Diacyl formation

Petoxycatboxyhc acids also have been prepared by the reaction of acid chlorides, anhydrides, or boric-catboxyhc anhydrides with hydrogen or sodium peroxide. These reactions ate carried out at low temperature and with excess peroxide to avoid the formation of diacyl peroxides (44,168,181,184). 

The NOBS system undergoes an additional reaction that forms a diacyl peroxide as a result of the nucleophilic attack of the peracid anion on the NOBS precursor as shown in equation 21. This undesirable side reaction can be minimized by the use of an excess molar quantity of hydrogen peroxide (91,96) or by the use of shorter dialkyl chain acid derivatives. However, the use of these acid derivatives also appears to result in less efficient bleaching. The dependence of the acid group on the side product formation is apparentiy the result of the proximity of the newly formed peracid to unreacted NOBS in the micellar environment (91). A variety of other peracid precursor stmctures can be found (97—118). 

An unusual dependence of the structure of the reaction product on the acylating agent (catalyst and acyl group) was observed by Balaban and Nenitzeseu in the diacylation of olefins 195, where R = Me (2-methyl-2-butene ) or R = Ph (2-methylpropenyl-benzene ) strong catalysts like AlClg or SbCls promote the formation of the 2,4,6-trisubstituted compound 197, whereas weaker... 

The diacyl peroxide-amine system, especially BPO-DMT or BPO-DMA, has been used and studied for a long time but still no sound initiation mechanism was proposed. Some controversy existed in the first step, i.e., whether there is formation of a charge-transfer complex of a rate-controlling step of nucleophilic displacement as Walling 1] suggested ... 

Hydrazides (RCONHNH2) are highly useful starting materials and intermediates in the synthesis of heterocyclic molecules.2 They can be synthesized by hydrazinolysis of amides, esters and thioesters.3 The reaction of hydrazine with acyl chlorides or anhydrides is also well known,4 but it is complicated by the formation of 1,2-diacylhydrazines, and often requires the use of anhydrous hydrazine which presents a high thermal hazard. Diacylation products predominate when hydrazine reacts with low molecular weight aliphatic acyl chlorides, which makes the reaction impractical for preparatory purposes.5... 

With 4,4-diacyl triafulvenes two principal fragmentation pathways have been observed5 s In 4-aroyl-4-acetyl triafulvenes 241 the molecular ion is followed by a fragment ion of probable structure 242 arising from primary loss of (CvI R), which surprisingly has incorporated a CH2 unit from the acetyl group and the exo-cyclic aryl residue. It is not unlikely that the (C7H6R)-residue corresponds to a substituted tropyl radical due to its well-known formation from electron-impact of benzylic precursors. 

Acyl nitroso compounds react with 1, 3-dienes as N-O heterodienophiles to produce cycloadducts, which have found use in the total synthesis of a number of nitrogen-containing natural products [21]. The cycloadducts of acyl nitroso compounds and 9,10-dimethylanthracene (4, Scheme 7.3) undergo thermal decomposition through retro-Diels-Alder reactions to produce acyl nitroso compounds under non-oxidative conditions and at relatively mild temperatures (40-100°C) [11-14]. Decomposition of these compounds provides a particularly clean method for the formation of acyl nitroso compounds. Photolysis or thermolysis of 3, 5-diphenyl-l, 2, 4-oxadiazole-4-oxide (5) generates the aromatic acyl nitroso compound (6) and ben-zonitrile (Scheme 7.3) [22, 23]. Other reactions that generate acyl nitroso compounds include the treatment of 5 with a nitrile oxide [24], the addition of N-methyl morpholine N-oxide to nitrile oxides and the decomposition of N, O-diacylated or alkylated N-hydroxyarylsulfonamides [25-29]. 

Scheme 7.5 Nitroxyl formation from a diacyl N,0-N-hydroxysulfonamide.

Peroxides. See also Inorganic peroxides Organic peroxides acid hydrolysis of, 23 459 diacyl, 24 282-284 explosive, 20 569-573 formation of, 20 577 as free-radical initiators, 24 279-293 organomercury-containing, 23 445 potassium salts of, 18 478 silylation and, 22 703 stereoisomers of, 28 459 as vulcanizing agents, 22 795 ... 

On treating diisobutene with acetic anhydride and anhydrous zinc chloride, A. C. Byrns and T. F. Doumani had isolated in 1943 a crystalline compound to which they had ascribed the structure of a zinc complex with a 1,3-diketone 40 the correct pyrylium chlorozincate structure was established by A. T. Balaban et al.41 in 1961, after extended investigation on the formation of pyrylium salts by alkene diacylation.42 This formation again had remained undetected for many decades during which alkenes had been acylated but only the water-insoluble monoacylation products had been investigated, whereas the water-soluble pyrylium salts went into the sink with the Lewis or Bronsted acid catalysts that had been used in the acylation. 

The role of protein kinase C in many neutrophil functions is undisputed and has been recognised for some time. For many years it was believed that the source of DAG, the activator of protein kinase C, was derived from the activity of PLC on membrane phosphatidylinositol lipids. Whilst this enzyme undoubtedly does generate some DAG (which may then activate protein kinase C), there are many reasons to indicate that this enzyme activity is insufficient to account for all the DAG generated by activated neutrophils. More recently, experimental evidence has been provided to show that a third phospholipase (PLD) is involved in neutrophil activation, and that this enzyme is probably responsible for the majority of DAG that is formed during cell stimulation. The most important substrate for PLD is phosphatidylcholine, the major phospholipid found in neutrophil plasma membranes, which accounts for over 40% of the phospholipid pool. The sn-1 position of phosphatidylcholine is either acyl linked or alkyl linked, whereas the sn-2 position is invariably acyl linked. In neutrophils, alkyl-phosphatidylcholine (1-0-alky 1-PC) represents about 40% of the phosphatidylcholine pool (and is also the substrate utilised for PAF formation), whereas the remainder is diacyl-phosphatidylcholine. Both of these types of phosphatidylcholine are substrates for PLD and PLA2. 

FIGURE 7.34 Decomposition of the symmetrical anhydride of A-methoxycarbonyl-valine (R1 = CH3) in basic media.2 (A) The anhydride is in equilibrium with the acid anion and the 2-alkoxy-5(4//)-oxazolone. (B) The anhydride undergoes intramolecular acyl transfer to the urethane nitrogen, producing thelV.AT-fcwmethoxycarbonyldipeptide. (A) and (B) are initiated by proton abstraction. Double insertion of glycine can be explained by aminolysis of the AA -diprotected peptide that is activated by conversion to anhydride Moc-Gly-(Moc)Gly-0-Gly-Moc by reaction with the oxazolone. (C) The A,A -diacylated peptide eventually cyclizes to the IV.AT-disubstituted hydantoin as it ejects methoxy anion or (D) releases methoxycarbonyl from the peptide bond leading to formation of the -substituted dipeptide ester. 

Formally related reactions are observed when anthracene [210] or arylole-fines [211-213] are reduced in the presence of carboxylic acid derivatives such as anhydrides, esters, amides, or nitriles. Under these conditions, mono- or diacylated compounds are obtained. It is interesting to note that the yield of acylated products largely depends on the counterion of the reduced hydrocarbon species. It is especially high when lithium is used, which is supposed to prevent hydrodimerization of the carboxylic acid by ion-pair formation. In contrast to alkylation, acylation is assumed to prefer an Sn2 mechanism. However, it is not clear if the radical anion or the dianion are the reactive species. The addition of nitriles is usually followed by hydrolysis of the resulting ketimines [211-213]. 

Diacyl-sn-glycerol, formation of, PHOSPHATIDATE PHOSPHATASE PHOSPHOLIPASE C... 

Despite continnons progress in amide bond formation, the acylation of hydroxylamine nnder carbodiimide promotion is often contaminated by Af,0-diacylation even with sub-stoichiometric amounts of acids. Appendino and colleagues have developed a practical solution to the problem by combining the in situ activation of carboxylic acids 102 with the cyclic phosphonic anhydride PPAA (103), and the generation of hydroxylamine from its corresponding hydrochloride to form 104 (Scheme 54). 

In 1972, Gnpta and coworkers reported the preparation of twelve A-arylhydroxamic acids by the condensation of A-l-naphthylhydroxylamine and acid chloride in diethyl ether medium . An aqneons snspension of sodium bicarbonate was added to neutralize the liberated hydrochloric acid. The formation of a diacylated derivative was practically prevented by carrying ont the reaction at low temperature, preferably below 0 °C. 

The attempted formation of Af-bromo- and Af-iodohydroxamic esters using fert-butyl hypobromite or icri-butyl hypoiodite resulted in formation of Af,Af -diacyl-Af,Af -dialkoxy-hydrazines as well as nitrenium-derived products (see Section in.C). ... 

Because the accuracy of the data for three of the diacyl peroxides is in question, we will attempt to derive enthalpies of formation for them from the reverse of equations 15 and 16. The enthalpy of reaction 15 for dibenzoyl peroxide, using enthalpy of formation values of unquestioned accurac)f, is —400.8 kJmor. This is the same as the ca —398 kJmol for the hquid non-aromatic diacyl peroxides discussed above. Using the solid phase enthalpy of reaction for dibenzoyl peroxide and the appropriate carboxylic acid enthalpies of formation, the calculated enthalpies of formation of bis(o-toluyl) peroxide and bis(p-toluyl) peroxide are —432.2 and —457.6 kJ moU, respectively. From the foregoing analysis, it would seem that the measured enthalpy of formation is accurate for the bis(p-toluyl) peroxide but is not for its isomer. The analysis for dicinnamoyl peroxide is complicated by there being two enthalpies of formation for frawi-cinnamic acid that differ by ca 12 kJmoU. One is from our archival source (—336.9 12 kJmoU ) and the other is a newer measurement (—325.3 kJmol ). The calculated enthalpies of formation of dicinnamoyl peroxide are thus —273.0 and —249.8 kJmoU. Both of these results are ca 80-100 kJmol less negative than the reported enthalpy of formation. 

The enthalpies of reaction 16 for solid and gaseous dibenzoyl peroxide are —45.8 and —47.3 kJmoU, respectively. These values are much smaller than those calculated for the liquid dialkyl peroxides ca —56 kJmoU ), the acyl peresters ca —70 kJmoU ) or the non-aromatic diacyl peroxides (—89 or —59 kJmol ). However, we have no reason not to accept the result. It would be futile to use this result for further calculations concerning the solid phase enthalpies of formation of bis(o-toluyl) peroxide, bis(p-toluyl) peroxide and dicinnamoyl peroxide because all the peroxide and the anhydride product enthalpy of formation data are from the same suspect source . 

---