The effect of peri-operative dexmedetomidine on the incidence of postoperative delirium in cardiac and non-cardiac surgical patients: a randomised, double-blind placebo-controlled trial.

Delirium occurs commonly following major non-cardiac and cardiac surgery and is associated with: postoperative mortality; postoperative neurocognitive dysfunction; increased length of hospital stay; and major postoperative complications and morbidity. The aim of this study was to investigate the effect of peri-operative administration of dexmedetomidine on the incidence of postoperative delirium in non-cardiac and cardiac surgical patients. In this randomised, double-blind placebo-controlled trial we included 63 patients aged ≥ 60 years undergoing major open abdominal surgery or coronary artery bypass graft surgery with cardiopulmonary bypass. The primary outcome was the incidence of postoperative delirium, as screened for with the Confusion Assessment Method. Delirium assessment was performed twice daily until postoperative day 5, at the time of discharge from hospital or until postoperative day 14. We found that dexmedetomidine was associated with a reduced incidence of postoperative delirium within the first 5 postoperative days, 43.8% vs. 17.9%, p = 0.038. Severity of delirium, screened with the Intensive Care Delirium Screening Checklist, was comparable in both groups, with a mean maximum score of 1.54 vs. 1.68, p = 0.767. No patients in the dexmedetomidine group died while five (15.6%) patients in the placebo group died, p = 0.029. For patients aged ≥ 60 years undergoing major cardiac or non-cardiac surgery, we conclude that the peri-operative administration of dexmedetomidine is associated with a lower incidence of postoperative delirium.

Size matters: Grey matter brain reserve predicts executive functioning in the elderly.

Preserved executive functioning (EF) is crucial for daily functioning in the elderly and it appears to predict dementia development. We sought to clarify the role of atrophy-corrected cortical grey matter (GM) volume as a potential brain reserve (BR) marker for EF in the elderly. In total, 206 pre-surgical subjects (72.50 ±â€¯4.95 years; mean MMSE score 28.50) were investigated. EF was primarily assessed using the Trail Making Test B (TMT B). Global/ lobar GM volumes were acquired with T1 MP-RAGE. Adjusting for key covariates including a brain atrophy index (i.e. brain parenchymal fraction), multiple linear regression analysis was used to study associations of GM volumes and TMT B. All GM volumes - most notably of global GM - were significantly associated with TMT B independently of GM atrophy (ß = -0.201 to -0.275, p = 0.001-0.012). Using atrophy-corrected GM volume as an estimate of maximal GM size in youth may serve as a BR predictor for cognitive decline in future studies investigating BR in the elderly.

Personalized risk prediction of postoperative cognitive impairment - rationale for the EU-funded BioCog project.

Postoperative cognitive impairment is among the most common medical complications associated with surgical interventions - particularly in elderly patients. In our aging society, it is an urgent medical need to determine preoperative individual risk prediction to allow more accurate cost-benefit decisions prior to elective surgeries. So far, risk prediction is mainly based on clinical parameters. However, these parameters only give a rough estimate of the individual risk. At present, there are no molecular or neuroimaging biomarkers available to improve risk prediction and little is known about the etiology and pathophysiology of this clinical condition. In this short review, we summarize the current state of knowledge and briefly present the recently started BioCog project (Biomarker Development for Postoperative Cognitive Impairment in the Elderly), which is funded by the European Union. It is the goal of this research and development (R&D) project, which involves academic and industry partners throughout Europe, to deliver a multivariate algorithm based on clinical assessments as well as molecular and neuroimaging biomarkers to overcome the currently unsatisfying situation.

Metabolism of isobutylnaphthyl acetic acid in rats: determination of the chemical structures of metabolites.

After oral and intravenous administration of radiolabelled isobutylnaphthyl acetic acid (INAA) to rats two metabolites were isolated from urine and plasma by HPLC. Field desorption, high resolution electron impact mass spectrometry as well as GC-MS after derivatization were used for structure elucidation and identification of the metabolites. The main biotransformation product in rat urine was found to be 5-(2'-hydroxy-2'-methyl-propyl)-1-naphthyl acetic acid (M1). The main metabolite in plasma was derived and was found to be 5-(2'-carboxypropyl)-1-naphthyl acetic acid (M2).

Metabolism and pharmacokinetics of metaclazepam (Talis), Part III: Determination of the chemical structure of metabolites in dogs, rabbits and men.

The metabolism of 7-bromo-1-methyl-2-methoxymethyl-5-(2'-chlorophenyl)-2, 3-dihydro-1H-1,4-benzodiazepine (metaclazepam, Talis) in animals and men is described. Based upon mass spectrometry fifteen metabolites could be identified. Qualitative and quantitative differences in the biotransformation products of metaclazepam in comparison with the well known metabolites of other drugs in the 1,4-benzodiazepine class could be demonstrated. Metabolites with a benzodiazepine-2-one structure representing the most characteristic feature of other 1,4-benzodiazepines and their metabolites, were found in trace amounts only. The major metabolic pathways of metaclazepam led via stepwise demethylation of the O-methyl and/or the N-methyl group to O-demethyl-metaclazepam (M 2), N-demethyl-metaclazepam (M 7) and bis-demethyl-metaclazepam (M 6). Further aromatic hydroxylation yielded the metabolite M 1. Two metabolites with amino-benzophenone structure (M 5, M 8) which are in general known to result from other 1,4-benzodiazepines could be detected. Additionally a 3-oxo-benzodiazepine (M 4) was found. Minor biotransformation pathways led to a chlorophenyl-bromo-benzodiazepine (M 9) by loss of the side chain from bis-demethyl-metaclazepam and N-demethyl-metaclazepam. By further oxidation and degradation the 2-oxo-benzodiazepine M 10 and the dihydro-quinazoline M 12 were formed. The respective N-methylated metabolites M 13 and M 16 were possibly generated by the same pathway. Still open is the formation of M 15, a 1-methyl-3-hydroxy-4-(2'-chlorophenyl)-6-bromo-1,2-dihydroquinoline and M 11, a 2-methyl-4-(2'-chlorophenyl)-6-bromo-quinazoline. The substitution of bromine by a hydroxyl group during the formation of M 14 can be explained by a NIH-shift mechanism. Quantitative investigations show that the methoxymethyl side chain in the benzodiazepine ring system of metaclazepam acts as an effective barrier with respect to the metabolic attack at position two. We assume that this barrier only can be overcome by complete side chain degradation. This multi-step reaction can hardly compete with more favourable and faster conjugation and elimination processes.

Pharmacokinetics and metabolism of 14C isobytylnaphtyl acetic acid in rat.

After oral administration to rats, absorption of INAA was slow but complete. Plasma level curves reached a plateau for INAA as well as for the two metabolites, which were rapidly formed (MI and MII). The plateau concentration led to an increase of the apparent elimination half-life, which was short after i.v. administration due to the small volume of distribution and to the high rate of metabolism. In any case the half-life was independent of the dose and the pharmacokinetics of INAA remained linear from 1.5 to 15 mg/kg. The two rapidly formed plasma metabolites were eliminated more slowly than INAA. INAA and its metabolites were distributed only sparsely in all tissues under investigation, probably due to the high protein binding. Both routes of administration resulted in elimination of the radioactivity mainly by the urine. Besides the two main metabolites with known structures (MI and MII) small amounts of INAA and two additional metabolites were detected.