Preanalytical Variables in Coagulation Testing: Setting the Stage for Accurate Results

• Abstract
• Specimen Collection of Preanalytical Variables
• Patient Selection
• Specimen Collection
• Phlebotomy Procedural Issues
• Whole Blood versus Tube Collection
• Systems and Blood Collection
• Needle Size
• Line Collections
• Tourniquet Technique
• Tube Size and Anticoagulant
• Order of Draw
• Fill Volume and Hematocrit Adjustment
• Specimen Transportation and Stability
• Specimen Processing and Storage
• Centrifugation of Specimens
• Sample Preparation and Pooling
• Frozen Sample Storage and Thawing
• Specimen Condition—Hemolysis, Lipemia, and Icterus
• Conclusions and Recommendations
• References

Abstract

Many preanalytical variables may affect the results of routine coagulation assays. While advances in laboratory instrumentation have partially addressed the laboratory's ability to recognize some of these variables, there remains an increased reliance on laboratory personnel to recognize the three potential areas where coagulation testing preanalytical issues may arise: (1) specimen collection (including patient selection), (2) specimen transportation and stability, and (3) specimen processing and storage. The purpose of this article is to identify the preanalytical variables associated with coagulation-related testing and provide laboratory practice recommendations in an effort to improve the quality of coagulation testing and accuracy of result reporting.

Many preanalytical variables may affect the results of routine coagulation assays. To improve the precision and accuracy of laboratory testing, it is critical to identify these variables and realize their potential impact.[1] [2] Additionally, advances in laboratory instrumentation have improved the reproducibility and sensitivity of the analytical phase, therefore creating greater dependence on specimen integrity.[1] [2] [3] [4] [5] The activated partial thromboplastin time (aPTT) and prothrombin time (PT) are among the most frequently ordered screening tests in the clinical laboratory. These assays are used in the evaluation of a wide variety of clinical conditions, either for diagnostic or monitoring purposes. These screening tests also form the basis of many special coagulation tests such as factor assays, and in some locations clot-based specialized assays (e.g., protein C [PC] and protein S [PS] activity assays, activated PC resistance [APCR]).

Since the introduction of coagulation assays, efforts have been made not only to automate them, but to better standardize such testing, thereby providing more accurate results to aid in clinical assessment.[6] [7] [8] [9] [10] [11] [12] [13] [14] Preanalytical variables pertaining to routine coagulation testing can be classified into three major categories: (1) specimen collection (including patient selection), (2) specimen transportation and stability, and (3) specimen processing and storage. Within each of these there are several individual variables, each of which may have a major impact on testing.

Many standards and guidance documents for testing in the general clinical laboratory, and specifically in the coagulation laboratory, have been developed in an effort to improve precision and accuracy.[6] [7] [8] [9] [10] The Clinical and Laboratory Standards Institute (CLSI) is the primary organization for clinical laboratories standards and guidance documents in the United States, although their guidelines may be referenced or used internationally.[6] CLSI was established in 1968 as a group of individuals representing industry, government, and professionals dedicated to the development of standards and guidance documents for clinical laboratory testing. There are several documents available from CLSI that have relevance to laboratory practitioners.[6] Despite its existence, there is still a lack of practice standardization among clinical laboratories, with regards to specimen collection, storage, and processing for coagulation testing. Some of the procedures in practice today remain founded on “tradition,” while others are based on guidance documents such as provided by CLSI, with and without significant published or supporting evidence. In addition, many of the CLSI coagulation-related documents are outdated, and often not renewed[6] [15] ([Table 1]). As a result, many problems, inconsistencies, and erroneous results can still arise based on preanalytical processing of specimens, and these discrepancies may be associated with disastrous outcomes. This article will review the preanalytical variables associated with coagulation-related testing. Point-of-care (POC) devices, which may use native or anticoagulated whole blood, are also affected by preanalytical variables, but will have limited focus in this document. While there are also many variables related to the analysis of the specimen that also impact on testing, primarily those dependent on reagent and instrumentation, these are beyond the scope of this particular document. A recommendation for the most appropriate methods based on published and new data will be presented together with recommendations for converting these to a form of laboratory guidance document.

Specimen Collection of Preanalytical Variables

Patient Selection

Patient age, gender, race, blood group, and health status are all contributing variables for hemostasis testing, with the largest impact being for test result interpretation. Therefore, each laboratory must be able to address these variables, which may require establishment of different reference intervals (RIs), depending on the test and test method. This is mandatory to assure proper result interpretation and prevention of potential misdiagnosis.

The liver is the primary organ for synthesis of most coagulation factors. As the liver is the last organ to fully develop, neonates (especially premature infants) will have generally lower levels of coagulation factors, and thereby different “normal” values. For most coagulation factors, levels reach adult values by the age of 6 months.[16] [17] Increasing age is associated with increases in D-dimer (sometimes abbreviated XDP),[18] [19] von Willebrand factor (VWF), factor (F) VIII (FVIII), as well as FV, FVII, FVIII, FIX, and FXI.[20] [21] Increasing age may also be associated with changes in thromboelastographic (THEG) measurements[22] [23] and endogenous thrombin potential (ETP) assessment.[23] In one study, the authors indicated there were no differences between adults and pediatric patients, yet the authors recommended age-adjusted RI determination for thromboelastogram (TEG) testing to allow for more “correct interpretation of the results.”[24]

There are several gender-related differences in hemostasis. Higher levels of FII, FVII, FX, FIX, FXI, and FXII are found in females as compared with males.[21] There are decreased levels of PS and increased levels of antithrombin (AT) activity in females.[25] Males have longer closure times for the PFA-100 collagen-adenosine diphosphate (CADP) cartridge, a test used for screening platelet function defects.[26] Additional variables for females are changes in hemostasis parameters secondary to menstrual cycle, oral contraceptive (OC) use, or hormone replacement therapy (HRT). Changes associated with OC use depends on hormone concentration. Ethinyl estradiol increased levels of FVII antigen, FVIII activity, and β-thromboglobulin.[27] The recommendations for blood collection for female patients with combined OC and HRT, are for therapy to be discontinued for 2 months prior to testing, especially for PS and APCR testing.[28] Most studies demonstrated no menstrual cyclic variation for fibrinogen, FXI, FXIII, tissue plasminogen activator (tPA), plasminogen activator inhibitor-1 (PAI-1), D-dimer, or α-2-antiplasmin; however, some studies have demonstrated VWF, FVIII, and platelet function are at their lowest levels during menstrual and early follicular phase, thus suggesting that these time frames may be optimal for assessing female patients for bleeding risk test parameters.[29] ETP was significantly higher in luteal phase as compared with follicular phase; and FX higher during follicular phase.[30] In menstruating females suspected of von Willebrand disease (VWD), the recommendations are for blood samples to be collected on cycle day 1 to 4.[28]

Pregnant females also have different levels of coagulation factors than those not pregnant. Pregnancy decreases aPTT, PT, and TEG parameters, with increased D-dimer and soluble fibrin monomer complexes, but causes no change in AT.[31] Pregnancy is also associated with increased fibrinogen, VWF, FVII, FVIII, FIX, FX, FXII, plasminogen, PAI-1, tPA antigen, and platelet function, with decreased levels of FXIII, APCR, free PS antigen, and activity.[28] [32] [33] Given the number of alterations associated with pregnancy, the current recommendations for assessing coagulopathy are to wait 2 months postpartum, especially when assessing for VWD and PS deficiencies.[28] In addition to pregnancy altering hemostasis levels, labor increases the neonatal levels of FVIII, VWF, FIX, FXI, FXII, and plasminogen for vaginal deliveries as compared with neonates delivered by elective caesarean. Meconium presence in neonates has resulted in reduced plasma levels of FII, FV, FVII, and FX.[34]

There are few, but notable differences between ethnicity/race and coagulation parameters, especially genetic mutations associated with thromboembolic or bleeding risk.[35] [36] [37] The majority of these risk factors are beyond the scope of this document, but readers should be aware of their potential impact when interpreting results. Notably, relatively common occurrences are single-nucleotide polymorphism of VWF in blacks,[38] presence of FXI deficiencies in Ashkenazi Jews,[39] and increased incidence of APCR in Caucasians.[40] Sickle cell disease, most predominantly a disease present in blacks and those with Mediterranean origins, is associated with increased FVIII, VWF, and D-dimer. Combined with noted increases in prothrombin fragment (F1.2) and thrombin–antithrombin (TAT) complexes, and P-selectin (an indicator of platelet activation) with decreased ADAMTS-13 (a disintegrin and metalloproteinase with a thrombospondin type 1 motif, member 13), these data are suggestive of coagulation and platelet activation.[41]

There are notable differences in coagulation parameters according to ABO blood group, especially for FVIII and VWF. In blood group O, there are lower levels of FVIII and VWF than non-O, and also FIX and FXII.[20] [21] [25] There was no association of Rh factor with any coagulation parameter, and no ABO effect was seen for PS, PC, or AT.[25]

Numerous health status issues will also affect the accurate measurement of hemostasis. Inflammatory conditions can lead to increased levels of fibrinogen, FVIII, VWF, and PAI-1, with decreased levels of PS activity. Mental or physiological stress can also cause changes in hemostasis. Exercise increases VWF, FVIII, and euglobulin lysis time (ELT), but not FXII, FV, FVII, FII, or fibrinogen.[28] Stress activity increased VWF, C-reactive protein, and platelet activation[42] with mental stress resulting in increases of VWF, fibrinogen, tPA, and FVIII.[28] Phobic anxiety, merely from a blood collection, was also associated with a hypercoagulable state[43] that resolved with antidepressant therapy.[44] Prolonged mental stress may lead to decreases in FV, FVIII, and FIX.[28] [42] Increased thyroid hormone levels (hyperthyroidism) are associated with increased VWF, fibrinogen, FVIII, and PAI-1, but decrease collagen/epinephrine and CADP closure times for the PFA-100.[45] In a dose escalating study in health volunteers, levothyroxine treatment was associated with increased levels of VWF, FVIII, FIX, FX, PAI-1, and ELT, and concomitant decreased aPTT.[46] Primary hyperparathyroidism is associated with increased levels of FVII, FX, and D-dimer.[47] Acidosis, and to a lesser degree hypothermia, result in altered PT and aPTT testing and TEG measurements.[48]

Of considerable importance is the assessment of the biological or circadian variance noted with coagulation-related testing. Biological variation is a change noted between measurements of a given test over specified time frames in a single individual or a population. The coagulation test with the smallest biological variation is the PT, and one with the largest variance is VWF testing.[49] Seasonal variation are also noted with fibrinogen and ETP, but not PT or platelet aggregation.[50] Circadian variations have been noted with heparin therapy,[51] testing for platelet function,[26] [52] and measurements of the fibrinolytic pathway.[53] Platelet function may also be affected by physiological stress (including exercise), smoking, and dietary factors including coffee, caffeine containing products, flavonoids, phytoestrogens, and polyphenols.[54] [55] [56] Ingestion of fatty acids can also affect platelet function, as well as increase levels of PAI-1 and promote activation of FVII.[57] With these noted bioanalytical and seasonal variables, multiple blood collections throughout various cycles maybe necessary to confirm abnormal findings.

Aside from congenital deficiencies that lead to bleeding or thrombotic risks, several disease states are associated with coagulopathy. Included, but not limited to, are trauma, shock, sepsis, cancer, renal failure, liver failure, systemic lupus erythematosus, antiphospholipid antibody syndrome (APS), and other autoimmune disorders, surgery, and amyloidosis. Mechanical or support interventions such as extracorporeal membrane oxygenation (also known as extracorporeal life support), hemodialysis, continuous venovenous/arteriovenous hemodialysis, blood oxygenators, or aortic balloon pumps may induce a mild consumptive coagulopathy in adults, which may be more pronounced in neonates and pediatric patients (weight associated).[58] [59] These mechanical interventions require anticoagulation which may be partially performed within the circuit, systemic (unfractionated heparin [UFH]), or local to device (citrate within device and calcium gluconate out of the device). Often, in these acute and seriously ill patients, POC methods (e.g., activated clotting time or THEG) are often measurement methods of choice, but laboratory methods may also be used to confirm POC findings.[59] Other mechanical assisting devices, such as left ventricular pumps, create a turbulent flow environment, causing an immediate acquired type 2 VWD from mechanical shearing of the VWF protein.[60]

Numerous pharmaceutical interventions that are designed to either alter or replace hemostatic factors in hemostasis may or may not have an impact on coagulation testing. Common anticoagulants, such as vitamin K antagonists (VKAs), heparins, direct thrombin inhibitors (DTIs), or direct oral anticoagulants (DOACs) may have an impact on routine and/or specific coagulation assays. Some of these therapies require monitoring, where others may not. Other pharmaceutical interventions that alter the hemostasis pathway include fibrinolytic therapies (e.g., tPA), defibrinating drugs, antifibrinolytics (e.g., tranexamic acid), and antithrombotics (usually this term refers to antiplatelet therapy such as clopidigrel, aspirin, prasugrel, etc.). Drug reversal may be in the form of human products (e.g., fresh frozen plasma, cryoprecipitate, liquid state plasma, etc.), nonspecific (3 and 4 factor prothrombin complex concentrates which may be activated), or specific to a drug (e.g., idarucizumab for dabigatran). Pharmaceutical interventions for a bleeding patient may include stimulating an in vivo response (e.g., nasal or infusion of desmopressin to increase circulating VWF) or infusion of an activated factor (e.g., NovoSeven, a recombinant FVIIa). Replacement therapies would include specific factors (e.g., FVIII or FIX), that may be human, recombinant, porcine, or involve other forms of treatment (e.g., emicizumab-kxwh, trade name Hemlibra). The laboratory should be knowledgeable about the effect of these pharmaceutical interventions on the impact of their assays. The laboratory should also be able to provide guidance on what assays are appropriate for assessing any drug concentration (pharmacokinetics [PKs]) or effect (pharmacodynamics) as appropriate. For common anticoagulants, such as warfarin (a VKA) or UFH, historical practice uses traditional screening tests such as the PT and aPTT, respectively. However, even these decades old anticoagulant strategies must be monitored appropriately, with blood samples being collected at the correct time to avoid overexposure of the drug or inappropriate dose changes ([Table 2]). Newer therapies (e.g., DOAC or Hemlibra), or assessing efficacy of therapies that are less well established (e.g., fibrinolytics), may require further investigation, but some provisional guidance is provided ([Table 2]). Patients with known congenital deficiencies (e.g., hemophilia A or B, VWD) may require PK studies to determine replacement therapy and investigation of potential inhibitor effects. The guidance for PK studies should be provided by drug labeling or physician, but some provisional guidance is provided ([Table 2]).

It must also be noted that some pharmaceutical interventions, where the primary target of the therapy is not related to coagulation, may have unintended impact on coagulation testing. Most commonly, antibiotic use may alter the intestinal flora to impact the utilization of vitamin K, causing a vitamin K factor deficiency (similar to warfarin treatment, causing decreases in FII, FVII, FIX, and FX) or exacerbating warfarin therapy. Additionally, some lipoglycopeptides (e.g., telavancin) may also interfere with coagulation assays due to their binding of the test reagent phospholipid sources.[61] [62] Spurious abnormal results, especially concomitant with new drug use, should be thoroughly investigated, including drug use, prior to potentially inappropriate clinical intervention. Given a rise of cases in the United States, the Centers for Disease Control alerted clinicians about the increasing use of synthetic cannabis with added rodenticides (brodifacoum), causing clinical bleeding and markedly prolonged PT and aPTT.[63] Brodifacoum is a VKA with an extremely long half-life, as compared with warfarin.[64]

Lastly, laboratories must be cognizant of test samples that may not be of human origin, or samples that may not represent “native” human plasma. As part of episodic quality assurance (QA) measures, facilities that collect and process cryoprecipitate may require assessment of FVIII and fibrinogen. These samples contain concentrated amounts (as compared with native plasma) of FVIII, fibrinogen, and VWF and thus modification of the test (dilutions) or sample (diluted with FVIII-deficient plasma) may be required prior to testing. Institutions with cell saving devices in the operating room may require anti-FXa assessment, and so the laboratory must have a system that provides adequate lower level of detection that is suitable for this QA process. Animal blood, while having similar coagulation proteins, often have significantly different levels of factors than humans.[65] As such, not all human-based tests may translate to animal systems, especially for factor levels, D-dimer, and platelet function testing. This is especially true if an immunoassay is employed, which uses animal-derived antibodies that may not react with animal proteins or may react differently than anticipated. Reagent manufacturers may be able to provide guidance on whether their reagent or method is suitable for animal testing.

Specimen Collection

Once the patient selection has been defined, and the appropriate tests and collection times are noted, the next step is in collecting the blood sample. Tantamount to this process are the appropriate identifiers that assure proper patient identification and concomitant phlebotomy orders. Once that process has been verified, the actual blood collection follows. Properly trained personnel in phlebotomy practices assure proper blood collection. In a published study, the authors demonstrated that a nurse trained in acquiring blood samples for coagulation testing provided better quality specimens for coagulation than an untrained nurse. Samples from untrained nurses contained increased levels of coagulation activation factors (D-dimer, F1.2, and TAT), indicating an activated coagulation process reflective of poorly collected samples.[66]

Phlebotomy Procedural Issues

Whole Blood versus Tube Collection

Whole blood would be appropriate for POC devices such as international normalized ratio (INR) monitors, TEG, or rotational thromboelastography (ROTEM). Depending on the desired test, these POC samples may use native whole blood or require anticoagulation using evacuation tubes as noted below. Each laboratory must consult manufacturing package insert of POC reagents and devices to confirm sample types and collection methods.

Systems and Blood Collection

There are several manufacturers of blood collection tubes. It has been noted that despite the similarities between manufacturers regarding citrate concentration, there are significant differences between these tubes and potentially the arising coagulation assay results derived from blood collected into different tubes. For example, differences in PT and aPTT results using different collection tube manufacturers with the same citrate concentration have been reported.[67] Such variability has prompted recommendations that each laboratory validate these systems, and assess/amend any associated RIs prior to implementation.[68] For laboratories that provide services outside their own region (e.g., reference laboratories), it is may be desirable to express to client the preferred blood collection tube and citrate concentration to avoid this preanalytical bias.

Blood may be collected in individual vacuum tubes or by the syringe technique. The syringe method has several limitations and should be limited to those circumstances that require its use. If the syringe technique is to be used, then a syringe of less than 25 mL (preferably 10 mL) with the correct concentration and volume of anticoagulant should be utilized. Syringe drawing procedures should preferably utilize a “butterfly” needle apparatus. The blood should be withdrawn slowly to avoid hemolysis, and coagulation and platelet activation. When multiple tubes are needed with different anticoagulants, the syringe should be filled, and the sample quickly transferred to the appropriate tube. The British Committee for Standards in Haematology recommends manually mixing of citrate tube (gently inverting, end-over-end the tube ∼5–6 times),[69] although there has been some evidence to suggest that this may not be necessary with some collection systems,[70] or in patients treated with oral VKAs.[71] However, it must be noted that these two published studies used a limited number of samples and collection tubes. As such, unless locally determined otherwise through diligent studies, it may be prudent to use best practice of gently mixing whole coagulation samples collected in citrate, heparin, ethylenediaminetetraacetic acid (EDTA), or other anticoagulants, as well as pediatric or reduced volume samples.

The syringe technique may be employed during blood collection when the phlebotomist prefers to control the vacuum force in a patient with difficult veins.[72] Use of a syringe requires that the blood collected be subsequently and quickly transferred to a specimen container. This method inherently increases the phlebotomist's risk of injection needle stick exposure, as the receptacle container must be held in one hand while the syringe needle is guided into the tube with the other hand.[73] The syringe method also increases the risk of hemolysis if blood is forced too quickly through the hypodermic needle or against the side of the collecting tube if improper technique is used.[73] If no anticoagulant is added to the syringe, then the specimen is also likely to clot if not transferred immediately (usually within 60 seconds). This likelihood increases with larger sizes of syringe.[73] Despite these logical shortcomings, scarce published data exists to substantiate these claims. In fact, the earliest studies on collection systems for coagulation testing supported the use of the syringe technique over the vacuum tube.[74] One might argue, however, that in the controlled environment of a study, incorrect syringe technique or leaving syringe samples too long and thus facilitate clotting would be less likely and not reflective of “real-life” practices in a busy hospital. In the syringe technique, a specimen is first drawn into an empty or coagulant containing syringe and subsequently transferred into either individual vacuum tubes or directly into a laboratory analyzer.

Needle Size

Needles are integral to the blood collection process and come in a variety of sizes (needle gauge) with increasing numbers signifying decreasing needle diameter. CLSI guidelines recommend that needle gauges for coagulation testing range from 22 to 19 gauge.[73] This recommendation is not referenced but is supported by tradition in many standard textbooks concerning blood collection. For pediatric patients, higher gauges (indicating smaller needle diameter) in the range of 21 to 23 may have to be used.[73] [75] If the syringe technique is employed, for collections of blood over 30 mL, an 18-gauge needle is recommended to ensure adequate blood flow and reduce the chance of hemolysis and in-syringe clotting.

Line Collections

Arterial lines collections are acceptable, if a two-syringe technique is used, with the first 10 mL of line blood being cleared and the second syringe being used for blood collection for testing.[73] [76] For smaller patients, if appropriate and sterilely collected the first 10 mL that would be otherwise discarded, can be replaced back to patient if the hospital has a procedure for replacement of the blood.[76] For intravenous line collection, the intravenous line is ideally turned off for 5 minutes, then the two-syringe technique used as above.[73] [75] Consideration to use of POC methods is suggested for patients with difficult venous or arterial access.

Tourniquet Technique

Prolonged tourniquet times will induce increased vessel pressure, hypoxia, and lower pH below the tourniquet, thereby potentially masking mild deficiencies in VWF, FVIII, tPA, and other endothelial associated coagulation proteins.[73] [77] Venipuncture technique is an important preanalytic variable in coagulation testing. This specifically concerns prolonged tourniquet application or inducing the release of procoagulant material by multiple failed attempts to draw blood (needle sticks). Application of the tourniquet for longer than 1 minute can result in hemoconcentration and endothelial cell release of proteins. The resulting venous stasis promotes anaerobic glycolysis with an accumulation of plasma lactate and a reduction in blood pH. The lower blood pH can alter protein binding, and in the case of calcium, result in a spuriously increased level. Prolonged tourniquet application is also noted to elevate coagulation factors such as FVIII, VWF, and tPA, thereby affecting the accuracy of the diagnosis of coagulation defects. Prolonged tourniquet application may also create an acidic microenvironment, potentially leading to factitious prolongation of clotting assays.

Tube Size and Anticoagulant

Vacuum tubes come in a variety of tube sizes to accommodate the patient size and to minimize blood loss and iatrogenic induction of anemia in hospitalized patients. The best practice guidance for tube size is to use the smallest tube to accommodate the patient, but that will provide enough plasma for all of the tests ordered, ensuring approximately 50% of the plasma is left-over for add-on tests if needed. It should be noted that some tubes by different manufacturers will only “half fill” the tube when at the appropriate level. This has posed an issue when untrained phlebotomists draw blood as they have usually been instructed to “completely fill the tube.” Tubes that are overfilled or underfilled are unacceptable for testing and should be rejected (see below).[78] The accepting laboratory personnel must also be aware of the fill requirements of each tube used by their laboratory. In some hospitals, small microtubes have been created to collect very small volumes on newborn infants; however, these tubes must be validated for use by the laboratory, as they may influence RIs and also affect anticoagulant monitoring.[79]

The majority of coagulation tests is established and validated using sodium citrate as the anticoagulant. Further, it is recommended that 3.2% (0.109 mol/L) sodium citrate is the concentration of choice.[69] [73] [80] The 3.2% sodium citrate is considered more tolerant for clotting-based assays. In the past, 3.8% (0.129 mol/L) sodium citrate was also used but is no longer recommended for routine coagulation studies. In the 3.8% sodium citrate tube, the excess sodium citrate that is present can potentially bind more calcium ions present, for example, as added back into the clot-based assay, thereby interfering with coagulation test results. Although the 3.2% sodium citrate is the recommended concentration, several of the manufacturer's sodium citrate concentration is only approximately 3.2%, with variation based on the manufacturer's protocol. It must be emphasized that 3.2 and 3.8% citrate collection tubes are not interchangeable in a given laboratory, as both citrate concentrations may yield different test RIs and patient results.

For some coagulation and platelet testing, other anticoagulants or no anticoagulant (generating serum) can and have been used.[73] Tubes containing citrate acid dextrose and citrate theophylline, adenosine, and dipyridamol have been used for inhibiting platelet activation. Tubes containing Phe-Pro-Arg-chloromethylketone and/or aprotinin have been used to inhibit activation of the coagulation system and the fibrinolytic systems, respectively.[81] Lithium heparin, EDTA, or no anticoagulant (to generate serum) have been used for immunoassay tests (e.g., heparin-induced thrombocytopenia testing and antibody testing for APS). Specialized tubes have been created for special tests such as the fibrin(ogen) degradation products[82] (high concentration of thrombin) and tPA assay[83] (acidified citrate), in which these tubes must be used for accurate results. If a nonstandard tube or a tube not recommended in the manufacturer's test's package insert, then the tube must be validated by the laboratory.

Order of Draw

Current CLSI guidelines recommend on an order for drawing of multiple samples that has become standard practice ([Table 3]).[69] [73] Samples drawn out of sequence for coagulation studies can potentially create interference of the coagulation test and generate a false result. As an example, in an unpublished study, sodium citrate tubes were contaminated in approximately 1 in 30 to 40 tubes if a green top tube with liquid heparin was used prior to drawing the sodium citrate tube and approximately 1 in 75 to 80 tubes were contaminated if a green top tube with dried heparin was drawn prior to the sodium citrate blue top tube. The heparin in the tube can potentially contaminate the blood which in turn contaminates the inside and outside of the needle that is then inserted into the sodium citrate tube, thereby contaminating the patient sample with heparin. Since the level of heparin in heparin-anticoagulated tubes is relatively high (∼10 U), even a small amount of heparin-contaminated blood can cause false prolongation of the next sample collected into sodium citrate.

If only tubes for coagulation studies are to be drawn, no discard tube is necessary.[84] This recommendation is based on results of several studies documenting that coagulation testing may be performed on the first tube without need for a discard tube.[84] This step will eliminate a large amount of biologic waste and likely result in reasonable cost savings for most laboratories.[84] However, a discard tube may be needed if a butterfly system is used, as the first tube collected will generally be underfilled because of the residual air in the collection tube system.

Fill Volume and Hematocrit Adjustment

Sodium citrate (3.2%) is the most widely used anticoagulant for coagulation (clotting-based) studies. Fill volume of sodium citrate tubes, and ratio of sodium citrate:plasma of the patient are critical preanalytical issues associated with blood collection. When the fill volume is incomplete, or the patient hematocrit is significant elevated (> 55%), the excess citrate in the plasma sample would potentially inhibit clot formation in the clotting test. As the calcium bound by citrate is replaced within the reagents of the clotting tests (e.g., PT, aPTT), excess citrate present in the test plasma (secondary to a low fill volume or high hematocrit), would bind the reagent calcium, producing artifactually prolonged clotting time values.[69] [73] [78] [80] Current guidelines dictate that the proportion of blood to anticoagulant volume be a ratio of 9:1.[69] [73] However, the literature demonstrates that some underfilling can be tolerated with tube being filled down to approximately 80% of the required volume for PT and approximately 90% for aPTT without a clinically significant effect.[69] [73] [78] Thus, some short sampling in tubes in patients, especially those with low hematocrits, may not be clinically significant, unless measuring for anticoagulant effect (heparin, DOAC, DTI), as the anticoagulant result may be artifactually decreased due to the dilution effect of low hematocrit and excess sodium citrate liquid volume.[85] However, the general rule of thumb is to reject citrate anticoagulant tube fills that fall below 90%, and the laboratory must follow the manufacturer's recommendations for acceptable tolerance of both low hematocrit and underfilling of tubes. Any acceptance and testing of samples from underfilled blood collection tubes, or blood collection tubes not meeting manufacturer blood collection recommendations, must be locally validated and then approved by a pathologist, or designate, as defined by the local institution or regional regulatory protocols.

Samples with high hematocrits (> 55%, like those found in neonates, severe dehydration, burn patients, polycythemia vera, high altitude temporary stay or residents) may result in factitiously high clotting times due to excess citrate in the sample relative to the residual plasma fluid in the sample; this “excess citrate” will bind the calcium that is added to the clotting assay via the testing reagent.[69] [73] [86] To circumvent this issue of inaccurate clotting results due to high hematocrit, the laboratory can create vacuum tubes with a reduced volume of anticoagulant, for example, by taking a very small gauge needle and removing 20% volume of the anticoagulant (without removing the vacuum).[86] These tubes can be stored in the laboratory and sent to the phlebotomist drawing the patient when the patient has a hematocrit > 55%. Before using these modified tubes, however, the laboratory must first validate that the modified tubes work. Alternative, the cap may be removed, the appropriate citrate amount removed, and the tube recapped. However, without vacuum, these tubes must be manually filled using the aforementioned syringe techniques.

Specimen Transportation and Stability

The transportation and processing of blood specimens for coagulation testing encompasses a critical set of preanalytic variables. These variables can and do have dramatic effects on results, which in turn can have serious consequences for patient care. Current guidelines differ in how long the sample is stable, at what temperature, and in what condition based on the named assay.[6] [69] These stability criteria also change depending on whether the patient is anticoagulated or not, and with what type of anticoagulant. The current recommendations for specimens for PT assays indicate these are remarkably stable up to 24 hours independent of processing methods (centrifuged or not), storage temperature (refrigeration or room temperature), and patient groups.[69] [73] The integrity of aPTT samples, unlike the PT, is dependent on both processing conditions and the presence of anticoagulant, especially UFH. The aPTT and anti-FXa monitoring of UFH, or anti-FXa measurement of DOAC, are all sensitive to time and processing methods when used to monitor anticoagulant therapy.[69] [73] [85] The requirement for samples suspected to contain UFH is to collect and process these within 1 hour, as samples containing UFH showed a clinically significant shortening of the aPTT in noncentrifuged samples stored at room temperature.[87] This critical shortening of aPTT appears to be due to neutralization of heparin by platelet factor 4, a high-affinity heparin-neutralizing protein secreted by stimulated platelets along with other heparin-binding proteins.[87]

Current guidelines specify that specimens for routine aPTT assays on nonheparinized patients must be tested within 4 hours of specimen collection, whether centrifuged or kept as whole blood at either 2 to 4°C or room temperature.[69] [73] [87] Centrifugation improves sample stability and, once centrifuged, stability is not substantially influenced by temperature.[87] It is also recommended that specimens submitted for other assays (factor assays, PC, VWF studies) be processed and stored within the 4-hour time limit.[69] [73] Testing of DTIs including dabigatran must be tested within 2 hours if using the thrombin time or a direct anti-FIIa chromogenic assay.[88] [89] This guidance should be followed unless superseded by the manufacturer's package insert or other manufacturer's guidance documents or as otherwise validated by laboratories for their own situation. Of note, there has been considerable investigation of stability of whole blood samples, with results that appear to show samples may be more robust than CLSI recommendations.[3] Each laboratory must investigate and document their rationale for implementing alternative sample stability limits that exceed CLSI or manufacturer recommendations.

For all testing not completed within 24 hours for PT and 4 hours for aPTT and other assays, it is recommend removing the plasma from the cells and storing it frozen in secondary plastic tubes with appropriate labeling.[69] [73] Specimens may be kept at –20°C for up to 2 weeks or –70°C for up to 6 months.[69] [73] [87] [88] Samples should be rapidly thawed at 37°C until all of the components return to solution (shortest duration possible).[87] [88]

For samples being drawn by home health care personnel, coagulation samples must be maintained at the temperatures required for all coagulation samples. Therefore, home health care personnel must ensure that the samples remain within the ambient temperature (21–24°C) requirement and not sitting in a hot car during summer or in the cold during winter. For whole blood samples being transported some distance (e.g., automobiles), it has been demonstrated that tubes maintained in a vertical position (e.g., in a rack) will reduce samples agitation and preserve PT and INR result accuracy.[90]

Pneumatic tube systems can generally be used to move anticoagulated whole blood specimens from the hospital patient floors to the laboratory for coagulation tests and standard TEG or ROTEM studies, but not for platelet function analysis, including POC platelet function testing, platelet aggregation studies, or THEG platelet function testing (e.g., TEG platelet mapping).[91] [92] [93]

Citrated whole blood tubes to be used for platelet function studies (“platelet aggregation”) and associated TEG, ROTEM, and Multiplate whole blood aggregometry studies should be collected as described above, but must sit at room temperature for 30 minutes to allow re-equilibration and return of normal platelet function, but no longer than 2 to 4 hours, after which platelet function deteriorates.[94] [95]

Specimen Processing and Storage

Centrifugation of Specimens

All blood specimens for coagulation tests (except whole blood POC methods, platelet function studies, and TEG or ROTEM) utilize platelet-poor plasma (PPP). PPP is defined as having < 10,000 platelets/µL (10 × 10⁹/L).[69] [73] [96] [97] PPP is required because platelets, as the last cell component to be removed from the plasma, can interfere with coagulation tests when they rupture or activate. This is especially true if the plasma sample is frozen and subsequently thawed for testing. The centrifugation parameters to remove the platelets depends on the speed of the centrifuge, radius of the centrifuge arm (both determine the “g” force), and the time of centrifugation.[69] [73] Therefore, essentially each centrifuge generates a different g force varying the time of centrifugation to obtain the desired PPP. Usually in large standard centrifuges, the g force is 10,000 g with a centrifugation time of 10 minutes. However, rapid centrifugation with smaller centrifuges with higher g forces and short centrifugation times (e.g., around 3 minutes) are available.[69] [73] [98] Each laboratory must determine the centrifugal force (g force values) and time required to obtain the desired PPP, defined as < 10 × 10⁹/L platelets.[69] [73] Each laboratory must periodically evaluate their centrifuge (both g force and time) to determine that their samples are still considered platelet-poor. Most accreditation organizations require this period evaluation from annually to 12 times per year. Some guidelines state that platelet counts of up to 200 × 10⁹/L is acceptable for immediate routine testing; however, these samples cannot be used for additional or specialized testing or cannot be frozen for later testing.[69] [73] Samples to be used for specialized testing are usually frozen, in which case the original sample should be centrifuged according to the standard laboratory procedure, the plasma removed, and added to a multi-identified labeled secondary tube and the plasma recentrifuged to remove all residual platelets.[69] [73] The platelet-free plasma is then removed from the secondary tube and added to a multi-identified labeled storage tube and the sample immediately frozen for storage. This “double-centrifugation” process also requires periodic checks of the final plasma sample to ensure the sample is sufficiently platelet-poor (again, < 10 × 10⁹/L platelets).[69] [73] Episodically (at least annually and/or after centrifuge maintenance or repair) verifying and documenting the centrifuge performance for achieving PPP by testing plasma platelet count after centrifugation process is required.

Light transmission platelet aggregation requires not only PPP but also platelet-rich plasma (PRP; plasma enriched with a high platelet count).[94] For this testing, the PRP is made by a slower centrifugation of the whole blood sample to remove the red blood cells (RBCs) and the majority of white blood cells (WBCs), while retaining the smaller platelets in solution. Again the “g” force and time is dependent on the centrifugation instrument and the time to remove the RBCs and WBCs. The PPP is made as per the previous paragraph and can be made from the sample in which the PRP has been removed.

Sample Preparation and Pooling

Most routine testing is performed in the primary (i.e., original) tube after centrifugation. After initial testing, some accreditation organizations or hospital/laboratory policy may require keeping samples for a specified time, either for add-on tests or for identification checking. If for add-on tests, then storage of the primary tube at 4°C is recommended for up to 24 hours (however, it should be noted that results for samples containing UFH may not be accurate).

If the tube is small and will not fit onto the instrument or the sample is being prepared for specialized tests or add-on tests, then sample must be removed from the primary tube, and spun a second time, as detailed in the preceding section, to ensure the sample is platelet-free prior to freezing. Use of secondary tubes labeled with multiple identifiers and the time and date of collection is required. If more than one primary tube is obtained and plasma samples are aliquoted and frozen, then the recommendation is that each primary tube should be independently double-centrifuged and individually aliquoted into their own secondary tube (i.e., plasma samples from different tubes should not be pooled and then aliquoted). This is since if one of the tubes has an issue (clotted, hemolyzed, etc.) then the whole specimen is considered to be unusable and must be discarded.

Frozen Sample Storage and Thawing

Plasma samples that have been properly prepared and labeled should be stored in special tubes (cryovials or appropriate plastic that will not crack or leak) with a cap that will remain on even at very low temperatures.[69] [73] [99] [100] Plasma samples should be aliquoted in volumes that allow for optimum testing of the specialized tests (e.g., either 0.5 or 1.0 mL aliquots, as appropriate for each laboratory). Once prepared, sample vials should be frozen in the freezer in which they will be stored. The freezer of choice is a –70 or –80°C nonfrost-free ultra-low freezer in which samples can be stored for 6 months.[99] [100] If the laboratory does not have an ultra-low freezer, plasma samples can be stored at –20°C for 2 weeks for further testing and/or send out tests,[99] [100] but refer to manufacturer's package insert or other test instructions to assure test stability at this temperature. Cyclic frost-free freezers should in general not be used, as this cyclic event generates repeated freeze-thaws that adversely affect enzymes and clotting factors. Thus, test results from samples stored in such freezers will not be accurate. An inventory storage system is recommended for laboratories that receive numerous samples per week for testing or send out. Freezing sample vials in dry ice is not recommended as the plasma sample may experience a change in pH which may affect the results of coagulation tests.[101]

Sample vials (with caps on) are thawed in a 37°C water bath with gentle mixing (inverting or gentle vortex, but not extensive or vigorous vortexing) for the minimal time needed to completely dissolve the plasma sample. As the sample thaws, the final component that goes into solution is the cryoprecipitate. Usually the thawing process takes approximately 5 to 7 minutes. The sample should not be allowed to sit in the 37°C water bath for an extended period of time as some labile factors (FVIII, FV, etc.) will start to decay, producing erroneously low values and falsely prolonged clotting times.[69] [73] [99] [100]

Specimen Condition—Hemolysis, Lipemia, and Icterus

Hemolysis, lipemia, and icterus may affect the accurate reading of a coagulation assay, especially when optical methods are used. Plausible reasons for optical instrument challenges with increased levels of hemolysis and bilirubin are spectral overlap and light scatter associated with lipid particles. Analyzers that have secondary wavelength (> 650 nm) can accurately assess hyperbilirubinemia samples and may improve readings for lipemic samples.[102] Mechanical removal of lipids (e.g., ultracentrifugation or solvents) have also been described,[102] but this is time consuming, not all laboratories have access to such centrifuges/solvents, and such samples should be processed and run in parallel with native samples to assure no biases associated with the lipid removal process.

Icterus may additionally interfere with chromogenic assays (e.g., AT activity), and results need to be interpreted with caution. Refer to reagent package inserts for further information about bilirubin levels and effect on individual chromogenic assays.

Hemolysis may indicate a poorly collected sample, but one must first rule out in vitro hemolysis (e.g., alcohol toxicity, sepsis). To easily differentiate, ex vivo hemolysis is associated with markedly elevated potassium levels and normal lactate dehydrogenase (LDH). Conversely, hemolysis that occurs in vivo is associated with normal potassium levels and markedly increased LDH. Consult the chemistry department to ascertain sample integrity and subsequent potassium and LDH results. PT is affected by moderate hemolysis using an optical device, but even markedly hemolysis had minimal effect on both the PT and aPTT using a mechanical device.[103] Hemolysis additionally will decrease fibrinogen and AT while factitiously increasing the D-dimer.[103] In a study creating artificial lysis, hemolysis factitiously increased the PT and decreased aPTT and fibrinogen, as well as generate a “dimerized plasmin D fragment” (D-dimer from clot lysis).[104] Unless in vivo hemolysis is confirmed, one should assume the more likely scenario of in vitro hemolysis and recommend a sample recollection. Requesting a recollection of hemolyzed samples, however, may be particular challenging in neonatal or pediatric patients, or when the sample is from a timed request (e.g., UFH drug monitoring), or an outpatient, but the potential for misleading test results may lead to misdiagnoses, dose changes, and other patient mismanagement.

Lastly, hemoglobin-based oxygen carriers are stroma-free products that may be used in patients with severe, life-threatening anemia with contraindications to traditional RBC replacements (e.g., religious beliefs). When transfused in a patient, the patient's plasma will mimic hemolysis, absent elevated LDH, or potassium levels. This pseudohemolysis appearance has been demonstrated to affect the ability of optical reading coagulation analyzers to correctly assess clot-based assays, but chromogenic-based assays may also be affected.[105] [106]

Conclusions and Recommendations

As we have described, there are numerous preanalytical variables associated with coagulation testing that may impact the diagnostic accuracy of a test result. Each laboratorian and clinician must assess and consider the impact of these variables when interpreting coagulation test data. A limitation for most published studies on these includes small sample sizes, but more importantly, limited reagent and instrument combinations. We also note the plausible causes for prolonged PT and aPTT ([Table 4]) as well as plausible causes for decreased PT and aPTT ([Table 5]).

Preanalytical variables may be associated with the patient themselves, specimen collection, specimen transportation, and specimen processing and storage. These can cause significant changes in values obtained from routine and specialized coagulation testing. Failure to recognize or address these preanalytical variables may create factitious test values, resulting in patient mismanagement, including misdiagnosis, improper dosing, and improper treatment. As summarized in this review, these numerous procedural errors, shortcuts, and omissions can lead to erroneous result reporting. Therefore, laboratory procedures must always use the most stringent recommendations and guidelines, including those from reagent or instrument manufacturer, to select and prepare specimens to optimize testing ([Table 6]). Following established guidelines and laboratory procedures that specifically address preanalytical variables may require retraining of all staff that collect, process, store, and test coagulation samples. Strict adherence to these procedures will result in more accurate and reproducible results.

Conflict of Interest

Mr. Gosselin reports personal fees from Siemens Healthcare Diagnostics, during the conduct of the study; personal fees from Grifols Diagnostic Solutions, Machaon Laboratory, Ferrer & Poiret, Garrett & Co., NovoNordisk, outside the submitted work; and Board member of International Council for Standardization in Haematology (ICSH), former board member (2018) of North American Specialized Coagulation Laboratory Association (NASCOLA), former board member (2018) of International Society for Laboratory Hematology (ISLH), former associate editor for J Laboratory Hematol (former as of February 28, 2018).

• References

• 1 Plebani M, Favaloro EJ, Lippi G. Patient safety and quality in laboratory and hemostasis testing: a renewed loop?. Semin Thromb Hemost 2012; 38 (06) 553-558
  Article in Thieme ConnectPubMedGoogle Scholar
• 2 Preston FE, Lippi G, Favaloro EJ, Jayandharan GR, Edison ES, Srivastava A. Quality issues in laboratory haemostasis. Haemophilia 2010; 16 (Suppl. 05) 93-99
  CrossrefPubMedGoogle Scholar
• 3 Adcock Funk DM, Lippi G, Favaloro EJ. Quality standards for sample processing, transportation, and storage in hemostasis testing. Semin Thromb Hemost 2012; 38 (06) 576-585
  Article in Thieme ConnectPubMedGoogle Scholar
• 4 Favaloro EJ, Lippi G, Adcock DM. Preanalytical and postanalytical variables: the leading causes of diagnostic error in hemostasis?. Semin Thromb Hemost 2008; 34 (07) 612-634
  Article in Thieme ConnectPubMedGoogle Scholar
• 5 Bonar R, Favaloro EJ, Adcock DM. Quality in coagulation and haemostasis testing. Biochem Med (Zagreb) 2010; 20: 184-199
  PubMedGoogle Scholar
• 6 Clinical and Laboratory Standards Institute (CLSI). Available at: https://clsi.org/ . Accessed March 09, 2019
  PubMed
• 7 International Organization for Standardization (ISO) document ISO 15189: 2012 . Medical laboratories— particular requirements for quality and competence. International Organization for Standardization, Geneva, Switzerland
  PubMed
• 8 United States Food and Drug Administration (FDA). Bioanalytical method validation guidance for industry. May 2018. Available at: https://www.fda.gov/downloads/Drugs/GuidanceComplianceRegulatoryInformation/Guidances/UCM070107.pdf . Accessed March 2019
  PubMed
• 9 Validation of analytical procedures: Text and methodology Q2(R1). ICH harmonised tripartite guideline. Available at: https://www.ich.org/products/guidelines/quality/article/quality-guidelines.html . Accessed March 2019
  PubMed
• 10 FDA Guidance for Industry Q2B Validation of Analytical Procedures: Methodology. 1996 . Available at: https://www.fda.gov/downloads/drugs/guidances/ucm073384.pdf . Accessed March 2019
  PubMed
• 11 Clinical laboratory improvement amendments of 1988: Final Rule. (42 CFR Part 405) Fed Reg 57:7001-7186. February 1992
  PubMedGoogle Scholar
• 12 Thompson, Michael & Ellison, Stephen & Wood, Roger. (2002). Harmonized guidelines for single-laboratory validation of methods of analysis (IUPAC Technical Report). Pure and Applied Chemistry - PURE APPL CHEM. 74. 835-855. DOI: 10.1351/pac200274050835 [epub ahead of print]
  PubMed
• 13 Magnusson B, Örnemark U. , eds. Eurachem Guide: The Fitness for Purpose of Analytical Methods – A Laboratory Guide to Method Validation and Related Topics. 2nd ed. 2014 . ISBN 978-91-87461-59-0. Available at: www.eurachem.org . Accessed May 27, 2019
  PubMedGoogle Scholar
• 14 Guideline on bioanalytical method validation EMEA/CHMP/EWP/192217/2009 Rev. 1 Corr. 2**. Available at: https://www.ema.europa.eu/en/documents/scientific-guideline/guideline-bioanalytical-method-validation_en.pdf . Accessed March 2019
  PubMed
• 15 Favaloro EJ, Gosselin R, Olson J, Jennings I, Lippi G. Recent initiatives in harmonization of hemostasis practice. Clin Chem Lab Med 2018; 56 (10) 1608-1619
  CrossrefPubMedGoogle Scholar
• 16 Toulon P. Developmental hemostasis: laboratory and clinical implications. Int J Lab Hematol 2016; 38 (Suppl. 01) 66-77
  CrossrefPubMedGoogle Scholar
• 17 Nowak-Göttl U, Limperger V, Kenet G. , et al. Developmental hemostasis: a lifespan from neonates and pregnancy to the young and elderly adult in a European white population. Blood Cells Mol Dis 2017; 67: 2-13
  CrossrefPubMedGoogle Scholar
• 18 Righini M, Nendaz M, Le Gal G, Bounameaux H, Perrier A. Influence of age on the cost-effectiveness of diagnostic strategies for suspected pulmonary embolism. J Thromb Haemost 2007; 5 (09) 1869-1877
  CrossrefPubMedGoogle Scholar
• 19 Giansante C, Fiotti N, Cattin L, Da Col PG, Calabrese S. Fibrinogen, D-dimer and thrombin-antithrombin complexes in a random population sample: relationships with other cardiovascular risk factors. Thromb Haemost 1994; 71 (05) 581-586
  Article in Thieme ConnectPubMedGoogle Scholar
• 20 Favaloro EJ, Soltani S, McDonald J, Grezchnik E, Easton L, Favaloro JW. Reassessment of ABO blood group, sex, and age on laboratory parameters used to diagnose von Willebrand disorder: potential influence on the diagnosis vs the potential association with risk of thrombosis. Am J Clin Pathol 2005; 124 (06) 910-917 Erratum in: Am J Clin Pathol. 2006;125(5):796
  CrossrefPubMedGoogle Scholar
• 21 Favaloro EJ, Soltani S, McDonald J, Grezchnik E, Easton L. Cross-laboratory audit of normal reference ranges and assessment of ABO blood group, gender and age on detected levels of plasma coagulation factors. Blood Coagul Fibrinolysis 2005; 16 (08) 597-605
  CrossrefPubMedGoogle Scholar
• 22 Ng KF. Changes in thrombelastograph variables associated with aging. Anesth Analg 2004; 99 (02) 449-454
  PubMedGoogle Scholar
• 23 Schneider T, Siegemund T, Siegemund R, Petros S. Thrombin generation and rotational thromboelastometry in the healthy adult population. Hamostaseologie 2015; 35 (02) 181-186
  Article in Thieme ConnectPubMedGoogle Scholar
• 24 Chan KL, Summerhayes RG, Ignjatovic V, Horton SB, Monagle PT. Reference values for kaolin-activated thromboelastography in healthy children. Anesth Analg 2007; 105 (06) 1610-1613
  CrossrefPubMedGoogle Scholar
• 25 Favaloro EJ, Soltani S, McDonald J, Grezchnik E, Easton L. Laboratory identification of familial thrombophilia: do the pitfalls exceed the benefits? A reassessment of ABO-blood group, gender, age, and other laboratory parameters on the potential influence on a diagnosis of protein C, protein S, and antithrombin deficiency and the potential high risk of a false positive diagnosis. Lab Hematol 2005; 11 (03) 174-184
  CrossrefPubMedGoogle Scholar
• 26 Haubelt H, Anders C, Vogt A, Hoerdt P, Seyfert UT, Hellstern P. Variables influencing Platelet Function Analyzer-100 closure times in healthy individuals. Br J Haematol 2005; 130 (05) 759-767
  CrossrefPubMedGoogle Scholar
• 27 Lindberg UB, Crona N, Stigendal L, Teger-Nilsson AC, Silfverstolpe G. A comparison between effects of estradiol valerate and low dose ethinyl estradiol on haemostasis parameters. Thromb Haemost 1989; 61 (01) 65-69
  Article in Thieme ConnectPubMedGoogle Scholar
• 28 Blombäck M, Konkle BA, Manco-Johnson MJ, Bremme K, Hellgren M, Kaaja R. ; ISTH SSC Subcommittee on Women's Health Issues. Preanalytical conditions that affect coagulation testing, including hormonal status and therapy. J Thromb Haemost 2007; 5 (04) 855-858
  CrossrefPubMedGoogle Scholar
• 29 Knol HM, Kemperman RF, Kluin-Nelemans HC, Mulder AB, Meijer K. Haemostatic variables during normal menstrual cycle. A systematic review. Thromb Haemost 2012; 107 (01) 22-29
  Article in Thieme ConnectPubMedGoogle Scholar
• 30 Chaireti R, Gustafsson KM, Byström B, Bremme K, Lindahl TL. Endogenous thrombin potential is higher during the luteal phase than during the follicular phase of a normal menstrual cycle. Hum Reprod 2013; 28 (07) 1846-1852
  CrossrefPubMedGoogle Scholar
• 31 Karlsson O, Sporrong T, Hillarp A, Jeppsson A, Hellgren M. Prospective longitudinal study of thromboelastography and standard hemostatic laboratory tests in healthy women during normal pregnancy. Anesth Analg 2012; 115 (04) 890-898
  CrossrefPubMedGoogle Scholar
• 32 Ataullakhanov FI, Koltsova EM, Balandina AN, Serebriyskiy II, Vuimo TA, Panteleev MA. Classic and global hemostasis testing in pregnancy and during pregnancy complications. Semin Thromb Hemost 2016; 42 (07) 696-716
  Article in Thieme ConnectPubMedGoogle Scholar
• 33 Fredrik Blomqvist LR, Strandell AM, Baghaei F, Elisabet Hellgren MS. Platelet aggregation in healthy women during normal pregnancy - a longitudinal study. Platelets 2018; 16: 1-7
  PubMedGoogle Scholar
• 34 Kulkarni AA, Osmond M, Bapir M. , et al. The effect of labour on the coagulation system in the term neonate. Haemophilia 2013; 19 (04) 533-538
  CrossrefPubMedGoogle Scholar
• 35 Tang L, Hu Y. Ethnic diversity in the genetics of venous thromboembolism. Thromb Haemost 2015; 114 (05) 901-909
  Article in Thieme ConnectPubMedGoogle Scholar
• 36 Bryant A, Mhyre JM, Leffert LR, Hoban RA, Yakoob MY, Bateman BT. The association of maternal race and ethnicity and the risk of postpartum hemorrhage. Anesth Analg 2012; 115 (05) 1127-1136
  CrossrefPubMedGoogle Scholar
• 37 Ho P, Ng C, Rigano J. , et al. Significant age, race and gender differences in global coagulation assays parameters in the normal population. Thromb Res 2017; 154: 80-83
  CrossrefPubMedGoogle Scholar
• 38 Flood VH, Gill JC, Morateck PA. , et al. Common VWF exon 28 polymorphisms in African Americans affecting the VWF activity assay by ristocetin cofactor. Blood 2010; 116 (02) 280-286
  PubMedGoogle Scholar
• 39 Duga S, Salomon O. Congenital factor XI deficiency: an update. Semin Thromb Hemost 2013; 39 (06) 621-631
  Article in Thieme ConnectPubMedGoogle Scholar
• 40 van Mens TE, Levi M, Middeldorp S. Evolution of factor V Leiden. Thromb Haemost 2013; 110 (01) 23-30
  Article in Thieme ConnectPubMedGoogle Scholar
• 41 Colombatti R, De Bon E, Bertomoro A. , et al. Coagulation activation in children with sickle cell disease is associated with cerebral small vessel vasculopathy. PLoS One 2013; 8 (10) e78801
  CrossrefPubMedGoogle Scholar
• 42 Hamer M, Gibson EL, Vuononvirta R, Williams E, Steptoe A. Inflammatory and hemostatic responses to repeated mental stress: individual stability and habituation over time. Brain Behav Immun 2006; 20 (05) 456-459
  CrossrefPubMedGoogle Scholar
• 43 Geiser F, Meier C, Wegener I. , et al. Association between anxiety and factors of coagulation and fibrinolysis. Psychother Psychosom 2008; 77 (06) 377-383
  CrossrefPubMedGoogle Scholar
• 44 Geiser F, Conrad R, Imbierowicz K. , et al. Coagulation activation and fibrinolysis impairment are reduced in patients with anxiety and depression when medicated with serotonergic antidepressants. Psychiatry Clin Neurosci 2011; 65 (05) 518-525
  CrossrefPubMedGoogle Scholar
• 45 Horacek J, Maly J, Svilias I. , et al. Prothrombotic changes due to an increase in thyroid hormone levels. Eur J Endocrinol 2015; 172 (05) 537-542
  CrossrefPubMedGoogle Scholar
• 46 Van Zaane B, Squizzato A, Debeij J. , et al. Alterations in coagulation and fibrinolysis after levothyroxine exposure in healthy volunteers: a controlled randomized crossover study. J Thromb Haemost 2011; 9 (09) 1816-1824
  CrossrefPubMedGoogle Scholar
• 47 Erem C, Kocak M, Hacihasanoglu A, Yilmaz M, Saglam F, Ersoz HO. Blood coagulation, fibrinolysis and lipid profile in patients with primary hyperparathyroidism: increased plasma factor VII and X activities and D-Dimer levels. Exp Clin Endocrinol Diabetes 2008; 116 (10) 619-624
  Article in Thieme ConnectPubMedGoogle Scholar
• 48 Ramaker AJ, Meyer P, van der Meer J. , et al. Effects of acidosis, alkalosis, hyperthermia and hypothermia on haemostasis: results of point-of-care testing with the thromboelastography analyser. Blood Coagul Fibrinolysis 2009; 20 (06) 436-439
  CrossrefPubMedGoogle Scholar
• 49 de Maat MP, van Schie M, Kluft C, Leebeek FW, Meijer P. Biological variation of hemostasis variables in thrombosis and bleeding: consequences for performance specifications. Clin Chem 2016; 62 (12) 1639-1646
  CrossrefPubMedGoogle Scholar
• 50 Rudez G, Meijer P, Spronk HM. , et al. Biological variation in inflammatory and hemostatic markers. J Thromb Haemost 2009; 7 (08) 1247-1255
  CrossrefPubMedGoogle Scholar
• 51 Vandiver JW, Vondracek TG. Antifactor Xa levels versus activated partial thromboplastin time for monitoring unfractionated heparin. Pharmacotherapy 2012; 32 (06) 546-558
  CrossrefPubMedGoogle Scholar
• 52 Hartley PS. The diurnal tick-tockery of platelet biology. Platelets 2012; 23 (02) 157-160
  CrossrefPubMedGoogle Scholar
• 53 Talens S, Malfliet JJ, Rudež G. , et al. Biological variation in tPA-induced plasma clot lysis time. Thromb Haemost 2012; 108 (04) 640-646
  Article in Thieme ConnectPubMedGoogle Scholar
• 54 Lordkipanidzé M. Platelet function tests. Semin Thromb Hemost 2016; 42 (03) 258-267
  Article in Thieme ConnectPubMedGoogle Scholar
• 55 Paglieroni TG, Janatpour K, Gosselin R. , et al. Platelet function abnormalities in qualified whole-blood donors: effects of medication and recent food intake. Vox Sang 2004; 86 (01) 48-53
  CrossrefPubMedGoogle Scholar
• 56 Pearson DA, Paglieroni TG, Rein D. , et al. The effects of flavanol-rich cocoa and aspirin on ex vivo platelet function. Thromb Res 2002; 106 (4-5): 191-197
  CrossrefPubMedGoogle Scholar
• 57 Miller GJ. Dietary fatty acids and the haemostatic system. Atherosclerosis 2005; 179 (02) 213-227
  CrossrefPubMedGoogle Scholar
• 58 Sy E, Sklar MC, Lequier L, Fan E, Kanji HD. Anticoagulation practices and the prevalence of major bleeding, thromboembolic events, and mortality in venoarterial extracorporeal membrane oxygenation: a systematic review and meta-analysis. J Crit Care 2017; 39: 87-96
  CrossrefPubMedGoogle Scholar
• 59 Winkler AM. Managing the precarious hemostatic balance during extracorporeal life support: implications for coagulation laboratories. Semin Thromb Hemost 2017; 43 (03) 291-299
  Article in Thieme ConnectPubMedGoogle Scholar
• 60 Bartoli CR, Kang J, Zhang D. , et al. Left ventricular assist device design reduces von Willebrand factor degradation: a comparative study between the HeartMate II and the EVAHEART left ventricular assist system. Ann Thorac Surg 2017; 103 (04) 1239-1244
  CrossrefPubMedGoogle Scholar
• 61 Gosselin R, Dager W, Roberts A. , et al. Effect of telavancin (Vibativ) on routine coagulation test results. Am J Clin Pathol 2011; 136 (06) 848-854
  CrossrefPubMedGoogle Scholar
• 62 Webster PS, Oleson Jr FB, Paterson DL. , et al. Interaction of daptomycin with two recombinant thromboplastin reagents leads to falsely prolonged patient prothrombin time/International Normalized Ratio results. Blood Coagul Fibrinolysis 2008; 19 (01) 32-38
  CrossrefPubMedGoogle Scholar
• 63 Centers for Disease Control and Prevention. Clinical action bulletin. April 2018. Available at: https://content.govdelivery.com/accounts/USCDC/bulletins/1eb9503 . Accessed March 2019
  PubMed
• 64 King N, Tran MH. Long-acting anticoagulant rodenticide (Superwarfarin) poisoning: a review of its historical development, epidemiology, and clinical management. Transfus Med Rev 2015; 29 (04) 250-258
  CrossrefPubMedGoogle Scholar
• 65 Karges HE, Funk KA, Ronneberger H. Activity of coagulation and fibrinolysis parameters in animals. Arzneimittelforschung 1994; 44 (06) 793-797
  PubMedGoogle Scholar
• 66 Stegnar M, Cuderman TV, Bozic M. Evaluation of pre-analytical, demographic, behavioural and metabolic variables on fibrinolysis and haemostasis activation markers utilised to assess hypercoagulability. Clin Chem Lab Med 2007; 45 (01) 40-46
  PubMedGoogle Scholar
• 67 Lima-Oliveira G, Lippi G, Salvagno GL, Montagnana M, Picheth G, Guidi GC. Sodium citrate vacuum tubes validation: preventing preanalytical variability in routine coagulation testing. Blood Coagul Fibrinolysis 2013; 24 (03) 252-255
  CrossrefPubMedGoogle Scholar
• 68 Bowen RA, Adcock DM. Blood collection tubes as medical devices: the potential to affect assays and proposed verification and validation processes for the clinical laboratory. Clin Biochem 2016; 49 (18) 1321-1330
  CrossrefPubMedGoogle Scholar
• 69 Mackie I, Cooper P, Lawrie A, Kitchen S, Gray E, Laffan M. ; British Committee for Standards in Haematology. Guidelines on the laboratory aspects of assays used in haemostasis and thrombosis. Int J Lab Hematol 2013; 35 (01) 1-13
  PubMedGoogle Scholar
• 70 Lima-Oliveira G, Lippi G, Salvagno GL. , et al. Processing of diagnostic blood specimens: is it really necessary to mix primary blood tubes after collection with evacuated tube system?. Biopreserv Biobank 2014; 12 (01) 53-59
  CrossrefPubMedGoogle Scholar
• 71 Chuang J, Sadler MA, Witt DM. Impact of evacuated collection tube fill volume and mixing on routine coagulation testing using 2.5-ml (pediatric) tubes. Chest 2004; 126 (04) 1262-1266
  CrossrefPubMedGoogle Scholar
• 72 Giavarina D, Lippi G. Blood venous sample collection: recommendations overview and a checklist to improve quality. Clin Biochem 2017; 50 (10-11): 568-573
  CrossrefPubMedGoogle Scholar
• 73 CLSI. Collection of Diagnostic Venous Blood Specimens. 7th ed. Standard GP41. Wayne, PA: Clinical and Laboratory Standards Institute; 2017
  Google Scholar
• 74 Ong ME, Chan YH, Lim CS. Observational study to determine factors associated with blood sample haemolysis in the emergency department. Ann Acad Med Singapore 2008; 37 (09) 745-748
  PubMedGoogle Scholar
• 75 Uman LS, Birnie KA, Noel M. , et al. Psychological interventions for needle-related procedural pain and distress in children and adolescents. Cochrane Database Syst Rev 2013; (10) CD005179
  PubMedGoogle Scholar
• 76 World Health Organization. WHO guidelines on drawing blood: best practices in phlebotomy. Available at: https://www.ncbi.nlm.nih.gov/books/NBK138650/pdf/Bookshelf_NBK138650.pdf . Accessed March 2019
  PubMed
• 77 Kang HJ, Han CD, Jahng JS, Ko SO. Blood gas and electrolyte changes after tourniquet application in total knee replacement surgery. Yonsei Med J 1992; 33 (02) 153-158
  CrossrefPubMedGoogle Scholar
• 78 Adcock DM, Kressin DC, Marlar RA. Minimum specimen volume requirements for routine coagulation testing: dependence on citrate concentration. Am J Clin Pathol 1998; 109 (05) 595-599
  CrossrefPubMedGoogle Scholar
• 79 Phelan MP, Reineks EZ, Berriochoa JP. , et al. Impact of use of smaller volume, smaller vacuum blood collection tubes on hemolysis in emergency department blood samples. Am J Clin Pathol 2017; 148 (04) 330-335
  CrossrefPubMedGoogle Scholar
• 80 Adcock DM, Kressin DC, Marlar RA. Effect of 3.2% vs 3.8% sodium citrate concentration on routine coagulation testing. Am J Clin Pathol 1997; 107 (01) 105-110
  CrossrefPubMedGoogle Scholar
• 81 Bovill EG, Terrin ML, Stump DC. , et al. Hemorrhagic events during therapy with recombinant tissue-type plasminogen activator, heparin, and aspirin for acute myocardial infarction. Results of the Thrombolysis in Myocardial Infarction (TIMI), Phase II Trial. Ann Intern Med 1991; 115 (04) 256-265
  CrossrefPubMedGoogle Scholar
• 82 Kadani M. , B N V S S, B M, , et al. Evaluation of plasma fibrinogen degradation products and total serum protein concentration in oral submucous fibrosis. J Clin Diagn Res 2014; 8 (05) ZC54-ZC57
  PubMedGoogle Scholar
• 83 Chapman SN, Mehndiratta P, Johansen MC, McMurry TL, Johnston KC, Southerland AM. Current perspectives on the use of intravenous recombinant tissue plasminogen activator (tPA) for treatment of acute ischemic stroke. Vasc Health Risk Manag 2014; 10: 75-87
  PubMedGoogle Scholar
• 84 Raijmakers MT, Menting CH, Vader HL, van der Graaf F. Collection of blood specimens by venipuncture for plasma-based coagulation assays: necessity of a discard tube. Am J Clin Pathol 2010; 133 (02) 331-335
  CrossrefPubMedGoogle Scholar
• 85 Douxfils J, Ageno W, Samama CM. , et al. Laboratory testing in patients treated with direct oral anticoagulants: a practical guide for clinicians. J Thromb Haemost 2018; 16 (02) 209-219
  CrossrefPubMedGoogle Scholar
• 86 Marlar RA, Potts RM, Marlar AA. Effect on routine and special coagulation testing values of citrate anticoagulant adjustment in patients with high hematocrit values. Am J Clin Pathol 2006; 126 (03) 400-405
  CrossrefPubMedGoogle Scholar
• 87 Salvagno GL, Lippi G, Montagnana M, Franchini M, Poli G, Guidi GC. Influence of temperature and time before centrifugation of specimens for routine coagulation testing. Int J Lab Hematol 2009; 31 (04) 462-467
  CrossrefPubMedGoogle Scholar
• 88 Zürcher M, Sulzer I, Barizzi G, Lämmle B, Alberio L. Stability of coagulation assays performed in plasma from citrated whole blood transported at ambient temperature. Thromb Haemost 2008; 99 (02) 416-426
  Article in Thieme ConnectPubMedGoogle Scholar
• 89 Gosselin RC, Adcock DM, Bates SM. , et al. International Council for Standardization in Haematology (ICSH) recommendations for laboratory measurement of direct oral anticoagulants. Thromb Haemost 2018; 118 (03) 437-450
  Article in Thieme ConnectPubMedGoogle Scholar
• 90 van Geest-Daalderop JH, Mulder AB, Boonman-de Winter LJ, Hoekstra MM, van den Besselaar AM. Preanalytical variables and off-site blood collection: influences on the results of the prothrombin time/international normalized ratio test and implications for monitoring of oral anticoagulant therapy. Clin Chem 2005; 51 (03) 561-568
  CrossrefPubMedGoogle Scholar
• 91 Glas M, Mauer D, Kassas H, Volk T, Kreuer S. Sample transport by pneumatic tube system alters results of multiple electrode aggregometry but not rotational thromboelastometry. Platelets 2013; 24 (06) 454-461
  CrossrefPubMedGoogle Scholar
• 92 Hübner U, Böckel-Frohnhöfer N, Hummel B, Geisel J. The effect of a pneumatic tube transport system on platelet aggregation using optical aggregometry and the PFA-100. Clin Lab 2010; 56 (1-2): 59-64
  PubMedGoogle Scholar
• 93 Wallin O, Söderberg J, Grankvist K, Jonsson PA, Hultdin J. Preanalytical effects of pneumatic tube transport on routine haematology, coagulation parameters, platelet function and global coagulation. Clin Chem Lab Med 2008; 46 (10) 1443-1449
  PubMedGoogle Scholar
• 94 CLSI. Platelet Function Testing by Aggregometry. 1st ed. H58A. Wayne, PA: Clinical and Laboratory Standards Institute; 2008
  Google Scholar
• 95 Chapman K, Favaloro EJ. Time dependent reduction in platelet aggregation using the multiplate analyser and hirudin blood due to platelet clumping. Platelets 2018; 29 (03) 305-308
  CrossrefPubMedGoogle Scholar
• 96 Lippi G, Rossi R, Ippolito L. , et al. Influence of residual platelet count on routine coagulation, factor VIII, and factor IX testing in postfreeze-thaw samples. Semin Thromb Hemost 2013; 39 (07) 834-839
  Article in Thieme ConnectPubMedGoogle Scholar
• 97 Magnette A, Chatelain M, Chatelain B, Ten Cate H, Mullier F. Pre-analytical issues in the haemostasis laboratory: guidance for the clinical laboratories. Thromb J 2016; 14: 49-53
  CrossrefPubMedGoogle Scholar
• 98 Nelson S, Pritt A, Marlar RA. Rapid preparation of plasma for ‘Stat’ coagulation testing. Arch Pathol Lab Med 1994; 118 (02) 175-176
  PubMedGoogle Scholar
• 99 Foshat M, Bates S, Russo W. , et al. Effect of freezing plasma at -20°C for 2 weeks on prothrombin time, activated partial thromboplastin time, dilute Russell viper venom time, activated protein C resistance, and D-dimer levels. Clin Appl Thromb Hemost 2015; 21 (01) 41-47
  CrossrefPubMedGoogle Scholar
• 100 Gosselin RC, Dwyre DW. Determining the effect of freezing on coagulation testing: comparison of results between fresh and once frozen-thawed plasma. Blood Coagul Fibrinolysis 2015; 26 (01) 69-74
  CrossrefPubMedGoogle Scholar
• 101 Odsæter IH, Lian IA, Bratberg K, Mikkelsen G. Dry ice exposure of plasma samples influences pH and lupus anticoagulant analysis. Clin Chem Lab Med 2015; 53 (05) 809-813
  PubMedGoogle Scholar
• 102 Lippi G, Plebani M, Favaloro EJ. Interference in coagulation testing: focus on spurious hemolysis, icterus, and lipemia. Semin Thromb Hemost 2013; 39 (03) 258-266
  Article in Thieme ConnectPubMedGoogle Scholar
• 103 D'Angelo G, Villa C, Tamborini A, Villa S. Evaluation of the main coagulation tests in the presence of hemolysis in healthy subjects and patients on oral anticoagulant therapy. Int J Lab Hematol 2015; 37 (06) 819-833
  CrossrefPubMedGoogle Scholar
• 104 Lippi G, Montagnana M, Salvagno GL, Guidi GC. Interference of blood cell lysis on routine coagulation testing. Arch Pathol Lab Med 2006; 130 (02) 181-184
  PubMedGoogle Scholar
• 105 Jahr JS, Lurie F, Gosselin R, Lin JS, Wong L, Larkin E. Effects of a hemoglobin-based oxygen carrier (HBOC-201) on coagulation testing. Clin Lab Sci 2000; 13 (04) 210-214
  PubMedGoogle Scholar
• 106 Jahr JS, Liu H, Albert OK. , et al. Does HBOC-201 (Hemopure) affect platelet function in orthopedic surgery: a single-site analysis from a multicenter study. Am J Ther 2010; 17 (02) 140-147
  CrossrefPubMedGoogle Scholar

Address for correspondence

• References

• 1 Plebani M, Favaloro EJ, Lippi G. Patient safety and quality in laboratory and hemostasis testing: a renewed loop?. Semin Thromb Hemost 2012; 38 (06) 553-558
  Article in Thieme ConnectPubMedGoogle Scholar
• 2 Preston FE, Lippi G, Favaloro EJ, Jayandharan GR, Edison ES, Srivastava A. Quality issues in laboratory haemostasis. Haemophilia 2010; 16 (Suppl. 05) 93-99
  CrossrefPubMedGoogle Scholar
• 3 Adcock Funk DM, Lippi G, Favaloro EJ. Quality standards for sample processing, transportation, and storage in hemostasis testing. Semin Thromb Hemost 2012; 38 (06) 576-585
  Article in Thieme ConnectPubMedGoogle Scholar
• 4 Favaloro EJ, Lippi G, Adcock DM. Preanalytical and postanalytical variables: the leading causes of diagnostic error in hemostasis?. Semin Thromb Hemost 2008; 34 (07) 612-634
  Article in Thieme ConnectPubMedGoogle Scholar
• 5 Bonar R, Favaloro EJ, Adcock DM. Quality in coagulation and haemostasis testing. Biochem Med (Zagreb) 2010; 20: 184-199
  PubMedGoogle Scholar
• 6 Clinical and Laboratory Standards Institute (CLSI). Available at: https://clsi.org/ . Accessed March 09, 2019
  PubMed
• 7 International Organization for Standardization (ISO) document ISO 15189: 2012 . Medical laboratories— particular requirements for quality and competence. International Organization for Standardization, Geneva, Switzerland
  PubMed
• 8 United States Food and Drug Administration (FDA). Bioanalytical method validation guidance for industry. May 2018. Available at: https://www.fda.gov/downloads/Drugs/GuidanceComplianceRegulatoryInformation/Guidances/UCM070107.pdf . Accessed March 2019
  PubMed
• 9 Validation of analytical procedures: Text and methodology Q2(R1). ICH harmonised tripartite guideline. Available at: https://www.ich.org/products/guidelines/quality/article/quality-guidelines.html . Accessed March 2019
  PubMed
• 10 FDA Guidance for Industry Q2B Validation of Analytical Procedures: Methodology. 1996 . Available at: https://www.fda.gov/downloads/drugs/guidances/ucm073384.pdf . Accessed March 2019
  PubMed
• 11 Clinical laboratory improvement amendments of 1988: Final Rule. (42 CFR Part 405) Fed Reg 57:7001-7186. February 1992
  PubMedGoogle Scholar
• 12 Thompson, Michael & Ellison, Stephen & Wood, Roger. (2002). Harmonized guidelines for single-laboratory validation of methods of analysis (IUPAC Technical Report). Pure and Applied Chemistry - PURE APPL CHEM. 74. 835-855. DOI: 10.1351/pac200274050835 [epub ahead of print]
  PubMed
• 13 Magnusson B, Örnemark U. , eds. Eurachem Guide: The Fitness for Purpose of Analytical Methods – A Laboratory Guide to Method Validation and Related Topics. 2nd ed. 2014 . ISBN 978-91-87461-59-0. Available at: www.eurachem.org . Accessed May 27, 2019
  PubMedGoogle Scholar
• 14 Guideline on bioanalytical method validation EMEA/CHMP/EWP/192217/2009 Rev. 1 Corr. 2**. Available at: https://www.ema.europa.eu/en/documents/scientific-guideline/guideline-bioanalytical-method-validation_en.pdf . Accessed March 2019
  PubMed
• 15 Favaloro EJ, Gosselin R, Olson J, Jennings I, Lippi G. Recent initiatives in harmonization of hemostasis practice. Clin Chem Lab Med 2018; 56 (10) 1608-1619
  CrossrefPubMedGoogle Scholar
• 16 Toulon P. Developmental hemostasis: laboratory and clinical implications. Int J Lab Hematol 2016; 38 (Suppl. 01) 66-77
  CrossrefPubMedGoogle Scholar
• 17 Nowak-Göttl U, Limperger V, Kenet G. , et al. Developmental hemostasis: a lifespan from neonates and pregnancy to the young and elderly adult in a European white population. Blood Cells Mol Dis 2017; 67: 2-13
  CrossrefPubMedGoogle Scholar
• 18 Righini M, Nendaz M, Le Gal G, Bounameaux H, Perrier A. Influence of age on the cost-effectiveness of diagnostic strategies for suspected pulmonary embolism. J Thromb Haemost 2007; 5 (09) 1869-1877
  CrossrefPubMedGoogle Scholar
• 19 Giansante C, Fiotti N, Cattin L, Da Col PG, Calabrese S. Fibrinogen, D-dimer and thrombin-antithrombin complexes in a random population sample: relationships with other cardiovascular risk factors. Thromb Haemost 1994; 71 (05) 581-586
  Article in Thieme ConnectPubMedGoogle Scholar
• 20 Favaloro EJ, Soltani S, McDonald J, Grezchnik E, Easton L, Favaloro JW. Reassessment of ABO blood group, sex, and age on laboratory parameters used to diagnose von Willebrand disorder: potential influence on the diagnosis vs the potential association with risk of thrombosis. Am J Clin Pathol 2005; 124 (06) 910-917 Erratum in: Am J Clin Pathol. 2006;125(5):796
  CrossrefPubMedGoogle Scholar
• 21 Favaloro EJ, Soltani S, McDonald J, Grezchnik E, Easton L. Cross-laboratory audit of normal reference ranges and assessment of ABO blood group, gender and age on detected levels of plasma coagulation factors. Blood Coagul Fibrinolysis 2005; 16 (08) 597-605
  CrossrefPubMedGoogle Scholar
• 22 Ng KF. Changes in thrombelastograph variables associated with aging. Anesth Analg 2004; 99 (02) 449-454
  PubMedGoogle Scholar
• 23 Schneider T, Siegemund T, Siegemund R, Petros S. Thrombin generation and rotational thromboelastometry in the healthy adult population. Hamostaseologie 2015; 35 (02) 181-186
  Article in Thieme ConnectPubMedGoogle Scholar
• 24 Chan KL, Summerhayes RG, Ignjatovic V, Horton SB, Monagle PT. Reference values for kaolin-activated thromboelastography in healthy children. Anesth Analg 2007; 105 (06) 1610-1613
  CrossrefPubMedGoogle Scholar
• 25 Favaloro EJ, Soltani S, McDonald J, Grezchnik E, Easton L. Laboratory identification of familial thrombophilia: do the pitfalls exceed the benefits? A reassessment of ABO-blood group, gender, age, and other laboratory parameters on the potential influence on a diagnosis of protein C, protein S, and antithrombin deficiency and the potential high risk of a false positive diagnosis. Lab Hematol 2005; 11 (03) 174-184
  CrossrefPubMedGoogle Scholar
• 26 Haubelt H, Anders C, Vogt A, Hoerdt P, Seyfert UT, Hellstern P. Variables influencing Platelet Function Analyzer-100 closure times in healthy individuals. Br J Haematol 2005; 130 (05) 759-767
  CrossrefPubMedGoogle Scholar
• 27 Lindberg UB, Crona N, Stigendal L, Teger-Nilsson AC, Silfverstolpe G. A comparison between effects of estradiol valerate and low dose ethinyl estradiol on haemostasis parameters. Thromb Haemost 1989; 61 (01) 65-69
  Article in Thieme ConnectPubMedGoogle Scholar
• 28 Blombäck M, Konkle BA, Manco-Johnson MJ, Bremme K, Hellgren M, Kaaja R. ; ISTH SSC Subcommittee on Women's Health Issues. Preanalytical conditions that affect coagulation testing, including hormonal status and therapy. J Thromb Haemost 2007; 5 (04) 855-858
  CrossrefPubMedGoogle Scholar
• 29 Knol HM, Kemperman RF, Kluin-Nelemans HC, Mulder AB, Meijer K. Haemostatic variables during normal menstrual cycle. A systematic review. Thromb Haemost 2012; 107 (01) 22-29
  Article in Thieme ConnectPubMedGoogle Scholar
• 30 Chaireti R, Gustafsson KM, Byström B, Bremme K, Lindahl TL. Endogenous thrombin potential is higher during the luteal phase than during the follicular phase of a normal menstrual cycle. Hum Reprod 2013; 28 (07) 1846-1852
  CrossrefPubMedGoogle Scholar
• 31 Karlsson O, Sporrong T, Hillarp A, Jeppsson A, Hellgren M. Prospective longitudinal study of thromboelastography and standard hemostatic laboratory tests in healthy women during normal pregnancy. Anesth Analg 2012; 115 (04) 890-898
  CrossrefPubMedGoogle Scholar
• 32 Ataullakhanov FI, Koltsova EM, Balandina AN, Serebriyskiy II, Vuimo TA, Panteleev MA. Classic and global hemostasis testing in pregnancy and during pregnancy complications. Semin Thromb Hemost 2016; 42 (07) 696-716
  Article in Thieme ConnectPubMedGoogle Scholar
• 33 Fredrik Blomqvist LR, Strandell AM, Baghaei F, Elisabet Hellgren MS. Platelet aggregation in healthy women during normal pregnancy - a longitudinal study. Platelets 2018; 16: 1-7
  PubMedGoogle Scholar
• 34 Kulkarni AA, Osmond M, Bapir M. , et al. The effect of labour on the coagulation system in the term neonate. Haemophilia 2013; 19 (04) 533-538
  CrossrefPubMedGoogle Scholar
• 35 Tang L, Hu Y. Ethnic diversity in the genetics of venous thromboembolism. Thromb Haemost 2015; 114 (05) 901-909
  Article in Thieme ConnectPubMedGoogle Scholar
• 36 Bryant A, Mhyre JM, Leffert LR, Hoban RA, Yakoob MY, Bateman BT. The association of maternal race and ethnicity and the risk of postpartum hemorrhage. Anesth Analg 2012; 115 (05) 1127-1136
  CrossrefPubMedGoogle Scholar
• 37 Ho P, Ng C, Rigano J. , et al. Significant age, race and gender differences in global coagulation assays parameters in the normal population. Thromb Res 2017; 154: 80-83
  CrossrefPubMedGoogle Scholar
• 38 Flood VH, Gill JC, Morateck PA. , et al. Common VWF exon 28 polymorphisms in African Americans affecting the VWF activity assay by ristocetin cofactor. Blood 2010; 116 (02) 280-286
  PubMedGoogle Scholar
• 39 Duga S, Salomon O. Congenital factor XI deficiency: an update. Semin Thromb Hemost 2013; 39 (06) 621-631
  Article in Thieme ConnectPubMedGoogle Scholar
• 40 van Mens TE, Levi M, Middeldorp S. Evolution of factor V Leiden. Thromb Haemost 2013; 110 (01) 23-30
  Article in Thieme ConnectPubMedGoogle Scholar
• 41 Colombatti R, De Bon E, Bertomoro A. , et al. Coagulation activation in children with sickle cell disease is associated with cerebral small vessel vasculopathy. PLoS One 2013; 8 (10) e78801
  CrossrefPubMedGoogle Scholar
• 42 Hamer M, Gibson EL, Vuononvirta R, Williams E, Steptoe A. Inflammatory and hemostatic responses to repeated mental stress: individual stability and habituation over time. Brain Behav Immun 2006; 20 (05) 456-459
  CrossrefPubMedGoogle Scholar
• 43 Geiser F, Meier C, Wegener I. , et al. Association between anxiety and factors of coagulation and fibrinolysis. Psychother Psychosom 2008; 77 (06) 377-383
  CrossrefPubMedGoogle Scholar
• 44 Geiser F, Conrad R, Imbierowicz K. , et al. Coagulation activation and fibrinolysis impairment are reduced in patients with anxiety and depression when medicated with serotonergic antidepressants. Psychiatry Clin Neurosci 2011; 65 (05) 518-525
  CrossrefPubMedGoogle Scholar
• 45 Horacek J, Maly J, Svilias I. , et al. Prothrombotic changes due to an increase in thyroid hormone levels. Eur J Endocrinol 2015; 172 (05) 537-542
  CrossrefPubMedGoogle Scholar
• 46 Van Zaane B, Squizzato A, Debeij J. , et al. Alterations in coagulation and fibrinolysis after levothyroxine exposure in healthy volunteers: a controlled randomized crossover study. J Thromb Haemost 2011; 9 (09) 1816-1824
  CrossrefPubMedGoogle Scholar
• 47 Erem C, Kocak M, Hacihasanoglu A, Yilmaz M, Saglam F, Ersoz HO. Blood coagulation, fibrinolysis and lipid profile in patients with primary hyperparathyroidism: increased plasma factor VII and X activities and D-Dimer levels. Exp Clin Endocrinol Diabetes 2008; 116 (10) 619-624
  Article in Thieme ConnectPubMedGoogle Scholar
• 48 Ramaker AJ, Meyer P, van der Meer J. , et al. Effects of acidosis, alkalosis, hyperthermia and hypothermia on haemostasis: results of point-of-care testing with the thromboelastography analyser. Blood Coagul Fibrinolysis 2009; 20 (06) 436-439
  CrossrefPubMedGoogle Scholar
• 49 de Maat MP, van Schie M, Kluft C, Leebeek FW, Meijer P. Biological variation of hemostasis variables in thrombosis and bleeding: consequences for performance specifications. Clin Chem 2016; 62 (12) 1639-1646
  CrossrefPubMedGoogle Scholar
• 50 Rudez G, Meijer P, Spronk HM. , et al. Biological variation in inflammatory and hemostatic markers. J Thromb Haemost 2009; 7 (08) 1247-1255
  CrossrefPubMedGoogle Scholar
• 51 Vandiver JW, Vondracek TG. Antifactor Xa levels versus activated partial thromboplastin time for monitoring unfractionated heparin. Pharmacotherapy 2012; 32 (06) 546-558
  CrossrefPubMedGoogle Scholar
• 52 Hartley PS. The diurnal tick-tockery of platelet biology. Platelets 2012; 23 (02) 157-160
  CrossrefPubMedGoogle Scholar
• 53 Talens S, Malfliet JJ, Rudež G. , et al. Biological variation in tPA-induced plasma clot lysis time. Thromb Haemost 2012; 108 (04) 640-646
  Article in Thieme ConnectPubMedGoogle Scholar
• 54 Lordkipanidzé M. Platelet function tests. Semin Thromb Hemost 2016; 42 (03) 258-267
  Article in Thieme ConnectPubMedGoogle Scholar
• 55 Paglieroni TG, Janatpour K, Gosselin R. , et al. Platelet function abnormalities in qualified whole-blood donors: effects of medication and recent food intake. Vox Sang 2004; 86 (01) 48-53
  CrossrefPubMedGoogle Scholar
• 56 Pearson DA, Paglieroni TG, Rein D. , et al. The effects of flavanol-rich cocoa and aspirin on ex vivo platelet function. Thromb Res 2002; 106 (4-5): 191-197
  CrossrefPubMedGoogle Scholar
• 57 Miller GJ. Dietary fatty acids and the haemostatic system. Atherosclerosis 2005; 179 (02) 213-227
  CrossrefPubMedGoogle Scholar
• 58 Sy E, Sklar MC, Lequier L, Fan E, Kanji HD. Anticoagulation practices and the prevalence of major bleeding, thromboembolic events, and mortality in venoarterial extracorporeal membrane oxygenation: a systematic review and meta-analysis. J Crit Care 2017; 39: 87-96
  CrossrefPubMedGoogle Scholar
• 59 Winkler AM. Managing the precarious hemostatic balance during extracorporeal life support: implications for coagulation laboratories. Semin Thromb Hemost 2017; 43 (03) 291-299
  Article in Thieme ConnectPubMedGoogle Scholar
• 60 Bartoli CR, Kang J, Zhang D. , et al. Left ventricular assist device design reduces von Willebrand factor degradation: a comparative study between the HeartMate II and the EVAHEART left ventricular assist system. Ann Thorac Surg 2017; 103 (04) 1239-1244
  CrossrefPubMedGoogle Scholar
• 61 Gosselin R, Dager W, Roberts A. , et al. Effect of telavancin (Vibativ) on routine coagulation test results. Am J Clin Pathol 2011; 136 (06) 848-854
  CrossrefPubMedGoogle Scholar
• 62 Webster PS, Oleson Jr FB, Paterson DL. , et al. Interaction of daptomycin with two recombinant thromboplastin reagents leads to falsely prolonged patient prothrombin time/International Normalized Ratio results. Blood Coagul Fibrinolysis 2008; 19 (01) 32-38
  CrossrefPubMedGoogle Scholar
• 63 Centers for Disease Control and Prevention. Clinical action bulletin. April 2018. Available at: https://content.govdelivery.com/accounts/USCDC/bulletins/1eb9503 . Accessed March 2019
  PubMed
• 64 King N, Tran MH. Long-acting anticoagulant rodenticide (Superwarfarin) poisoning: a review of its historical development, epidemiology, and clinical management. Transfus Med Rev 2015; 29 (04) 250-258
  CrossrefPubMedGoogle Scholar
• 65 Karges HE, Funk KA, Ronneberger H. Activity of coagulation and fibrinolysis parameters in animals. Arzneimittelforschung 1994; 44 (06) 793-797
  PubMedGoogle Scholar
• 66 Stegnar M, Cuderman TV, Bozic M. Evaluation of pre-analytical, demographic, behavioural and metabolic variables on fibrinolysis and haemostasis activation markers utilised to assess hypercoagulability. Clin Chem Lab Med 2007; 45 (01) 40-46
  PubMedGoogle Scholar
• 67 Lima-Oliveira G, Lippi G, Salvagno GL, Montagnana M, Picheth G, Guidi GC. Sodium citrate vacuum tubes validation: preventing preanalytical variability in routine coagulation testing. Blood Coagul Fibrinolysis 2013; 24 (03) 252-255
  CrossrefPubMedGoogle Scholar
• 68 Bowen RA, Adcock DM. Blood collection tubes as medical devices: the potential to affect assays and proposed verification and validation processes for the clinical laboratory. Clin Biochem 2016; 49 (18) 1321-1330
  CrossrefPubMedGoogle Scholar
• 69 Mackie I, Cooper P, Lawrie A, Kitchen S, Gray E, Laffan M. ; British Committee for Standards in Haematology. Guidelines on the laboratory aspects of assays used in haemostasis and thrombosis. Int J Lab Hematol 2013; 35 (01) 1-13
  PubMedGoogle Scholar
• 70 Lima-Oliveira G, Lippi G, Salvagno GL. , et al. Processing of diagnostic blood specimens: is it really necessary to mix primary blood tubes after collection with evacuated tube system?. Biopreserv Biobank 2014; 12 (01) 53-59
  CrossrefPubMedGoogle Scholar
• 71 Chuang J, Sadler MA, Witt DM. Impact of evacuated collection tube fill volume and mixing on routine coagulation testing using 2.5-ml (pediatric) tubes. Chest 2004; 126 (04) 1262-1266
  CrossrefPubMedGoogle Scholar
• 72 Giavarina D, Lippi G. Blood venous sample collection: recommendations overview and a checklist to improve quality. Clin Biochem 2017; 50 (10-11): 568-573
  CrossrefPubMedGoogle Scholar
• 73 CLSI. Collection of Diagnostic Venous Blood Specimens. 7th ed. Standard GP41. Wayne, PA: Clinical and Laboratory Standards Institute; 2017
  Google Scholar
• 74 Ong ME, Chan YH, Lim CS. Observational study to determine factors associated with blood sample haemolysis in the emergency department. Ann Acad Med Singapore 2008; 37 (09) 745-748
  PubMedGoogle Scholar
• 75 Uman LS, Birnie KA, Noel M. , et al. Psychological interventions for needle-related procedural pain and distress in children and adolescents. Cochrane Database Syst Rev 2013; (10) CD005179
  PubMedGoogle Scholar
• 76 World Health Organization. WHO guidelines on drawing blood: best practices in phlebotomy. Available at: https://www.ncbi.nlm.nih.gov/books/NBK138650/pdf/Bookshelf_NBK138650.pdf . Accessed March 2019
  PubMed
• 77 Kang HJ, Han CD, Jahng JS, Ko SO. Blood gas and electrolyte changes after tourniquet application in total knee replacement surgery. Yonsei Med J 1992; 33 (02) 153-158
  CrossrefPubMedGoogle Scholar
• 78 Adcock DM, Kressin DC, Marlar RA. Minimum specimen volume requirements for routine coagulation testing: dependence on citrate concentration. Am J Clin Pathol 1998; 109 (05) 595-599
  CrossrefPubMedGoogle Scholar
• 79 Phelan MP, Reineks EZ, Berriochoa JP. , et al. Impact of use of smaller volume, smaller vacuum blood collection tubes on hemolysis in emergency department blood samples. Am J Clin Pathol 2017; 148 (04) 330-335
  CrossrefPubMedGoogle Scholar
• 80 Adcock DM, Kressin DC, Marlar RA. Effect of 3.2% vs 3.8% sodium citrate concentration on routine coagulation testing. Am J Clin Pathol 1997; 107 (01) 105-110
  CrossrefPubMedGoogle Scholar
• 81 Bovill EG, Terrin ML, Stump DC. , et al. Hemorrhagic events during therapy with recombinant tissue-type plasminogen activator, heparin, and aspirin for acute myocardial infarction. Results of the Thrombolysis in Myocardial Infarction (TIMI), Phase II Trial. Ann Intern Med 1991; 115 (04) 256-265
  CrossrefPubMedGoogle Scholar
• 82 Kadani M. , B N V S S, B M, , et al. Evaluation of plasma fibrinogen degradation products and total serum protein concentration in oral submucous fibrosis. J Clin Diagn Res 2014; 8 (05) ZC54-ZC57
  PubMedGoogle Scholar
• 83 Chapman SN, Mehndiratta P, Johansen MC, McMurry TL, Johnston KC, Southerland AM. Current perspectives on the use of intravenous recombinant tissue plasminogen activator (tPA) for treatment of acute ischemic stroke. Vasc Health Risk Manag 2014; 10: 75-87
  PubMedGoogle Scholar
• 84 Raijmakers MT, Menting CH, Vader HL, van der Graaf F. Collection of blood specimens by venipuncture for plasma-based coagulation assays: necessity of a discard tube. Am J Clin Pathol 2010; 133 (02) 331-335
  CrossrefPubMedGoogle Scholar
• 85 Douxfils J, Ageno W, Samama CM. , et al. Laboratory testing in patients treated with direct oral anticoagulants: a practical guide for clinicians. J Thromb Haemost 2018; 16 (02) 209-219
  CrossrefPubMedGoogle Scholar
• 86 Marlar RA, Potts RM, Marlar AA. Effect on routine and special coagulation testing values of citrate anticoagulant adjustment in patients with high hematocrit values. Am J Clin Pathol 2006; 126 (03) 400-405
  CrossrefPubMedGoogle Scholar
• 87 Salvagno GL, Lippi G, Montagnana M, Franchini M, Poli G, Guidi GC. Influence of temperature and time before centrifugation of specimens for routine coagulation testing. Int J Lab Hematol 2009; 31 (04) 462-467
  CrossrefPubMedGoogle Scholar
• 88 Zürcher M, Sulzer I, Barizzi G, Lämmle B, Alberio L. Stability of coagulation assays performed in plasma from citrated whole blood transported at ambient temperature. Thromb Haemost 2008; 99 (02) 416-426
  Article in Thieme ConnectPubMedGoogle Scholar
• 89 Gosselin RC, Adcock DM, Bates SM. , et al. International Council for Standardization in Haematology (ICSH) recommendations for laboratory measurement of direct oral anticoagulants. Thromb Haemost 2018; 118 (03) 437-450
  Article in Thieme ConnectPubMedGoogle Scholar
• 90 van Geest-Daalderop JH, Mulder AB, Boonman-de Winter LJ, Hoekstra MM, van den Besselaar AM. Preanalytical variables and off-site blood collection: influences on the results of the prothrombin time/international normalized ratio test and implications for monitoring of oral anticoagulant therapy. Clin Chem 2005; 51 (03) 561-568
  CrossrefPubMedGoogle Scholar
• 91 Glas M, Mauer D, Kassas H, Volk T, Kreuer S. Sample transport by pneumatic tube system alters results of multiple electrode aggregometry but not rotational thromboelastometry. Platelets 2013; 24 (06) 454-461
  CrossrefPubMedGoogle Scholar
• 92 Hübner U, Böckel-Frohnhöfer N, Hummel B, Geisel J. The effect of a pneumatic tube transport system on platelet aggregation using optical aggregometry and the PFA-100. Clin Lab 2010; 56 (1-2): 59-64
  PubMedGoogle Scholar
• 93 Wallin O, Söderberg J, Grankvist K, Jonsson PA, Hultdin J. Preanalytical effects of pneumatic tube transport on routine haematology, coagulation parameters, platelet function and global coagulation. Clin Chem Lab Med 2008; 46 (10) 1443-1449
  PubMedGoogle Scholar
• 94 CLSI. Platelet Function Testing by Aggregometry. 1st ed. H58A. Wayne, PA: Clinical and Laboratory Standards Institute; 2008
  Google Scholar
• 95 Chapman K, Favaloro EJ. Time dependent reduction in platelet aggregation using the multiplate analyser and hirudin blood due to platelet clumping. Platelets 2018; 29 (03) 305-308
  CrossrefPubMedGoogle Scholar
• 96 Lippi G, Rossi R, Ippolito L. , et al. Influence of residual platelet count on routine coagulation, factor VIII, and factor IX testing in postfreeze-thaw samples. Semin Thromb Hemost 2013; 39 (07) 834-839
  Article in Thieme ConnectPubMedGoogle Scholar
• 97 Magnette A, Chatelain M, Chatelain B, Ten Cate H, Mullier F. Pre-analytical issues in the haemostasis laboratory: guidance for the clinical laboratories. Thromb J 2016; 14: 49-53
  CrossrefPubMedGoogle Scholar
• 98 Nelson S, Pritt A, Marlar RA. Rapid preparation of plasma for ‘Stat’ coagulation testing. Arch Pathol Lab Med 1994; 118 (02) 175-176
  PubMedGoogle Scholar
• 99 Foshat M, Bates S, Russo W. , et al. Effect of freezing plasma at -20°C for 2 weeks on prothrombin time, activated partial thromboplastin time, dilute Russell viper venom time, activated protein C resistance, and D-dimer levels. Clin Appl Thromb Hemost 2015; 21 (01) 41-47
  CrossrefPubMedGoogle Scholar
• 100 Gosselin RC, Dwyre DW. Determining the effect of freezing on coagulation testing: comparison of results between fresh and once frozen-thawed plasma. Blood Coagul Fibrinolysis 2015; 26 (01) 69-74
  CrossrefPubMedGoogle Scholar
• 101 Odsæter IH, Lian IA, Bratberg K, Mikkelsen G. Dry ice exposure of plasma samples influences pH and lupus anticoagulant analysis. Clin Chem Lab Med 2015; 53 (05) 809-813
  PubMedGoogle Scholar
• 102 Lippi G, Plebani M, Favaloro EJ. Interference in coagulation testing: focus on spurious hemolysis, icterus, and lipemia. Semin Thromb Hemost 2013; 39 (03) 258-266
  Article in Thieme ConnectPubMedGoogle Scholar
• 103 D'Angelo G, Villa C, Tamborini A, Villa S. Evaluation of the main coagulation tests in the presence of hemolysis in healthy subjects and patients on oral anticoagulant therapy. Int J Lab Hematol 2015; 37 (06) 819-833
  CrossrefPubMedGoogle Scholar
• 104 Lippi G, Montagnana M, Salvagno GL, Guidi GC. Interference of blood cell lysis on routine coagulation testing. Arch Pathol Lab Med 2006; 130 (02) 181-184
  PubMedGoogle Scholar
• 105 Jahr JS, Lurie F, Gosselin R, Lin JS, Wong L, Larkin E. Effects of a hemoglobin-based oxygen carrier (HBOC-201) on coagulation testing. Clin Lab Sci 2000; 13 (04) 210-214
  PubMedGoogle Scholar
• 106 Jahr JS, Liu H, Albert OK. , et al. Does HBOC-201 (Hemopure) affect platelet function in orthopedic surgery: a single-site analysis from a multicenter study. Am J Ther 2010; 17 (02) 140-147
  CrossrefPubMedGoogle Scholar