In vivo imaging of muscarinic cholinergic receptors in temporal lobe epilepsy with a new PET tracer: [76Br]4-bromodexetimide.

UNLABELLED: Muscarinic acetyl cholinergic receptors (mAChRs) may be involved in the pathophysiology of partial epilepsy. Previous experimental and imaging studies have reported medial temporal abnormalities of mAChR in patients with medial temporal lobe epilepsy (MTLE). Suitable radiotracers for mAChR are required to evaluate these disturbances in vivo using PET. Dexetimide is a specific mAChR antagonist that has been labeled recently with 76Br. This first study in humans focused on regional distribution and binding kinetics of [76Br]4-bromodexetimide (BDEX) in patients with MTLE. METHODS: Ten patients with well-lateralized MTLE had combined MRI, 18F-fluorodeoxyglucose (FDG) PET and 76Br-BDEX PET studies. Time-activity curves were generated in PET-defined regions of interest, including the medial, polar and lateral regions of the temporal lobe; the basal ganglia; the external and medial occipital cortex; and the white matter. RESULTS: The highest radioactivity concentration was observed in the basal ganglia and in the cortical regions, whereas radioactivity was lower in the white matter. On late images of PET studies, 76Br-BDEX uptake was statistically significantly decreased only in the medial temporal region ipsilateral to the seizure focus (1.37 +/-0.28, P < 0.01) as determined by FDG PET imaging, anatomic MRI and electroencephalogram correlation, compared with the contralateral medial temporal region (1.46 +/- 0.31). CONCLUSION: 76Br-BDEX concentration is reduced in the temporal lobe ipsilateral to the seizure focus in patients with MTLE. This preliminary study suggests that 76Br-BDEX is a suitable radiotracer for studies of mAChR in humans. Further studies are required to investigate the potential value of 76Br-BDEX PET in other neurological disorders with muscarinic disturbances.

Evaluation of a novel diffusion cell for in vitro transdermal permeation: effects of injection height, volume and temperature.

The objective of this study was to evaluate the performance of a new, compact, dynamic diffusion cell for in vitro transdermal permeation. These so-called Kelder-cells were developed as an automated alternative to the static Franz diffusion cells. The new cells were used in combination with the ASPEC-system (automatic sample preparation with extraction columns) which was initially designed for the automation of solid-phase extractions. Three variables were tested to optimize the performance of the new cell system: injection height into the inlet compartment, volume flowing through the receptor compartment and temperature. Experiments were performed using the tritium labelled anticholinergic [3H]dexetimide permeating through an artificial membrane (Silastic). The injection height of the needle into the inlet compartment of the cell should be programmed at -34 mm to ensure complete air tightness, thus forcing the buffer to flow through the cell. The volume of buffer flow through the receptor compartment is important in maintaining sink conditions: a volume of 117 microliters was chosen to replace the total content of the cell (84 microliters) every 2 min. The temperature was precisely controlled in a thermostatic cabinet to minimize variations in experimental conditions. For [3H]dexetimide, an increase in temperature of 20 degrees C reduced the lag time by a factor of approximately two, however the influence on the flux was negligible. The data for the Kelder-cells were comparable with static Franz diffusion cells at a pseudo-steady state, however Kelder-cells have the advantage of automatic sampling, continuous replacement of the receptor solution, and unattended operation over at least 24 h.

Pharmacological characterization and positron emission tomography evaluation of 4-[76Br]bromodexetimide and 4-[76Br]bromolevetimide for investigations of central muscarinic cholinergic receptors.

4-[76Br]bromodexetimide and its inactive enantiomer 4-[76Br]bromolevetimide were prepared via electrophilic bromodesilylation using chloramine-T and no-carrier-added (NCA) [76Br]NH4. In vitro, Bmax measured on rat cortex membranes were 3.7 +/- 0.2 and < 0.07 pmol/mg protein for 4-[76Br]bromodexetimide and 4-[76Br]bromolevetimide, respectively. The kD of 4-[76Br]bromodexetimide was 1.9 +/- 0.3 nM. In vivo studies in rats showed specific uptake of 4-[76Br]bromodexetimide in cortex, striatum, thalamus and hippocampus. No specific uptake was observed with 4-[76Br]bromolevetimide. With [76Br]bromodexetimide, positron emission tomography (PET) studies in primates demonstrated a preferential accumulation of the radioactivity in the cortex and striatum which was displaced to the level of cerebellum by dexetimide. With 4-[76Br]bromolevetimide, the radioactivity concentrations in the cortex and striatum were similar to that of cerebellum.

Human dosimetry and biodistribution of iodine-123-iododexetimide: a SPECT imaging agent for cholinergic muscarinic neuroreceptors.

UNLABELLED: Iodine-123-iododexetimide (IDEX) has recently been used for SPECT imaging of muscarinic cholinergic neuroreceptors (mAChR) in humans. We report the human radiation dosimetry, whole-body and normal cerebral distribution of IDEX. METHODS: Serial whole-body planar and brain SPECT scans were performed over 24 hr in four normal subjects. Organ activity was calculated from attenuation-corrected geometric mean counts from ROIs drawn over visible organs. Thigh activity was used for background subtraction. Organ absorbed doses and effective dose were calculated using the MIRD schema. Brain SPECT was performed 6 hr postinjection in ten normal subjects. ROIs placed over cortical and subcortical structures were used to determine brain distribution. RESULTS: The effective dose was 24.7 microSv/MBq. An average of 54% of IDEX remained in the body background. Decay-corrected brain uptake was 6.9% of injected dose at 1 hr, 8.6% at 6 hr and 8.1% at 24 hr. Regional brain distribution showed high uptake in striatum and cortex with low activity in thalamus and cerebellum. At 6 hr, activity relative to striatum was 70% for frontal and parietal cortex, 102% for occipital cortex, 54% for thalamus and 11% for cerebellum. CONCLUSION: Iodine-123-IDEX produced high quality SPECT images with activity at 6 hr reflecting the known distribution of mAChR receptors. The favorable dosimetry of IDEX and high synthetic yield (50%-70%) suggest it to be a suitable agent for clinical studies.

Heterogeneous receptor binding of classical quaternary muscarinic antagonists. I. Bovine tissue distribution.

In competition experiments with the tertiary radioligand [3H]dexetimide, classical quaternary muscarinic antagonists like ipratropium bromide and N-methylscopolamine bromide distinguished two muscarinic binding sites in bovine brain (total brain minus cerebellum) membranes, in contrast to their tertiary analogues, atropine and scopolamine, which recognized only one binding site. This binding behavior was found to be almost identical in bovine striatal membranes, both in terms of binding affinities and proportions of high (Q1) and low (Q2) affinity binding sites. Both in total brain and in striatal membranes, the Q1/Q2 binding heterogeneity was independent of pirenzepine binding heterogeneity (M1/M2). In peripheral tissues, the binding properties of quaternary muscarinic antagonists varied. Whereas tertiary as well as quaternary compounds showed only high affinity binding towards muscarinic receptors in bovine atrial and left ventricular membranes, heterogeneous binding behavior was observed with quaternary but not with tertiary antagonists in bovine tracheal smooth muscle membranes. The tissue distribution found in the present study suggests that bovine tracheal smooth muscle contraction studies might shed light on the functional significance of the anomalous binding behavior of quaternary muscarinic antagonists.

In vivo biodistribution of two [18F]-labelled muscarinic cholinergic receptor ligands: 2-[18F]- and 4-[18F]-fluorodexetimide.

Two [18F]-labelled analogues of the potent muscarinic cholinergic receptor (m-AChR) antagonist, dexetimide, were evaluated as potential ligands for imaging m-AChR by positron emission tomography (PET). Intravenous administration of both 2-[18F]- or 4-[18F]-fluorodexetimide resulted in high brain uptake of radioactivity in mice. High binding levels were observed in m-AChR rich areas, such as cortex and striatum, with low levels in the receptor-poor cerebellum. Uptake of radioactivity was saturable and could be blocked by pre-administration of dexetimide or atropine. Drugs with different sites of action were ineffective at blocking receptor binding. The results indicate that both radiotracers are promising candidates for use in PET studies.

Positron labeled muscarinic acetylcholine receptor antagonist: 2- and 4-[18F]fluorodexetimide. Syntheses and biodistribution.

Two 18F-labeled analogues of dexetimides, 2-[18F]fluorodexetimide (2-FDEX) and 4-[18F]fluorodexetimide (4-FDEX), were prepared and evaluated in vivo as possible agents for the study of the muscarinic acetylcholine receptor (mAChR) with PET. Two synthetic approaches, a 2-step reductive alkylation procedure and a 4-step alkylation approach, were investigated. The alkylation approach with higher overall radiochemical yields was used to prepare 2- and 4-FDEX for biodistribution studies. The overall synthesis time for both compounds was 2.5 h and the overall radiochemical yield at end-of-synthesis was 12%. The specific activity was found to be greater than 600 mCi/mumol. Biodistribution studies of 2-FDEX in rats produced striatum-to-cerebellum and cortex-to-cerebellum ratios of 8.6 +/- 1.1 and 8.4 +/- 1.0 at 1 h after injection, and 12.1 +/- 2.1 and 10.7 +/- 2.2 at 3 h, respectively. Substantial radioactivity detected in bone indicated the in vivo defluorination of 2-FDEX. The striatum-to-cerebellum ratio for 4-FDEX was slightly lower at 1 h (5.9 +/- 0.9) but equally high at 3 h (12.3 +/- 2.0) when compared to 2-FDEX, and there was little bone uptake. The uptake of both 2-FDEX and 4-FDEX into mAChR rich brain regions (e.g. striatum, cortex) was blocked by a dose of dexetimide (5 mg/kg). Our results suggest 4-FDEX is a potential PET agent for study mAChR in vivo.