Ortho-substitution

Certain ortho substituted derivatives of aromatic amines are difficult to acetylate under the above conditions owing to steric hindrance. The process is facilitated by the addition of a few drops of concentrated sulphuric acid (compare Section IV,47), which acts as a catalyst, and the use of a large excess of acetic anhydride. 

Some ortho substituted phenols such as o mtrophenol have significantly lower boiling points than those of the meta and para isomers This is because the intramolec ular hydrogen bond that forms between the hydroxyl group and the substituent partially compensates for the energy required to go from the liquid state to the vapor... 

Halogenation Bromination and chlorination of phenols occur readily even in the absence of a cata lyst Substitution occurs primarily at the position para to the hydroxyl group When the para position IS blocked ortho substitution is observed... 

Another indole/oxindole synthesis achieves the critical ortho-substitution by Sommelet-Hauser rearrangement of an anilinosiilfonium ion intermediate. Use of P-thioketones (G = R, an alkyl group) generates 2-substituted indoles, whereas P-thioesters (G = OR) lead to oxindoles. In each case, a 3-thio substituent must be removed by desulfuri2ation. 

The ratio of ortho-to-para substitution depends on the nature of the cation and the pH. Para substitution is favored by K" andNa" ions and higher pH, whereas ortho substitution is favored at lower pH and by divalent cations, such as Ba ", Ca ", and Mg " ( 2). 

In a series of organic acids of similar type, not much tendency exists for one acid to be more reactive than another. For example, in the replacement of stearic acid in methyl stearate by acetic acid, the equilibrium constant is 1.0. However, acidolysis in formic acid is usually much faster than in acetic acid, due to higher acidity and better ionizing properties of the former (115). Branched-chain acids, and some aromatic acids, especially stericaHy hindered acids such as ortho-substituted benzoic acids, would be expected to be less active in replacing other acids. Mixtures of esters are obtained when acidolysis is carried out without forcing the replacement to completion by removing one of the products. The acidolysis equilibrium and mechanism are discussed in detail in Reference 115. 

Clearly, the proportion of substitution occurring adjacent to the pyridinic nitrogen atom is increased by protonation. Also noteworthy are the high proportion of ortho substitution product and the selective attack at C-3 in the iV-phenyl derivative. 

This synthesis works especially well with cyclohexanone giving 80% oxaziridines with either chloramine (77JPR195) or (V-chloromethylamine. Simple aliphatic ketones and ortho substituted aromatic aldehydes yield 30-50% oxaziridines with N-chloromethylamine (65CB2516). 

Steric effects play a major role in determining the ortho para ratio in Friedel-Crafts alkylations. The amount of ortho substitution of toluene decreases as the size of the entering alkyl group increases along the series methyl, ethyl, /-propyl. No ortho product is found when the entering group is /-butyl. ... 

Polynuclear aromatics react with fluoroxy reagents to give high yields of ortho substitution products accompanied by varying yields of geminal difluoro products Thegeminal difluonnation occurs presumably by an addition-elimination mechanism [27 28, 29, 30, 31, 32] Unactivated aromatic systems are fluorinated in lower yield to give monofluonnated products (Table 1, entries 6 and 7) Examples of fluonnation of polynuclear systems [/5, 21, 25, 30, 32, 7 ] are shown m equations 7-10... 

It will be obvious that the treatment thus far includes only substituents that are meta or para to the reaction site. When Hammett plots are made with data for ortho-substituted reactants, scatter diagrams usually result. This failure might be attributed to steric effects, but this is not very helpful, and many attempts have been made... 

The ortho effect may consist of several components. The normal electronic effect may receive contributions from inductive and resonance factors, just as with tneta and para substituents. There may also be a proximity or field electronic effect that operates directly between the substituent and the reaction site. In addition there may exist a true steric effect, as a result of the space-filling nature of the substituent (itself ultimately an electronic effect). Finally it is possible that non-covalent interactions, such as hydrogen bonding or charge transfer, may take place. The role of the solvent in both the initial state and the transition state may be different in the presence of ortho substitution. Many attempts have been made to separate these several effects. For example. Farthing and Nam defined an ortho substituent constant in the usual way by = log (K/K ) for the ionization of benzoic acids, postulating that includes both electronic and steric components. They assumed that the electronic portion of the ortho effect is identical to the para effect, writing CTe = o-p, and that the steric component is equal to the difference between the total effect and the electronic effect, or cts = cr — cte- They then used a multiple LFER to correlate data for orrAo-substituted reactants. 

A bifunctional reagent such as ethanolamine can favor ortho substitution of azines due to hydrogen bonding as in 62. With a bifunctional nucleophile such as ethylene glycol anion, facilitation of... 

The general principle that activation of para substitution is greater than of ortho substitution holds true also for an azinium moiety in the one instance studied. Thus, the activation energy for the 4-chloropyridine quaternary salt 280 (Table II, line 9) is 1 kcal lower than that for the 2-isomer (line 5). The rate relation (2- > 4-isomer) is controlled by the entropies of activation in this reaction due to electrostatic attraction in the transition state (281). The reverse rate relation (4- > 2-position) is predicted for aminations of such quaternary compounds due to electrostatic repulsion (282) plus the difference in E. A kinetic study of the 2- and 4-pyridine quaternary salts... 

The most accurate data on isomer distributions in alkylation of heterocycles have been obtained from the reaction of 3-n-butylpyridine with methyl radicals in acetic aeid. The ratio of the monomethyl products was determined by infrared spectroscopy and gas chromatography and is showm in (27). A small amount of 2,6-dimethyl-3-n-butylpyridine was also obtained. These ratios again show a high proportion of ortho substitution. 

It is of interest that these reactions exhibit stronger activation of the substituent at C-5 by a neighboring electron-acceptor group compared with the corresponding ortho-substituted benzene. This is possibly owing either to the effect of the nitrogen hetero atom or to a weaker delocalization of multiple bonds in the heterocyclic nucleus. 

Part of the reason for ortho substitution in such compounds is to decrease metabolic transformation by enzymic... 

The sulfur analogue of the Hauser ortho-substitution rearrangement provides access to an arylacet-ic NSAID. Reaction of the aminobenzophenone 176 with ethyl methylthioacetate and tert-butyl hypochlorite gives the intermediate 178. The reaction probably proceeds by way of formation of the S-chlorinated sulfonium derivative 177 displacement on sulfur will lead to the salt 178. Treatment with triethylamine leads initially to the betaine 179. Electrocyelic rearrangement of that transient intermediate leads, after rearomatization, to the homoanthranilic acid 180. Internal ester-amine interchange leads then to indolone 181 [45]. The thiomethyl group is then removed with Raney niekel. Saponifieation of intermediate 182 affords bromfenac (183) [46J. 

J. de Boer, Q. T. Dao, P. G. Wester, S. Bowadt and U. A. Th Brinkman, Deteimination of mono-ortho substituted cWorobiphenyls by multidimensional gas cliromatography and thek conti ibution toTCDD equivalents . Anal. Chim. Acta 300 155-165 (1995). 

Pheuylboronic acid, CgHsBfOH) is nitrated to give 15% ortho-substitution product and 85% meta. Explain the meta-directing effect of the —B(OH)2 group. 

Through the use of a tin(iv) enolate with benzaldehyde it was possible to generate the anti A diastereomer 47 with high selectivity (Entry 5). With tin(n) etiolates a highly substituent-dependent outcome was observed. Low selectivities resulted with para-substituted aromatic aldehydes, but good selectivities were observed for ortho-substituted aromatic aldehydes (Entries 7-9). Simultaneous re-... 

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