Monthly ibandronate suppresses serum CTX-I within 3 days and maintains a monthly fluctuating pattern of suppression.

UNLABELLED: Bone turnover markers such as serum C-terminal cross-linking telopeptide of type I collagen (CTX-I) can be used to assess drug efficacy in osteoporosis. This study evaluated the pattern of CTX-I suppression in postmenopausal osteoporotic women receiving ibandronate. Ibandronate decreased serum CTX-I levels within 3 days of therapy initiation. Over 6 months, the levels remained suppressed below baseline. INTRODUCTION: This randomized, double-blind, placebo-controlled study evaluated the rapidity of onset and pattern of suppression of the bone resorption marker serum CTX-I in women with postmenopausal osteoporosis (PMO) who received once-monthly oral ibandronate. METHODS: Women diagnosed with PMO received once-monthly oral ibandronate (150 mg) or placebo for 6 months. Serum CTX-I was measured at baseline and after study dose administration on day 3 (month 1 only) and days 7, 14, 21, and 28 (months 1-6). Bone-specific alkaline phosphatase was measured on days 7 and 28 (months 1-6). RESULTS: This study enrolled 67 women: 49 received ibandronate, 17 received placebo, and one took no study drug. At day 3, median reduction in serum CTX-I from baseline was 70.2% with ibandronate and 6.0% with placebo (difference, -64.2%; 95% confidence interval, -80.3% to -46.2%; p < 0.0001). In women receiving ibandronate, serum CTX-I levels remained consistently below baseline, exhibiting a regular monthly fluctuating pattern of suppression over 6 months. Ibandronate was well-tolerated. CONCLUSIONS: Monthly ibandronate decreased serum CTX-I within 3 days. Over 6 months, in women receiving once-monthly ibandronate, serum CTX-I remained suppressed below baseline. A monthly fluctuation, related to time from last dose, was observed.

Rapid suppression of bone resorption marker levels with ibandronate therapy in a bisphosphonate-naïve population.

This 6-mo open-label study assessed the pattern of bone turnover marker (BTM) level changes in bisphosphonate-naïve women with postmenopausal osteoporosis treated with monthly oral ibandronate 150mg and the correlation between month 1 and month 6 serum C-terminal cross-linking telopeptide of type I collagen (sCTX) levels. The following BTMs were monitored: sCTX, urinary N-terminal telopeptide of type I collagen (uNTX), serum procollagen type 1 N-terminal propeptide (PINP), serum osteocalcin (OC), and serum bone-specific alkaline phosphatase (bALP). BTM levels were measured immediately before dosing at baseline and months 1, 2, 3, and 6, and 7d after dosing at baseline and month 4. A multiple regression model was applied to determine whether month 1 sCTX response predicted month 6 sCTX change. sCTX levels declined 70% 7d after dosing at baseline and month 4. Predosing sCTX declined 55% at month 6. The pattern of uNTX reduction was similar to sCTX. Bone formation markers PINP, OC, and bALP declined gradually over time. Month 1 sCTX change was a significant predictor of Month 6 change (p=0.0001). Once monthly 150mg oral ibandronate treatment reduced BTMs in women with osteoporosis. sCTX reduction occurred within 7d and was sustained over 6mo. Month 1 sCTX predicted month 6 sCTX.

The hololipoprotein complex of beta(2)-glycoprotein I and dicaproyl phosphatidylserine.

The ability of beta(2)-glycoprotein I (formerly referred to as apolipoprotein H) to act as an autoantigen for antibodies from patients with antiphospholipid syndrome is dependent upon its binding in vivo to anionic phospholipid surfaces or to surfaces in vitro which mimic their surface characteristics. The ability of the autoepitope(s) of beta(2)-glycoprotein I to be exposed by binding a short-chain (6-carbon), anionic phospholipid has not been explored. Here, we describe our studies of the hololipoprotein generated by reacting beta(2)-glycoprotein I with dicaproyl phosphatidylserine. The formation of the complex is accompanied by inhibition of beta(2)-glycoprotein I binding to phospholipid-coated polystyrene surfaces, with 50% reduction in binding occurring at about 10 mM. At concentrations >10 mM, dicaproyl phosphatidylserine also displaces beta(2)-glycoprotein I bound to anionic phospholipid surfaces. Physicochemical studies suggest that at DCPS concentrations >6 mM, the solutions are colloidal and that beta(2)-glycoprotein I forms a supramolecular complex with organized phospholipid structures. Using a standard human autoimmune anti-beta(2)-glycoprotein I plasma, as well as a series of six additional sera from patients with antiphospholipid syndrome, the complex did not generate a detectable epitope. We conclude that lipid binding, per se, is not sufficient for the presentation of the epitope(s) of beta(2)-glycoprotein I or its recognition by autoantibodies from patients with antiphospholipid syndrome.

Modification of beta 2glycoprotein I by glutardialdehyde. Conformational changes and aggregation accompany exposure of the cryptic autoepitope.

Autoantibodies from patients with antiphospholipid syndrome (APS) recognize an epitope on beta 2glycoprotein I (beta 2 GPI) only when native beta 2 GPI is adsorbed on surfaces composed of anionic phospholipids or oxidized polystyrene. beta 2 GPI was modified with the crosslinking agent, glutardialdehyde (GDA), which induced exposure of the anti-beta 2 GPI epitope at GDA:beta 2 GPI mol ratios in the range of 500-2000. A second crosslinking agent, dimethyl-suberimidate (DMS), did not expose the epitope, which may be a consequence of its having less tendency than GDA to form intermolecular links. SDS-PAGE experiments demonstrate that GDA does promote extensive intermolecular crosslinking of beta 2 GPI, and DMS does not. Formaldehyde also reacts with the lysine residues of beta 2 GPI, but does not expose the epitope. The circular dichroism spectra of native and modified beta 2 GPI confirm that GDA induces changes in conformation that are qualitatively different from those caused by formaldehyde. These data provide evidence that binding of lysine residues is not a sufficient condition for exposure of the autoepitope, and also support the likelihood that anti-beta 2 GPI antibodies bind only to aggregates of the protein. Thus, by synthesizing an active holoantigen of beta 2 GPI, conditions were defined that are necessary for binding of human autoantibodies.

Inhibition of beta 2glycoprotein I binding to anionic phospholipids: a strategy for the development of antiphospholipid syndrome-specific drugs.

The binding of beta 2glycoprotein I (beta 2GPI) to anionic phospholipids (PL) leads to the presentation of one or more epitopes recognized by autoantibodies from patients with antiphospholipid syndrome (APS). The inhibition of beta 2GPI binding to PL mixtures coated on polystyrene microtiter wells (MTW) and to large, multilamellar PL vesicles (LMV) was examined. Inhibitors included phosphorylated monosaccharide metabolites, myo-inositol monophosphate (IMP), hexaphosphate (IHP) and hexasulfate (IHS), pyrophosphate (PPi), methyl bisphosphonate (MBP) and phenyl phosphonate, and a series of carboxylic and aromatic sulfonic acids. Inhibitors were incubated with beta 2GPI at 37 degrees C for 2 hr either with dimyristoylphosphatidic acid, 80%/dimyristoylphosphatidyl choline, 20% (DMPA/DMPC) coated on MTW or in a suspension of LMV. Phospholipid-bound beta 2GPI to PA/PC on MTW was detected using an immunoassay based on rabbit anti-beta 2GPI; free beta 2GPI (not bound to LMV) was detected by fluorescence spectroscopy. Inhibition was studied over the range 0.01-9.0 mumoles/10(-4)L (0.1-90 mM). Inhibition at maximum concentration in the MTW system ranged from 0.1% (for ADP) to > 94% (for IHP). IHP also provided the greatest inhibition in the LMV system (76%) and was also effective in displacing beta 2GPI already bound to PL surfaces (approximately 50% displaced at 0.25 mM). These data suggest that a strategy for development of therapeutic agents for APS may be based on the use of small cyclic, organic oligoanions such as inositol derivatives to act as ligands for lysine residues at the PL binding site of beta 2GPI.

A stable, multi-subunit complex of beta2glycoprotein I.

Beta2glycoprotein I (beta2GPI) is a 54-kDa plasma protein which is recognized as an autoantigen for antibodies from patients with antiphospholipid syndrome (APS). SDS-PAGE (under reducing conditions) of beta2GPI from three sources indicates that the 54-kDa beta2GPI band is accompanied by a band corresponding to an 8-kDa protein. In the absence of detergent and reducing agents (native PAGE), beta2GPI demonstrated a large complex (molecular mass approximately 320 kDa) which is dissociable by boiling in 6-8 M urea, yielding several lower molecular mass bands, one of which corresponds to the 8-kDa protein observed in SDS-PAGE. Sera from five healthy adults demonstrated native beta2GPI migration equivalent to the commercially purified protein. Atomic force microscopy (AFM) images of native beta2GPI show aggregrates of particles each having a diameter of 30-35 nm. This is consistent with a globular unit the size of which would be substantially larger than that expected for a 54-kDa protein. These experiments suggest that the 54-kDa beta2GPI monomer subunits exist as a multimeric complex with the 8-kDa protein.