Coagulation and Transfusion Medicine / Optimizing ThrombinGeneration Assays Optimization of Plasma Fluorogenic ThrombinGeneration Assays Wayne L. Chandler, MD, and Mikhail Roshal, MD, PhD Key Words: Thrombin generation; Fluorogenic; Tissue factor; Plasma; Coagulation DOI: 1.139/AJCP6AY4HTRAAJFQ Abstract We optimized fluorogenic thrombingeneration assays with regard to sample volume, calibration, analytic corrections, and activation reagents. Lower sample volumes (4 vs 8 µl) were associated with better recovery of thrombin activity, lower interference due to absorbance of light, and higher total thrombin generation (area under the curve), even using internal standards to calibrate plasma samples. With lower sample volumes, there was no advantage to internal calibration of samples without obvious interference (hemolysis). Previously developed corrections for measured vs expected fluorescence units, residual macroglobulin activity, and hemolysis improved the analytic accuracy of the assay. An optimized assay with a 4µL sample volume, analytic corrections, and a corn trypsin inhibitor to block contact activation showed that.6 pmol/l tissue factor activator was better than 5 pmol/l at differentiating healthy subjects from patients with sepsis while demonstrating good reproducibility (area under the curve, 4% withinrun and 7% betweenrun coefficient of variation). Thrombingeneration assays measure the amount of active thrombin produced in plasma or whole blood after recalcification. Thrombin generation can be initiated by tissue factor bearing microparticles or other substances in the sample itself (native thrombin generation) or by addition of exogenous activators such as tissue factor and phospholipids. Older methods measured the formation of thrombinantithrombin complexes or other thrombin markers as a measure of thrombin generation. This method worked but was timeconsuming, manually intensive, and not suited for the evaluation of large numbers of clinical samples. Subsequently, methods based on thrombinsensitive fluorogenic or chromogenic peptide substrates have been developed that offer greater applicability to clinical studies. Fluorogenic assays have the advantages that they do not require addition of fibrin polymerization inhibitors and can be calibrated to absolute thrombingeneration rates (nmol/l of active thrombin per minute) rather than a percentage of normal plasma. Prospective studies have shown that these assays have the potential for predicting the risk of thrombosis. 1,2 Currently, there are 2 commercially available fluorogenic thrombingeneration assays, the Calibrated Automated Thrombogram, developed by Hemker et al 3 and marketed by Thrombinoscope, Maastricht, the Netherlands, and the Technothrombin TGA method marketed by Technoclone, Vienna, Austria. Although similar in overall design, the details of these 2 methods are different, and many modifications have been described in the literature. 28 The purpose of this study was to optimize fluorogenic thrombingeneration assays with regard to sample volume, calibration, activation reagents, and corrections for hemolysis and other problems. We did not attempt to repeat all prior evaluations of these assays. When an extensive evaluation had already been done, Downloaded from http://ajcp.oxfordjournals.org/ by guest on January 29, 216 Am J Clin Pathol 29;132:169179 169 169 DOI: 1.139/AJCP6AY4HTRAAJFQ 169
Chandler and Roshal / Optimizing ThrombinGeneration Assays we confirmed the results and evaluated whether it should be incorporated in an optimized method. Materials and Methods Human Subjects The study was approved by the University of Washington (Seattle) Human Subjects Review Committee. Informed consent was obtained from subjects. Blood samples were anticoagulated with.19 mol/l citrate. Citrated blood was centrifuged at 4,4g for 2 minutes at room temperature. Plateletpoor plasma was decanted and frozen at 8 C. Materials Lipidated recombinant human tissue factor (RecombiPlasTin) was obtained from Instrumentation Lab, Bedford, MA. Corn trypsin inhibitor was obtained from EMD Biosciences, San Diego, CA. Lαphosphatidylcholine and Lαphosphatidylserine were obtained from Avanti Polar Lipids, Alabaster, AL. Phospholipid vesicles composed of.8 mmol/l phosphatidylcholine and.2 mmol/l phosphatidylserine in 2 mmol/l HEPES, 1 mmol/l sodium chloride,.2 g/l sodium azide, ph 7.5, were prepared by drying the phospholipids under dry nitrogen, then strong vacuum, followed by suspension in HEPES buffer and sonication. Pooled normal plasma anticoagulated with.19 mol/l citrate was obtained from Precision Biologics, Dartmouth, Canada. Thrombin calibrator (865 nmol/l) and thrombinsensitive fluorogenic substrate (ZGlyGlyArg AMC) calcium reagent were obtained from Technoclone through DiaPharma Group, Columbus, OH. Thrombin α 2 macroglobulin calibrator (equivalent to 625 nmol/l active thrombin) 3 and ZGlyGlyArgAMC calcium reagent were obtained from Thrombinoscope through Diagnostica Stago, Parsippany, NJ. ThrombinGeneration Assay Both fluorogenic thrombingeneration assays combine 3 solutions, a plasma sample, an activation reagent, and a combined fluorogenic substrate and calcium solution to start the reaction. When only buffer is added as the activation reagent (termed native thrombin generation), initiation of thrombin generation is dependent on procoagulants present in the plasma. All samples and reagents were warmed to 37 C before use. The activation reagent consisted of thrombingeneration buffer (2 mmol/l HEPES, 14 mmol/l sodium chloride, 5 mg/ml bovine serum albumin,.2% sodium azide, ph 7.35) containing variable amounts of lipidated tissue factor, phospholipid vesicles, and corn trypsin inhibitor to block contact activation. In the Technoclone assay, 4 µl of plasma was added to 1 µl of activation reagent followed by 5 µl of calcium fluorogenic substrate reagent (7.5 mmol/l calcium and.5 mmol/l substrate final reaction concentrations) to start the reaction. In the Thrombinoscope assay, 8 µl of plasma was added to 2 µl of activation reagent followed by 2 µl of calcium fluorogenic substrate reagent (16.7 mmol/l calcium and.42 mmol/l substrate final reaction concentrations). Fluorescence units were monitored at 37 C at 1minute intervals for 9 minutes using a Synergy HT microplate reader (BioTek Instruments, Winooski, VT) set at an excitation wavelength of 36 nm and an emission wavelength of 46 nm. Results included determination of lag time in minutes, defined as the interval from the start of substrate/calcium addition until formation of 1 nmol/l of thrombin, 3 peak height for thrombin generation in nmol/l, peak height time in minutes, velocity index or peak rate of thrombin generation [peak thrombin/(peak time lag time)], and area under the curve (AUC), defined as the sum of thrombin concentrations from 1 to 9 minutes (nmol/l min). The AUC has also been referred to as the endogenous thrombin potential (ETP). 3 Correction of measured fluorescence units for the inner filter effect and substrate exhaustion and correction for residual macroglobulin complex formed during the reaction were as previously described. 3 Absorbance in plasma at 36 and 46 nm was determined in a clear microtiter plate using the same sample volume used in the thrombingeneration assay. Statistics Results are given as the mean ± SD unless otherwise indicated. Statistical comparisons used paired t tests for paired samples and 2way unpaired t tests for unpaired samples. Results Comparison of the Technoclone and Thrombinoscope Methods zfigure 1z shows a comparison of the AUC results for the Technoclone method run per manufacturer s recommendations (thrombin calibrator in buffer, no fluorescence unit correction, no residual macroglobulin correction) vs the Thrombinoscope method run per manufacturer s recommendations ( macroglobulin calibrator added to plasma samples, correction for inner filter effect, correction for residual macroglobulin) in samples without obvious hemolysis or other interference. On average, the Technoclone method gave higher AUC results for most samples. Downloaded from http://ajcp.oxfordjournals.org/ by guest on January 29, 216 17 Am J Clin Pathol 29;132:169179 17 DOI: 1.139/AJCP6AY4HTRAAJFQ
Coagulation and Transfusion Medicine / Original Article Effect of Plasma Volume The 2 assays use different amounts of plasma in their final reactions. The Technoclone assay uses 4 µl of plasma in a 1µL total volume (4% plasma), whereas the Thrombinoscope assay uses 8 µl of plasma in a 12µL total volume (67% plasma). zfigure 2z shows that as the percentage of plasma volume in the assay decreases, thrombin generation goes up, peaking when the plasma volume is about 2% to 3% and then falling for lower plasma volumes. The pattern was similar for substrates from either company. Calibration of Thrombin Generation ztable 1z shows a comparison of the purified active thrombin calibrator from Technoclone with the macroglobulin complex calibrator from Thrombinoscope. The specific activity of the 2 calibrators was similar in both assays, but each company s calibrator showed slightly more activity in its own assay. In the Thrombinoscope assay, the Thrombinoscope calibrator in buffer had a specific activity 6% higher than the Technoclone calibrator in buffer. In the Technoclone assay, the Thrombinoscope calibrator in buffer had a specific activity 2% lower than the Technoclone calibrator in buffer. Effect of Corrections The Thrombinoscope assay uses 3 corrections to improve the accuracy of estimated active thrombin concentrations generated in plasma that are not used in the Technoclone method: (1) a correction for inner filter effect and substrate exhaustion, (2) a correction for residual macroglobulin activity in the sample, and (3) a correction for hemolysis and other interfering factors. 3,4 We evaluated the effect of these corrections on the Technoclone method. When thrombin generation is high, measured fluorescence unit levels may be underestimated owing to a combination of substrate exhaustion and the inner filter effect. 3 We found that as substrate was consumed, measured fluorescence units underestimated expected fluorescence in the Technoclone assay zfigure 3z. Based on this observation, we determined the fluorescence unit correction for our fluorescence reader and confirmed that the correction was a function of the Thrombinoscope AUC (nmol/l min) 5, 4, 3, 2, 1, 1, 2, 3, Technoclone AUC (nmol/l min) 4, 5, zfigure 1z Comparison of thrombingeneration area under the curve (AUC) for the Technoclone and Thrombinoscope assays in 38 samples. Stimulated thrombin generation was initiated by addition of.6 pmol/l human recombinant tissue factor, 1 µmol/l phospholipid, and 4 µg/ml corn trypsin inhibitor (final reaction mixture). Percent of Maximum AUC 12 1 8 6 4 2 Technoclone assay standard volume Thrombinoscope assay standard volume 1 2 3 4 5 6 7 8 Percent Plasma in Final Reaction Volume zfigure 2z Effect of the percentage of plasma in the assay on the area under the curve (AUC). Filled circles and solid line, Technoclone assay; open squares and dashed line, Thrombinoscope assay. Arrows show the standard plasma volumes used in each commercial assay. Stimulated thrombin generation was initiated by addition of.6 pmol/l human recombinant tissue factor, 1 µmol/l phospholipid, and 4 µg/ml corn trypsin inhibitor (final reaction mixture). Downloaded from http://ajcp.oxfordjournals.org/ by guest on January 29, 216 ztable 1z Technothrombin vs Thrombinoscope Calibrator Assay * Calibrator Thrombinoscope Technoclone Technoclone: purified thrombin in buffer 7.41 ±.66 8.8 ±.78 Thrombinoscope: macroglobulin in buffer 7.86 ±.46 7.5 ±.43 * Specific activity of each calibrator given as mean ± SD fluorescence units per minute per nanomole per liter of thrombin in the final reaction mixture based on the reported equivalent active thrombin concentration in the calibrator. Am J Clin Pathol 29;132:169179 171 171 DOI: 1.139/AJCP6AY4HTRAAJFQ 171
Chandler and Roshal / Optimizing ThrombinGeneration Assays A B 3, 3, Fluorescence Units 25, 2, 15, 1, 5, Corrected Fluorescence Units 25, 2, 15, 1, 5, 2 4 6 8 1 5, 1, 15, 2, Time (min) Measured Fluorescence Units C Peak Thrombin Generation Corrected Fluorescence Units (nmol/l) 8 6 4 2 2 4 6 8 Peak Thrombin Generation Measured Fluorescence Units (nmol/l) zfigure 3z Measured vs predicted fluorescence generation. A, Increasing amounts of thrombin calibrator (sample concentrations, 54, 18, 216, and 432 nmol/l) were added to substrate and buffer in the Technoclone assay followed by measurement of fluorescence for 9 minutes at 37 C. Solid lines show the initial slope for the first 5 minutes representing the theoretical slope if inner filter effect and substrate depletion were not occurring. The filled circles represent measured fluorescence units over time. B, Plot of measured fluorescence units vs expected or corrected fluorescence units based on the slope of the reaction during the first 5 minutes for all data shown in A. C, Comparison of tissue factor stimulated peak thrombin generation (PTG) values based on measured vs corrected fluorescence unit values: Corrected PTG = (1.35 Measured PTG) 2; r 2 =.983; n = 98. Stimulated thrombin generation was initiated by addition of.6 pmol/l human recombinant tissue factor, 1 µmol/l phospholipid, and 4 µg/ml corn trypsin inhibitor (final reaction mixture). Downloaded from http://ajcp.oxfordjournals.org/ by guest on January 29, 216 measured fluorescence units only, not the thrombin concentration. 3 Figure 3 shows that on average, the peak thrombin generation was 22% ± 1% higher when the fluorescence unit correction was applied. During the thrombingeneration assay, part of the thrombin formed binds to α 2 macroglobulin in plasma and accumulates as macroglobulin complexes that remain active against the fluorogenic substrate but do not activate coagulation, leading to a stable level of apparent residual thrombin activity at the end of the reaction. 4 We determined that this residual macroglobulin activity was present in the Technoclone assay zfigure 4z, leading to an overestimate of the AUC. The correction for residual macroglobulin activity had only a minor effect on peak thrombin generation, producing results that were on average 2% lower than the uncorrected values with high correlation (r 2 =.99), but had a greater effect on the AUC, which was, on average, 26% ± 7% lower (r 2 =.91). Correction for Hemolysis Hemolysis, icterus, and other factors that increase the absorbance in the sample can result in a falsely low AUC owing to absorbance of the excitation and emission light in the sample. Hemker et al 3 proposed a method for correcting absorbance interference to the AUC or ETP by adding a known amount of exogenous macroglobulin to each sample as an internal calibrator. The Thrombinoscope method recommends calibrating every sample using exogenous macroglobulin, even the samples showing no evidence of hemolysis or other interference. 3 172 Am J Clin Pathol 29;132:169179 172 DOI: 1.139/AJCP6AY4HTRAAJFQ
Coagulation and Transfusion Medicine / Original Article A Thrombin (nmol/l) 14 12 1 8 6 4 2 Raw thrombin generation Corrected thrombin generation Estimated macroglobulin 2 4 6 8 1 Time (min) B Peak Thrombin Generation Corrected for Thrombinα 2 Macroglobulin (nmol/l) 8 6 4 2 2 4 6 8 Peak Thrombin Generation Original Uncorrected (nmol/l) C AUC Corrected for Thrombin α 2 Macroglobulin (nmol/l min) 12, 1, 8, 6, 4, 2, 2, 4, 6, 8, 1,12, AUC Original Uncorrected (nmol/l min) zfigure 4z Correction for residual macroglobulin complex. A, Typical thrombingeneration curve showing correction for residual macroglobulin complex; dashed line, original thrombingeneration data showing residual thrombin activity at the end of the assay due to macroglobulin complex formed in plasma; solid line, final data after correction to remove contribution by macroglobulin complex formed in plasma; dotted line, estimated macroglobulin complex formed during the assay. B, Effect of correction for residual thrombin α 2 macroglobulin complex formed in plasma on peak thrombin generation in the Technoclone assay (r 2 =.999; n = 92). C, Effect of correction for residual macroglobulin complex formed in plasma on the area under the curve (AUC) in the Technoclone assay (Corrected AUC = [.836 Original AUC] 513; r 2 =.91; n = 92). Stimulated thrombin generation was initiated by addition of.6 pmol/l human recombinant tissue factor, 1 µmol/l phospholipid, and 4 µg/ ml corn trypsin inhibitor (final reaction mixture). Downloaded from http://ajcp.oxfordjournals.org/ by guest on January 29, 216 In the Thrombinoscope assay, background absorbance was twice as high as in the Technoclone assay (8 vs 4µL sample volumes), resulting in more interference in that assay, even in samples with no apparent hemolysis or other problems. In the Thrombinoscope assay (8µL sample volume), the macroglobulin calibrator showed 71% ± 5% as much activity in normal plasma as it did in buffer (n = 12). In the Technoclone assay (4µL sample volume), the macroglobulin calibrator showed 96% ± 4% as much activity in normal plasma as it did in buffer (n = 12). In the Technoclone assay using pooled normal plasma (PNP), the withinrun coefficient of variation was 5% for the AUC and 5% for the macroglobulin calibrator slope but 8% for the AUC calibrated using macroglobulin added to each plasma sample (n = 8 for each). In plasma samples without evidence of hemolysis, icterus, or other color changes, calibration in each sample with exogenous macroglobulin did not improve the precision and had only minor effects on the accuracy of AUC measurements using the Technoclone assay with a 4µL sample volume but was useful in the Thrombinoscope assay to improve calibration accuracy. To evaluate the effect of hemolysis on the assay, increasing amounts of hemoglobin up to 7 mg/dl were added to normal plasma. The AUC was reduced in direct proportion to the concentration of hemoglobin in the sample. Addition of macroglobulin as an internal calibrator in the hemolyzed plasma samples corrected the AUC on average to 98% ± 5% of the original unhemolyzed value (n = 6). We compared the correction predicted by calibration with Am J Clin Pathol 29;132:169179 173 173 DOI: 1.139/AJCP6AY4HTRAAJFQ 173
Chandler and Roshal / Optimizing ThrombinGeneration Assays macroglobulin with absorbance measurements at the excitation (36 nm) and emission (46 nm) wavelengths in 56 samples containing varying levels of plasma hemoglobin and bilirubin. Sample absorbance at 36 nm (Abs 36 nm) and 46 nm (Abs 46 nm) showed correlations of r 2 =.72 and.8, respectively, with the correction predicted by the macroglobulin. The best correlation with the macroglobulin correction was with what we termed the absorbance ratio (r 2 =.92) zfigure 5z. Absorbance Ratio 16 14 12 1 8 6 4 2 1 2 3 4 5 Thrombin α 2 Macroglobulin Correction zfigure 5z Correcting the area under the curve in 56 samples with varying levels of hemolysis and icterus. Comparison of correction based on individual sample calibration using exogenous macroglobulin vs absorbance ratio described in the text using sample absorbance measurements at 36 and 46 nm. A Absorbance Ratio = Sample Abs 36 nm Sample Abs 46 nm + PNP Abs 36 nm PNP Abs 46 nm By using the best fit between the absorbance ratio and the macroglobulin correction, we estimated an absorbancebased correction. In hemolyzed samples, the absorbance correction adjusted the AUC to 1% ± 6% of the original unhemolyzed value (n = 6). Sample Activation Both companies offer a variety of activation reagents ranging from physiologic buffer only for native thrombin generation to increasing amounts of tissue factor and phospholipid. Prior studies have shown that contact activation is occurring in the Thrombinoscope assay; it can be blocked by using corn trypsin inhibitor, and in the presence of corn trypsin inhibitor, healthy subjects showed little or no spontaneous thrombin generation. 8 We evaluated the effect of contact system inhibition with corn trypsin inhibitor on the Technoclone assay. Addition of corn trypsin inhibitor to plasma to block contact activation during native thrombin generation (no tissue factor or phospholipids added) prolonged the lag time and reduced the peak thrombin generation ( vs 4 µg/ml; P =.12; paired t test) zfigure 6z. The amount of peak thrombin generation due to contact activation (as estimated by percentage of activity blocked by corn trypsin inhibitor) varied widely among different healthy subjects, ranging from 16% to nearly 1%. With corn trypsin inhibitor present, little or no native thrombin generation occurred in normal plasma. When relatively high concentrations of tissue factor were added, the effect of contact system inhibition decreased as the tissue factor in the activator became B Downloaded from http://ajcp.oxfordjournals.org/ by guest on January 29, 216 Peak Thrombin Generation (nmol/l) 12 1 8 6 4 2 2 4 >4 Corn Trypsin Inhibitor ( g/ml) Lag Time (s) 12 1 8 6 4 2 2 4 >4 Corn Trypsin Inhibitor ( g/ml) zfigure 6z Effect of corn trypsin inhibitor concentration on native thrombin generation (n = 8). A, Peak generation. B, Lag time, defined as the interval from the start of substrate addition until the formation of 1 nmol/l of thrombin. 3 Boxes indicate the mean; error bars, SD. 174 Am J Clin Pathol 29;132:169179 174 DOI: 1.139/AJCP6AY4HTRAAJFQ
Coagulation and Transfusion Medicine / Original Article the primary initiator of thrombin generation. Owing to the variable nature of contact activation, at intermediate levels of tissue factor and phospholipid, it became difficult to separate whether the tissue factor was the primary activator or the contact system. The effect of adding phospholipid was highly dependent on whether contact activation was blocked. Peak thrombin generation increased nearly 6fold as phospholipid was increased from to 4 µmol/l when no corn trypsin inhibitor was present and contact activation was occurring, but when corn trypsin inhibitor was present and contact activation blocked, addition of up to 4 µmol/l exogenous phospholipids increased peak thrombin generation only 88% zfigure 7z. Based on the preceding results, we selected a candidate assay for further testing of tissue factor and phospholipid: 4µL sample volume to increase thrombin generation and reduce interference, correction for inner filter effect and residual macroglobulin to improve accuracy, and addition of 4 µg/ml corn trypsin inhibitor to block contact activation. With this candidate assay, peak thrombin generation rose as more tissue factor was added to the reaction zfigure 8z. The most rapid change in peak thrombin generation occurred between and 1 pmol/l tissue factor in the final reaction, but peak thrombin generation continued to rise even at the maximum tissue factor concentration tested, 6 pmol/l. Similarly the AUC rose as more tissue factor was added, but the AUC appeared to plateau at about 1 pmol/l tissue factor with only a slow rise with higher tissue factor concentrations. With corn trypsin inhibitor present, addition of phospholipids increased peak thrombin generation only at the highest tissue factor concentrations. The maximum effect occurred at a phospholipid concentration of approximately 1 µmol/l. By using 5 normal samples and 5 samples from patients with sepsis, we evaluated the effect on thrombin generation of 3 tissue factor phospholipid concentrations (with corn trypsin inhibitor present): (1) no tissue factor or phospholipid (native thrombin generation), (2).6 pmol/l tissue factor and 1 µmol/l phospholipid, and (3) 5 pmol/l tissue factor and 4 µmol/l phospholipid ztable 2z. Peak thrombin generation and the AUC were significantly different between healthy subjects and patients with sepsis when native thrombin generation was used (no activator, contact activation blocked). Peak thrombin generation was also significantly different between healthy subjects and patients with sepsis when relatively low concentrations of tissue factor (.6 pmol/l) and phospholipid (1 µmol/l) were used to activate thrombin generation. Peak thrombin generation and AUC were not significantly different between healthy subjects and patients with sepsis when a relatively high concentration of activator was used (5 pmol/l tissue factor and 4 µmol/l phospholipid). Based on these results, we selected 2 options for further thrombingeneration testing: native Peak Thrombin Generation (nmol/l) 25 2 15 1 5 thrombin generation with no activator and tissue factor stimulated thrombin generation with relatively low levels of tissue factor (.6 pmol/l) and phospholipid (1 µmol/l). Reference Range and Imprecision Native thrombin generation and tissue factor stimulated thrombin generation were evaluated in samples from 25 healthy subjects ztable 3z. The majority of healthy subjects showed little or no native thrombin generation with corn trypsin inhibitor present. ztable 4z shows the withinrun and betweenrun imprecision for tissue factor stimulated peak thrombin generation and the AUC. Discussion 1 2 3 4 5 Phospholipid Concentration ( mol/l) zfigure 7z Effect of phospholipid concentration on tissue factor stimulated peak thrombin generation. Thrombin generation was initiated by addition of.6 pmol/l human recombinant tissue factor. Filled circles, no corn trypsin inhibitor added; open circles, 4 µg/ml corn trypsin inhibitor added. Thrombingeneration assays have multiple potential uses, including estimation of hemorrhagic and thrombotic risk, monitoring of therapy, and detection of circulating procoagulants and microparticles. 3,9 Different protocols may be needed depending on the specific use. Two types of thrombingeneration assays are currently available. 5 Chromogenic thrombingeneration assays use high concentrations of tissue factor or partial thromboplastin time reagents as activators, produce empiric results reported as a percentage of normal, require fibrin polymerization inhibitors, and have other disadvantages. 6,1 Fluorogenic thrombingeneration assays use lower levels of tissue factor activator and are calibrated to give an estimate of the actual concentration of active thrombin formed in the assay. We optimized fluorogenic thrombingeneration Downloaded from http://ajcp.oxfordjournals.org/ by guest on January 29, 216 Am J Clin Pathol 29;132:169179 175 175 DOI: 1.139/AJCP6AY4HTRAAJFQ 175
Chandler and Roshal / Optimizing ThrombinGeneration Assays assays with regard to sample volume, calibration, activation reagents, and corrections for thrombingeneration assays with regard to hemolysis and other problems. Thrombingeneration assays can be calibrated by using purified thrombin standards in buffer or macroglobulin standards added to plasma. The apparent specific activity of the 2 commercial thrombingeneration calibrators in buffer was similar but not identical. Substantial betweenbatch variability in calibrators has been reported. 11 Further work is needed to define an international standard for calibration of thrombin generation. The macroglobulin calibrator has the advantage that it can be used as a calibrator and as an internal standard for samples with absorbance interference problems, as discussed later. 8 8 Peak Thrombin Generation (nmol/l) AUC (nmol/l min) 6 4 2 8, 6, 4, 2, 1 2 3 4 5 6 7 1 2 Tissue Factor (pmol/l) 4 mol/l PL 3 mol/l PL 2 mol/l PL 1 mol/l PL.6 mol/l PL.3 mol/l PL.1 mol/l PL. mol/l PL 4 mol/l PL 3 mol/l PL 2 mol/l PL 1 mol/l PL.6 mol/l PL.3 mol/l PL.1 mol/l PL. mol/l PL 3 4 5 6 7 Peak Thrombin Generation (nmol/l) AUC (nmol/l min) 6 4 2 8, 6, 4, 2, 1 2 3 4 5 Phospholipid ( mol/l) 1 2 3 4 5 6 pmol/l TF 4 pmol/l TF 3 pmol/l TF 2 pmol/l TF 1 pmol/l TF.6 pmol/l TF.3 pmol/l TF. pmol/l TF 6 pmol/l TF 4 pmol/l TF 3 pmol/l TF 2 pmol/l TF 1 pmol/l TF.6 pmol/l TF.3 pmol/l TF. pmol/l TF Downloaded from http://ajcp.oxfordjournals.org/ by guest on January 29, 216 Tissue Factor (pmol/l) Phospholipid ( mol/l) zfigure 8z Effect of tissue factor (TF) and phospholipid (PL) concentrations on peak thrombin generation and area under the curve (AUC). All reactions contained corn trypsin inhibitor, 4 µg/ml final concentration. The first column shows TF on the xaxis, and curves show PL concentrations. The second column shows PL concentration on the xaxis, and curves show TF concentrations. 176 Am J Clin Pathol 29;132:169179 176 DOI: 1.139/AJCP6AY4HTRAAJFQ
Coagulation and Transfusion Medicine / Original Article Lower sample volumes in both assays were associated with increased total thrombin generation (AUC or ETP), down to a plasma volume of about 2% to 3% of the total reaction volume. This effect has been reported in another study and has been attributed to lower thrombin inhibition due to reduced antithrombin levels as the plasma volume in the assay is reduced. 12 Prior studies reported that owing to absorbance of the excitation and emission light by substances in plasma, recovery of macroglobulin calibrator added to plasma was approximately 3% lower than calibrator added to buffer and was highly variable between different samples, even in the absence of hemolysis. 13 Based on this observation, it was suggested that thrombin generation must be calibrated in each plasma sample analyzed using a separate reaction with macroglobulin calibrator added to plasma and that each plasma sample and plasma plus calibrator be run in duplicate to quadruplicate to reduce variability, resulting in 4 to 8 reactions per sample analyzed. 3 We determined that when using an 8µL sample volume in samples without obvious interference (hemolysis), the recovery of standard in normal pooled plasma was indeed reduced approximately 3% and showed up to 18% variability between different samples. However when a 4µL volume was used in samples without obvious interference, calibration was similar in buffer or plasma with less variability between plasma samples. Thrombingeneration assays using higher plasma volumes ztable 2z Effect of Activator Concentrations on Thrombin Generation in Clinical Samples * Peak Thrombin Generation (nmol/l) require calibration in each sample, whereas lower plasma volume assays may use a single assay calibrator if the sample does not show absorbance interference (eg, hemolysis or icterus). Running the sample in duplicate is still required because occasional samples showed aberrant curves owing to bubbles or other problems. 3 As expected, use of higher sample volumes (8 µl) in the Thrombinoscope assay was associated with greater interference when hemolysis was present. We determined that hemolysis affects the Technoclone assay and that the ztable 4z Imprecision for Tissue Factor Stimulated Thrombin Generation Parameters * Peak Thrombin Area Under the Curve Generation (nmol/l) (nmol/l min) Withinrun (n = 8) Mean 454 5,159 SD 18 24 CV (%) 4 4 Betweenrun (n = 15) Mean 44 4,553 SD 38 334 CV (%) 9 7 CV, coefficient of variation. * Tissue factor stimulated thrombingeneration run with final reaction concentrations of.6 pmol/l recombinant human tissue factor, 1. µmol/l phospholipid, and 4 µg/ml corn trypsin inhibitor. Area under the curve determined over 9 minutes. Area Under the Curve (nmol/l min) Tissue Factor Phospholipid Healthy Patients With Healthy Patients With (pmol/l) (µmol/l) Subjects Sepsis P Subjects Sepsis P 58 ± 22 276 ± 9.1 1,617 ± 719 4,181 ± 1,55.3.6 1. 198 ± 34 362 ± 17.2 3,672 ± 394 4,587 ± 1,52 NS 5. 4. 534 ± 46 54 ± 132 NS 4,565 ± 349 5,228 ± 1,764 NS Downloaded from http://ajcp.oxfordjournals.org/ by guest on January 29, 216 NS, not significant. * Data are given as mean ± SD. Unpaired t test, healthy subjects vs patients with sepsis; n = 5 for each group. ztable 3z Reference Ranges * Native TG TFStimulated TG Peak thrombin generation (nmol/l) 13 (172) 24 (143369) Lag time (min) 79 (329) 8 (61) Peak time (min) 89 (499) 16 (1322) Velocity index (nmol/l/min) 2 (5) 29 (1451) Area under the curve (nmol/l min) 179 (122,75) 4,522 (3,2295,641) * Range based on 25 healthy donors (12 women and 13 men; mean ± SD age, 32 ± 1 years; range, 1956 years). Native thrombin generation (TG) run with corn trypsin inhibitor (4 µg/ml). Tissue factor (TF)stimulated TG run with.6 pmol/l recombinant human tissue factor, 1. µmol/l phospholipid, and 4 µg/ml corn trypsin inhibitor. Data are shown as the median followed by the 4th to 96th percentile of the distribution. Area under the curve determined over 9 minutes. Am J Clin Pathol 29;132:169179 177 177 DOI: 1.139/AJCP6AY4HTRAAJFQ 177
Chandler and Roshal / Optimizing ThrombinGeneration Assays macroglobulin calibrator added to plasma could be used to correct the AUC, similar to prior reports for the Thrombinoscope assay. 3 In addition, we developed a sample absorbance ratio that could be used in place of an internal standard to provide a similar correction to the AUC in hemolyzed and icteric samples. We determined that inner filter effect, substrate exhaustion, and residual macroglobulin activity occur in the Technoclone assay, as previously described for the Thrombinoscope assay. 3 We further determined that corrections for measured vs expected fluorescence units and residual macroglobulin activity can be used in the Technoclone assay to improve analytic accuracy. Native thrombin generation is potentially useful for detecting circulating procoagulants in plasma. Variable levels of contact activation occurred in samples during thrombin generation in the Technoclone assay and have been reported in the Thrombinoscope assay. 8 To assess native thrombin generation, contact activation must be blocked, 8 which has typically been done by using corn trypsin inhibitor at 4 µg/ml. 7,8 In the Technoclone assay, healthy subjects showed little or no thrombin generation in the presence of corn trypsin inhibitor. Because most patients show little or no native thrombin generation, it cannot be used to assess the overall response of the system to a given stimulus. Most studies have used a fixed amount of activator, usually tissue factor and phospholipid, to stimulate thrombin generation. The optimal tissue factor phospholipid concentration for clinical studies is still being evaluated; higher tissue factor concentrations produced less variability in the AUC and less sensitivity to contact activation, whereas lower concentrations were more sensitive to changes in thrombin generation. 1,7,14 Prior studies reported no difference in the plasma AUC and lower peak thrombin generation in control subjects vs patients with sepsis using 5 pmol/l tissue factor and no corn trypsin inhibitor. 15 By using corn trypsin inhibitor, we found that native and lowlevel tissue factor (.6 pmol/l) stimulated thrombin generation could be used to differentiate healthy subjects from patients with sepsis, but higher levels of tissue factor stimulation (5 pmol/l), which overwhelmed differences in normal vs septic samples, could not be used. Others have reported that corn trypsin inhibitor plus low tissue factor stimulation could be used to differentiate pathologic from normal samples. 7,8 At present, tissue factor preparations are highly variable in source material and specific activity. International standards are needed for tissue factor activators. Both of the commercial assays had disadvantages. Based on the results, we developed an optimized assay. We selected a sample volume of 4 µl to increase thrombin generation and reduce interference and still allow use of commercial fluorogenic substrate calcium reagents. The optimized assay uses corrections for inner filter effect and residual macroglobulin to improve accuracy and addition of 4 µg/ml corn trypsin inhibitor to block contact activation. Calibration with macroglobulin has the advantage that it can be used as an internal standard for samples with absorbance interference problems. As an alternative, the AUC can be corrected by using an absorbance ratio. Like others, we found that in the presence of corn trypsin inhibitor and lower dose tissue factor activator seemed to be more sensitive to differences in thrombin generation between plasma samples. 7,8,14 Tissue factor and phospholipid concentrations can be adjusted to suit specific clinical questions. This assay depends on fluorescence measurements that are less standardized than absorbance measurements. Fluorescence can vary with the light source and detectors used in the instrument. An important question is, What aspects of this study apply to other microtiter plate fluorescence instruments? In setting up this assay on any instrument from any company, including the model used in this study, it is most important to calibrate thrombin generation using an active thrombin standard. If inner filter effect and substrate exhaustion corrections will be used, the correction factors will need to be determined. The correction for residual macroglobulin activity is independent of the fluorescence instrument used. If exogenous macroglobulin calibrator is used to correct the AUC for hemolysis or other interference, this is also independent of the fluorescence instrument. If an absorbancebased hemolysis correction is used, the correction will need to be determined for the instrument used because it is dependent on the original fluorescence measurements. Once all of these have been established, reference range and imprecision should be determined based on the final reagents and instrument selected. From the Department of Laboratory Medicine, University of Washington, Seattle. Address reprint requests to Dr Chandler: Dept of Laboratory Medicine, Box 35711, University of Washington, Seattle, WA 98195. References 1. Hron G, Kollars M, Binder BR, et al. Identification of patients at low risk for recurrent venous thromboembolism by measuring thrombin generation. 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