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2 acylating agents

It should be noted that the Friedel-Crafts acylation differs from the Friedel-Crafts alkylation (compare Sections IV,3-4 and discussion preceding Section IV,1) in one important respect. The alkylation requires catal3d.ic quantities of aluminium chloride, but for acylation a molecular equivalent of aluminium chloride is necessary for each carbonyl group present in the acylating agent. This is because aluminium chloride is capable of forming rather stable complexes with the carbonyl group these complexes probably possess an oxonium... [Pg.725]

Most of the known acylations have been described for 2-aminothiazoles, the activity of the acylating agent being in the order, acid halides > anhydrides > esters > acids — amides. [Pg.47]

These acylating agents are the most commonly used (246). Acid chlorides react with 5-nitro-2-aminothiazoIe (88) despite the deactivating effect of the nitro group (Scheme 61) (247), but more vigorous conditions are required (248). [Pg.48]

These compounds are easily prepared from the appropriate 2-aminothiazole and acyl chloride (see Section III.2.D) or by general heterocydization methods. Acyl chlorides may be replaced by the corresponding anhydrides (471). Acids themselves may be used as acylating agents provided that the imidazole-triphenyl phosphine mixture is used as a catalyst (472). The Curtius degradation of 247 yields 2-acetamido-4-phenylthiazole (248) (Scheme 149) (473). [Pg.90]

Amines are convert ed to amides on reaction with acyl chlorides Other acylating agents such as carboxylic acid anhydrides and esters may also be used but are less reactive... [Pg.936]

Acylation (Section 25 22) Esterifi cation of the available hydroxyl groups occurs when carbohydrates are treated with acylating agents... [Pg.1064]

Acylating agent Reference Product CAS Registry Number End use... [Pg.321]

Ketone Synthesis. In the Friedel-Crafts ketone synthesis, an acyl group is iatroduced iato the aromatic nucleus by an acylating agent such as an acyl haUde, acid anhydride, ester, or the acid itself. Ketenes, amides, and nittiles also may be used aluminum chloride and boron ttitiuotide are the most common catalysts (see Ketones). [Pg.557]

Appaiendy a molai equivalent of catalyst (AlCl ) combines with the acyl halide, giving a 1 1 addition compound, which then acts as the active acylating agent. Reaction with aromatics gives the AlCl complex of the product ketone hberating HX ... [Pg.557]

A further consequence of association of acylating agents with basic compounds is an increase in the bulk of the reagent, and greater resistance to attack at the more stericaHy hindered positions of aromatic compounds. Thus acylation of chrysene and phenanthrene in nitrobenzene or in carbon disulfide occurs to a considerable extent in an outer ring, whereas acylation of naphthalene leads to extensive reaction at the less reactive but stericaky less hindered 2-position. [Pg.557]

Cyclo acylations leadUy take place in intermoleculai acylations involving bifunctional acylating agents. Both functional groups may be acyl (as in the case of a,CO-diacyl halides) or one may be an alkylating group (as in unsaturated acyl halides or certain haloacyl halides) (18). [Pg.559]

Polystyrene can be cross-linked by its acylation with bifunctional acylating agents such as adipoyl, sebacoyl, or malonyl chlorides ia the presence of AlCl iu CS2 solution at 0°C (106). [Pg.559]

In these reactions the active acylating agent is the carbamyl chloride, formed by the reaction of the isocyanate with hydrogen chloride (137) ... [Pg.560]

Substitution at the Alcohol Group. Acylation of the OH group by acylating agents such as acid chlorides or anhydrides is one of the important high yielding substitution reactions at the OH group of lactic acid and its functional derivatives. AUphatic, aromatic, and other substituted derivatives can be produced. [Pg.513]

Most other acylating agents act on salts of either primary or secondary nitroparaffins by O-acylation, giving first the nitronic anhydrides which rearrange to give, eg, nitrosoacyloxy compounds (28). [Pg.99]

Higher nitroalkanes are prepared from lower primary nitroalkanes by a one-pot synthesis (69). Successive condensations with aldehydes and acylating agents are followed by reduction with sodium borohydride. Overall conversions in the 75—80% range are reported. [Pg.101]

Other unsymmetrical peroxides can be prepared by this reaction by employing other acylating agents, eg, alkyl chloroformates, organosulfonyl chlorides, and carbamoyl chlorides (210). Unsymmetrical and symmetrical di(diacyl peroxides) also are obtained by the reaction of dibasic acid chlorides directiy with peroxycarboxyhc acids or monoacid chlorides directiy with diperoxycarboxyhc acids in the presence of a base (44,187,203). [Pg.125]

Fig. 2. Synthetic routes to alkyl peroxyesters. The acylating agent reacts with R OOH in each case. Fig. 2. Synthetic routes to alkyl peroxyesters. The acylating agent reacts with R OOH in each case.
Acylation. Aliphatic amine oxides react with acylating agents such as acetic anhydride and acetyl chloride to form either A[,A/-diaLkylamides and aldehyde (34), the Polonovski reaction, or an ester, depending upon the polarity of the solvent used (35,36). Along with a polar mechanism (37), a metal-complex-induced mechanism involving a free-radical intermediate has been proposed. [Pg.191]

Qu tern iy S Its. The ring nitrogen of quinoline reacts with a wide variety of alkylating and acylating agents to produce useful intermediates like A/-benzoylquinolinium chloride [4903-36-0] (8). The quinoline 1,2-adducts, eg, A/-benzyl-2-cyano-l,2-dihydroquinoline [13721 -17-0] (9), or Reissert compounds (28), formed with potassium cyanide can produce 2-carboxyquinoline [93-10-7] (10) or 2-cyanoquinoline [11436-43-7] (11). [Pg.390]

Esters of the phenohc hydroxyl are obtained easily by the Schotten-Baumaim reaction. The reaction ia many cases iavolves an acid chloride as the acylating agent. However, acylation is achieved more commonly by reaction with an acid anhydride. The single most important commercial reaction of this type is the acetylation of sahcyhc acid with acetic anhydride to produce acetylsahcyhc acid [50-78-2] (aspirin). [Pg.285]

Ca.rboxyhc Acids. Esters are the main products in the reaction of chloroformates with carboxyHc acids. The intermediate mixed carboxyhc—carbonic anhydrides are very active acylating agents (25—27) but these agents may be isolated in cold temperatures for producing useful products (28). [Pg.39]

Acylation. Aryl chloroformates are good acylating agents, reacting with aromatic hydrocarbons under Eriedel-Crafts conditions to give the expected aryl esters of the aromatic acid (38). [Pg.39]

Under more forcing conditions with acid anhydrides, EDA can form tetraacyl derivatives (29). However, much milder conditions or less active acylating agents are needed to obtain the monoamide essentially free of the diamide (30—32). [Pg.42]

In contrast to the hydrolysis of prochiral esters performed in aqueous solutions, the enzymatic acylation of prochiral diols is usually carried out in an inert organic solvent such as hexane, ether, toluene, or ethyl acetate. In order to increase the reaction rate and the degree of conversion, activated esters such as vinyl carboxylates are often used as acylating agents. The vinyl alcohol formed as a result of transesterification tautomerizes to acetaldehyde, making the reaction practically irreversible. The presence of a bulky substituent in the 2-position helps the enzyme to discriminate between enantiotopic faces as a result the enzymatic acylation of prochiral 2-benzoxy-l,3-propanediol (34) proceeds with excellent selectivity (ee > 96%) (49). In the case of the 2-methyl substituted diol (33) the selectivity is only moderate (50). [Pg.336]

Acylation of pyridazinethiones with acetyl chloride or benzoyl chloride gives the corresponding S-acylated products. 6-Mercaptopyridazine-3(2//)-thione gives either mono- or di-S-acylated products. A bispyridazinyl derivative is formed when phosgene or thiophos-gene is used as acylating agent. [Pg.37]

Alkylamino-5-nitrosopyrimidines undergo acylation in their isonitroso forms to yield acyloxyimino derivatives, such as the 5-benzoyloxyimino-6-methylimino-5,6-dihy-dropyrimidine-2,4(l//,3//)-dione (277) (70CB900), which are powerful acylating agents in their own right. [Pg.88]

Several triazinyl ketones isomerize to 4-acetamidopyrimidines. TTiis is seen in the C-acylation of 2,4,6-trimethyl-l,3,5-triazine (708) with benzoyl chloride in the presence of sodium amide to give the ketone (709) which undergoes a Dimroth-like rearrangement in boiling water to afford A-(2-methyl-6-phenylpyrimidin-4-yl)acetamide (710) it can be seen that the acylating agent determines the identity of the 6-substituent 64JHC145). [Pg.120]

Unsubstituted isoxazolium salts (247) lose the 3-proton under very mild conditions, e.g. at pH 7 in aqueous solution, to give intermediate acylketenimines (248) which convert carboxylic acids into efficient acylating agents (249) (79AHC(25)147). [Pg.71]


See other pages where 2 acylating agents is mentioned: [Pg.477]    [Pg.235]    [Pg.92]    [Pg.136]    [Pg.906]    [Pg.1017]    [Pg.401]    [Pg.557]    [Pg.557]    [Pg.557]    [Pg.558]    [Pg.561]    [Pg.126]    [Pg.540]    [Pg.66]    [Pg.76]    [Pg.49]    [Pg.293]    [Pg.336]    [Pg.413]    [Pg.105]    [Pg.52]   
See also in sourсe #XX -- [ Pg.525 , Pg.526 , Pg.527 , Pg.528 ]

See also in sourсe #XX -- [ Pg.526 , Pg.527 ]

See also in sourсe #XX -- [ Pg.131 ]

See also in sourсe #XX -- [ Pg.259 , Pg.261 , Pg.267 ]

See also in sourсe #XX -- [ Pg.526 , Pg.527 ]

See also in sourсe #XX -- [ Pg.356 , Pg.399 ]




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1- Oxycarbonyl- pyridine use as acylating agents

2- ester acylating agent

Acetic anhydride, as acylating agent

Active acylating agent

Acyl chlorides, as acylating agents

Acyl transfer agents

Acyl transfer agents selenol esters

Acyl trifluoroacetates, acylating agents

Acylating Agents and Isocyanates

Acylating agent isolable

Acylating agent resonance stabilization

Acylating agents Reformatsky reaction

Acylating agents acid esters

Acylating agents acyl sulfonates

Acylating agents carboxyl compounds

Acylating agents cation

Acylating agents enantioselective

Acylating agents from carboxylic acids

Acylating agents ketenes

Acylating agents mild, selective

Acylating agents nucleophile reactivity

Acylating agents polymer-based

Acylating agents stabilization

Acylating agents, common

Acylating agents, polymeric

Acylating agents, polymeric types

Acylating agents, selectivity, cyclic

Acylation agents

Acylation agents

Amino acids acylating agents

Anhydrides, as acylating agents

Carboxylic acids acylating agent

Carboxylic acids conversion into acylating agents

Carboxylic acids, as acylating agents

Chloroformates, as acylating agents

Conversion of Carboxylic Acids into Isolable Acylating Agents

Effect of the acylating agent

Electrophilicity acylating agents

Fluorides, acyl fluorinating agents

Heterocyclic acylating agents

Hypohalites acyl, as halogenating agents

L-Acetyl- pyridine, use acylating agents

Lewis acids acylating agent activation

Metal enolates acylating agent

Nucleophiles reactivity with acylating agents

Pivaloyl acylating agents

Polymer acylating agents

Preparation and reactions of active acylating agents

Protecting agents, acyl azides

Pyridines acylating agents

Quinolines acylating agents

Reactions acylating agents

Reactions with Alkylating and Acylating Agents

Reagents Simple Acylating Agents

Regioselective Acylation of Drug Intermediate for an Antileukaemic Agent

Regioselective acylating agents

Synthesis with C-acyl Meldrums Acid as the A-Acylating Agent

Transfer of Carbamate Group to Acylating Agents

Trifluoroacetic anhydride acylating agent

Trifluoroacetic anhydrides, mixed, acylating agents

With Acylating Agents Followed by Acids, Bases, or Hydrogen Peroxide (for Pyrimidin-4-ones)

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