FVIIa to form TFFVIIa complex (extrinsic
    pathway)
  • Activates FX to FXa, which activates prothrombin
    to thrombin

13
Measurement Principle
  • Universal tool for analysis and monitoring of
    hemostatic system on an individual basis
    (universal monitor of clotting function)

14
MEASUREMENT PRINCIPLE
The coagulation cascade is activated upon
addition of different concentrations of - tissue
factor - phospholipids TECHNOTHROMBIN TGA
is based on monitoring the fluorescence generated
by the cleavage of a fluorogenic substrate by
thrombin over time
ZGGR-AMC
AMC
15
Measurement Principle
  • Thrombin Generation Parameters
  • Lag phase ( clotting time)
  • From addition of reagents until first burst of
    thrombin
  • Slope steepest rate of thrombin formation per
    min.
  • Velocity Index (nM/s)
  • peak thrombin
  • Peak time lag time
  • Peak Max FIIa formed
  • Time to Peak
  • AUC (area under curve) ETP (Endogenous thrombin
    potential) amount of work that can potentially
    be done by thrombin how much, and how long is it
    active?
  • Inactivation Phase

16
Measurement Principle
  • General assay procedure
  • Add reagents consisting of coagulation trigger
    (PL, TF) and plasma
  • PPP need PL PRP dont necessarily need PL
  • Add mixture of fluorogenic substrate and Ca2 to
    begin coagulation
  • Instrument takes absorbance readings
  • Software program calculates all parameters (Peak
    height/Max FIIa, lag time, etc.) expresses
    results in nM Thrombin

17
Potential Advantages
  • Taken together with routine clotting parameters,
    allows analysis of clotting defects
    thrombophilia in more detail
  • Technically simple
  • Few reagents required
  • Adaptable to semi-automated instrumentation or to
    manual technology
  • Step-by-step instructions provided
  • Flexible
  • Can be adapted for different purposes assay can
    be tweaked to suit many needs
  • Applicable for both hemophilia A B
  • Sensitive

18
Potential Disadvantages
  • Time-consuming
  • 60 90 minutes per assay, unlike typical
    chromogenic clotting assays
  • Full clinical utility still being investigated
  • Does not necessarily replace specific tests for
    i.e. thrombophilia, etc.

19
Applications
  • Identify clotting defects / thrombophilic
    patients in more detail
  • Obtain full picture of thrombotic tendency of
    patients at risk for thrombosis or bleeding
  • Measure acquired thrombotic disorders like with
    use of oral contraceptives
  • Monitor anticoagulant therapies
  • i.e. warfarin, heparins, anti-platelet drugs
  • Development of anti-thrombotic drugs
  • Hemophilia A B
  • Monitoring treatment such as with FVIII, FVIIa,
    FEIBA
  • Microparticles

20
Applications - Thrombophilia
  • Thrombophilia
  • Determine states of thrombophilia
  • Clotting assays dont indicate thrombotic
    tendency of unknown origin
  • Measurement of overall thrombin generation
    enables the assessment of simultaneous effects of
    numerous small changes in the hemostatic system
  • May either reinforce or compensate each other

21
Applications - Thrombophilia
  • In some forms of thrombophilia, such as AT,
    Protein C, and Protein S deficiencies,
    TF-triggered clotting produces larger amount of
    thrombin compared to normal plasma
  • Assaying thrombin generation in PPP can detect
    such deficiencies

22
Applications - Thrombophilia
  • Measurement of overall thrombin generation
    enables the assessment of simultaneous effects of
    numerous small changes, which may either
    reinforce each other or compensate each other
  • Hemker HC et al. Calibrated Automated Thrombin
    Generation Measurement in Clotting Plasma.
    Pathophysiol Haemost Thromb 2003 334-15

23
Applications - Thrombophilia
  • Risk of recurrent thrombosis (DVT or PE)
  • Relative risk of recurrent VTE correlates with
    peak thrombin concentration
  • (Hron et al. Identification of patients with low
    risk of recurrent venous thromboembolism by
    measuring thrombin generation. www.technoclone.com
    )
  • Patients can be grouped according to risk of
    recurrence using the TGA

24
Applications - Thrombophilia
  • Risk of recurrence 60 lower when peak thrombin
    is less than 400 nM

25
Applications Anticoagulation Therapy Monitoring
  • No single clotting test that reacts similarly to
    different types of anticoagulants
  • Clotting tests measure length of initial stage of
    thrombin formation
  • Clotting occurs at end of initiation pahse and is
    complete when gt95 of all thrombin is still to
    appear
  • Length of initiation phase doesnt usually
    indicate the amount of thrombin activity still to
    come

26
Applications Anticoagulation Therapy Monitoring
  • Antithrombotic drugs diminish amount of thrombin
    that appears in clotting plasma, but not
    necessarily the lag time (i.e. clotting time)
  • Lag time (clotting time) could be normal, but
    with less thrombin formed TGA will reflect this

27
Applications Anticoagulation Therapy Monitoring
  • Anticoagulation Monitoring
  • Calculate INR values for patients
  • Significant correlation between INR values
    determined with Technothrombin TGA and PTs
  • Sensitive to presence of anti-platelet
    anti-thrombotic agents

28
Applications Anticoagulation Therapy Monitoring
  • Lag time, velocity of propagation phase relevant
    when indirect FXa inhibitor or rFVIIa are present
    in therapeutic concentrations
  • Method can be useful for study of different
    anti-thrombotic agents
  • Regardless of mechanism of action (LMWHs, direct
    indirect FXa inhibitors, direct FIIa inhibitors)

29
Applications Anticoagulation Therapy Monitoring
  • Using a calibration set (AK-Calibrant
    anti-vitamin K), Technothrombin TGA can be used
    for direct INR determination

30
Applications Hemophilia A B
  • Determine states of bleeding disorders
  • Hemophilia A B
  • Monitor therapy in hemophilia patients
  • Monitor during Factor VIII inhibitor by-passing
    therapy (FVIIa, FEIBA)
  • Post-infusion studies/characterization of
    hemostasis
  • Monitoring gene therapy

31
Applications Hemophilia FVIII Bypassing Therapy
  • Hemophilia A patients with inhibitors generally
    treated with preparations containing activated
    coagulation factors to achieve hemostasis by
    bypassing FVIII

32
Applications Hemophilia FVIII Bypassing Therapy
  • TGA no thrombin generation observed in FVIII
    inhibitor plasma
  • When spiked with FEIBA or rFVIIa (NovoSeven),
    rate and peak of thrombin generation increases
    dose-dependently
  • Changes in TG properties coincide with
    administration of FEIBA
  • FEIBA less sensitive to TF levels than rFVIIa

33
Applications Hemophilia FVIII Bypassing
Therapy
  • TGA enables monitoring of pharmacodynamic
    pharmacokinetic properties of by-passing
    therapies
  • Can help optimize FEIBA or rFVIIa treatment
  • TGA is suitable to assess hemostatic effects of
    both product in vitro in vivo

34
Applications Microparticles
  • Microparticles
  • Circulating microparticles contribute to thrombus
    formation possible major risk factor for
    thrombosis in atherosclerotic patients
  • Level of circulating microparticles currently
    determined by ELISA or FACS, based on
    flip-flopping of phosphatidylserine to surface
    of microparticles and membrane protein markers
    (using Annexin V as marker)

35
Applications Microparticles
  • Microparticles
  • Determination of clotting activity of
    microparticles would allow to directly relate
    their circulating levels to the
    microparticle-induced thrombotic tendency.

36
Applications Microparticles
  • Microparticles generated during endotoxinemia are
    thrombogenic and can be measured by the TGA.

37
Applications Microparticles
  • Determine thrombogenic activity of apoptotic MPs
    using TGA
  • Can see difference in activity of apoptotic MPs
    derived from ECs, SMCs, and U937Cs
  • Analyze mechanisms leading to thrombin generation
    induced by these apoptotic MP
  • May be difference in mechanisms leading to
    thrombin generation among apoptotic MPs

38
Technothrombin TGA
  • Rapid reliable measurement of coagulation
    parameters in patients undergoing anticoagulation
    therapy, in patients with hemophilic or
    thrombophilic disorders, and for the measurement
    of circulating microparticles.

39
TECHNOTHROMBIN TGA
FOR RESEARCH USE ONLY
Kit components
In addition, TGA Reagent A (RA) without Tissue
Factor and a microparticle free control (MFC) are
available. Kit for whole blood samples also
available.
? All reagents are available on a modular basis.
40
Technothrombin TGAReaders Software
  • Readers with software available from Technoclone
  • Bio-Tek FLx800 TBI Fluorometer
  • BIO-TEK Technothrombin TGA package with KC4TM
    software
  • Flexible and affordable solution for fluorescence
    measurements
  • Ideal for use with Technothrombin TGA
  • Black plates for the TGA determination on the
    fluorescence reader are available on request

41
Technothrombin TGAReaders Software
  • Readers with software available from Technoclone
  • Applications for many fluorescent readers
    available from DiaPharma
  • TECAN, Flurostar BMG, Fluoroscan Thermo Electron,
    VICTOR PerkinElmer, Molecular Devices SpectraMax
    (in development)
  • More applications being developed see your
    DiaPharma representative for specific requests.

42
Technothrombin TGA
  • Whole blood or plasma
  • Negatively charged phospholipids containing
    different amounts of TF and CaCl2
  • Provides different TF concentrations, monitors
    whole kinetics of thrombin generation during
    initiation, amplification, and down-regulation of
    thrombin formation
  • Can detect changes in thrombin formation

43
Technothrombin TGA
  • Based on monitoring fluorescence generated by
    cleavage of a thrombin substrate over time, upon
    activation of the coagulation cascade by
    different concentrations of PL and TF
  • Concentration of thrombin is automatically
    calculated using thrombin calibrator and
    appropriate software
  • Allows for visualization of the different phases
    of clot formation

44
Technothrombin TGA Test Procedure
  • Allow reagents to reach RT before use
  • Fluorometer wavelength 360 nm/460 nm
    (excitation/emission)
  • Temperature during measurment 37?C

45
TECHNOTHROMBIN TGA
Test Procedure
Sample Preparation Citrated plasma (PPP or
PRP) PRP samples generally more
stable Color of the plasma does not
influence the TGA measurement
Mechanical agitation leads to significant changes
thrombin generation Thrombin Standard
Curve Calibration range 5-500 nM
thrombin Add thrombin calibrator
substrate (thrombin standard calibrated
against WHO preparation) Read for 10
minutes at 30 sec intervals Samples Add
sample reagent substrate Read for 60
minutes at 60 sec intervals 90 minutes
for FVIII inhibitor bypassing therapy Analysis
Software calculates thrombin generation,
results are given in nM Thrombin
46
Technothrombin TGA Test Procedure
  • Lag phase depends in general on amount of TF
    added, and therefore type of TGA reagent (TGA RB,
    RCLow, or RCHigh) used
  • Slope and peak thrombin can depend on amount of
    PL in sample
  • For RB, RCLow (low PL), value determined in PPP
    by number and composition of MPs present in sample

47
Technothrombin TGA Test Procedure
  • Anticoagulation Therapy RCHigh
  • Thrombophilia PPP, RCLow
  • Hemophilia FEIBA RB
  • Hemophilia rFVIIa RCLow

48
Technothrombin TGA Test Procedure
  • Excess of TF will cause mechanism of
    prothrombinase formation to take EXTRINSIC
    pathway (FVII, V, X, TFPI)
  • Decreased TF changes pathway of thrmobin
    formation to included FVIII, FIX, FXI
  • Absence of TF (but high PL) thrombin generation
    occurs via INTRINSIC pathway
  • In PPP, without PL, thrombin generation depends
    on PL present in plasma, i.e. presence of
    circulating pro-coagulant microparticles

49
Technothrombin TGA Test Procedure
  • Expected Ranges
  • See pkg insert for expected values in PPP and PRP
  • In general, PRP yields higher peak FIIa
  • Lot-specific batch table will include reference
    ranges
  • Plasma preparation very important for accurate
    results

50
Ceveron Alpha Coagulation Analyzer
  • Fully automated coagulation analyzer
  • Allows routine measurements of all relevant
    coagulation parameters on one analyzer.
  • Can perform clotting, turbidometric (LIA),
    fluorometric, and chromogenic assays
  • Ideal for small to medium labs or as a back-up
    instrument

51
Ceveron Alpha Coagulation Analyzer
52
Ceveron Alpha Coagulation Analyzer
  • Ideal for use with the Technothrombin TGA kit
  • Thrombin generation is measured with a special
    adapted TGA fluorometric module which is placed
    over the cuvette motor
  • UV emitter (360 nm) is placed in the module
  • Optimal wavelength for specific substrate is
    determined by spectrometry
  • TGA graphs can be shown for single evaluations
    and for multiple comparisons

53
Summary
  • Regular global clotting assays like the PT and
    aPTT do not discriminate patients with thrombotic
    tendency they dont tell the whole story
  • The TGA is a physiological function test of the
    thrombotic-hemostatic system that can measure
    clotting and bleeding tendencies, as well as
    measure effects of treatment with a combination
    of drugs or a combination of pathological
    conditions

54
Summary
  • The Technothrombin TGA is a reliable global
    coagulation test suitable for discriminating
    patients with bleeding as well as thrombotic
    tendencies
  • Use of a fluorogenic substrate along with a
    thrombin calibrator eliminates major assay
    interferences

55
Publications References
  • Kaufmann V et al. Validation of the thrombin
    generation assay Technothrombin TGA.
    www.technoclone.com.
  • Varadi K et al. Applications of thrombin
    generation assay in characterizing FVIII
    Bypassing Agents. XXth Congress of the ISTH,
    Sydney, Australia, Aug. 8 12, 2005.
  • Varadi K et al. Monitoring the bioavailability of
    FEIBA with a thrombin generation assay. J Thromb
    Haemost. 2003 Nov. 1 (11) 2374-80.
  • Gerotziafas GT et al. Toward a standardization of
    thrombin generation assessment The influence of
    tissue factor, platelets, and phospholipid
    concentration on the normal values of the
    Thrombogram-Thrombinoscope assay. Thrombosis
    Journal 2005 Oct. 26 (3)16.
  • Hemker HC et al. Continuous registration of
    thrombin generation in plasma, its use for the
    determination of the thrombin potential. Thromb
    Haemost 1993 70 617-624.
  • Hemker HC et al. Thrombin generation, an
    essential step in haemostasis and thrombosis
    Haemostasis and Thrombosis. Edinburgh, Churchill
    Livingstone, 1994 477-490.
  • Technothrombin TGA Package Insert.
    www.technoclone.com.
  • Kaufmann V. et al.  TECHNOTHROMBIN TGA a novel
    Thrombin Generation Assay suitable for the new
    routine coagulation analyzer Ceveron alpha. ISTH
    Sydney 2005.
  • Tappenden KA et al. Evaluation of Fluorogenic
    Substrates for the Monitoring of Thrombin
    Generation. ISTH Sydney 2005. P1897.
Write a Comment
User Comments (0)
About PowerShow.com