Low-molecular-weight heparins in thrombosis and cancer: emerging links.
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Mousa SA
Low-molecular-weight heparins in thrombosis and cancer: emerging links.
Cardiovasc Drug Rev. 2004 Summer;22(2):121-34.
- PubMed ID
- 15179449 [ View in PubMed]
- Abstract
Heparin as well as low-molecular-weight heparins (LMWHs) have polypharmacological actions at various levels. Earlier studies focused on the plasma anti-Xa and anti-IIa pharmacodynamics (PD) for the different LMWHs. Other important PD parameters for heparin and LMWHs might explain the diverse clinical impacts of this class of agents in thrombosis and beyond: the release of the vascular tissue factor pathway inhibitor (TFPI), inhibition of key matrix-degrading enzymes, and other mechanisms. There is much evidence for the key role of LMWHs in hypercoagulation in thrombosis and cancer, angiogenesis, and inflammatory disorders. Many cancer patients reportedly have a hypercoaguable state, with recurrent thrombosis due to the impact of cancer cells and chemotherapy or radiotherapy on the coagulation cascade. Studies have demonstrated that unfractionated heparin (UFH) or its low molecular weight fractions interfere with various processes involved in tumor growth and metastasis. Clinical trials have suggested a clinically relevant and improved efficacy of LMWHs, as compared to UFH, on the survival of cancer patients with deep vein thrombosis. Our laboratory has demonstrated a significant role for LMWHs and for LMWH-releasable TFPI on the regulation of angiogenesis, tumor growth, and tumor metastasis; we have also seen potent inhibition of matrix-degrading enzymes by LMWHs but not by TFPI. The antiangiogenesis effect of LMWHs or non-anticoagulant LMWH derivatives was shown to be reversed by anti-TFPI. Thus, modulation of tissue factor/VIIa noncoagulant activities by LMWH-releasable TFPI and the inhibitory effects on matrix-degrading enzymes beside the anticoagulant efficacy have provided an expanded clinical utility for LMWHs in angiogenesis-associated disorders, including human tumor growth and metastasis.