Homocysteine elevation with fibrates: is it a class effect?

BACKGROUND: Case-control and prospective studies indicate that an elevated plasma homocysteine level is a powerful risk factor for atherosclerotic vascular diseases. Certain medications can induce hyperhomocystinemia, such as methotrexate, trimethoprim and anti-epileptic drugs. There are few reports indicating an interaction between lipid-lowering drugs (cholestyramine and niacin) and homocysteine. Recently, an interaction was shown between fenofibrate and benzafibrates (a fibric acid derivative) and homocysteine plasma levels. OBJECTIVES: To evaluate the effects of different fibrates on plasma homocysteine levels and to measure the reversibility of this effect. METHODS AND RESULTS: We investigated the effects of ciprofibrate and bezafibrate on homocysteine levels in patients with type IV hyperlipidemia and/or low high density lipoprotein levels. While a 57% increase in homocysteine was detected in the ciprofibrate-treated group (n = 26), a 17% reduction in homocysteine was detected in the group treated with bezafibrate (n = 12). The increase in homocysteine in the ciprofibrate-treated group was sustained for the 12 weeks of treatment and was partially reversible after 6 weeks of discontinuing the ciprofibrate therapy. CONCLUSIONS: These results indicate that an increase in plasma homocysteine levels following administration of fibrates is not a class effect, at least in its magnitude. Moreover, it is reversible upon discontinuation of the treatment.

The pathogenic role of anti-phosphatidylserine antibodies: active immunization with the antibodies leads to the induction of antiphospholipid syndrome.

Primary antiphospholipid syndrome (pAPS) can be experimentally induced in mice by immunization with anti-cardiolipin (aCL) antibodies (Abs). Recently, we have pointed to the pathogenic role of antiphosphatidylserine (aPS) Abs by inducing an experimental model of pAPS in naive mice following passive transfer of human aPS to the tail vein of ICR mice. The aim of the present study was to induce experimental pAPS in mice following active immunization with aPS. Mice were immunized with IgG and IgM aPS, purified from two patients with pAPS. The sera of the mice were examined for the presence of different antiphospholipid Abs, and the beta 2 GPI dependency of aPS, using an enzyme-linked immunosorbent assay (ELISA). Inhibition ELISA studies, with silica beads coated with phospholipids, were used to detect cross-reactivity of aPS or aCL to other phospholipids. The mice were also tested for the presence of thrombocytopenia, prolonged activated partial thromboplastin time (APTT), and the percentage of fetal resorptions. The purified IgG aPS but not IgM aPS had a strong lupus anticoagulant activity. Both IgG and IgM aPS were beta 2 GPI dependent and did not bind PS in the absence of the glycoprotein. The mice immunized with IgG aPS, but not IgM aPS, developed high titers of mouse aPS. The mice generated polyspecific Abs, cross-reacting with aCL and aPS, as well as individual aPS or aCL Abs. Only the mice immunized with IgG aPS developed clinical parameters of pAPS: prolonged APTT, thrombocytopenia, and an increased fetal resorption rate. In conclusion, active immunization with IgG, but not IgM, aPS induces experimental pAPS in naive mice, thus pointing to the participation of aPS in the idiotypic network.