Hydroxybromierung und Methoxybromierung von (Z)-Cycloocten

In addition totrans-2-bromocyclooctanol andtrans-1,2-dibromocyclooctane,cis-4-bromocyclooctanol,cis-1,4-dibromocyclooctane,trans-1,4-dibromocyclooctane, and (Z)-5-bromocyclooctene are obtained, when (Z)-cyclooctene is treated with N-bromosuccinimide in the presence of water. Similarly the methoxybromination of (Z)-cyclooctene gives transanular products.     

Isotopenaustauschvorgänge bei homogen katalysierten reaktionen—II: H/D-Austausch bei der deuterierung von cycloalkenen in gegenwart von tris-(triphenylphosphin-)rhodium(I)-chlorid

The homogeneous deuteration of cycloalkenes in benzene solution at 22±1° under normal pressure using tris(triphenylphosphine)rhodium(I)chloride (1) is reported. In all cases isotopic scrambling accompanies deuteration, the extent of this scrambling depends very much on the ring size. Simultaneously a H/D-exchange takes place in the cycloalkenes. These results are discussed on the base of a mechanistic scheme containing reversible formation of rhodiumalkyl species.     

Determination of Aroma Compounds from Alcoholic Beverages in Spiked Blood Samples by Means of Dynamic Headspace GC–MS

Some aroma compounds found in alcoholic beverages are characteristic of a certain beverage (i.e. 2,4-decadienoic acid ethyl ester is characteristic of pear spirit and 5-butyltetrahydro-4-methylfuran-2-on “whiskey lactone” is characteristic of aged spirits like whiskey). These substances were detectable in beverages but not in blood samples. The aim of this investigation was to find a sensitive sampling technique for aroma compounds in whole blood samples. This technique may be used in forensic toxicology for examination of drinking claims. The method comprises dynamic headspace sampling using a purge and trap concentrator, followed by quantitative gas chromatography–mass spectrometry (dynamic HS–GC–MS). The influence of sample preparation, trap adsorbents and sample temperature as well as desorption time and purge time on the quality of the analytical results were investigated. The following optimal parameters were determined: stirred and diluted whole blood sample without salt addition, use of Carbotrap C as trap material, sample temperature at 80 °C, desorption time 20 min and purge time 30 min. These optimal parameters were used for the determination of detection limits (LOD). The LOD of aroma compounds by means of dynamic headspace sampling were compared with the results of conventional sampling: the static headspace technique. Limits of detection for the aroma compounds with conventional static headspace GC are in the range 400–10,000 μg L^?1. Dynamic headspace–GC was found to be a more sensitive sampling technique for most of the aroma compounds investigated (e.g. C₄–C₈ ethyl esters, benzoic acid ethyl ester, linalool oxide and 4-ethylguaiacol) with detection limits between 1 and 50 μg L^?1, but there were also limits to the sampling of substances with lower volatility like decanoic acid ethyl ester, 2,4-decadienoic acid ethyl ester, eugenol and whiskey lactone with detection limits of about 1,000 μg L^?1.     

Hydroxybromierung,Methoxybromierung und Acetoxybromierung von (Z)- und (E)-Cyclododecen

The reactions of (Z)- and (E)-cyclododecene with N-bromosuccinimide in the presence of water, methanol or acetic acid, are described. In every case,trans-1,2-addition is observed. Whereas hydroxybromination and methoxybromination result in the formation of 2-bromocyclododecanol, and 2-bromo-1-methoxycyclododecane, resp., acetoxybromination gives 1-acetoxy-2-bromocyclododecane in addition to 2,2-dibromodicyclododecylether.

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Aus der Dissertation zur Promotion A,G. Haufe, Karl-Marx-Universität Leipzig, 1975.     

Magnetic Separation Immunoassay for Digoxin in Plasma with Flow Injection Fluorescence Detection

Immunoassay (IA) is a sensitive and selective approach for low level quantitation of drugs. Magnetic separation immunoassays use magnetic beads to facilitate the separation of bound labeled antigens from free antigens in solution. Digoxin was chosen for this study because low level analysis (ngmL^–1) in biological samples isrequired, antibodies to digoxin were commercially available and derivatization procedures for fluorescence labeling were well established. A competitive immunoassay format was used in this study. Streptavidin coated magnetic beads were attached to biotinylated anti-digoxin antibodies for the separation. The inhibition curve for off-line magnetic separation immunoassay of digoxin in spiked plasma was characterized and the dynamic range of the curve was 0.25–2.5ngmL^–1. A power fit weighted by the inverse of concentration was found to provide the best fit to the data (r=0.9934). The percent RSDs for the two controls, 0.8 and 2.2ngmL^–1, were 9.95% and 20.62% (n=6) and the percent errors were 11.75% and 22.63% (n=6), respectively. The limit of detection (LOD) in plasma is 0.14ngmL^–1. The dynamic range of the inhibition curve for on-line magnetic separation immunoassay of digoxin was 0.5–15ngmL^–1 of digoxin. A quadratic fit was found to provide the best fit to the data (r=0.9937). The percent RSDs for the two controls, 4.0 and 12ngmL^–1, were 14.1% and 10.7% (n=6) and the percent errors were 5.8% and 3.3% (n=6) from the spiked value, respectively. The LOD was estimated to be 0.44ngmL^–1 (determined as two times the standard deviation of the blank, n=6). The on-line method has the advantages of being relatively easy to automate in the continuous flow mode and is adaptable for use in conjunction with HPLC separations.