Abstract
Recent years have seen increasing worldwide interest in the use of viscoelastic coagulation monitoring tests, performed using devices such as ROTEM and TEG. The use of such tests to guide haemostatic therapy may help reduce transfusion of allogeneic blood products in bleeding patients and is supported in European guidelines for managing trauma and severe perioperative bleeding. In addition, viscoelastic tests form the basis of numerous published treatment algorithms. However, some publications have stated that viscoelastic tests are not validated. A specific definition of the term validation is lacking and regulatory requirements of the US Food and Drug Administration (FDA) and European Medicines Agency (EMA) have been fulfilled by ROTEM and TEG assays. Viscoelastic tests have been used in pivotal clinical trials, and they are approved for use in most of the world’s countries. Provided that locally approved indications are adhered to, the regulatory framework for clinicians to use viscoelastic tests in routine clinical practice is in place.
Introduction
Perioperative monitoring of blood coagulation is important for diagnosing the potential causes of bleeding and guiding haemostatic therapy [Citation1]. As a result, recent years have seen increasing worldwide interest in the use of viscoelastic coagulation monitoring tests, performed using devices such as ROTEM® (Tem International, Munich, Germany) and TEG® (Haemonetics, Braintree, MA, USA) [Citation2–7]. The annual number of published clinical trials involving ROTEM or TEG increased from eight in 2004 to 65 in 2014. Increased future use of viscoelastic tests is anticipated as new devices with increased automation (e.g. ROTEM sigma, TEG 6S) become available. These devices are easier to use and have the potential to increase reproducibility compared with the previous generation of devices, for reasons such as lack of need for accurate pipetting, decreased sensitivity to external vibrations, and electronic quality control before each measurement. The main drawbacks with ROTEM sigma and TEG 6S are the lack of peer-reviewed publications characterizing their performance, and the fact that few clinicians have access to these devices.
It is common for algorithms to be constructed as a means of guiding haemostatic therapy in bleeding patients, and the use of viscoelastic tests in preference to standard laboratory tests as a basis for treatment decisions has been advocated [Citation8]. Such algorithms facilitate individualized goal-directed therapy, with intended improvements such as reduced transfusion of allogeneic blood products, reduced adverse outcomes, reduced mortality and increased cost-effectiveness. Evidence to support this approach exists in cardiac surgery [Citation9,Citation10], trauma [Citation11–13], postpartum haemorrhage [Citation14] and liver transplantation [Citation15–17]. Notably, algorithms developed for TEG or ROTEM are not interchangeable between the two devices. This is because different assays are used with each device, with differences between reagents and their concentrations even for equivalent assays. In addition, it has been shown that when the same reagents are used, clot amplitude results are not consistent across the two devices [Citation18]. Normal ranges and threshold values for intervention are specific to either TEG or ROTEM, necessitating specific algorithms for each device. TEG and ROTEM results are based on arbitrary, preset scales, meaning that they do not measure absolute physical properties of the blood clot such as shear modulus (G) [Citation19].
The use of viscoelastic tests to characterize coagulopathy and guide haemostatic therapy is endorsed in guidelines for managing trauma, postpartum haemorrhage and severe perioperative bleeding [Citation20–23]. A comprehensive UK NHS assessment of viscoelastic tests concluded that they are more effective than standard laboratory tests and cost saving [Citation24]. In 2014, the UK National Institute for Health and Care Excellence (NICE) recommended use of ROTEM and TEG to monitor blood clotting during and after cardiac surgery [Citation25]. In trauma and post-partum haemorrhage, it was recommended that ROTEM and TEG should only be used for research because of uncertainty as to how much benefit they provide in these settings [Citation25]. However, more recent data have demonstrated the effectiveness of viscoelastic testing in trauma and post-partum haemorrhage [Citation14,Citation24,Citation26].
Existing evidence, not only relating to treatment algorithms, shows potential for the use of ROTEM and TEG to reduce transfusion of allogeneic blood products in bleeding patients [Citation9,Citation24,Citation27]. Viscoelastic coagulation tests have also been shown to be cost-saving in both cardiac surgery and trauma [Citation24]. On the other hand, there is an absence of evidence that TEG or ROTEM improves morbidity or mortality in patients with severe bleeding [Citation24,Citation28]. This may be because the devices and assays themselves do not change patient care. Instead, improvements in morbidity and mortality are dependent on clinicians’ interpretation of viscoelastic test results and consequent treatment decisions. The availability of therapeutic agents will also affect outcomes. The design of treatment algorithms based on viscoelastic tests has much greater potential impact on clinical outcomes than the initial decision of whether to use viscoelastic tests.
There is some debate regarding the status of viscoelastic tests and some publications have stated that they are not validated [Citation29–33]. In the most recent of these examples, the authors wrote: ‘However TEG continues to be a second-level hemostasis test due to the lack of its quality assurance procedures and that TEG is not validated, as far as international standards are concerned’ [Citation32]. This text is unclear because no definition of the term ‘international standards’ is provided. However, such statements may lead to the reliability of viscoelastic tests being questioned and cause concern among clinicians applying these tests in clinical practice.
Regulatory requirements for viscoelastic coagulation monitoring tests
For market authorisation of in vitro diagnostic products such as ROTEM and TEG, the FDA require data showing the analytical performance characteristics including bias or inaccuracy, imprecision and the analytical specificity and sensitivity [Citation34]. FDA regulatory requirements for in vitro diagnostic products make no mention of the term ‘validation’.
In vitro diagnostic medical devices (e.g. ROTEM, TEG) are not subject to pre-market authorization by a regulatory authority in Europe, but to a conformity assessment which, for the majority of devices, is carried out under the sole responsibility of the manufacturer [Citation35]. Once certified, devices bear the CE marking which allows them to circulate freely in the EU/EFTA countries and Turkey. The regulations specify that the performance characteristics of in vitro diagnostic medical devices support the intended purpose, and that manufacturer-stated performance is achieved in relation to analytical performance (e.g. accuracy [trueness and precision], bias, sensitivity, specificity, reproducibility) and clinical performance (e.g. diagnostic sensitivity, diagnostic specificity, positive and negative predictive value). No specific requirements for validation are mentioned in the EU regulations for in vitro diagnostic medical devices [Citation35].
Calibration is necessary to ensure the accuracy of devices providing quantitative information (e.g. measuring the concentration of a specific protein in plasma). It is also a consideration with the ROTEM and TEG devices but, because viscoelastic methods are semi-quantitative, formal calibration such as proficiency testing or inter-laboratory comparison is not a prerequisite. TEG 5000 devices are calibrated twice a year using biological controls [Citation36], and this could be considered as an alternative assessment protocol in line with practices recommended by the Clinical and Laboratory Standards Institute [Citation37]. ROTEM devices are calibrated during manufacture, and subsequent calibration procedures are not considered by the manufacturer to be required.
What is meant by ‘validation’?
‘Assay validation’ implies documented control of the test performance according to predefined criteria, relating for example to precision, linearity, accuracy, robustness, measurement limits. Such validation per se does not improve the assay quality, it simply attests the ‘quality check status’ (i.e. the assay has been quality checked). ‘Clinical validation’ of an assay is different, because it requires the assessment of relevance to clinical practice. Key considerations include comparability of the results with previous results, and evaluation of the effects of factors that may be encountered in clinical practice (e.g. variations in patient characteristics).
According to the US Food and Drug Administration (FDA), ‘Analytical method validation is the process of demonstrating that an analytical procedure is suitable for its intended purpose’ [Citation38]. The FDA also states that ‘Validation data must be generated under a protocol approved by the sponsor following current good manufacturing practices with the description of methodology of each validation characteristic and predetermined and justified acceptance criteria, using qualified instrumentation’ [Citation38]. The European Medicines Agency (EMA) has defined validation with similar wording to the FDA: ‘The objective of validation of an analytical procedure is to demonstrate that it is suitable for its intended purpose’ [Citation39].
Although not included within the definition of validation, methods for viscoelastic coagulation monitoring must be shown to meet applicable international standards to be considered as validated. For example, ISO 13485 sets out the requirements for quality management systems relating to medical devices, and IEC 62304 specifies the software requirements. With comprehensive assessment of accuracy, precision, interference, reagent stability, and reference ranges as well as software validation, both ROTEM and TEG devices have been shown to meet all such applicable standards. The intention of quality control procedures is to ensure consistent, accurate device performance. The need for standardization of viscoelastic coagulation tests, with regular external quality assessment to ensure accurate results, has been highlighted in the literature [Citation40–42]. Coefficients of variation require measurement using both intra and inter-laboratory samples. However, standardization is complicated by the fact that plasma would typically be used for this purpose, while in clinical practice the viscoelastic coagulation tests are performed using whole blood.
Have the viscoelastic tests been validated?
The ROTEM and TEG systems and their assays have been CE marked, ISO certified and FDA approved. Market authorization has therefore been granted in most of the world’s countries. To achieve this recognition, performance has been evaluated in accordance with the requirements outlined above. Both devices are routinely used in many centres to guide administration of haemostatic therapy, and both devices have been used in pivotal licensing trials [Citation43–45]. Therefore, it is reasonable to state that the FDA and EMA definitions of validation (‘suitable for intended purpose’) have been met for both ROTEM and TEG. For the regulatory approval, performance characteristics of the devices were demonstrated, meaning that ‘assay validation’ has been achieved. Further evidence of assay validation for both ROTEM and TEG is available from a significant number of published studies, but it is beyond the scope of this publication to review these in detail.
Considering ‘clinical validation’, the reference method for both ROTEM and TEG is thrombelastography as introduced by Hartert in 1948 [Citation46,Citation47]. The TEG 5000 device uses methodology that is closely based on the apparatus developed by Hartert, and ROTEM assays have been shown to correlate with this method [Citation48–51]. Correlations between viscoelastic test results and standard laboratory measurements have been reported, e.g. between FIBTEM MCF and plasma fibrinogen level [Citation52] and between TEG maximum amplitude and platelet count [Citation53]. However, ROTEM and TEG tests are conducted differently from all standard laboratory coagulation tests, meaning that differences are to be expected. For example, the FIBTEM assay and plasma fibrinogen concentration tests measure different physical properties with different SI units, and fibrinogen is not the only determinant of FIBTEM MCF [Citation54,Citation55]. Therefore, neither the FDA nor the EMA has decreed that any of the standard laboratory coagulation tests should be used as a reference method for ROTEM or TEG tests. Cut-off values for the management of coagulation in settings such as cardiovascular surgery, trauma and obstetric/post-partum haemorrhage have been established in numerous studies conducted with both ROTEM and TEG. Detailed consideration of these data is beyond the scope of this publication.
Conclusion
The use of ROTEM and TEG tests to diagnose coagulopathy and determine haemostatic treatment – commonly when implementing treatment algorithms – is increasing. Such use of these tests is accepted by European and American regulatory bodies, both in clinical trials and routine practice. Although the term ‘validation’ does not have a specific definition in relation to viscoelastic coagulation tests, relevant criteria within EMA and FDA documentation are fulfilled. There is evidence that viscoelastic coagulation tests can help reduce transfusion rates and that they are cost-effective. In addition, bleeding management guidelines support the use of viscoelastic tests. ROTEM and TEG devices/assays have been used in pivotal clinical trials and are approved for use in most of the world’s countries. Provided that locally approved indications are adhered to, the regulatory framework for clinicians to use viscoelastic tests in routine clinical practice is in place.
Acknowledgements
Editorial assistance was provided by Meridian HealthComms Ltd, funded by CSL Behring.
Disclosure statement
Cristina Solomon is an employee of CSL Behring and previously received speaker honoraria and research support from Tem International and CSL Behring, and travel support from Haemoscope Ltd (former manufacturer of TEG). Lars Asmis has received speaker honoraria or research support from Axon Lab, Bayer, Boehringer Ingelheim, CSL Behring, GlaxoSmithKline, Pfizer, Sanofi Aventis and Vifor. Donat R. Spahn has received honoraria or travel support for consulting or lecturing from the following companies: Abbott AG, Baar, Switzerland; AMGEN GmbH, Munich, Germany; AstraZeneca AG, Zug, Switzerland; Bayer (Schweiz) AG, Zürich, Switzerland; Baxter AG, Volketswil, Switzerland; Baxter S.p.A., Roma, Italy; B. Braun Melsungen AG, Melsungen, Germany; Boehringer Ingelheim (Schweiz) GmbH, Basel, Switzerland; Bristol-Myers-Squibb, Rueil-Malmaison Cedex, France, and Baar, Switzerland; CSL Behring GmbH, Hattersheim am Main, Germany, and Berne, Switzerland; Curacyte AG, Munich, Germany; Ethicon Biosurgery, Sommerville, NJ, USA; Fresenius SE, Bad Homburg v.d.H., Germany; Galenica AG, Bern, Switzerland (including Vifor SA, Villars-sur-Glâne, Switzerland); GlaxoSmithKline GmbH & Co. KG, Hamburg, Germany; Janssen-Cilag AG, Baar, Switzerland; Janssen-Cilag EMEA, Beerse, Belgium; Merck Sharp & Dohme AG, Luzern, Switzerland; Novo Nordisk A/S, Bagsvärd, Denmark; Octapharma AG, Lachen, Switzerland; Organon AG, Pfäffikon/SZ, Switzerland; Oxygen Biotherapeutics, Costa Mesa, CA, USA; Photonics Healthcare GmbH, Munich, Germany; ratiopharm Arzneimittel Vertriebs-GmbH, Vienna, Austria; Roche Diagnostics International Ltd, Reinach, Switzerland; Roche Pharma (Schweiz) AG, Reinach, Switzerland; Schering-Plough International, Inc., Kenilworth, NJ, USA; Tem International GmbH, Munich, Germany; Verum Diagnostica GmbH, Munich, Germany; Vifor Pharma Deutschland GmbH, Munich, Germany; Vifor Pharma Österreich GmbH, Vienna, Austria; and Vifor (International) AG, St. Gallen, Switzerland.
References
- Kozek-Langenecker SA. Perioperative coagulation monitoring. Best Pract Res Clin Anaesthesiol 2010;24:27–40.
- Coelho MC, Vieira Neto L, Kasuki L, Wildemberg LE, Santos CV, Castro G, Gouvea G, Veloso OC, Gadelha T, Gadelha MR. Rotation thromboelastometry and the hypercoagulable state in Cushing's syndrome. Clin Endocrinol (Oxf) 2014;81:657–64.
- Ghavidel AA, Toutounchi Z, Shahandashti FJ, Mirmesdagh Y. Rotational thromboelastometry in prediction of bleeding after cardiac surgery. Asian Cardiovasc Thorac Ann 2015;23:525–9.
- Sawhney C, Subramanian A, Kaur M, Anjum A, Albert V, Soni KD, Kumar A. Assessment of hemostatic changes after crystalloid and colloid fluid preloading in trauma patients using standard coagulation parameters and thromboelastography. Saudi J Anaesth 2013;7:48–56.
- Chen GY, Ou Yang XL, Wu JH, Wang LH, Yang JH, Gu LN, Lu ZJ, Zhao XZ. [Comparison of thromboelastography and routine coagulation tests for evaluation of blood coagulation function in patients]. Zhongguo Shi Yan Xue Ye Xue Za Zhi 2015;23:546–51.
- Da Luz LT, Nascimento B, Shankarakutty AK, Rizoli S, Adhikari NK. Effect of thromboelastography (TEG®) and rotational thromboelastometry (ROTEM®) on diagnosis of coagulopathy, transfusion guidance and mortality in trauma: descriptive systematic review. Crit Care 2014;18:518.
- McDaniel LM, Etchill EW, Raval JS, Neal MD. State of the art: massive transfusion. Transfus Med 2014;24:138–44.
- Weber CF, Zacharowski K, Meybohm P, Adam EH, Hofer S, Brun K, Volk T, Kreuer S. Hemotherapy algorithms for coagulopathic cardiac surgery patients. Clin Lab 2014;60:1059–63.
- Gorlinger K, Dirkmann D, Hanke AA, Kamler M, Kottenberg E, Thielmann M, Jakob H, Peters J. First-line therapy with coagulation factor concentrates combined with point-of-care coagulation testing is associated with decreased allogeneic blood transfusion in cardiovascular surgery: a retrospective, single-center cohort study. Anesthesiology 2011;115:1179–91.
- Weber CF, Gorlinger K, Meininger D, Herrmann E, Bingold T, Moritz A, Cohn LH, Zacharowski K. Point-of-care testing: a prospective, randomized clinical trial of efficacy in coagulopathic cardiac surgery patients. Anesthesiology 2012;117:531–47.
- Nardi G, Agostini V, Rondinelli B, Russo E, Bastianini B, Bini G, Bulgarelli S, Cingolani E, Donato A, Gambale G, Ranaldi G. Trauma-induced coagulopathy: impact of the early coagulation support protocol on blood product consumption, mortality and costs. Crit Care 2015;19:83.
- Schochl H, Nienaber U, Maegele M, Hochleitner G, Primavesi F, Steitz B, Arndt C, Hanke A, Voelckel W, Solomon C. Transfusion in trauma: thromboelastometry-guided coagulation factor concentrate-based therapy versus standard fresh frozen plasma-based therapy. Crit Care 2011;15:R83.
- Spahn DR. TEG®- or ROTEM®-based individualized goal-directed coagulation algorithms: don’t wait – act now! Crit Care 2014;18:637.
- Mallaiah S, Barclay P, Harrod I, Chevannes C, Bhalla A. Introduction of an algorithm for ROTEM-guided fibrinogen concentrate administration in major obstetric haemorrhage. Anaesthesia 2015;70:166–75.
- Leon-Justel A, Noval-Padillo JA, Alvarez-Rios AI, Mellado P, Gomez-Bravo MA, Alamo JM, Porras M, Barrero L, Hinojosa R, Carmona M, Vilches-Arenas A, Guerrero JM. Point-of-care haemostasis monitoring during liver transplantation reduces transfusion requirements and improves patient outcome. Clin Chim Acta 2015;446:277–83.
- Roullet S, Freyburger G, Cruc M, Quinart A, Stecken L, Audy M, Chiche L, Sztark F. Management of bleeding and transfusion during liver transplantation before and after the introduction of a rotational thromboelastometry-based algorithm. Liver Transpl 2015;21:169–79.
- Kirchner C, Dirkmann D, Treckmann JW, Paul A, Hartmann M, Saner FH, Gorlinger K. Coagulation management with factor concentrates in liver transplantation: a single-center experience. Transfusion 2014;54:2760–8.
- Solomon C, Sorensen B, Hochleitner G, Kashuk J, Ranucci M, Schochl H. Comparison of whole blood fibrin-based clot tests in thrombelastography and thromboelastometry. Anesth Analg 2012;114:721–30.
- Hochleitner G, Sutor K, Levett C, Leyser H, Schlimp CJ, Solomon C. Revisiting Hartert's 1962 calculation of the physical constants of thrombelastography. Clin Appl Thromb Hemost 2015. [Epub ahead of print]. doi: 10.1177/1076029615606531.
- Kozek-Langenecker SA, Afshari A, Albaladejo P, Santullano CA, De Robertis E, Filipescu DC, Fries D, Gorlinger K, Haas T, Imberger G, Jacob M, Lance M, Llau J, Mallett S, Meier J, Rahe-Meyer N, Samama CM, Smith A, Solomon C, Van der Linden P, Wikkelso AJ, Wouters P, Wyffels P. Management of severe perioperative bleeding: guidelines from the European Society of Anaesthesiology. Eur J Anaesthesiol 2013;30:270–382.
- Spahn DR, Bouillon B, Cerny V, Coats TJ, Duranteau J, Fernandez-Mondejar E, Filipescu D, Hunt BJ, Komadina R, Nardi G, Neugebauer E, Ozier Y, Riddez L, Schultz A, Vincent JL, Rossaint R. Management of bleeding and coagulopathy following major trauma: an updated European guideline. Crit Care 2013;17:R76.
- American Society of Anesthesiologists Task Force on Perioperative Blood Management. Practice guidelines for perioperative blood management: an updated report by the American Society of Anesthesiologists task force on perioperative blood management. Anesthesiology 2015;122:241–75.
- Collins P, Abdul-Kadir R, Thachil J, The Subcommittees on Women’s Health Issues in Thrombosis and Haemostasis and on Disseminated Intravascular Coagulation. Management of coagulopathy associated with postpartum hemorrhage: guidance from the SSC of the ISTH. J Thromb Haemost 2016;14:205–10.
- Whiting P, Al M, Westwood M, Ramos IC, Ryder S, Armstrong N, Misso K, Ross J, Severens J, Kleijnen J. Viscoelastic point-of-care testing to assist with the diagnosis, management and monitoring of haemostasis: a systematic review and cost-effectiveness analysis. Health Technol Assess 2015;19:1–228.
- National Institute for Health and Care Excellence. Detecting, managing and monitoring haemostasis: viscoelastometric point-of-care testing (ROTEM, TEG and Sonoclot systems). NICE diagnostics guidance [DG13]. 2014. Available from: https://www.nice.org.uk/guidance/dg13 [last accessed February 2016].
- Gonzalez E, Moore EE, Moore HB, Chapman MP, Chin TL, Ghasabyan A, Wohlauer MV, Barnett CC, Bensard DD, Biffl WL, Burlew CC, Johnson JL, Pieracci FM, Jurkovich GJ, Banerjee A, Silliman CC, Sauaia A. Goal-directed hemostatic resuscitation of trauma-induced coagulopathy: a pragmatic randomized clinical trial comparing a viscoelastic assay to conventional coagulation assays. Ann Surg 2015;263:1051–9.
- Schaden E, Kimberger O, Kraincuk P, Baron DM, Metnitz PG, Kozek-Langenecker S. Perioperative treatment algorithm for bleeding burn patients reduces allogeneic blood product requirements. Br J Anaesth 2012;109:376–81.
- Afshari A, Wikkelso A, Brok J, Moller AM, Wetterslev J. Thrombelastography (TEG) or thromboelastometry (ROTEM) to monitor haemotherapy versus usual care in patients with massive transfusion. Cochrane Database Syst Rev 2011;16:CD007871.
- Samama CM, Ozier Y. Near-patient testing of haemostasis in the operating theatre: an approach to appropriate use of blood in surgery. Vox Sang 2003;84:251–5.
- Gaunt C, Woolley T. Management of haemorrhage in major trauma. Contin Educ Anaesth Crit Care Pain 2014;14:251–5.
- Sie P, Steib A. Central laboratory and point of care assessment of perioperative hemostasis. Can J Anaesth 2006;53:S12–20.
- Subramanian A, Albert V, Agrawal D, Saxena R, Pandey RM. Evaluation of the utility of thromboelastography in a tertiary trauma care centre. ISRN Hematol 2014;2014:849626.
- Samama CM. Thromboelastography: the next step. Anesth Analg 2001;92:563–4.
- US Food and Drug Administration. Overview of IVD Regulation. 2015. Available from: http://www.fda.gov/MedicalDevices/DeviceRegulationandGuidance/IVDRegulatoryAssistance/ucm123682.htm#1 [last accessed November 2015].
- European Commission. Proposal for a regulation of the European Parliament and of the council on in vitro diagnostic medical devices. 2012. Available from: http://ec.europa.eu/health/medical-devices/files/revision_docs/proposal_2012_541_en.pdf [last accessed October 2015].
- Haemoscope Corporation. TEG 5000 Thrombelastograph hemostasis system: user manual. 2015. Available from: http://diamedil.info/MediGal/Technical%20Support/PN06-510_TEG_UserManual_v4_3_2008-10.PDF [last accessed November 2015].
- Clinical and Laboratory Standards Institute. Assessment of laboratory tests when proficiency testing is not available; Approved guideline: second edition. 2008. Available from: http://shop.clsi.org/GP29.html [last accessed November 2015].
- US Department of Health and Human Services (Food and Drug Administration). Analytical procedures and methods validation for drugs and biologics – guidance for industry. 2015. Available from: www.fda.gov/downloads/drugs/guidancecomplianceregulatoryinformation/guidances/ucm386366.pdf [last accessed October 2015].
- European Medicines Agency. Validation of analytical procedures: text and methodology. 1995. Available from: http://www.ema.europa.eu/docs/en_GB/document_library/Scientific_guideline/2009/09/WC500002662.pdf [last accessed October 2015].
- Chitlur M, Lusher J. Standardization of thromboelastography: values and challenges. Semin Thromb Hemost 2010;36:707–11.
- Kitchen DP, Kitchen S, Jennings I, Woods T, Walker I. Quality assurance and quality control of thrombelastography and rotational thromboelastometry: the UK NEQAS for blood coagulation experience. Semin Thromb Hemost 2010;36:757–63.
- Marlar RA, Gausman JN, Engel JW. Validation of hemostasis and coagulation assays: recommendations and guidelines. Semin Thromb Hemost 2014;40:186–94.
- ClinicalTrials.gov. Study of fibrinogen concentrate (Human) (FCH) to control bleeding during complex cardiovascular surgery (REPLACE). 2015. Available from: https://clinicaltrials.gov/ct2/show/NCT01475669 [last accessed November 2015].
- Manco-Johnson MJ, Dimichele D, Castaman G, Fremann S, Knaub S, Kalina U, Peyvandi F, Piseddu G, Mannucci P, Fibrinogen Concentrate Study Group. Pharmacokinetics and safety of fibrinogen concentrate. J Thromb Haemost 2009;7:2064–9.
- Rahe-Meyer N, Solomon C, Hanke A, Schmidt DS, Knoerzer D, Hochleitner G, Sorensen B, Hagl C, Pichlmaier M. Effects of fibrinogen concentrate as first-line therapy during major aortic replacement surgery: a randomized, placebo-controlled trial. Anesthesiology 2013;118:40–50.
- Hartert H. [Blutgerinnungsstudien mit der Thrombelastographie; einem neuen Untersuchungs verfahren]. Klin Wochenschr 1948;26:577–83.
- Schöchl H, Solomon C, Voelckel W. Thromboelastometry in the perioperative setting. Neth J Crit Care 2010;14:23–31.
- Calatzis A, Calatzis A, Fritzsche P, Kling M, Hipp R, Stemberger A. An analysis of the correlation of the ROTEG coagulation analyzer and the Hellige Thrombelastograph. D Ann Hematol 1996;72:P87.
- Calatzis A, Kling M, Stemberger A, Calatzis A, Hipp R, Bluemel G. Pitfalls in the application of TEG during liver transplantation and ways to escape. Ann Hematol 1995;70:A21.
- Fritzsche P, Calatzis A, Stemberger A, Calatzis A. The ROTEG-4 coagulation analyzer: technology and precision. Ann Hematol 1998;76:A88.
- Lang T, Bauters A, Braun SL, Potzsch B, von Pape KW, Kolde HJ, Lakner M. Multi-centre investigation on reference ranges for ROTEM thromboelastometry. Blood Coagul Fibrinolysis 2005;16:301–10.
- Haas T, Spielmann N, Mauch J, Madjdpour C, Speer O, Schmugge M, Weiss M. Comparison of thromboelastometry (ROTEM®) with standard plasmatic coagulation testing in paediatric surgery. Br J Anaesth 2012;108:36–41.
- Alexander DC, Butt WW, Best JD, Donath SM, Monagle PT, Shekerdemian LS. Correlation of thromboelastography with standard tests of anticoagulation in paediatric patients receiving extracorporeal life support. Thromb Res 2010;125:387–92.
- Solomon C, Cadamuro J, Ziegler B, Schochl H, Varvenne M, Sorensen B, Hochleitner G, Rahe-Meyer N. A comparison of fibrinogen measurement methods with fibrin clot elasticity assessed by thromboelastometry, before and after administration of fibrinogen concentrate in cardiac surgery patients. Transfusion 2011;51:1695–706.
- Solomon C, Rahe-Meyer N, Schochl H, Ranucci M, Gorlinger K. Effect of haematocrit on fibrin-based clot firmness in the FIBTEM test. Blood Transfus 2013;11:412–18.