by accumulation of pathological mast cells in potentially any or all organs and tissues and/or

1 Supplementary Material to Seidel et al. Bleeding diathesis in patients with mast cell activation disease (Thromb Haemost 2011; 106.5) Definition of mast cell activation disease The term mast cell activation disease (MCAD) denotes a collection of disorders characterized by accumulation of pathological mast cells in potentially any or all organs and tissues and/or aberrant release of variable subsets of mast cell mediators (1, 2). A classification has been proposed which differentiates several types and subclasses of MCAD. The traditionally recognized subclass termed systemic mastocytosis (SM) includes disorders characterized by certain pathological immunohistochemical and mutational findings (the WHO criteria; [3]) which are divided into several subtypes. On the other hand, mast cell activation syndrome (MCAS) presents a complex clinical picture of multiple mast cell mediator-induced symptoms, failure to meet the WHO criteria for diagnosis of SM, and exclusion of relevant differential diagnoses (1, 2, 4-7). Mast cell activation disease in general has long been thought to be rare. However, although SM is truly rare, recent findings suggest MCAS is a fairly common disorder ([2], further references therein). Symptoms observed in patients with MCAS are little, if any, different from those seen in patients with SM ([2], further references therein). The clinical manifestation results from episodic release of both preformed and newly-synthesized mast cell mediators either in response to trigger stimuli or spontaneously. The clinical presentation of MCAD is very diverse, since due to both the widespread distribution of mast cells and the great heterogeneity of aberrant mediator expression patterns, symptoms can occur in virtually all organs and tissues. Moreover, symptoms often occur in a temporally staggered fashion, waxing and waning over years to decades. Patients often have a history of chronic and acute mediator-

2 related symptoms such as pruritus, flushing, tachycardia, palpitations, light-headedness, dizziness, shortness of breath, nausea, diarrhoea and headache. Patients and methods Patients Data from 68 patients (for details, see Fig. 1A) presenting consecutively between May 2005 and April 2008 with MCAD were enrolled in this cross-sectional study. All data were collected as part of the regular routine examination program for patients with MCAD with their consent for use in connection with research projects. Mast cell mediator-related symptoms were recorded in a standardized form by use of a validated checklist (see supplementary text to [8]) which lists the complaint complexes to be considered. The presence of episodic or ongoing systemic mast cell mediator-related symptoms during a period of at least the last 2 years were taken into account. A score value can be calculated to identify the pattern of symptoms caused by the unregulated increased release of mediators from mast cells. Relevant differential diagnoses of a systemic MCAD (a survey is given in [2]) were ruled out by unchanged pathognomonic laboratory parameters, imaging and/or endoscopic methods concerning this matter. Diagnoses given in the present study (for details, see Fig. 1) were made according to the proposed criteria on MCAD (1, 2, 4, 6, 7). Evaluation of hemostasis parameters Bleeding tendency was evaluated from the medical history of each patient using a clinical questionnaire from which a score value was calculated (9, 10). In order to provoke hemostasis by non-pharmacological means in an easily accessible compartment of the body we have applied a well-established venous occlusion stress test (e.g., [11, 12]) with venous occlusion

3 of the upper arm for 10 minutes, using a cuff inflated 10 mmg Hg above diastolic pressure. It can be assumed that hypoxia induced by the stasis of blood flow in the arm could stimulate cells located in this compartment (13); in particular, it might induce an activation of resident mast cells accompanied by a release of mediators which are involved in hemostasis. Venous blood samples were drawn by puncture of cubital veins just before venous occlusion (baseline) and after 10 minutes of venous occlusion. The patients had not taken drugs known to affect blood clotting. Routine diagnostics of bleeding diathesis including detailed analysis of primary (plateletdependent) and secondary hemostasis (blood coagulation including inhibitory mechanisms such as heparin and antithrombin) and fibrinolytic system were performed using standard methods. Venous blood samples for fibrinolysis studies were drawn before (baseline) and after venous occlusion using Stabilyte tubes for tissue-type plasminogen activator activity (tpa) and CTAD tubes for plasminogen activator inhibitor 1 (PAI) activity stabilisation. Concentrations of tpa and PAI antigen, as well as plasmin-antiplasmin (PAP) antigen complexes were determined by ELISA techniques (Technoclone, Austria). For heparin stabilisation in plasma CTAD also was used. Heparin levels were determined by chromogenic anti-factor Xa assay (Dade Behring). Statistics The statistical analysis of the data was performed by means of the program SPSS Statistics 18.0 (SPSS, Chicago, USA). The statistical tests used are given in the discussion of the respective figures. P values less than 0.05 were considered statistically significant.

4 Further aspects of findings of the present study Heparin The elevated heparin levels detected were not accompanied by prolonged APTT values (Suppl. Table S2). This is most likely due to the different sample materials used for heparin determination by chromogenic anti-factor Xa (anti-xa) assay and for APTT determination. The anti-xa assay is done from CTAD plasma containing platelet inhibitors theophylline, adenosine and dipyridamol. The inhibitors prevent the release of heparin neutralizing factors such as platelet factor 4 (PF4) during preanalytic phase before sample centrifugation and, therefore, stabilize the biochemically active form of heparin. For APTT determination standard citrate plasma is regularly used. Herein, heparin is not protected from neutralization by heparin-binding proteins such as PF4. Thus, circulating heparin levels in thromboprophylactic range in standard citrate plasma are most likely inactivated during the preanalytic storage phase before platelets and blood cells are removed by centrifugation (14). Consequently no APTT prolongations were detected in our patients. Furthermore, the APTT determination is based in principle on highly stimulated thrombin generation and subsequently induced fibrin formation. The amount of thrombin generated by the stimulation of intrinsic contact phase activation and the positive thrombin-induced feedback activation of the coagulation cofactors factor VIII and factor V rapidly outbalances the basic factor Xa generation so that heparin levels in the ranges detected in our patients do not significantly influence APTT. In the same way determination of significant APTT prolongation is often missing during thromboprophylaxis by low-dose heparin application. Intrinsic and extrinsic pathways In the present study there is no evidence that the intrinsic (contact factor) pathway or the extrinsic (tissue factor) pathway was consistently altered in MCAD, although there are several individual patients (up to 25% of the patients) in whom pathological values were determined

5 (Suppl. Table S2). These changes may be secondary in nature, i.e. due to action of other mast cell mediators such as histamine and tryptase actions. Additionally, the increase in factor VIII observed in 28% of the patients (Suppl. Table S2) may be due to a release of factor VIII from mast cells by degranulation (15, 16) as well as by stimulation of acute phase reaction by release of mast cell-related mediators leading to increased release of factor VIII from hepatocytes or endothelial cell storage pools. References 1. Valent P, Akin C, Escribano L et al. Standards and standardization in mastocytosis: consensus statements on diagnostics, treatment recommendations and response criteria. Eur J Clin Invest 2007; 37:435-53. 2. Molderings GJ, Brettner S, Homann J et al. Mast cell activation disease: A concise practical guide for diagnostic workup and therapeutic options. J Hematol Oncol 2011; 4:10. 3. Valent P, Horny HP, Escribano L et al. Diagnostic criteria and classification of mastocytosis: a consensus proposal. Leuk Res 2001; 25:603-25. 4 Akin C, Valent P, Metcalfe DD. Mast cell activation syndrome: Proposed diagnostic criteria. J Allergy Clin Immunol 2010; 126:1099-104. 5. Alvarez-Twose I, González de Olano D, Sánchez-Muñoz L et al. Clinical, biological, and molecular characteristics of clonal mast cell disorders presenting with systemic mast cell activation symptoms. J Allergy Clin Immunol 2010; 125:1269-78. 6. Hamilton MJ, Hornick JL, Akin C et al. Mast cell activation syndrome: A newly recognized disorder with systemic clinical manifestations. J Allergy Clin Immunol 2011; 128:147-52. 7. Homann J, Kolck UW, Ehnes A et al. Systemic mastocytosis - definition of an internal disease. Med Klin (Munich) 2010; 105:544-53. 8. Alfter K, von Kügelgen I, Haenisch B et al. New aspects of liver abnormalities as part of

6 the systemic mast cell activation syndrome. Liver Int 2009; 29:181-6. 9. Rodeghiero F, Tosetto A, Castaman G. How to estimate bleeeding risk in mild bleeding disorders. J Thromb Haemost 2007; 5, Suppl. 1:157-66. 10. Albert FW, Eichler H, Haubelt H et al. Haemostatic testing prior to elective surgery? Yes! Hämostaseologie 2009; 29:58-63 11. Amery A, Vermylen J, Maes H et al. Enhancing the fibrinolytic activity in human blood by occlusion of blood vessels. I. The appearance of the phenomenon. Thromb Diath Haemorrh 1962; 7:70-85. 12. Nguyen G, Horellou MH, Kruithof EK et al. Residual plasminogen activator inhibitor activity after venous stasis as a criterion for hypofibrinolysis: a study in 83 patients with confirmed deep vein thrombosis. Blood 1988; 72:601-5. 13. Steiner DR, Gonzalez NC, Wood JG. Mast cells mediate the microvascular inflammatory response to systemic hypoxia. J Appl Physiol 2003; 94:325-34. 14. van den Besselaar AM, Meeuwisse-Braun J, Jansen-Grüter R et al. Monitoring heparin therapy by the activated partial thromboplastin time - the effect of pre-analytical conditions. Thromb Haemost 1987; 57:226-31. 15. Kindblom LG. Factor VIII related antigen and mast cells. Acta Pathol Microbiol Immunol Scand 1982; 90:437-9. 16. Akiyama M, Watanabe Y, Nishikawa T. Immunohistochemical characterization of human cutaneous mast cells in urticaria pigmentosa (cutaneous mastocytosis). Acta Pathol Jpn 1991; 41:344-9.

7 Suppl. Table S1: Peripheral red and white blood count (basal values, i.e. before venous occlusion) Parameter Results (mean ± SEM; n; range) Reference ranges Leukocytes ( x 10 9 /L) 6.9 ± 0.2 (63; 3.4-12) 3-10 Red blood cells (RBC) ( x 10 12 /L) 4.52 ± 0.05 (63; 3.3-5.4) 3.9-5.3 Hemoglobin ( g/dl) 14.0 ± 0.1 (63; 9.6-16.5) 12-16 Hematocrit (L/L) 0.412±0.004 (63; 0.295-0.469) 0.37-0.48 Mean cell volume (MCV, fl) 91.2 ± 0.5 (63; 81.1-99.3) 84-98 Platelets (G/L) 265 ± 8 (63; 87-473) 150-400 Mean platelet volume (fl) 9.0 ± 0.1 (63; 7.4-11.1) 7-11

Suppl. Table S2: Selected parameters of the coagulant system (basal values, i.e. before venous occlusion) 8 Parameter Results (mean ± SEM; n; range) Reference values Number of patients with decreased values Number of patients with increased values APTT (s) 25.9 ± 0.4 (63; 20.1-43.9) 26-34 36 Thrombin time (s) 9.6 ± 0.1 (63; 8.7-12) 9.5-12.5 40 Prothrombin time (Quick %) 112.9 ± 2.1 (63; 19-130) 70-130 1 Factor VIII (%) 129.9 ± 4.5 (63; 68-242) 60-135 18 D-dimer (µg/ml) 0.36 ± 0.10 (62; 0.07-6.65) 0-0.49 5 α 2 -antiplasmin (%) 109.2 ± 1.2 (63; 82-124) 90-110 32 APTT activated partial thrombin time

9 Suppl. Fig. S1: Correlation of the intensity of bleeding tendency estimated by a score value and the increase in tissue plasminogen activator levels detected in blood after venous occlusion. Grades of bleeding severity (modified from [9, 10]): score value 0 - no signs of bleeding; score value 0.5-2.5 signs of trivial bleeding; score value > 2.5 bleeding diathesis. Blue columns: lower than 3-fold increase in tissue plasminogen activator levels after venous occlusion; green columns: more than 3-fold increase in tissue plasminogen activator levels after venous occlusion. Patients with an increase in tissue plasminogen activator levels after venous occlusion lower than 3-fold had significantly lower score values (P<0.05, Fisher s exact test) than patients with more than 3-fold increase in tissue plasminogen activator levels after venous occlusion. Total number of patients included into the analysis: 44.