Alkylated a-carbon

Synthesis of 7 and 8 supports the olefin oxidation mechanisms in Fig. 6. These mechanisms have several important and noteworthy points about Ptm chemistry i) Olefins coordinate to Ptm at the axial position, which is contrasted to the -coordination of olefins perpendicular to the square planar coordination plane of Pt11. Olefin coordination to Ptm should also be contrasted to the behavior of PtIV species which do not bind olefins, ii) Pt111 is strongly electron-withdrawing, and the coordinated olefin undergoes nucleophilic attack, iii) The alkyl a-carbon on the Ptm undergoes nucleophilic attack in aqueous solution, whereas in aprotic solvent, aldehyde (and possibly also ketone in other cases) is produced by reductive elimination. 

The Ptm-Ptm bond in the alkyl complexes exhibits a unique character in that the Pt-atom acts both as Ptn and Pt lv or as an intermediate through electron localization and delocalization along the Pt-Pt axis i) Coordination of olefin is aPt11 characteristic, since no olefin-PtIV complex is known. ii) Nucleophilic attack on the coordinated alkyl a-carbon atoms takes place, which is a PtIV characteristic, and does not occur at a-carbon atoms of alkyl-Pt11 complexes [75-77],... 

Initial attempts to form carbon-group-VA transition-metal bonds with [Ta( -Cp)2Me2][BF4] give instead deprotonation of the primary alkyl a-carbon atom" ... 

Metalation of dimethylhydrazone derivatives of aldehydes and ketones occurs cleanly. Unsymmetrical ketones suffer proton abstraction from the lesser-alkylated a-carbon atom specifically, and the a-lithiated dimethylhydrazones react more vigorously than the corresponding enolates with halides (Scheme 23), oxirans, and carbonyl compounds (Scheme 23). Cuprate derivatives can be obtained from the lithiated species in the usual manner and the cuprates undergo Michael addition to ajS-unsaturated ketones. 

It has been tentatively suggested that one mechanism underlies the Willgerodt reaction and the Kindler modification of it. A labile intermediate is first formed which has a carbon—carbon bond in the side chain. The scheme is indicated below it postulates a series of steps involving the addition of ammonia or amine (R = H or alkyl), elimination of water, re addition and eUmination of ammonia or amine until the unsaturation appears at the end of the chain then an irreversible oxidation between sulphur and the nitrogen compound may occur to produce a thioamide. 

Carbanions are negatively charged organic species with an even number of electrons and the charge mainly concentrated on a carbon atom. In alkyl, alkenyl, and alkynyl anions all of the... 

The introduction of additional alkyl groups mostly involves the formation of a bond between a carbanion and a carbon attached to a suitable leaving group. S,.,2-reactions prevail, although radical mechanisms are also possible, especially if organometallic compounds are involved. Since many carbanions and radicals are easily oxidized by oxygen, working under inert gas is advised, until it has been shown for each specific reaction that air has no harmful effect on yields. 

In peptide syntheses, where partial racemization of the chiral a-carbon centers is a serious problem, the application of 1-hydroxy-1 H-benzotriazole ( HBT") and DCC has been very successful in increasing yields and decreasing racemization (W. Kdnig, 1970 G.C. Windridge, 1971 H.R. Bosshard, 1973), l-(Acyloxy)-lif-benzotriazoles or l-acyl-17f-benzo-triazole 3-oxides are formed as reactive intermediates. If carboxylic or phosphoric esters are to be formed from the acids and alcohols using DCC, 4-(pyrrolidin-l -yl)pyridine ( PPY A. Hassner, 1978 K.M. Patel, 1979) and HBT are efficient catalysts even with tert-alkyl, choles-teryl, aryl, and other unreactive alcohols as well as with highly bulky or labile acids. 

Hydroxyl groups take precedence over ( outrank ) alkyl groups and halogen substituents m determining the direction m which a carbon chain is numbered The OH group is assumed to be attached to C 1 of a cyclic alcohol and is not numbered... 

Section 5 15 Dehydrohalogenation of alkyl halides by alkoxide bases is not compli cated by rearrangements because carbocations are not intermediates The mechanism is E2 It is a concerted process m which the base abstracts a proton from the p carbon while the bond between the halogen and the a carbon undergoes heterolytic cleavage... 

Cyanide ion ( C = N ) The negatively charged carbon atom of cyanide ion IS usually the site of its nucleophilic character Use of cyanide ion as a nucleophile permits the extension of a carbon chain by carbon-carbon bond formation The product is an alkyl cyanide or nitrile... 

Organometallic compounds contain a carbon-metal bond They are named as alkyl (or aryl) derivatives of metals... 

The anion produced by prolon abslraclion from efhyl acefoacefafe is nucleophilic Adding an alkyl halide lo a solulion of fhe sodium sail of efhyl acefoacefafe leads lo alkylalion of fhe a carbon... 

Dialkylation of ethyl acetoacetate can also be accomplished opening the way to ketones with two alkyl substituents at the a carbon... 

The anion of a p keto ester may be alkylated at carbon with an alkyl halide and the product of this reaction subjected to ester hydrolysis and decarboxylation to give a ketone... 

The most widely used method for the laboratory synthesis of a ammo acids is a modification of the malonic ester synthesis (Section 21 7) The key reagent is diethyl acetamidomalonate a derivative of malonic ester that already has the critical nitrogen substituent m place at the a carbon atom The side chain is introduced by alkylating diethyl acetamidomalonate m the same way as diethyl malonate itself is alkylated... 

Gabriel synthesis (Section 22 8) Method for the synthesis of primary alkylamines in which a key step is the formation of a carbon-nitrogen bond by alkylation of the potassium salt of phthalimide... 

Tertiary amine (Section 22 1) Amine of the type R3N with any combination of three alkyl or aryl substituents on nitrogen Tertiary carbon (Section 2 13) A carbon that is directly at tached to three other carbons... 

Synthetic utility of stereoselective alkylations in natural product chemistry is exemplified by the preparation of optically active 2-arylglycine esters (38). Chirally specific a-amino acids with methoxyaryl groups attached to the a-carbon were prepared by reaction of the dimethyl ether of a chiral bis-lactam derivative with methoxy arenes. Using SnCl as the Lewis acid, enantioselectivities ranging from 65 to 95% were obtained. 

Alkyl or aryl phosphonates, which contain a carbon—phosphoms bond, are comparatively more stable. They are of interest as antiscaling additives and corrosion inhibitors for cooling towers and heat exchangers (see Dispersants Water, industrial water treatment), surfactants (qv), sequestrants, and textile-treating agents. Trialkyl phosphites are usehil as esterification (qv) reagents. 

A useful apphcation of phosphines for replacing a carbonyl function with a carbon—carbon double bond is the Wittig reaction (91). A tertiary phosphine, usually triphenylphosphine, treated with the appropriate alkyl halide which must include at least one a-hydrogen, yields the quaternary salt [1779A9-3] which is then dehydrohalogenated to form the Wittig reagent, methylenetriphenylphosphorane [19943-09-5] an yhde. 

Nitriles. Nitriles can be prepared by a number of methods, including ( /) the reaction of alkyl haHdes with alkaH metal cyanides, (2) addition of hydrogen cyanide to a carbon—carbon, carbon—oxygen, or carbon—nitrogen multiple bond, (2) reaction of hydrogen cyanide with a carboxyHc acid over a dehydration catalyst, and (4) ammoxidation of hydrocarbons containing an activated methyl group. For reviews on the preparation of nitriles see references 14 and 15. 

The tautomeric character of the pyrazolones is also illustrated by the mixture of products isolated after certain reactions. Thus alkylation normally takes place at C, but on occasion it is accompanied by alkylation on O and N. Similar problems can arise during acylation and carbamoylation reactions, which also favor C. Pyrazolones react with aldehydes and ketones at to form a carbon—carbon double bond, eg (41). Coupling takes place when pyrazolones react with diazonium salts to produce azo compounds, eg (42). 

Alkylation a.ndAryla.tion, The direct introduction of carbon—carbon bonds in quinoline rings takes place in low yield and with Htde selectivity. The most promising report involves carboxyHc acids with ammonium persulfate and silver nitrate (31). 

The initiating step in these reactions is the attachment of a group to the sulfoxide oxygen to produce an activated intermediate (5). Suitable groups are proton, acyl, alkyl, or almost any of the groups that also initiate the oxidations of alcohols with DMSO (40,48). In a reaction, eg, the one between DMSO and acetic anhydride, the second step is removal of a proton from an a-carbon to give an yUde (6). Release of an acetate ion generates the sulfur-stabilized carbonium ion (7), and the addition of acetate ion to the carbonium ion (7) results in the product (eq. 15) ... 

Carbon is alkylated ia the form of enolates or as carbanions. The enolates are ambident ia activity and can react at an oxygen or a carbon. For example, refluxing equimolar amounts of dimethyl sulfate and ethyl acetoacetate with potassium carbonate gives a 36% yield of the 0-methylation product, ie, ethyl 3-methoxy-2-butenoate, and 30% of the C-methylation product, ie, ethyl 2-methyl-3-oxobutanoate (26). Generally, only one alkyl group of the sulfate reacts with beta-diketones, beta-ketoesters, or malonates (27). Factors affecting the 0 C alkylation ratio have been extensively studied (28). Reaction ia the presence of soHd Al O results mosdy ia C-alkylation of ethyl acetoacetate (29). 

Transesterification has become a convenient method for synthesi2ing high alkyl, aryl, or alkyl aryl carbonates. Fiber- and film-forming polycarbonates are produced by transesterifying dialkyl, dicycloalkyl, or diaryl carbonates with alkyl, cycloalkyl, or aryl dihydroxy compounds (62). 

Developing agents must also be soluble in the aqueous alkaline processing solutions. Typically such solutions are maintained at about pH 10 by the presence of a carbonate buffer. Other buffers used include borate and, less frequendy, phosphate. Developer solubiUty can be enhanced by the presence of hydroxyl or sulfonamide groups, usually in the A/-alkyl substituent. The solubilization also serves to reduce developer allergenicity by reducing partitioning into the lipophilic phase of the skin (46). 

Alkylation. The substitution of a hydrogen atom by an alkyl group can take place at a carbon, nitrogen, or oxygen atom. 

A nitrogen atom at X results in a variable downfield shift of the a carbons, depending in its extent on what else is attached to the nitrogen. In piperidine (45 X = NH) the a carbon signal is shifted by about 20 p.p.m., to ca. S 47.7, while in A-methylpiperidine (45 X = Me) it appears at S 56.7. Quaternization at nitrogen produces further effects similar to replacement of NH by A-alkyl, but simple protonation has only a small effect. A-Acylpiperidines show two distinct a carbon atoms, because of restricted rotation about the amide bond. The chemical shift separation is about 6 p.p.m., and the mean shift is close to that of the unsubstituted amine (45 X=NH). The nitroso compound (45 X = N—NO) is similar, but the shift separation of the two a carbons is somewhat greater (ca. 12 p.p.m.). The (3 and y carbon atoms of piperidines. A- acylpiperidines and piperidinium salts are all upfield of the cyclohexane resonance, by 0-7 p.p.m. 

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