Determination of chidamide in rat plasma and cerebrospinal fluid.

Chidamide is a new subtype-selective histone deacetylase inhibitor (HDACi), which has been approved for the treatment of recurrent or refractory peripheral T-cell lymphoma (PTCL) in China. However, there are few studies about the application of chidamide in PTCL with central nervous system (CNS) involvement. It is essential to investigate the penetration of chidamide in the blood brain barrier (BBB). LC-MS methods were established firstly to determine the concentration of chidamide in rat plasma and CSF. Then five rats were anaesthetized and the plasma and CSF samples were collected at the time of 5, 15, 30, 60, 120, 180, 240, 360 and 480 min after being administered 1 mg/kg chidamide by intravenous injection, respectively. All samples were analyzed with the established LC-MS method by using the precursor/product transitions (m/z) of 391.1/265.1 for chidamide and 441.1/138.2 for internal standard (IS). The PK parameters were calculated after both of the concentrations of chidamide in plasma and CSF were determined. The penetration ratio of chidamide in BBB ranged from 0.19% to 0.67%. Result indicated chidamide could pass through the BBB, enter into the CNS and have the potential to be utilized in PTCL with CNS involvement.

Marbostat-100 Defines a New Class of Potent and Selective Antiinflammatory and Antirheumatic Histone Deacetylase 6 Inhibitors.

Epigenetic modifiers of the histone deacetylase (HDAC) family contribute to autoimmunity, cancer, HIV infection, inflammation, and neurodegeneration. Hence, histone deacetylase inhibitors (HDACi), which alter protein acetylation, gene expression patterns, and cell fate decisions, represent promising new drugs for the therapy of these diseases. Whereas pan-HDACi inhibit all 11 Zn2+-dependent histone deacetylases (HDACs) and cause a broad spectrum of side effects, specific inhibitors of histone deacetylase 6 (HDAC6i) are supposed to have less side effects. We present the synthesis and biological evaluation of Marbostats, novel HDAC6i that contain the hydroxamic acid moiety linked to tetrahydro-ß-carboline derivatives. Our lead compound Marbostat-100 is a more potent and more selective HDAC6i than previously established well-characterized compounds in vitro as well as in cells. Moreover, Marbostat-100 is well tolerated by mice and effective against collagen type II induced arthritis. Thus, Marbostat-100 represents a most selective known HDAC6i and the possibility for clinical evaluation of a HDAC isoform-specific drug.

Lack of Antiparkinsonian Effects of Systemic Injections of the Specific T-Type Calcium Channel Blocker ML218 in MPTP-Treated Monkeys.

Dopaminergic medications ameliorate many of the motor impairments of Parkinson's disease (PD). However, parkinsonism is often only partially reversed by these drugs, and they can have significant side effects. Therefore, a need remains for novel treatments of parkinsonism. Studies in rodents and preliminary clinical evidence have shown that T-type calcium channel (TTCC) antagonists have antiparkinsonian effects. However, most of the available studies utilized nonselective agents. We now evaluated whether systemic injections of the specific TTCC blocker ML218 have antiparkinsonian effects in MPTP-treated parkinsonian Rhesus monkeys. The animals were treated chronically with MPTP until they reached stable parkinsonism. In pharmacokinetic studies, we found that ML218 reaches a peak CSF concentration 1-2 h after s.c. administration. In electrocardiographic studies, we found no effects of ML218 on cardiac rhythmicity. As expected, systemic injections of the dopamine precursor L-DOPA dose-dependently increased the movements in our parkinsonian animals. We then tested the behavioral effects of systemic injections of ML218 (1, 10, or 30 mg/kg) or its vehicle, but did not detect specific antiparkinsonian effects. ML218 (3 or 10 mg/kg) was also not synergistic with L-DOPA. Using recordings of electrocorticogram signals (in one animal), we found that ML218 increased sleep. We conclude that ML218 does not have antiparkinsonian effects in MPTP-treated parkinsonian monkeys, due at least in part, to the agent's sedative effects.

Regional distribution and in vivo binding of the atypical antipsychotic drug remoxipride. A biochemical and autoradiographic analysis in the rat brain.

The regional brain distribution and binding of the antipsychotic benzamide drug remoxipride was studied in the male rat. After i.v. injections of 3H-remoxipride (1 mumol.kg-1) more than 85% of the radioactivity was identified as authentic remoxipride in brain by using reversed-phase liquid chromatography. Autoradiographic and spectroscopic analysis showed that 3H-remoxipride was distributed relatively even in different brain areas, with exception of the following structures, which showed highest drug concentrations: the choroid plexus, septum, medial part of the caudate nucleus, different areas of the thalamus and hypothalamus situated close to the cerebral ventricles. A closer analysis of the autoradiograms showed a gradient of radioactivity extending from the cerebral ventricles to the deeper parts of the brain at 30 minutes after injections. After 60 minutes radioactivity was detected throughout all forebrain dopamine receptive areas. These findings suggest that remoxipride enters the cerebrospinal fluid (CSF) via the vascular bed of the choroid plexus and that it enters the brain interstitial fluid from the CSF. In the caudate nucleus, nucleus accumbens, olfactory tubercle and olfactory bulb 30-40% of the radioactivity was reduced by pretreatment with the dopamine D-2 selective drug raclopride. In addition, small, but significant, reductions (10-15%) of 3H-remoxipride derived radioactivity was found in the neocortex, hippocampus and the cerebellum, suggesting that remoxipride interacts with a D-2 receptor also in these cortical structures. Taken together, these studies show that after i.v. injections, 3H-remoxipride enters the brain primarily in unmetabolized form when given in doses that affect DA receptor mediated behaviours, that it distributes to most areas throughout the neuraxis and that it binds to D-2 receptors in different parts of the basal ganglia, neocortex, hippocampus and cerebellum.