Some Hydroids (Cnidaria, Hydrozoa) from the Great Australian Bight in the collection of the South Australian Museum.

This report adds to knowledge of the shelf hydroid fauna of the Great Australian Bight. Hydroids were collected by the South Australian Museum and Department of Primary Industries of South Australia (PIRSA). Well known species are annotated, poorly known species are redescribed and four new species are described.

Two bathyal hydroids (Hydrozoa: Leptothecata) from the Southwest Indian Ocean.

Two species of hydroids were recovered from a mooring rope and experimentally deployed whale bone attached to an underwater transponder buoy at a depth of 732 m on the Coral Seamount on the Southwest Indian Ocean Ridge (41° 22.31'S, 54° 57'E) in the Southern Indian Ocean. The material was collected approximately 1,500 km south south-east of Madagascar during Voyage JC066 of the British Royal Research Ship R.R.S. James Cook on 20/11/2011. Hydroids were collected from the mooring rope and whale bone on board the ship after underwater retrieval by ROV.

A new species of Gonionemus (Hydrozoa: Limnomedusae) from southern Australia.

A new species of a crawling limnomedusa belonging to the genus Gonionemus (Hydrozoa: Limnomedusae: Olindiidae) was collected from the brown alga Cystophora monilifera in an intertidal rock pool in Western Port, Victoria, Australia. The new species is described and compared with the three known species of Gonionemus. The mitochondrial DNA barcode markers cytochrome oxidase I and 16S rRNA were sequenced and compared to sequences from other olindiid species. The sequencing results corroborate the morphological findings.

An evaluation of the brain distribution of [(11)C]GSK1034702, a muscarinic-1 (M 1) positive allosteric modulator in the living human brain using positron emission tomography.

BACKGROUND: The ability to quantify the capacity of a central nervous system (CNS) drug to cross the human blood-brain barrier (BBB) provides valuable information for de-risking drug development of new molecules. Here, we present a study, where a suitable positron emission tomography (PET) ligand was not available for the evaluation of a potent muscarinic acetylcholine receptor type-1 (M1) allosteric agonist (GSK1034702) in the primate and human brain. Hence, direct radiolabelling of the novel molecule was performed and PET measurements were obtained and combined with in vitro equilibrium dialysis assays to enable assessment of BBB transport and estimation of the free brain concentration of GSK1034702 in vivo. METHODS: GSK1034702 was radiolabelled with (11)C, and the brain distribution of [(11)C]GSK1034702 was investigated in two anaesthetised baboons and four healthy male humans. In humans, PET scans were performed (following intravenous injection of [(11)C]GSK1034702) at baseline and after a single oral 5-mg dose of GSK1034702. The in vitro brain and plasma protein binding of GSK1034702 was determined across a range of species using equilibrium dialysis. RESULTS: The distribution of [(11)C]GSK1034702 in the primate brain was homogenous and the whole brain partition coefficient (V T) was 3.97. In contrast, there was mild regional heterogeneity for GSK1034702 in the human brain. Human whole brain V T estimates (4.9) were in broad agreement with primate V T and the f P/f ND ratio (3.97 and 2.63, respectively), consistent with transport by passive diffusion across the BBB. CONCLUSION: In primate and human PET studies designed to evaluate the transport of a novel M1 allosteric agonist (GSK1034702) across the BBB, we have demonstrated good brain uptake and BBB passage consistent with passive diffusion or active influx. These studies discharged some of the perceived development risks for GSK1034702 and provided information to progress the molecule into the next stage of clinical development. TRIAL REGISTRATION: Clinical trial details: 'Brain Uptake of GSK1034702: a Positron Emission Tomography (PET) Scan Study.'; clinicaltrial.gov identifier: NCT00937846 .

Receptor occupancy and brain free fraction.

This study was designed to investigate whether brain unbound concentration (C(u,brain)) is a better predictor of dopamine D(2) receptor occupancy than total brain concentration, cerebrospinal fluid concentration (C(CSF)), or blood unbound concentration (C(u,blood)). The ex vivo D(2) receptor occupancy and concentration-time profiles in cerebrospinal fluid, blood, and brain of six marketed antipsychotic drugs were determined after oral administration in rats at a range of dose levels. The C(u,brain) was estimated from the product of total brain concentration and unbound fraction, which was determined using a brain homogenate method. In conclusion, the C(u,brain) of selected antipsychotic agents is a good predictor of D(2) receptor occupancy in rats. Furthermore, C(u,brain) seems to provide a better prediction of D(2) receptor occupancy than C(CSF) or C(u,blood) for those compounds whose mechanism of entry into brain tissue is influenced by factors other than simple passive diffusion.

Attenuation of amphetamine-induced activity by the non-selective muscarinic receptor agonist, xanomeline, is absent in muscarinic M4 receptor knockout mice and attenuated in muscarinic M1 receptor knockout mice.

The muscarinic acetylcholine receptor (mAChR) agonist, xanomeline, attenuates amphetamine-induced activity in WT mice. This effect is abolished in mice lacking the M(4) muscarinic acetylcholine receptor (M(4) mAChR KO) and partially attenuated in mice lacking M(1) muscarinic acetylcholine receptor (M(1) mAChR KO). Collectively, these data suggest that the efficacy exhibited by xanomeline in the mouse amphetamine-induced hyperactivity model, is mediated predominantly by M(4) muscarinic acetylcholine receptors, and that M(1) muscarinic acetylcholine receptors may play a more minor role. This supports the hypothesis that activation of M(4), and to a lesser extent M(1) muscarinic acetylcholine receptors, may represent a potential target for the treatment of psychosis seen in schizophrenia.