Mathematical Model of Serine Protease Inhibition in the Tissue Factor Pathway to Thrombin

Leipold, Robert J.; Bozarth, Tracy A.; Racanelli, Adrienne L.; Dicker, Ira B.

doi:10.1074/jbc.270.43.25383

Cited by 30 publications

(22 citation statements)

References 34 publications

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“…The Mathematical Model-The enzyme reactions used in the current model are similar to those described earlier for the mathematical modeling of extrinsically triggered blood coagulation (7,8), except that antithrombin-III and fibrinogen/fibrin are additionally incorporated into the model, but the involvement of meizothrombin described in the previous literatures (7,8) is not considered in the current study. The reaction scheme used in the current model is summarized in Fig.…”

Section: Resultsmentioning

confidence: 99%

“…As indicated in these tables, the parameter values used in the current study are largely derived from the previous literature (8), which also describes a mathematical model of an extrinsic pathway-triggered blood coagulation. The numerical calculation was started by the addition of a small amount of TF:VIIa complex (5 pM), which is assumed to be fully formed at the start of coagulation.…”

Section: Resultsmentioning

confidence: 99%

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Studies on the Different Modes of Action of the Anticoagulant Protease Inhibitors DX-9065a and Argatroban

Nagashima¹

2002

Journal of Biological Chemistry

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Studies on the Different Modes of Action of the Anticoagulant Protease Inhibitors DX-9065a and Argatroban

Nagashima¹

2002

Journal of Biological Chemistry

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“…The mathematical model of TF-initiated thrombin generation in reconstituted systems developed by Jones and Mann [17] was used with modifications by other groups to study the effects of various therapeutic agents and mechanisms of their action. Leipold et al [57] advanced this model to include exogenous serine protease inhibitors with affinity for any or all of coagulation factors VIIa, IXa, Xa, and IIa. Application of the revised model for predicting the affinity profile of the optimal inhibitor and the inhibitory potency of several compounds revealed the following: 1) The predicted thrombin generation times are mostly insensitive to changes in the affinity at the inhibition constant K i >1 nM; 2) However, for compounds with high affinity for both FVIIa and FIXa, inhibition of thrombin generation decreases as the affinity for thrombin increases (K i from 1000 to 5 nM); 3) Inhibitors with affinity for a single serine protease are less potent compared to inhibitors with a spectrum of affinities; 4) Compounds with high affinity for FVIIa, FXa and thrombin are predicted to be highly-potent, regardless of their affinity for FIXa.…”

Section: Drug Design and Therapeutic Strategy Planningmentioning

confidence: 99%

Mathematical Models of Blood Coagulation and Platelet Adhesion: Clinical Applications

Panteleev

Ananyeva²,

Ataullakhanov³

et al. 2007

CPD

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At present, computer-assisted molecular modeling and virtual screening have become effective and widelyused tools for drug design. However, a prerequisite for design and synthesis of a therapeutic agent is determination of a correct target in the metabolic system, which should be either inhibited or stimulated. Solution of this extremely complicated problem can also be assisted by computational methods. This review discusses the use of mathematical models of blood coagulation and platelet-mediated primary hemostasis and thrombosis as cost-effective and time-saving tools in research, clinical practice, and development of new therapeutic agents and biomaterials. We focus on four aspects of their application: 1) efficient diagnostics, i.e. theoretical interpretation of diagnostic data, including sensitivity of various clotting assays to the changes in the coagulation system; 2) elucidation of mechanisms of coagulation disorders (e.g. hemophilias and thrombophilias); 3) exploration of mechanisms of action of therapeutic agents (e.g. recombinant activated factor VII) and planning rational therapeutic strategy; 4) development of biomaterials with non-thrombogenic properties in the design of artificial organs and implantable devices. Accumulation of experimental knowledge about the blood coagulation system and about platelets, combined with impressive increase of computational power, promises rapid development of this field.

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“…Previous coagulation models have typically been formulated as systems of nonlinear ordinary differential equations, using mass action or more complex kinetics, to describe the rates of biochemical conversions [18][19][20][21][22]. Mechanistic ODE coagulation models from our laboratory [23,24] were built upon the earlier studies of Jones and Mann [25], Hockin et al [26], and later Butenas et al [27] who developed and then subsequently refined highly mechanistic coagulation models.…”

Section: Introductionmentioning

confidence: 99%

Dynamic Modeling of the Human Coagulation Cascade Using Reduced Order Effective Kinetic Models

Sagar

Varner

2015

Processes

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In this study, we present a novel modeling approach which combines ordinary differential equation (ODE) modeling with logical rules to simulate an archetype biochemical network, the human coagulation cascade. The model consisted of five differential equations augmented with several logical rules describing regulatory connections between model components, and unmodeled interactions in the network. This formulation was more than an order of magnitude smaller than current coagulation models, because many of the mechanistic details of coagulation were encoded as logical rules. We estimated an ensemble of likely model parameters (N = 20) from in vitro extrinsic coagulation data sets, with and without inhibitors, by minimizing the residual between model simulations and experimental measurements using particle swarm optimization (PSO). Each parameter set in our ensemble corresponded to a unique particle in the PSO. We then validated the model ensemble using thrombin data sets that were not used during training. The ensemble predicted thrombin trajectories for conditions not used for model training, including thrombin generation for normal and hemophilic coagulation in the presence of platelets (a significant unmodeled component). We then used flux analysis to understand how the network operated in a variety of conditions, and global sensitivity analysis to identify which parameters controlled the performance of the network. Taken together, the hybrid approach produced a surprisingly predictive model given its small size, suggesting the proposed framework could also be used to dynamically model other biochemical networks, including intracellular metabolic networks, gene expression programs or potentially even cell free metabolic systems.

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Mathematical Model of Serine Protease Inhibition in the Tissue Factor Pathway to Thrombin

Cited by 30 publications

References 34 publications

Studies on the Different Modes of Action of the Anticoagulant Protease Inhibitors DX-9065a and Argatroban

Studies on the Different Modes of Action of the Anticoagulant Protease Inhibitors DX-9065a and Argatroban

Mathematical Models of Blood Coagulation and Platelet Adhesion: Clinical Applications

Dynamic Modeling of the Human Coagulation Cascade Using Reduced Order Effective Kinetic Models

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