BACKGROUND: Thrombin-induced aggregation of human platelets can be completely inhibited by melagatran, the bioactive form of ximelagatran, an oral direct thrombin inhibitor. METHODS: The potential of melagatran to differentially inhibit alpha- and gamma-thrombins was tested with a synthetic thrombin substrate. Washed human platelets were also employed to determine if melagatran differentially inhibited alpha- and gamma-thrombin-induced platelet aggregation at distinct platelet thrombin receptors. In vitro studies were conducted with washed human platelets to determine thrombin-induced aggregation responses in the presence of varying doses of the anti-thrombotic drugs: melagatran, argatroban, heparin, and hirudin. RESULTS: Melagatran rapidly inhibits the hydrolysis of a thrombin chromogenic substrate within 0-1 min with alpha-, beta- and gamma-thrombin being equally inhibited by high dose melagatran while alpha-thrombin was significantly more sensitive at low doses. The maximum level of melagatran inhibition of alpha- and gamma-thrombin-induced platelet aggregation requires platelets to be pre-incubated with the drug for 10-30 min. Melagatran appears to have no direct effect on the PAR-1 receptor. It does appear to have a direct effect on the GPIbalpha thrombin receptor activity as well as the PAR-4 receptor. Inhibition of platelet aggregation is dose dependent, however, at low melagatran doses (0.01-0.04 nM) platelets aggregate at significantly (P < 0.05) higher levels. The lower the level of thrombin-induced aggregation that was observed with control samples (aggregations from 10% to 39%), corresponded with a higher observed melagatran-induced stimulation with drug-treated platelets. The range of stimulation varies between several hundred percent at approximately 10% aggregation to around 20% at about 20-39% aggregation. Preliminary studies indicate that this in vitro stimulatory effect is abrogated in platelets derived from volunteers who took aspirin (81 mg/day) for 7 days. Three other anti-thrombotic drugs, argatroban, heparin and hirudin, were tested with low drug levels but none were found to consistently stimulate the reaction. CONCLUSIONS: These results indicate that melagatran acts as both a direct thrombin inhibitor and indirectly by some interaction with the platelet membrane. While melagatran has been withdrawn from clinical use, its ability to differentially inhibit gamma-thrombin/PAR-4 versus alpha-thrombin/PAR-1 at low doses may warrant it, or less toxic analogs to be used in the future for as yet unknown disease states involving PAR-4.
BACKGROUND:Thrombin-induced aggregation of human platelets can be completely inhibited by melagatran, the bioactive form of ximelagatran, an oral direct thrombin inhibitor. METHODS: The potential of melagatran to differentially inhibit alpha- and gamma-thrombins was tested with a synthetic thrombin substrate. Washed human platelets were also employed to determine if melagatran differentially inhibited alpha- and gamma-thrombin-induced platelet aggregation at distinct platelet thrombin receptors. In vitro studies were conducted with washed human platelets to determine thrombin-induced aggregation responses in the presence of varying doses of the anti-thrombotic drugs: melagatran, argatroban, heparin, and hirudin. RESULTS:Melagatran rapidly inhibits the hydrolysis of a thrombin chromogenic substrate within 0-1 min with alpha-, beta- and gamma-thrombin being equally inhibited by high dose melagatran while alpha-thrombin was significantly more sensitive at low doses. The maximum level of melagatran inhibition of alpha- and gamma-thrombin-induced platelet aggregation requires platelets to be pre-incubated with the drug for 10-30 min. Melagatran appears to have no direct effect on the PAR-1 receptor. It does appear to have a direct effect on the GPIbalpha thrombin receptor activity as well as the PAR-4 receptor. Inhibition of platelet aggregation is dose dependent, however, at low melagatran doses (0.01-0.04 nM) platelets aggregate at significantly (P < 0.05) higher levels. The lower the level of thrombin-induced aggregation that was observed with control samples (aggregations from 10% to 39%), corresponded with a higher observed melagatran-induced stimulation with drug-treated platelets. The range of stimulation varies between several hundred percent at approximately 10% aggregation to around 20% at about 20-39% aggregation. Preliminary studies indicate that this in vitro stimulatory effect is abrogated in platelets derived from volunteers who took aspirin (81 mg/day) for 7 days. Three other anti-thrombotic drugs, argatroban, heparin and hirudin, were tested with low drug levels but none were found to consistently stimulate the reaction. CONCLUSIONS: These results indicate that melagatran acts as both a direct thrombin inhibitor and indirectly by some interaction with the platelet membrane. While melagatran has been withdrawn from clinical use, its ability to differentially inhibit gamma-thrombin/PAR-4 versus alpha-thrombin/PAR-1 at low doses may warrant it, or less toxic analogs to be used in the future for as yet unknown disease states involving PAR-4.
Authors: Stefan C Carlsson; Christer Mattsson; Ulf G Eriksson; Troy C Sarich; Karin Wåhlander; Asa Eliasson; Björn W Karlson; Sunita B Sheth; Peter Held Journal: Thromb Res Date: 2005 Impact factor: 3.944
Authors: D Gustafsson; T Antonsson; R Bylund; U Eriksson; E Gyzander; I Nilsson; M Elg; C Mattsson; J Deinum; S Pehrsson; O Karlsson; A Nilsson; H Sörensen Journal: Thromb Haemost Date: 1998-01 Impact factor: 5.249