Potassium hydroxide, functional group

The procedures presented here are simple, Inexpensive, and may be used on a large scale. The use of potassium hydroxide In this reaction may, however, prove Incompatible with certain base-sensitive functional groups. 

Alcoholic potassium hydroxide or sodium hydroxide are normally used to convert the halohydrins to oxiranes. Other bases have also been employed to effect ring closure in the presence of labile functional groups such as a-ketols, e.g., potassium acetate in ethanol, potassium acetate in acetone or potassium carbonate in methanol.However, weaker bases can lead to solvolytic side reactions. Ring closure under neutral conditions employing potassiunT fluoride in dimethyl sulfoxide, dimethylformamide or A-methyl-pyrrolidone has been reported in the patent literature. 

Many types of functional groups are tolerated in a Suzuki reaction, and the yields are often good to very good. The presence of a base, e.g. sodium hydroxide or sodium/potassium carbonate, is essential for this reaction. The base is likely to be involved in more than one step of the catalytic cycle, at least in the transmetal-lation step. Proper choice of the base is important in order to obtain good results." In contrast to the Heck reaction and the Stille reaction, the Suzuki reaction does not work under neutral conditions. 

When a cold (-78 °C) solution of the lithium enolate derived from amide 6 is treated successively with a,/ -unsaturated ester 7 and homogeranyl iodide 8, intermediate 9 is produced in 87% yield (see Scheme 2). All of the carbon atoms that will constitute the complex pentacyclic framework of 1 are introduced in this one-pot operation. After some careful experimentation, a three-step reaction sequence was found to be necessary to accomplish the conversion of both the amide and methyl ester functions to aldehyde groups. Thus, a complete reduction of the methyl ester with diisobutylalu-minum hydride (Dibal-H) furnishes hydroxy amide 10 which is then hydrolyzed with potassium hydroxide in aqueous ethanol. After acidification of the saponification mixture, a 1 1 mixture of diastereomeric 5-lactones 11 is obtained in quantitative yield. Under the harsh conditions required to achieve the hydrolysis of the amide in 10, the stereogenic center bearing the benzyloxypropyl side chain epimerized. Nevertheless, this seemingly unfortunate circumstance is ultimately of no consequence because this carbon will eventually become part of the planar azadiene. 

The hydrogeh atom bound to the amide nitrogen in 15 is rather acidic and it can be easily removed as a proton in the presence of some competent base. Naturally, such an event would afford a delocalized anion, a nucleophilic species, which could attack the proximal epoxide at position 16 in an intramolecular fashion to give the desired azabicyclo[3.2.1]octanol framework. In the event, when a solution of 15 in benzene is treated with sodium hydride at 100 °C, the processes just outlined do in fact take place and intermediate 14 is obtained after hydrolytic cleavage of the trifluoroacetyl group with potassium hydroxide. The formation of azabi-cyclo[3.2.1]octanol 14 in an overall yield of 43% from enone 16 underscores the efficiency of Overman s route to this heavily functionalized bicycle. 

The nitrile group in 82 has been transformed into other versatile functional groups, and the derivatives so obtained have been used in the synthesis of various naturally occurring C-nucleosides and their analogs. Reduction of 82 with lithium aluminum hydride gave the amine 90 which was, in turn, transformed84 into the ureido and N-ni-troso derivatives (91-93) by treatment with nitrourea, followed by benzylation, and nitrosation.85 The diazo derivative 94, obtained by treatment of 93 with alcoholic potassium hydroxide, was a key intermediate in the synthesis of formycin B and oxoformycin B (see Section III,2,a,b). 

Cyclic ketene acetals, which have utility as co-polymers with functional groups capable of cross-linking, etc., have been prepared by the elimination of HX from 2-halomethyl-l,3-dioxolanes. Milder conditions are used under phase-transfer conditions, compared with traditional procedures, which require a strong base and high temperatures. Solid liquid elimination reactions frequently use potassium f-butoxide [27], but acceptable yields have been achieved with potassium hydroxide and without loss of any chiral centres. The added dimension of sonication reduces reaction times and improves the yields [28, 29]. Microwave irradiation has also been used in the synthesis of methyleneacetals and dithioacetals [30] and yields are superior to those obtained with sonofication. 

For cyclopropanation of alkenes devoid of base-sensitive functional groups a one-pot procedure has been developed [649]. In this procedure diazomethane is generated in a biphasic system from A-methyl-A-nitrosourea and potassium hydroxide in the presence of a palladium complex (e.g. Pd(acac)2, (PhCN)2PdCl2, or Pd[P(OPh)3]4) and the alkene. In this way the handling of diazomethane is elegantly avoided. 

Considerable effort has been carried out by different groups in the preparation of amphiphihc block copolymers based on polyfethylene oxide) PEO and an ahphatic polyester. A common approach relies upon the use of preformed co- hydroxy PEO as macroinitiator precursors [51, 70]. Actually, the anionic ROP of ethylene oxide is readily initiated by alcohol molecules activated by potassium hydroxide in catalytic amounts. The equimolar reaction of the PEO hydroxy end group (s) with triethyl aluminum yields a macroinitiator that, according to the coordination-insertion mechanism previously discussed (see Sect. 2.1), is highly active in the eCL and LA polymerization. This strategy allows one to prepare di- or triblock copolymers depending on the functionality of the PEO macroinitiator (Scheme 13a,b). Diblock copolymers have also been successfully prepared by sequential addition of the cyclic ether (EO) and lactone monomers using tetraphenylporphynato aluminum alkoxides or chloride as the initiator [69]. 

Hoff and Feit (8) reacted samples in a 2-cm3 hypodermic syringe before injection onto the gas chromatographic column. Reagents were selected either to remove certain functional groups or to alter them to obtain different peaks. Reagents used included metallic sodium, ozone, hydrogen, sulfuric acid, hydroxyl-amine, sodium hydroxide (20%), sodium borohydride (15%), and potassium permanganate (concentrated). 

In the course of a study on organic functionalization of CNTs, Haddon s group discovered in 1998 that dichlorocarbene was covalently bound to soluble SWCNTs (Scheme 1.18) [97]. Originally, the carbene was generated from chloroform with potassium hydroxide [79a] and later from phenyl(bromodichloromethyl)mercury [97]. However, the degree of functionalization was as low as 1.6 at. % of chlorine only, determined by XPS [153],... 

The presence of the /3-hydroxypropionic ester unit in deacetylpicraline is established by oxidation with chromic acid in acetone, which yields an aldehyde base, picralinal, C21H22N2O4 the latter is readily deform yla ted by short treatment with methanolic potassium hydroxide, which affords picrinine in quantitative yield. Reduction of picralinal with sodium borohydride regenerates deacetylpicraline. Vigorous treatment of deacetylpicraline with sodium borohydride gives a noncrystalline indoline base, which exhibits the UV-absorption of an anilinium ion in concentrated perchloric acid hence, the Na-carbinol-amine ether function must have suffered reduction. Since acetylation of the noncrystalline base gives a product which exhibits acylaniline UV-absorption, picraline and its derivatives must contain an NaH group (53, 54). 

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