INDEX amine reaction

In the flask were placed 10.0 g of the propargylic amine (see Chapter lIII-5, Exp. 1). The air in the flask was replaced with nitrogen and a solution of 0.01 mol of KO-tert.-Ci,H,3 in 10 g of THF (free from hydroperoxide) was added. The mixture was warmed at about 40 C. A weakly exothermic reaction was observed and the temperature rose to about 45°C. After 1-2 min the gel originally present, had disappeared almost completely and a brown solution had formed. The refractive index of the solution (note 1) was measured after intervals of about 2 min. After the... 

Examples of the protection of alkynes, carboxylic acids, alcohols, phenols, aldehydes, amides, amines, esters, ketones, and alkenes are also indexed on p. xvii. Section (designated with an A 15A, 30A, etc.) with protecting group reactions are located at the end of pertinent chapters. 

The most important route to 1-acylaminoanthraquinones involves reaction of 1-aminoanthraquinone with acid chlorides in an organic solvent. Reaction of 1-aminoanthraquinone with benzoylchloride in nitrobenzene at 100 to 150°C affords 1-benzoylaminoanthraquinone, a yellow pigment which is registered as Colour Index Constitution No. 60515. The reaction may also be performed in the presence of a tertiary amine, which acts as a proton acceptor ... 

An appendix systematically lists references to reactions of dialkylalkoxy-malonates with amines, including not only the common aliphatic and aromatic amines, but also a very wide variety of heterocyclic amines classified according to ring system. The appendix also provides systematic references to the different ring systems obtained by ring closure of the dialkylaminomethylenemalonates. The appendix should be used in conjunction with the subject index a separate subject index is provided for this monograph volume. 

In order to integrate further some of the various reactions mentioned, and to detect its presence by other methods, the vessels of the rat s mesoappendix were employed as a test object (Chambers-Zweifach preparation, 12). A good correlation between the presence of a vasoexcitor material-like substance in the extracts and the presence of hypertension was found. When the whole rat was used for assay, a much cruder index, sizable quantities of active pressor material were isolated from the blood only of those patients showing at least a degree of renal impairment (lessened ability to concentrate urine, etc.). In general it may be stated unequivocally that patients with severe hypertension have in their arterial blood extractable substances which are pressor for the rat there are less or undemonstrable amounts in blood of less severe or neurogenic hypertensive patients there is little or none in blood of normotensive subjects a vasoexcitor material-like activity is exerted by blood from most hypertensive patients adenyl compounds, having a depressor action, present in extracts of blood are less prevalent in those from hypertensive patients the active rat pressor material (pherentasin) is probably aminelike in nature, is not a protein, but may be a simple peptide or an amine. 

Morrall2 used a HPLC system with two columns. The first column was loaded with the controlled pore glass (CPG) to be modified. The second column was used for separation of the reaction effluents. This column was coupled to a refractive index detector, allowing for quantitative detection of the effluents. The reaction was initiated by injecting an APTS/toluene mixture and stopped by injection of pure toluene. With this so-called stop-flow mechanism reaction times down to 18 seconds could be used. From these analyses it became evident that upon mixing of the aminosilane with the silica, a very rapid physisorption occurs. The initial adsorption of the APTS (from toluene solution on dried CPG) occurred before the 18 second minimum time delay of the stop-flow apparatus. For non-aminated silanes the adsorption proved to be much slower. This study also revealed the pivotal role of surface water in the modification of siliceous surfaces with alkoxysilanes, as discussed in the previous chapter. 

The relationships of oxidation potential to radical reactivity index Sr and nucleophilic reactivity index Sn illustrated in Figure 4 are very similar to those with antioxidation and antiozonization, where the maximum values were observed at 0.4 and 0.25 volt. Therefore, antioxidation seems to proceed by a radical mechanism in contrast to the nucleophilic type of antiozonization. Indeed, the antioxidation effect of amines toward NR, SBR, BR, and HR is well correlated with radical reactivity as shown in Figures 5-8. The protection of SBR solution by amines from oxidative degradation and the termination of chain reaction in the oxygen-Tetralin system are also shown as functions of Sr in Figures 9 and 10. 

Zirconium and hafnium complexes of an amine bis(phenolate) ligand with a THF side-arm donor have been shown to perform living polymerization of 1-hexene when activated with B(C6F5)3. The Zr catalysts (1) possess very high activities of 21 OOOgnunol cath. In neat olefin, the reaction is very exothermic and accompanied by various termination processes resulting in a higher polydispersity index than observed when the monomer is diluted in chlorobenzene. 

As illustrated in O Scheme 65, 33 reacts with an amine to give an imine 326 that isomerizes into an aminoketose 327 (Amadori product), existing as an equilibrium mixture of cyclic hemi-acetals, whereas 40 affords, by way of 328, the hexosamine derivatives 329 and 330 (Heyns products), also in cyclic form The Amadori-He)ms compounds index Amadori-Heyns com-pounds % are at the head of the complex sequences of the Maillard reaction. The crystal structure of the Amadori product 331 between 33 and glycine has been determined more than three decades after the first proposal of its structure. Alternative preparations and X-ray analyses of Heyns products 332 and 333 have been reported [273,274]. 

By now this basic formulation has had many interpretations. For example (Activity) has been used to refer to coke-on-catalyst, amine index of the material, reference to conversion in some specific chemical test who knows what else. The value of n, reported in various studies as ranging from 0 to 12, has been represented to indicate diffusion control (0.5) up to essentially "... we don t know what is going on here. .. (12). .. ". The factor is a proportionality constant specific to catalyst, operating conditions and chemical reaction. Voorhies model, based on time-on-stream observations, is obviously not general, but it is a good place to start. 

Properties Yellow crystals or light-yellow liquid mild odor. Mp 15C, bp 51C, d 1.14 (20/20C), bulkd 10.0 lb/gal (20C), vapor has a green color and burns with a violet flame, refr index 1.3826 (20C). Polymerizes on standing or in presence of a trace of water. An aqueous solution contains monomolecu-lar glyoxal and reacts weakly to acid. Undergoes many addition and condensation reactions with amines, amides, aldehydes and hydroxyl-containing materials. Glyoxal VP resists discoloration. 

Properties Colorless, volatile liquid amine odor. Strong alkaline reaction, bp 32.4C, fp -101C, d 0.6881 (20/20C), bulk d 5.7 lb/gal (20C), refr index 1.3770 (15C), flash p -35F (-37.2C) (OC), autoign temp 756F (402C). Miscible with water, alcohol, and ether. 

Fig. 2 Reactions at the hydroxyl groups of glycosyl residues of oligo-/polysaccharides. (A) Basic a(l 4) linked glycosyl residue. (B) Oxidation at C6 position to form uronic acid. (C) Oxidation/substitution at C2 position to form acetate. (D) Oxidation/ substitution at C2 position to form glucosyl-2-amine. (E) Oxidation/substitution/compatibilization at C2 position to form glucosyl-2-A-acetyl. (F) Oxidation/substitution/compatibilization at C4 position compatibilization glycosyl-4-sulfate. (G) Oxidation/activation at C6 position compatibilization glucosyl-6-phosphate. (Molecular modeling SWEET, http //www.dkfz-heidelberg.de/spec/sweet2/doc/index.php. Chemistry MDL ISIS/draw.) (View this art in color at www.dekker.com.)...

Nucleophilicity. Good descriptors of this property are rare. Consistent kinetic data from nucleophilic reactions are available only for a limited number of amines. Since nucleophilicity related to the properties of the lone pair electrons on the nitrogen, indirect measures related to the lone pair must be used. The base properties are involved, so pK, is in part a descriptor of nucleophilicity. Also the polarizability is part of the picture, and for this property the refractive index is a generally available descriptor. Other descriptors which can be used in this context are the ionization potential and the frontier orbital energies. Unfortunately, these descriptors are not available for a sufficiently large number of amines. 

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