Experimental Evaluation of a New Tissue Factor-Based Topical Hemostat (TT-173) for Treatment of Hepatic Bleeding.

Background: Excessive blood loss is a relevant complication of partial liver resection. Topical hemostatic agents have proven useful to improve the control of the bleeding in this among other surgical indications. Until now all of these products have been based on the action of thrombin. In contrast TT-173 is a new topical hemostatic agent based on recombinant tissue factor naturally incorporated into membrane vesicles. This work sought to assess the efficacy and toxicity of TT-173 in an animal model of liver resection.Materials and Methods: Procoagulant activity of 0.15, 0.41, and 1 mg of TT-173 was evaluated in pigs subjected the resection of hepatic lobe margins. The most effective of these doses was also compared against thrombin. In addition, the toxicity, local tolerance, systemic absorption, and immunogenicity of the product were investigated in rats subjected to liver biopsy lesion.Results: The three doses of TT-173 evaluated significantly reduced the bleeding time in liver lesions. The highest dose of product was significantly more effective than the others and thrombin. Application of high doses of TT-173 in rats did not cause any local or systemic alterations. Absorption into blood stream was negligible and no immunogenic reaction against the product was detected.Conclusions: TT-173 shows favorable pharmacodynamic properties for improving hemostasis in partial liver resection which support further investigation of the product in this surgical indication.

Construction and characterization of a truncated tissue factor­coagulation­based composite system for selective thrombosis in tumor blood vessels.

The selective induction of tumor vascular thrombosis using truncated tissue factor (tTF) delivered via a target ligand is a promising novel antitumor strategy. In the present study, an anti­neuropilin­1 (NRP­1) monoclonal antibody (mAb)­streptavidin (SA):tTF­biotin (B) composite system was established. In this system, anti­NRP­1­mAb located tTF to the tumor vascular endothelial cell surface and induced vascular embolization. Due to their high binding affinity, SA and B were used to enhance thrombogenic activity. mAb was conjugated with SA using a coupling method with water­soluble 1­ethyl­3­(3­dimethylaminopropyl) carbodiimide and N­hydroxysulfosuccinimide. Biotinylated tTF (tTF­B) was prepared using a B­labeling kit subsequent to the generation and purification of fusion protein tTF. Confocal microscopy and flow cytometry indicated that the anti­NRP­1­mAb­SA conjugate retained mAb targeting activity. The preservation of B­conjugate binding capacity was confirmed using a competitive ELISA, and factor X­activation analysis revealed that tTF­B retained the procoagulant activity exhibited by tTF. Live imaging was performed to assess mAb­SA distribution and tumor­targeting capability, and this yielded promising results. The results of in vivo studies in mice with subcutaneous xenografts demonstrated that this composite system significantly induced tumor vascular thrombosis and inhibited tumor growth, whereas these histological changes were not observed in normal organs.

Virus envelope tissue factor promotes infection in mice.

Essentials The coagulation initiator, tissue factor (TF), is on the herpes simplex virus 1 (HSV1) surface. HSV1 surface TF was examined in mice as an antiviral target since it enhances infection in vitro. HSV1 surface TF facilitated infection of all organs evaluated and anticoagulants were antiviral. Protease activated receptor 2 inhibited infection in vivo and its pre-activation was antiviral. SUMMARY: Background Tissue factor (TF) is the essential cell surface initiator of coagulation, and mediates cell signaling through protease-activated receptor (PAR) 2. Having a diverse cellular distribution, TF is involved in many biological pathways and pathologies. Our earlier work identified host cell-derived TF on the envelope covering several viruses, and showed its involvement in enhanced cell infection in vitro. Objective In the current study, we evaluated the in vivo effects of virus surface TF on infection and on the related modulator of infection PAR2. Methods With the use of herpes simplex virus type 1 (HSV1) as a model enveloped virus, purified HSV1 was generated with or without envelope TF through propagation in a TF-inducible cell line. Infection was studied after intravenous inoculation of BALB/c, C57BL/6J or C57BL/6J PAR2 knockout mice with 5 × 105 plaque-forming units of HSV1, mimicking viremia. Three days after inoculation, organs were processed, and virus was quantified with plaque-forming assays and quantitative real-time PCR. Results Infection of brain, lung, heart, spinal cord and liver by HSV1 required viral TF. Demonstrating promise as a therapeutic target, virus-specific anti-TF mAbs or small-molecule inhibitors of coagulation inhibited infection. PAR2 modulates HSV1 in vivo as demonstrated with PAR2 knockout mice and PAR2 agonist peptide. Conclusion TF is a constituent of many permissive host cell types. Therefore, the results presented here may explain why many viruses are correlated with hemostatic abnormalities, and indicate that TF is a novel pan-specific envelope antiviral target.

Specific tissue factor delivery using a tumor-homing peptide for inducing tumor infarction.

Targeting the human blood coagulation-inducing protein tissue factor (TF) to the tumor vasculature to induce infarction and disrupt the blood vessels has proven to be an effective approach for tumor therapy. In this study, we investigated the thrombogenic activity and anti-tumor potential of a novel fusion protein (tTF-CREKA) comprising the extracellular domain of human tissue factor (truncated TF, tTF) and a tumor targeting pentapeptide, Cys-Arg-Glu-Lys-Ala (CREKA). tTF is soluble and inactive in its free state, but when it is targeted to the plasma membrane of both tumor vessel endothelial cells and stromal cells by the CREKA peptide, its native coagulation-inducing activity is restored. Systemic administration of the tTF-CREKA fusion protein into tumor-bearing mice induced tumor-selective intravascular thrombosis and reduced tumor blood perfusion, consequently inhibiting tumor growth. The development of tTF-CREKA introduces a new method for treating a wide spectrum of solid tumors by selectively blocking tumor blood supply.

A Step Toward Balance: Thrombin Generation Improvement via Procoagulant Factor and Antithrombin Supplementation.

BACKGROUND: The use of prothrombin complex concentrates in trauma- and surgery-induced coagulopathy is complicated by the possibility of thromboembolic events. To explore the effects of these agents on thrombin generation (TG), we investigated combinations of coagulation factors equivalent to 3- and 4-factor prothrombin complex concentrates with and without added antithrombin (AT), as well as recombinant factor VIIa (rFVIIa), in a dilutional model. These data were then used to develop a computational model to test whether such a model could predict the TG profiles of these agents used to treat dilutional coagulopathy. METHODS: We measured TG in plasma collected from 10 healthy volunteers using Calibrated Automated Thrombogram. TG measurements were performed in undiluted plasma, 3-fold saline-diluted plasma, and diluted plasma supplemented with the following factors: rFVIIa (group rFVIIa); factors (F)II, FIX, FX, and AT (group "combination of coagulation factors" [CCF]-AT); or FII, FVII, FIX, and FX (group CCF-FVII). We extended an existing computational model of TG to include additional reactions that impact the Calibrated Automated Thrombogram readout. We developed and applied a computational strategy to train the model using only a subset of the obtained TG data and used the remaining data for model validation. RESULTS: rFVIIa decreased lag time and the time to thrombin peak generation beyond their predilution levels (P < 0.001) but did not restore normal thrombin peak height (P < 0.001). CCF-FVII supplementation decreased lag time (P = 0.034) and thrombin peak time (P < 0.001) and increased both peak height (P < 0.001) and endogenous thrombin potential (P = 0.055) beyond their predilution levels. CCF-AT supplementation in diluted plasma resulted in an improvement in TG without causing the exaggerated effects of rFVIIa and CCF-FVII supplementation. The differences between the effects of CCF-AT and supplementation with rFVIIa and CCF-FVII were significant for lag time (P < 0.001 and P = 0.005, respectively), time to thrombin peak (P < 0.001 and P = 0.004, respectively), velocity index (P < 0.001 and P = 0.019, respectively), thrombin peak height (P < 0.001 for both comparisons), and endogenous thrombin potential (P = 0.034 and P = 0.019, respectively). The computational model generated subject-specific predictions and identified typical patterns of TG improvement. CONCLUSIONS: In this study of the effects of hemodilution, CCF-AT supplementation improved the dilution-impaired plasma TG potential in a more balanced way than either rFVIIa alone or CCF-FVII supplementation. Predictive computational modeling can guide plasma dilution/supplementation experiments.

TETIS study: evaluation of new topical hemostatic agent TT-173 in tooth extraction.

OBJECTIVES: TT-173 is a new hemostatic agent consisting of yeast-derived microvesicles containing a modified version of recombinant human tissue factor. In the present work, the procoagulant activity of TT-173 has been evaluated for the first time in humans. METHODS: This is a phase I, randomized, placebo-controlled study to evaluate the efficacy, safety, systemic absorption, and immunogenicity of TT-173 in healthy volunteers undergoing tooth extraction. Subjects received TT-173 or placebo into the alveolar cavity, just after tooth extraction. Time to clot formation, bleeding time, and adverse events were recorded. RESULTS: Treatment with TT-173 reduced the bleeding time and the time to clot formation. No adverse events related with product administration were reported. In the same way, neither systemic absorption nor immunogenic reaction against the product was detected. Our findings pave the way to evaluate the usefulness of this new topical hemostatic agent in more complex oral surgeries and in those patients affected with coagulation disorders that may compromise the realization of dental procedures. CONCLUSION: The new hemostatic agent TT-173 has proven efficacious and safe in healthy subjects undergoing tooth extraction supporting its further evaluation in more complex surgeries. CLINICAL RELEVANCE: The development of this new topical hemostatic agent could contribute to bleeding control in oral and maxillofacial surgery.

Avaliação da peroxidação lipídica no plasma de ratos submetidos à lesão tecidual e tratados com hidrogel de poliamido de mandioca / Evaluación de la peroxidación de lípidos en plasma de ratas sometidas a lesión tisular y tratadas con hidrogel de poliamida de yuca / Evaluación de la peroxidación de lípidos en plasma de ratas sometidas a lesión tisular y tratadas con hidrogel de poliamida de yuca

As espécies reativas ao oxigênio (EROS) são produzidas como mecanismo de defesa celular, participando dos processos de cicatrização celular. Entretanto, altos níveis de EROS podem causar danos como a peroxidação lipídica (PL). O presente estudo teve como objetivo, verificar os níveis de PL por meio da determinação das substâncias reativas ao ácido tiobarbitúrico (TBARS) no plasma de ratos com lesão tecidual induzida. Foram utilizados 32 ratos machos, Rattus norvegicus albinus da linhagem Wistar, os quais foram pesados e da média ± 10% do peso foram distribuídos em quatro grupos: A ­ controle negativo; B - Vetaglós®; C ­ hidrogel de poliamido de mandioca+ Vetaglós®; D ­ Hidrogel de poliamido de mandioca. Após 21 dias, todos os animais foram anestesiados com isoflurano e foi feita a coleta de sangue por punção cardíaca, e os plasmas foram obtidos após centrifugação, na sequência por superdosagem do anestésico foi realizada a eutanásia. Os níveis de PL nos plasmas dos ratos foram determinados pelo método do TBARS. Não houve diferença significativa entre os grupos em relação à PL, indicando um equilíbrio entre as defesas antioxidantes celulares e os níveis de EROS produzidos durante o processo de cicatrização celular. Essa ausência nos diferentes grupos experimentais, em relação à PL, deixa claro a importância de se contemplar estudos de parâmetros de bioindicadores de estresse oxidativo em protocolos experimentais.

Reactive oxygen species (ROS) are produced as a cellular defense mechanism, participating in the processes of cellular healing. However, high levels of ROS can cause damages such as lipid peroxidation (LPO). This study aimed to verify the levels of LPO through the determination of reactive substances to thiobarbituric acid (TBARS) in rat plasma with induced tissue injury. A total of 32 Rattus norvegicus albinus Wistar were used, with a mean weight ± 10%. They were divided into four groups: A ­ negative control; B - Vetaglós®; C - Polyamide cassava; D - Polyamide cassava + Vetaglós®. After 21 days, all animals were anesthetized with isoflurane and blood was collected by cardiac puncture. Plasma was obtained after centrifugation. Euthanasia was performed with administration of an overdose of inhalational anesthetic previously used. The LPO levels in rat plasma were determined using the TBARS method. There was no significant difference between the groups in relation to LPO, indicating a balance between antioxidant defenses and cellular levels of ROS produced during the cellular healing process. This absence in the different experimental groups in relation to LPO emphasizes the importance of further studies related to the bio-indicator parameters for oxidative stress in experimental protocols.

Las especies reactivas al oxígeno (EROS) se producen como mecanismo de defensa celular, que participan en los procesos de curación celulares. Sin embargo, los altos niveles de EROS pueden causar daños como la peroxidación lipídica (PL). Este estudio tuvo como objetivo verificar los niveles de peroxidación lipídica por sustancias reactivas al ácido tiobarbitúrico (TBARS) en el plasma de ratas con lesión tisular inducida. Se han utilizado 32 ratas machos, Rattus norvegicus albinus de linaje Wistar, que se pesaron y la media ± 10% en peso, y se dividieron en cuatro grupos: A ­ control negativo; B - Vetaglós®; C ­ hidrogel de poliamida de yuca + Vetaglós®; D ­ Hidrogel de poliamida de yuca. Después de 21 días, todos los animales fueron anestesiados con isoflurano y se hizo la extracción de sangre por punción cardiaca, y se obtuvieron los plasmas después de la centrifugación, enseguida con sobredosis de anestésico se realizó la eutanasia. Los niveles de PL en los plasmas de las ratas se determinaron por el método de TBARS. No hubo diferencia significativa entre los grupos en relación a la peroxidación lipídica, lo que indica un equilibrio entre las defensas antioxidantes celulares y los niveles de EROS producidos durante el proceso de curación celular. Esa ausencia en los diferentes grupos experimentales, en relación a la PL, pone de manifiesto la importancia de contemplarse estudios de parámetros de bioindicadores de estrés oxidativo en los protocolos experimentales.

Calidad de las tromboplastinas utilizadas en el laboratorio clínico y en los equipos POCT y su impacto en la dosificación de acenocumarol en pacientes con terapia anticoagulante oral / Types of thromplastin used for INR determination in patients under chronic oral anticoagulant treatment: discrepancies that may affect the dose of coumarin derivatives needed for treatment safety

Antecedentes: El monitoreo del tratamiento con anticoagulantes cumarínicos se realiza a través del INR (International Normalized Ratio) que es el parámetro estandarizado del Tiempo de Protrombina. Las recomendaciones de la OMS indican que la precisión en el cálculo del INR puede ser mejorada usando reactivo de tromboplastina con Indice de Sensibilidad Internacional (ISI) bajo, considerándose como ISI de referencia internacional el valor 1,0. Debido a incongruencias observadas en los INR de pacientes controlados en el Servicio de Salud Metropolitano Occidente, comparando valores de muestra venosa con resultados de INR capilar obtenidos en el mismo paciente el mismo día y hora (con reactivos Tromboplastina de distinto ISI), se efectuó un ensayo clínico cruzado entre los distintos métodos. Materiales y métodos: En 100 pacientes se comparó INR venoso con dos tromboplastinas de diferente ISI (1,3 y 1,0) vs aquel efectuado con muestra capilar (ISI 1,0). Resultados: Los resultados del estudio muestran que a partir de valores de INR 3,0 las determinaciones obtenidas usando Tromboplastina de cerebro de conejo ISI=1,3 subestiman el valor de INR para un mismo paciente y una misma muestra. Conclusiones: El uso de Tromboplastina recombinante humana ISI 1,0 permite evitar la subestimación del INR en pacientes con mayor riesgo tromboembóli-co (indicación de INR objetivo más alto). Por ello, este método se adoptó en el control del TACO en pacientes controlados en el Servicio de Salud Occidente.

Background: INR (International Normalized Ratio) is the standard Prothrombin Time parameter for monitoring anticoagulant treatment with coumarin derivatives Recommendations of WHO indicate that precision in the calculation of the INR can be improved using thromboplastins with a low Index of International Sensibility (ISI=1,0). Discrepancies in INR obtained using either this technique or conventional rabbit brain derived reagents in the same sample in patients attending the Servicio de Salud Metropolitano Occidente (West Metropolitan Health Service) were observed. Our objective was to evaluate these discrepancies in a systematic way. Materials and methods: A comparative study was conducted using two thromboplastins of different ISI (1.0 and 1.3) for the calculation of venous INR in comparison with capillary INR in 100 patients. Results: The study showed that INR values may differ significantly according to the method used. In particular, rabbit brain thromboplastin ISI = 1.3 underestimates the value of INR in the range of INR ≥3.0. Conclusions: The use of human recombinant thromboplastin ISI= 1.0. for determination of INR may significantly decrease the risk of hemorrhagic complications in patients requiring higher levels of anticoagulation.

Interconnections between autophagy and the coagulation cascade in hepatocellular carcinoma.

Autophagy has an important role in tumor biology of hepatocellular carcinoma (HCC). Recent studies demonstrated that tissue factor (TF) combined with coagulation factor VII (FVII) has a pathological role by activating a G-protein-coupled receptor called protease-activated receptor 2 (PAR2) for tumor growth. The present study aimed to investigate the interactions of autophagy and the coagulation cascade in HCC. Seventy HCC patients who underwent curative liver resection were recruited. Immunohistochemical staining and western blotting were performed to determine TF, FVII, PAR2 and light chain 3 (LC3A/B) expressions in tumors and their contiguous normal regions. We found that the levels of autophagic marker LC3A/B-II and coagulation proteins (TF, FVII and PAR2) were inversely correlated in human HCC tissues. Treatments with TF, FVII or PAR2 agonist downregulated LC3A/B-II with an increased level of mTOR in Hep3B cells; in contrast, knockdown of TF, FVII or PAR2 increased LC3A/B. Furthermore, mTOR silencing restored the impaired expression of LC3A/B-II in TF-, FVII- or PAR2-treated Hep3B cells and activated autophagy. Last, as an in vivo correlate, we administered TF, FVII or PAR2 agonist in a NOD/severe combined immunodeficiency xenograft model and showed decreased LC3A/B protein levels in HepG2 tumors with treatments. Overall, our present study demonstrated that TF, FVII and PAR2 regulated autophagy mainly via mTOR signaling. The interaction of coagulation and autophagic pathways may provide potential targets for further therapeutic application in HCC.

A combination of radiosurgery and soluble tissue factor enhances vascular targeting for experimental glioblastoma.

Radiosurgery for glioblastoma is limited to the development of resistance, allowing tumor cells to survive and initiate tumor recurrence. Based on our previous work that coadministration of tissue factor and lipopolysaccharide following radiosurgery selectively induced thrombosis in cerebral arteriovenous malformations, achieving thrombosis of 69% of the capillaries and 39% of medium sized vessels, we hypothesized that a rapid and selective shutdown of the capillaries in glioblastoma vasculature would decrease the delivery of oxygen and nutrients, reducing tumor growth, preventing intracranial hypertension, and improving life expectancy. Glioblastoma was formed by implantation of GL261 cells into C57Bl/6 mouse brain. Mice were intravenously injected tissue factor, lipopolysaccharide, a combination of both, or placebo 24 hours after radiosurgery. Control mice received both agents after sham irradiation. Coadministration of tissue factor and lipopolysaccharide led to the formation of thrombi in up to 87 ± 8% of the capillaries and 46 ± 4% of medium sized vessels within glioblastoma. The survival rate of mice in this group was 80% versus no survivor in placebo controls 30 days after irradiation. Animal body weight increased with time in this group (r = 0.88, P = 0.0001). Thus, radiosurgery enhanced treatment with tissue factor, and lipopolysaccharide selectively induces thrombosis in glioblastoma vasculature, improving life expectancy.

Vascular infarction by subcutaneous application of tissue factor targeted to tumor vessels with NGR-peptides: activity and toxicity profile.

tTF-NGR consists of the extracellular domain of the (truncated) tissue factor (tTF), a central molecule for coagulation in vivo, and the peptide GNGRAHA (NGR), a ligand of the surface protein aminopeptidase N (CD13). After deamidation of the NGR-peptide moiety, the fusion protein is also a ligand for integrin αvß3 (CD51/CD61). Both surface proteins are upregulated on endothelial cells of tumor vessels. tTF-NGR showed binding to specific binding sites on endothelial cells in vitro as shown by flow cytometry. Subcutaneous injection of tTF-NGR into athymic mice bearing human HT1080 fibrosarcoma tumors induced tumor growth retardation and delay. Contrast enhanced ultrasound detected a decrease in tumor blood flow in vivo after application of tTF-NGR. Histological analysis of the tumors revealed vascular disruption due to blood pooling and thrombotic occlusion of tumor vessels. Furthermore, a lack of resistance was shown by re-exposure of tumor-bearing mice to tTF-NGR after regrowth following a first cycle of treatment. However, after subcutaneous (s.c.) push injection with therapeutic doses (1-5 mg/kg bw) side effects have been observed, such as skin bleeding and reduced performance. Since lethality started within the therapeutic dose range (LD10 approximately 2 mg/kg bw) no safe therapeutic window could be found. Limiting toxicity was represented by thrombo-embolic events in major organ systems as demonstrated by histology. Thus, subcutaneous injection of tTF-NGR represents an active, but toxic application procedure and compares unfavourably to intravenous infusion.

Tissue factor-bearing microparticles derived from tumor cells: impact on coagulation activation.

BACKGROUND: Tissue factor (TF)-bearing microparticles (MP) from different origins are thought to be involved in the pathogenesis of cancer-associated thrombosis. However, the role of circulating tumor cell-derived TF is not well understood. METHODS: TF antigen and activity were measured in MP generated in vitro from human TF-expressing cancer cells by ELISA and clotting or thrombin generation assays, respectively. TF antigen and activity were also measured in vivo in cell-free plasmas from mice previously injected with in vitro-generated MP or in cell-free plasmas from nude mice bearing orthotopically injected human cancer cells. RESULTS: Tumor cell-derived MP (TMP) exhibited strong TF-dependent procoagulant activity (PCA) in vitro and in vivo. Injection of TMP into mice was associated with acute thrombocytopenia and signs of shock, which were prevented by prior heparinization. Human TF antigen and activity could be detected in mouse cell-free plasmas up to 30 min after TMP injections. Human TF was detected in the spleen of injected mice and its clearance from circulation was delayed in splenectomized mice, suggesting the involvement of the spleen in the rapid clearance of circulating MP in vivo. Detectable levels of TF-dependent PCA and thrombin-antithrombin complex were found in cell-free plasmas from mice growing pancreatic human tumors, suggesting that circulating tumor-derived TF causes coagulation activation in vivo. CONCLUSIONS: MP derived from certain cancer cells exhibit TF-dependent PCA both in vitro and in vivo. These results provide new information about the specific contribution of tumor-derived MP to the hypercoagulable state observed in cancer.

Coadministration of low-dose lipopolysaccharide and soluble tissue factor induces thrombosis after radiosurgery in an animal arteriovenous malformation model.

OBJECTIVE: Radiosurgery for arteriovenous malformations is limited to small lesions and may take 3 years to produce total occlusion. It has recently been shown that coadministration of low-dose lipopolysaccharide (LPS) and soluble tissue factor (sTF) selectively induces thrombosis in murine tumor models, attributable perhaps to the prothrombotic phenotype of tumor vasculature. Radiosurgery may induce changes in endothelial prothrombotic molecules similar to those found in tumors. This study aimed to determine if a similar strategy could be used to stimulate thrombus formation in an animal arteriovenous malformation model. METHODS: Seventeen rats underwent creation of a carotid-to-jugular anastomosis. Animals were intravenously injected with sTF, low-dose LPS, a combination of both, or placebo 24 hours after stereotactic irradiation of the anastomosis. Control animals received both agents after sham irradiation. RESULTS: Coadministration of sTF and LPS led to the formation of thrombi in up to 69% of small vessels and 39% of medium-sized vessels within the target region. The irradiated vasculature demonstrated intermediate rates of thrombosis after treatment with either sTF or LPS alone as did vessels within the fistula in the control group. Logistic regression analysis demonstrated significant associations between development of thrombi and treatment with radiation, sTF, or LPS (P < 0.005). There was no evidence of systemic thrombus formation or toxicity in any group. CONCLUSION: Treatment with sTF and LPS selectively induces thrombosis of irradiated vessels in a rat model of arteriovenous malformation. Stimulation of thrombosis may improve the efficacy of radiosurgery, increasing the treatable lesion size and reducing latency.

In vivo induction of endothelial apoptosis leads to vessel thrombosis and endothelial denudation: a clue to the understanding of the mechanisms of thrombotic plaque erosion.

BACKGROUND: The mechanisms of thrombosis on plaque erosion are poorly understood. We examined the potential role of endothelial apoptosis in endothelial erosion and vessel thrombosis. METHODS AND RESULTS: Segments of New Zealand White rabbit femoral arteries were temporarily isolated in vivo. One artery was incubated with staurosporin for 30 minutes, whereas the contralateral artery was incubated with saline and served as control. Three days later, thrombosis was evaluated angiographically and histologically. TUNEL score in the endothelial layer was significantly increased in staurosporin-treated arteries compared with controls (2.43+/-0.30 versus 0.93+/-0.44, respectively; P=0.001). Large areas of endothelial denudation were detectable in staurosporin-treated vessels, whereas endothelium integrity was almost preserved in the saline group. Vessel thrombosis occurred in 58% of staurosporin-treated arteries (7 of 12) but in only 8% of saline-treated segments (P<0.01). Immunoreactivities for tissue factor, platelets, and fibrin were detectable within the thrombus. Addition of ZVAD-fmk (0.1 mmol/L) significantly reduced the occurrence of thrombosis (1 of 7 arteries or 14%, P=0.04). These results were confirmed in balloon-injured atheromatous arteries. CONCLUSIONS: In vivo induction of endothelial apoptosis leads to both vessel thrombosis and endothelial denudation. Endothelial apoptosis may be a critical step in the transition from a stable endothelialized plaque to plaque erosion and thrombosis.

Blockade of GPIIb/IIIa by eptifibatide and tirofiban does not alter tissue factor induced thrombin generation in human endotoxemia.

Activated platelets facilitate thrombin generation by providing a catalytic surface on which coagulation activation occurs. The glycoprotein (GP) IIb/IIIa receptor might play a major role in this process as shown by in vitro and animal experiments. However, it is controversial whether the GPIIb/IIIa receptor facilitates tissue factor-induced thrombin generation in humans as well. We therefore investigated whether two clinically used GPIIb/IIIa antagonists (tirofiban and eptifibatide) may blunt TF-induced coagulation in humans. Thirty male volunteers received 2 ng/kg endotoxin and standard doses of eptifibatide, tirofiban or placebo over 5 hours in a randomized, double-blind, placebo-controlled, double-dummy parallel-group trial. Markers of thrombin generation (prothrombin fragment 1+2, thrombin-antithrombin complexes), fibrinolysis (D-dimer, plasmin-antiplasmin complexes) as well as inflammatory markers (interleukin-6, tumor necrosis factor-alpha) were measured by enzyme linked immunoasssays, TF-mRNA expression was quantified by RT-PCR. Neither eptifibatide nor tirofiban influenced LPS-induced coagulation activation or fibrinolytic activity. Additionally, the increase of TNF-alpha and IL-6 was similar in all groups. In conclusion, GPIIb/IIIa blockade with eptifibatide or tirofiban did not influence TF-induced coagulation activation in human low grade endotoxemia.

Inhibition of localized thrombosis in P2Y1-deficient mice and rodents treated with MRS2179, a P2Y1 receptor antagonist.

Previous studies in experimental models revealed a role for the P2Y1 platelet ADP receptor in systemic vascular thromboembolism models. In the present work, we used models of localized arterial and venous thrombosis to assess the role of the P2Y1 receptor in these processes. Arterial thrombosis was induced in one mesenteric arteriole of a mouse using FeCl3, while venous thrombosis was studied in a Wessler model adapted to rats. P2Y1-deficient mice and mice treated with the P2Y1 antagonist MRS2179 displayed significantly less arterial thrombosis than their respective controls. Combination of P2Y1 deficiency with P2Y12 inhibition led to a significant additive effect. Venous thrombosis was slightly but significantly inhibited in MRS2179-treated rats. These results demonstrate a role for the P2Y1 receptor in both arterial and venous thrombosis, further establishing this receptor as a potential target for antithrombotic drugs.

Soluble tissue factor induces coagulation on tumor endothelial cells in vivo if coadministered with low-dose lipopolysaccharides.

OBJECTIVE: This study was performed to evaluate the mechanisms leading to tumor vessel occlusion by tissue factor-based drugs, which are used in vascular targeting approaches for the treatment of malignant tumors. METHODS AND RESULTS: The effects of nontargeted soluble tissue factor were evaluated in vitro and in vivo. Tumor-bearing mice were treated with (1) the extracellular portion of tissue factor (soluble tissue factor), (2) low nontoxic doses of lipopolysaccharides, or (3) a combination thereof. The combination treatment showed the best effects and resulted in selective thrombosis of tumor vessels. On the basis of our data from subsequent in vitro analyses, including surface plasmon resonance measurements and endothelial cell based coagulation assays, we propose a model on how soluble tissue factor, although lacking its membrane anchor, can promote selective tumor vessel occlusion. CONCLUSIONS: To our knowledge, this is the first report to describe the molecular mechanisms of coagulation induction by untargeted soluble tissue factor in vivo. Combination treatments including soluble tissue factor might represent an alternative vascular targeting approach for the treatment of malignant tumors.

Infarction of solid Hodgkin's tumors in mice by antibody-directed targeting of tissue factor to tumor vasculature.

We demonstrated previously that selective thrombosis of the blood vessels of solid tumors in mice can be achieved by targeting the extracellular domain of tissue factor by means of an antibody to an experimentally induced marker on tumor vascular endothelium. In the present study, we extend this finding to a naturally occurring marker of tumor vascular endothelium, vascular cell adhesion molecule-1 (VCAM-1). VCAM-1 is expressed by vascular endothelial cells in Hodgkin's disease and various solid tumors in mice and humans. It is absent from vascular endothelial cells in normal tissues in mice, with the exception of the heart and lungs, where it is present on venules. A monoclonal antibody to murine VCAM-1 was covalently linked to the extracellular domain of human tissue factor to create a "coaguligand." After i.v. administration to severe combined immunodeficient mice bearing human Hodgkin's tumors, the coaguligand localized selectively to VCAM-1-expressing vessels, caused thrombosis of those vessels, and retarded tumor growth. The coaguligand also localized to VCAM-1-expressing vessels in the heart and lungs of the mice but did not induce thrombosis in these sites. An immunohistochemical evaluation of the distribution of a monoclonal anti-phosphatidylserine (PS) antibody in the mice showed that the VCAM-1-expressing vessels in the tumor expressed PS, whereas the VCAM-1-expressing vessels in the heart and lungs lacked PS. The lack of thrombotic effect of the coaguligand on heart and lung vessels may be because PS is needed to provide the procoagulant surface upon which coagulation complexes can assemble. The requirement for coincident expression of the targeted marker and PS on tumor endothelium probably contributes to the selectivity of thrombotic action and the safety of coaguligands.