Metastatic Pancreatic Cancer Clinical Trial
Official title:
A Phase III Multi-centre Double-blind Placebo Controlled Study Analysing the Efficacy and Safety of Daily Administration of a P2Y12 Inhibitor (Clopidogrel) for the Treatment of Locally Advanced or Metastatic Pancreatic Cancer
Clopidogrel has been shown to slow down tumor progression in orthoptic pancreatic murine
tumor.
In a pilot study, the rate of microparticles was correlated with response rate of pancreatic
adenocarcinoma.
The aim of the study is;
- to compare the phenotypes of coagulation, the tumor progression and metastasis formation
with and without clopidogrel treatment in association with chemotherapy in advanced
pancreatic cancer patients
- to correlate the decrease of microparticles levels after one month of chemotherapy with
tumor response (ancillary study)
Several studies have been performed to understand the cellular mechanisms involved in the
development of VTE in cancer patients. The pathogenesis of a thrombotic state is linked to
the presence of a tumor and is associated with the development of a hypercoagulant state,
namely coagulopathy, which confers numerous advantages to the cancer cells. Indeed, both
activation of the coagulation cascade and aggregation of blood platelets around cancer cells
protect themselves from the immune response; facilitate their circulation in the bloodstream
and their adhesion at potential sites of metastasis. Beside its implication in the activation
of coagulation, the TF/FVIIa complex also influences pathways that activate cell-bound
protease activated receptors (PARs) leading to the activation of inflammatory and angiogenic
responses. Furthermore, a soluble variant of TF, known as alternatively spliced TF (asTF)
stimulates angiogenesis independent of FVIIa. This leads to a model in which the presence of
Tissue Factor (TF), generation of thrombin and platelets activation all directly participate
to the cancer progression and dissemination. The presence of TF and the activation of
platelets participate to the progression of the tumor.
A retrospective study collected clinical information and plasma samples of 117 patients with
pancreatic or biliary cancer, of which 68% were pancreatic cancer and 29% biliary cancers.
Thrombotic events occurred in 52 (44.4%) patients. Mean and median tissue factor for all
patients were 2.15 pg/mL and 1.20 pg/mL, respectively (range: 0.17-31.01 pg/mL). Elevated
Tissue Factor levels were significantly associated with VTE events (P=0.04), and an elevated
tissue Factor level was associated with a worse overall survival (hazard ratio, HR: 1.05;
P=0.01).
This procoagulant state could be due to the expression of active TF and transmembrane
proteins (PSGL-1, Muc1, …) by the cancer cell itself or cancer cell-derived microparticles
leading to platelets activation and aggregation. While studying the key role of TF bearing
cancer cell-derived microparticles in cancer associated thrombosis, the investigators have
previously shown (Dubois C, INSERM UMR 1076 Marseille) that both endogenously generated and
exogenously injected pancreatic cancer cell-derived microparticles expressing TF (PancO2),
but not their parental tumor cells, accumulated at the site of injury in a P-selectin
dependent manner. Their presence directly correlates with the size of the thrombus. Based on
these data, the investigators first hypothesized that treatment with anticoagulant and / or
antiplatelet drugs may prevent tumor progression and formation of metastasis, as well as
thrombosis associated cancer, in addition to prevention of coagulopathy.
Then Dubois & al compared the effect of an inhibitor of platelet activation, Clopidogrel, and
an inhibitor of the activation of the coagulant cascade, low molecular weight heparin (LMWH)
on tumor growth and thrombosis associated with cancer. Concentrations of drugs used were
calculated to induce a 50% reduction of thrombus formation following a laser-induced injury
in healthy mice. A diminution of kinetics of tumor growth was observed in mice treated by the
2 drugs in comparison with non-treated mice. Twenty days following injection of cancer cells,
the volume of the tumor was reduced by 85% and 87% when LMHW or Clopidogrel were used,
respectively. However, kinetics of tumor growth and volumes of tumors 20 days post-injection
were similar in mice treated by Clopidogrel in presence or absence of pathological TF
expressed by cancer cells.
Cancer cell-derived microparticles are responsible for the thrombotic phenotype observed in
mice developing a cancer via interactions between P-selectin expressed by aggregating
platelets and activated endothelium and PSGL-1 present at the surface of cancer cell-derived
microparticles. Before injury but after their infusion in bloodstream, exogenous labeled
cancer cell-derived microparticles were detected in the cremaster microcirculation of
non-treated or Clopidogrel treated mice. However, following an injury, cancer cell-derived
microparticles were accumulating at the site of thrombus formation only in non-treated mice
bearing a PancO2-LowTF or High TF tumor. Tissue Factor (TF) is both a main effector of the
coagulation cascade and a protein involved in the development of solid tumors. In vivo,
following a laser-induced injury, the activation of the endothelial wall, as well as the
presence of activated platelets, are the main source of P-selectin. The quantity of
P-selectin present at the site of injury was 4 fold less important in mice bearing a PancO2
tumor and treated by Clopidogrel in comparison with non-treated mice. Interestingly, PanCO2
cancer cell-derived microparticles express both TF and TFPI (Tissue Factor Inhibitor), a
biological inhibitor of the coagulation cascade in an active form. To confirm that
cancer-cell derived microparticles may participate in the inhibition of the blood coagulation
observed when the pathological TF is shut down, the investigators compared fibrin generation
at the site of injury in PancO2-High TF and Low-TF cancer mice in presence of absence of
Clopidogrel.
Fibrin formation at the site of laser-induced injury was significantly more important
(P<0,01) in mice following injection of Panc02-High TF in comparison with wild type mice.
Treatment of these mice by Clopidogrel diminished the production of fibrin at a level
comparable to the ones observed in wild type mice. When the pathological TF was shut down,
production of fibrin was strongly reduced in comparison with both the group of mice injected
by Panc02 cells and the group of wild type mice. the investigators conclude that when cancer
cells and cancer cell-derived microparticles express active TF, their incorporation to a
growing thrombus participates to the generation of a thrombotic phenotype. When TF expressed
by cancer cells is shut down, cancer cells microparticles still incorporate at the site of
thrombus formation, but reduces activation of TF, inhibiting fibrin generation and thrombus
formation by bringing TFPI at the site of injury.
Based on observations, the investigators hypothesized that inhibition of platelet activation
by reducing both thrombosis associated with cancer and tumor growth could constitute an
interesting therapy to treated cancer and thrombosis. To test the hypothesis the
investigators then developed a syngeneic orthoptic model of pancreatic cancer and could
confirm that when mice were treated with Clopidogrel or Aspirin, the growth of the primary
tumor was significantly reduced and the development of metastasis was limited (Mege et al.).
However the benefit from aspirin was observed in mice only when treated immediately at time
of onset of cancer, id est when injection of cancer cells were performed. On the contrary,
the effects of clopidogrel were obtained independently of the tumor size, and tumor
development or onset and even once cancer was at an advanced stage. Altogether with the
action of anti-platelet drugs on thrombosis, these results indicate that Clopidogrel does
represent a promising therapeutic drug to limit thrombosis and reduce the development of
tumors and metastasis.
The investigators showed in the experimental model that TF expressed by cancer cells was
involved in thrombosis associated with a cancer and in the growth of the tumor in vivo.
Beside its functions in coagulation, TF was also described following phosphorylation and
binding of its cytoplasmic tail to filamin, to induce transcriptional activation of different
growth factors, including VEGF. This intracellular pathway may also participate in the growth
of the tumor, but also in angiogenesis. Furthermore, TF expression was also reported to
influence motility, survival and proliferation of cancer cells via the activation of PAR-1
and PAR-2, although in this study proliferation of Panc02 cells were not affected by
inhibition of TF expression. Cancer cells may directly activate platelets by secreting ADP,
Thromboxane A2 and MMP-2 (Matrix Metallo Proteinase 2) and express at their surface ligands
to platelets, such as PSGL-1. In bloodstream, this leads to an aggregation of platelets
around cancer cells described to protect them from destruction by the immune system, blood
shear stress and to facilitate cancer cells interactions with the endothelium. However, the
direct involvement of these platelet agonists was not demonstrated in vivo. When mice were
treated with LMWH, a decrease in tumor development was observed similar to the ones obtained
when pathological TF was shut down. Also, treatment by Clopidogrel did not significantly
affect the growth of the tumor in the group of Panc02 miRNA TF mice or in the group of Panc02
mice treated by LMWH. This strongly suggests that activation of platelets is involved in the
growth of the tumor, but also that the main activator of platelet is TF expressed by cancer
cells and nor ADP nor Thromboxane A2. These secondary agonists may be involved when secreted
as a consequence of platelet activation generated by thrombin through a TF dependent pathway.
Last, they may play an important role not directly in the growth of the tumor, but rather in
the formation of metastasis when cancer cells have to be present in the bloodstream.
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