Antigen-induced histamine release from blood cells and acceleration of blood coagulation: Inhibition by tame

Abstract Background. Hemostatic tests have been utilized to clarify the blood coagulation potential of both healthy and diseased individuals. They include tests for whole blood and plasma clotting times, coagulation and fibrinolytic factors and, recently, thrombin generation (TG). TG assays provide explicit information and remain the most physiologically-relevant hemostatic tests ex vivo. We have currently been using a TG assay in whole blood, described by Ninivaggi et al. (2012), for the evaluation of several hemostatic agents and disorders of blood coagulation. Methods. Whole blood from either healthy donors or trauma patients was drawn into 3.2% sodium citrate [± 0.1 mg/mL corn trypsin inhibitor (CTI) prior to the assay; prevents contact pathway activation] or into 3.2% sodium citrate/0.1 mg/mL CTI. Selected agents were added to blood prior to recalcification and TG was monitored in a fluorogenic assay. Packed red blood cells (pRBC) from healthy donors were reconstituted with platelet-poor plasma (PPP) and treated with 0.1 mg/mL CTI. TG was monitored in the absence of any exogenous initiation, in the presence of 5 pM TF initiation and also in the presence of synthetic phospholipids. Results. Whole Blood A. Blood from 10 healthy donors was collected into both citrate (with CTI added prior to the assay) and CTI/citrate and TG was monitored ± 5 pM relipidated tissue factor (TF) initiation. In the absence of TF, blood collected into citrate led to a lag phase ~3-fold longer than that in the presence of TF and peak thrombin ~1.4-fold lower. Blood collected into CTI/citrate, in the absence of TF, led to a lag phase ~6.4-fold longer than that in the presence of TF and peak thrombin ~4.3-fold lower. B. Titrations of relipidated TF and FXIa into citrated blood containing CTI led to concentration-dependent changes in the duration of the lag phase. C. Several TG antagonists were evaluated in citrated blood containing CTI triggered with 5 pM TF. a. 0.5 U/mL unfractionated heparin prolonged the lag phase ~2-fold and suppressed the peak thrombin ~3-fold. b. Hemophilia A and B were "induced" via the addition of inhibitory antibodies to FVIII and FIX, respectively, and although the lag phase was not altered both additions led to significant TG suppression with peak thrombin dropping ~3-fold. c. Several thrombin and FXa inhibitors were evaluated at their pharmacologic concentrations. Fondaparinux slightly prolonged the lag phase, whereas dabigatran increased it by 2.6-fold. Rivaroxaban doubled the lag phase while bivalirudin was slightly less efficient. None of these inhibitors had a pronounced effect on the rate and peak value of TG. d. Activated protein C (APC) at 10 nM slightly prolonged the lag phase and suppressed the peak thrombin. D. Citrate blood from a trauma patient was tested for endogenous activity. In the presence of CTI and absence of an initiator, α-TF antibody did not alter TG, indicating the absence of functional TF. α-FXIa antibody prolonged the lag phase and suppressed TG and α-FIXa antibody completely abolished TG, indicating the presence of active FXIa and FIXa. Packed Red Blood Cells (pRBC) In the absence of an initiator, no TG was observed in pRBC/CTI reconstituted with PPP. The addition of 5 pM TF led to TG after ~8 min with a peak value slightly lower than in blood (described in A).The addition of phospholipids did not change the TG profile. Conclusions. This continuous whole blood TG assay requires 15 µL of blood for a triplicate analysis of a single condition and has the potential for the evaluation of TG in disorders relevant to blood coagulation and for the monitoring of treatments administered in response to these disorders. Disclosures Mann: Haematologic Technologies, Inc.: Employment, Equity Ownership; Baxter: Consultancy; Bayer: Consultancy; Biogen IDEC: Consultancy; CSL Behring: Consultancy; Merck: Consultancy; Pfizer: Consultancy; The Medicines Company: Consultancy; XO1: Consultancy; Vascular Solutions: Consultancy; Stago: Consultancy.

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Histamine release from blood cells and serum ECP in patients with asthma, during and after a mild pollen season

Inflammation Research ◽

10.1007/s00011-004-0435-5 ◽

2005 ◽

Vol 54 (S1) ◽

pp. S76-S77

Author(s):

A. Davidsson ◽

B. Schmekel

Keyword(s):

Histamine Release ◽

Blood Cells ◽

Pollen Season

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Blood Coagulation in Arthropods

Blood ◽

10.1182/blood.v6.11.1173.1173 ◽

1951 ◽

Vol 6 (11) ◽

pp. 1173-1198 ◽

Cited By ~ 32

Author(s):

CH. GRÉGOIRE

Keyword(s):

Blood Coagulation ◽

Blood Cells ◽

Phase Contrast ◽

Continuous Process ◽

The Other ◽

Present Material ◽

Plasma Coagulation ◽

Phase Contrast Microscope ◽

Contrast Microscope ◽

Special Category

Abstract 1. Thin films of freshly drawn hemolymph of about 360 insects belonging to 61 different species were observed under the phase contrast microscope and the process of coagulation investigated. Control of the observations by motion picture recordings were performed in a few species. 2. In the hemolymph of all the insects investigated, a category of hyaline hemocytes can easily be recognized under the phase contrast microscope from the other kinds of blood cells. Attempts of identification of these hyaline hemocytes with elements described in the classifications of insect blood cells based on fixation and staining were inconclusive. 3. In the insects in which the blood clotting does not occur, these hyaline hemocytes do not exhibit any important alteration. In species inn which blood coagulation occurs, the cells of this category appear to be highly labile to contact to glass surfaces. They undergo rapid modifications in their structure which play an important if not exclusive part in the initiation of the plasma coagulation. In the present material these alterations are of two kinds, each of them being related to a different appearance of the plasma reaction. They can occur alone or together. 4. In contrast to the hyaline hemocytes, the other categories of blood cells do not take part in the process of coagulation. Scattered or agglutinated at random, they are passively embedded in the coagulum. 5. In the present material, hemolymph coagulation appears to be a continuous process, initiated by alterations taking place in a single category of hemocytes. These alterations are followed by various degrees of plasma coagulation, from a general macroscopic clotting to a limited reaction detectable only under the microscope. 6. The results are at variance with former data in which the coagulation of insect blood was described as being either a cellular agglutination, in which no special part was recognized to be played by a special category of cells, or a plasma coagulation, both considered as two physiologically distinct processes, which can occur independently or together. On the other hand, the present results show an analogy with the type of coagulation described in crustacean blood by Hardy, Tait, Tait and Gunn, in which a special category of cells, Hardy's explosive cells, as distinguished from the other blood cells, has a specific and important part to play.

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