Benzodiazepine receptor binding in cerebellar degenerations studied with positron emission tomography

We used positron emission tomography with [ 11 C]flumazenil to study gamma‐aminobutyric acid type A/benzodiazepine receptor binding quantitatively in the cerebral hemispheres, basal ganglia, thalamus, cerebellum, and brainstem of 72 subjects, including 14 with multiple system atrophy of the ataxic (olivopontocerebellar atrophy) type, 5 with multiple system atrophy of the extrapyramidal/autonomic (Shy‐Drager syndrome) type, 18 with sporadic olivoponto‐cerebellar atrophy, 15 with dominantly inherited olivopontocerebellar atrophy, and 20 normal control subjects with similar age and sex distributions. In comparison with data obtained from the normal control subjects, we found significantly Decemberreased ligand influx in the cerebellum and brainstem of multiple system atrophy patients of the olivopontocerebellar atrophy type and in patients with sporadic olivopontocerebellar atrophy, but not in patients with multiple system atrophy of the Shy‐Drager syndrome type. Despite these differences in ligand influx, benzodiazepine binding was largely preserved in the cerebral hemispheres, basal ganglia, thalamus, cerebellum, and brainstem in patients with multiple system atrophy of both types as well as those with sporadic or dominantly inhierited olivoponto‐cerebellar atrophy as compared with normal control subjects. The finding of relative preservation of benzodiazepine receptors indicates that these sites are available for pharmacological therapy in these disorders.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/92122/1/410380209_ftp.pd

Mechanisms of comorbidity, continuity, and discontinuity in anxiety-related disorders

We discuss comorbidity, continuity, and discontinuity of anxiety-related disorders from the perspective of a two-dimensional neuropsychology of fear (threat avoidance) and anxiety (threat approach). Pharmacological dissection of the "neurotic" disorders justifies both a categorical division between fear and anxiety and a subdivision of each mapped to a hierarchy of neural modules that process different immediacies of threat. It is critical that each module can generate normal responses, symptoms of another syndrome, or syndromal responses. We discuss the resultant possibilities for comorbid dysfunction of these modules both with each other and with some disorders not usually classified as anxiety related. The simplest case is symptomatic fear/anxiety comorbidity, where dysfunction in one module results in excess activity in a second, otherwise normal, module to generate symptoms and apparent comorbidity. More complex is syndromal fear/anxiety comorbidity, where more than one module is concurrently dysfunctional. Yet more complex are syndromal comorbidities of anxiety that go beyond the two dimensional fear/anxiety systems: depression, substance use disorder, and attention-deficit/hyperactivity disorder. Our account of attention-deficit/hyperactivity disorder-anxiety comorbidity entails discussion of the neuropsychology of externalizing disorders to account for the lack of anxiety comorbidity in some of these. Finally, we link the neuropsychology of disorder to personality variation, and to the development of a biomarker of variation in the anxiety system among individuals that, if extreme, may provide a means of unambiguously identifying the first of a range of anxiety syndromes

Intervals and the deduction of drug binding site models

In the search for new drugs, it often occurs that the binding affinities of several compounds to a common receptor macromolecule are known experimentally, but the structure of the receptor is not known. This article describes an extraordinarily objective computer algorithm for deducing the important geometric and energetic features of the common binding site, starting only from the chemical structures of the ligands and their observed binding. The user does not have to propose a pharmacophore, guess the bioactive conformations of the ligands, or suggest ways to superimpose the active compounds. The method takes into account conformational flexibility of the ligands, stereospecific binding, diverse or unrelated chemical structures, inaccurate or qualitative binding data, and the possibility that chemically similar ligands may or may not bind to the receptor in similar orientations. The resulting model can be viewed graphically and interpreted in terms of one or more binding regions of the receptor, each preferring to be occupied by various sorts of chemical groups. The model always fits the given data completely and can predict the binding of any other ligand, regardless of chemical structure. The method is an outgrowth of distance geometry and Voronoi polyhedra site modeling but incorporates several novel features. The geometry of the ligand molecules and the site is described in terms of intervals of internal distances. Determining the site model consists of reducing the uncertainty in the interregion distance intervals, and this uncertainty is described as intervals of intervals. Similarly, the given binding affinities and their experimental uncertainties are treated as intervals in the affinity scale. The final site model specifies an entire region of interaction energy parameters that satisfy the training set rather than a single set of parameters. Predicted binding for test compounds results in an interval which, when compared to the experimental interval, may be correct, incorrect, or vague. There is a pervasive ternary logic involved in the assessment of predictions, in the search for a satisfactory model, and in judging whether a given molecule may bind in a particular orientation: true, false, or maybe. The approach is illustrated on an extremely simple artificial example and on a real data set of cocaine analogues binding to a nerve membrane receptor in vitro. © 1995 by John Wiley & Sons, Inc.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/38288/1/540160412_ftp.pd

Effects of Antiepileptic Drugs on GABA Responses and on Reduction of GABA Responses by PTZ and DMCM on Mouse Neurons in Cell Culture

The mechanisms of action of antiepileptic drugs effective against generalized absence seizures (antiabsence AEDs) remain uncertain. Antiabsence AEDs are generally effective against seizures induced in experimental animals by pentylenÉtÉtrazol (PTZ) and methyl-6,7-dimethoxy-4-ethyl-Β-carboline-3-carboxylate (DMCM), drugs which reduce GABAergic inhibition. Thus, antiabsence AEDs have been suggested to enhance GABAergic inhibition. We studied the effects of several AEDs on GABA responses recorded from mouse spinal cord neurons grown in primary dissociated cell culture. Four antiabsence AEDs were included: ethosuximide (ESM), dimethadione (DMO), sodium valproate (VPA), and diazepam (DZP). Two experimental AEDs, CGS 9896 and ZK 91296, with anticonvulsant action against PTZ- or DMCM-induced seizures were also included. Possible effects of the antiabsence and experimental AEDS on PTZ- and DMCM-induced inhibition of GABA responses were also evaluated. PTZ and DMCM revers-ibly reduced GABA responses in a concentration-dependent manner. PTZ complÉtÉly inhibited GABA responses at 10 mM (IC 50 of 1.1 mM), whereas DMCM-induced inhibition of GABA responses reached a plateau level of 39% of control values at 1 p.M (IC 50 of 33 nM). ESM (1,200 ΜM), DMO (6 mM), VPA (200 u.M), CGS 9896 (2 ΜM), and ZK 98% (2 Μ M ) did not alter GABA responses. DZP enhanced GABA responses in a concentration-dependent manner. The inhibition of GABA responses produced by PTZ 1 mM was unaltered by ESM (600 Μ M ), DMO (6 mM), CGS 9896 (1 Μ M), or ZK 9896 (1 ΜM)- Coapplication of VPA (200 ΜM) and PTZ (1 mM) slightly enhanced the PTZ effect. DZP (> 10 nM), however, reversed the PTZ-induced reduction of GABA responses. The DMCM (250 nM) inhibition of GABA-responses was unaltered by ESM (600 Μ.M), DMO (2 mM), or VPA (200 ΜM). CGS 9896 (2 Μ M ) and ZK 91296 (2 ΜM), however, antagonized the DMCM effect. DZP (> 10 nM) significantly reversed the DMCM-induced inhibition of GABA responses. The lack of effect of VPA, ESM, and DMO on postsynaptic GABA responses suggests that direct enhancement of postsynaptic GABA action is not a common mechanism of action of antiabsence AEDs. The AEDs DZP, CGS 98%, and ZK 912% all reversed DMCM, but not PTZ, reduction of GABA responses, suggesting that these AEDs blocked DMCM seizures by acting at benzodiazepine receptors. However, since only DZP enhanced GABA responses, it is unclear how CGS 98% and ZK 912% blocked PTZ seizures. Key Words: Anticonvulsants–GABA–Neuron culture–Cell culture–Spinal cord neurons–Convulsants. RESUMEN Los mecanismos de accidn de las medicaciones antiepilÉpticas eficaces contra los ataques generalizados de ausencia (AEDs antiausencia) permanecen inciertos. Los AEDs antiausencia son, generalmente, eficaces contra ataques experimentales inducidos por el pentilentetrazol (PTZ) y el metil-6,7-dimetoxy-4-etil-Pcarbolina-3-carboxilato (DMCM) en animates, medicaciones que reducen la inhibiciÓn GABAÉrgica. Hemos estudiado los efectos de varios AEDs sobre respuestas-GABA registradas en las neuronas de la mÉdula espinal de ratones que habian crecido en cultivos de cÉlulas primarieas disociadas. Cuatro AEDs antiausencia fueron incluidos: etoxusimida (ESM), dimetadiona (DMO), valproato sÓdico (VPA) y diazepan (DZP). TambtÉn se incluyeron dos AEDs experimentales, CGS 9896 y ZK 912%, con acciÓn anticonvulsiva contra los ataques inducidos por PTZ o DMCM. TambiÓn se valoraron los posibles efectos de los AEDs antiausencia y experimentales sobre el PTZ y la inhibiciÓn de las respuestas-GABA inducidas por el DMCM. El PTZ y el DMCM redujeron las respuestas-GABA de modo reversible y dependiendo de sus concentraciones. El PTZ inhibiÓ cmpleta-mente las respuestas-GABA a 10 mM (IC 50 de 1.1 mM) mientras que la inhibitiÓn de las respuestas GABA inducida por el DMCM alcanzÓ un nivel estable del 39% de los valores control con 1 Μ. M (IC 50 de 33 mM). La ESM (1200 Μ.M), la DMO (6 mM), el VPA (200 Μ M ), el CGS 98% (2 Μ M) y el ZK 98% (2 Μ M) no alteraron las respuestas-GABA. El DZP aumentÓ las respuestas GABA de una manera concentraciÓn-dependiente. La inhibition de las respuestas-GABA producidas por el PTZ (1 mM), no se altero con las ESM (600 Μ M), la DMO (6 mM), el CGS 98% (1 Μ M) o el ZK 98% (1 Μ .M). La co-aplicacion de VPA (200 Μ M) y el PTZ (1 mM) aument6 ligeramente los efectos del PTZ. Sin embargo el DZP (10 nM) revirtiÓ significativamente la inhibition de las respuestas GABA inducidas por el DMCM. La falta de efectos de CPA, ESM y DMO sobre las respuestas GABA post-sinÁpticas sugiere que el incremento de la acciÓn GABA post-sinÁptica no es un mecanismo comÚn de actuatiÓn de las AEDs antiausencia. Todas las AEDs DZP, CGS 98% y ZK 912% revirtieron la reduction de las respuestas GABA producidas por el DMCM pero no las inducidas por el PTZ lo que sugiere que estos AEDs bloquean los ataques DMCM actuando sobre los receptores de la benzodiazepina. Sin embargo, puesto que el incremento de las respuestas GABA sÓlÓ se produce por el DZP, permanece todavia sin aclarar el por quÉ el CGS 98% y el ZK 912% bloquean los ataques producidos por el PTZ. ZUSAMMENFASSUNG Der Wirkmechansimus von Antiepileptika gegen generalisierte Absencen ist unklar. Antiabsencemittel sind generell wirkungs-voll gegen PTZ- und Methyl-6,7-Dimethoxy-4-Äthyl-P-Carbolin-Β-Carboxylat (DMCM) induzierte tierexperimentelle AnfÄlle, also von Medikamenten, die die GABA-erge Inhibition reduzieren. Es wurde vermutet, daß Antiabsencemittel die GABA-erge Inhibition verstÄrken. Wir untersuchten die Wirkung von verschiedenen Antiepileptika auf GABA-Antworten in spinalen MÄuseneuronen, die in Zellkulturen gew-achsen waren. Es wurden 4 Absencemittel untersucht: Ethosux-imid (ESM), Dimethadion (DMD), Sodium Valproat (VPA) und Diazepam (DZP). ZusÄtzlich wurden 2 experimentelle Antiepileptika, CGS 98% und ZK 912%, die gegen PTZ0 oder DMCM-induzierte AnfÄlle wirkungsvoll sind, eingeschlossen. Mogliche Wirkungen der Antiabsence- und experimentellen Antiepileptika auf PTZ- und DMCM-induzierte Hemmung der GABA-Antworten wurden ebenfalls ausgewertet. PTZ und DMCM zeigten eine konzentrationsabhÄngige reversible Reduktion der GABA-Antworten. PTZ zeigte eine komplette Hemmung der GABA-Antworten bei 10 mM (IC 50 1,1 mM), DMCM-Hemmung der GABA-Antworten zeigte ein Plateau von 39% der Kontroll-werte bei 1 uJtf (ICJO von 33 mAfl. ESM (1200 uJtf), DMD (6 mM), VPA (200 Μ M), CGS 98% (2 Μ M) und ZK 98% (2 Μ M) anderten nicht die GABA-Antworten. DZP verstarkte die GABA-Antworten konzentrationsabhangig. Die durch PTZ (1 mM) hervorgerufene Hemmung der GABA-Antworten war bei ESM (600 Μ M), DMD (6 mM), CGS 98% (1 mAO und ZK 3836 (1 mM) unverÄndert. ZusÄtliche Anwendung von VPA (200 mM) und PTZ (1 mM) verstÄrkten geringfÜgig den PTZ-Effekt. DZP (10 nM) kehrte die durch PTZ hervorgerufene Reduktion der GABA-Antworten um. Die durch DMCM (250 nM) hervorgerufene Hemmung der GABA-Antworten war durch ESM (600 Μ .M), DMD (2 mM) und VPA (200 Μ M ) unbeeinflusst. CGS 98% (2 Μ M) und ZK 912% (2 Μ M ) antagonisierten die DMCM-Wirkung. DZP (>10 nM) kehrte die durch DMCM-induzierte Hemmung der GABA-Antworten um. Das Fehlen einer Wirkung von VPA. ESM und DMD auf die postsynaptischen GABA-Antworten legen nahe, daß eine direkte VerstÄrkung der postsynaptischen GABA-Aktion kein gemeinsamer Mechanis-mus der Antiabsencemittel darstellt. Die Antiepileptika DZP, CGS 98% und ZK 912% kehrten die DMCM-Wirkung auf die GABA-Antworten um, jedoch nicht die von PTZ, was vermuten lapt, daß diese Antiepileptika die DMCM-AnfÄlle Über die Wirkung an den Benzodiazipin-Rezeptoren verhinderte. Da jedoch nur DZP GABA-Antworten verstarkte, ist unklar, in welcher Weise CGS 98% und ZK 912% die PTZ-AnfaUe ver-hinderten.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/65188/1/j.1528-1157.1989.tb05275.x.pd

Altered excitatory and inhibitory amino acid receptor binding in hippocampus of patients with temporal lobe epilepsy

We examined binding to excitatory amino acid and inhibitory amino acid receptors in frozen hippocampal sections prepared from surgical specimens resected from 8 individuals with medically refractory temporal lobe epilepsy. The excitatory receptors studied included N -methyl-D-aspartate (NMDA), strychnine-insensitive glycine, phencyclidine, and quisqualate. The inhibitory receptors studied were gamma-aminobutyric acid type A (GABA A ) and benzodiazepine. Excitatory and inhibitory amino acid receptor binding were differentially altered in the patients with temporal lobe epilepsy in comparison to 8 age-comparable autopsy control subjects, and changes in receptor binding were regionally selective in four areas. Binding to phencyclidine receptors associated with the NMDA channel was reduced by 35 to 70% in all regions in the hippocampi of the patients. In contrast, binding to the NMDA recognition site and its associated glycine modulatory site was elevated by 20 to 110% in the cornu ammonis (CA) 1 area and dentate gyrus of the hippocampus of the patients. Binding to these sites was unaffected in area CA4. Binding to the quisqualate-type excitatory amino acid receptor was unchanged in all regions except the stratum lacunosum moleculare CA1, where it was increased by 63%. GABA A and benzodiazepine receptor binding was reduced by 20 to 60% in CA1 and CA4, but unchanged in dentate gyrus. The data indicate that excitatory and inhibitory amino acid receptors are altered in the hippocampus of patients with temporal lobe epilepsy.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/50343/1/410290513_ftp.pd

The emergence of new psychoactive substance (NPS) benzodiazepines: a review

The market for new psychoactive substances has increased markedly in recent years and there is now a steady stream of compounds appearing every year. Benzodiazepines consist of only a fraction of the total number of these compounds but their use and misuse has rapidly increased. Some of these benzodiazepines have only been patented, some of them have not been previously synthesised and the majority have never undergone clinical trials or tests. Despite their structural and chemical similarity, large differences exist between the benzodiazepines in their pharmacokinetic parameters and metabolic pathways and so they are not easily comparable. As benzodiazepines have been clinically used since the 1960s many analytical methods exist to quantify them in a variety of biological matrices and it is expected that these methods would also be suitable for the detection of benzodiazepines that are new psychoactive substances. Illicitly obtained benzodiazepines have been found to contain a wide range of compounds such as opiates which presents a problem since the use of them in conjunction with each other can lead to respiratory depression and death. The aim of this review is to collate the available information on these benzodiazepines and to provide a starting point for the further investigation of their pharmacokinetics which is clearly required

The Effect of Opioid Receptor Blockade on the Neural Processing of Thermal Stimuli

The endogenous opioid system represents one of the principal systems in the modulation of pain. This has been demonstrated in studies of placebo analgesia and stress-induced analgesia, where anti-nociceptive activity triggered by pain itself or by cognitive states is blocked by opioid antagonists. The aim of this study was to characterize the effect of opioid receptor blockade on the physiological processing of painful thermal stimulation in the absence of cognitive manipulation. We therefore measured BOLD (blood oxygen level dependent) signal responses and intensity ratings to non-painful and painful thermal stimuli in a double-blind, cross-over design using the opioid receptor antagonist naloxone. On the behavioral level, we observed an increase in intensity ratings under naloxone due mainly to a difference in the non-painful stimuli. On the neural level, painful thermal stimulation was associated with a negative BOLD signal within the pregenual anterior cingulate cortex, and this deactivation was abolished by naloxone