Phthalimides, reaction with alcohols

Phosphine(s), chirality of, 314 Phosphite, DNA synthesis and, 1115 oxidation of, 1116 Phospholipid, 1066-1067 classification of, 1066 Phosphopantetheine, coenzyme A from. 817 structure of, 1127 Phosphoramidite, DNA synthesis and, 1115 Phosphoranc, 720 Phosphoric acid, pKa of, 51 Phosphoric acid anhydride, 1127 Phosphorus, hybridization of, 20 Phosphorus oxychloride, alcohol dehydration with. 620-622 Phosphorus tribromide, reaction with alcohols. 344. 618 Photochemical reaction, 1181 Photolithography, 505-506 resists for, 505-506 Photon, 419 energy- of. 420 Photosynthesis, 973-974 Phthalic acid, structure of, 753 Phthalimide, Gabriel amine synthesis and, 929... 

Although the initial report included amine nucleophiles, the scope was limited to activated amines such as indole (which actually undergoes C-alkylation at the 3-position), phthalimide, and 7/-methylaniline. Furthermore, enantioselectivities were inferior to those observed with alcohols as nucleophiles. Lautens and Fagnou subsequently discovered a profound halide effect in these reactions. The exchange of the chloride for an iodide on the rhodium catalyst resulted in an increased enantioselectivity that is now comparable to levels achieved with alcoholic nucleophiles ... 

Phthalimide. C<,H4 (CO), NH, is an imide of commercial and industrial importance, forming a number of interesting derivatives. With alcoholic potash, phthalimide forms a potassium derivative. C(,H4 (COb -NK. which, when reacted with ethyl iodide (or other alkyl halides), yields eihylphthalimidc. C(,H4 (COi N - C2Hj Ihe latter product, when hydrolyzed wilh an acid or alkali, further yields ethylamine. Such reaction chains are useful in ihe preparation of certain primary amines and their derivatives. 

Phenylethylamine has been made by a number of reactions, many of which are unsuitable for preparative purposes. Only the most important methods, from a preparative point of view, are given here. The present method is adapted from that of Adkins,1 which in turn was based upon those of Mignonac,2 von Braun and coworkers,3 and Mailhe.4 Benzyl cyanide has been converted to the amine by catalytic reduction with palladium on charcoal,5 with palladium on barium sulfate,6 and with Adams catalyst 7 by chemical reduction with sodium and alcohol,8 and with zinc dust and mineral acids.9 Hydrocinnamic acid has been converted to the azide and thence by the Curtius rearrangement to /3-phenyl-ethylamine 10 also the Hofmann degradation of hydrocinnamide has been used successfully.11 /3-Nitrostyrene,12 phenylthioaceta-mide,13 and the benzoyl derivative of mandelonitrile 14 all yield /3-phenylethylamine upon reduction. The amine has also been prepared by cleavage of N- (/3-phenylethyl) -phthalimide 15 with hydrazine by the Delepine synthesis from /3-phenylethyl iodide and hexamethylenetetramine 16 by the hydrolysis of the corre-... 

The Mannich reaction is readily applied to isatins. The products of this reaction, the N-aminomethylisatins (Mannich bases), can also be obtained from the A -hydroxymethyl derivatives by reaction with an amine95 or by reaction with acetyl chloride to yield N-chloromethylisatin which can be further treated with potassium phthalimide or alcohols to give the corresponding A-phthalimidomethyl or TV-alkoxymethyl isatins96. The Mannich reaction can also be performed with isatin derivatives, such as isatin-3-hydrazones97 and isatin-3-thiosemicarbazones98. 

Alkyl selenides are most conveniently prepared by the dialkylation of Na2Se or by the monoalkylation of selenolates. Common routes to aryl derivatives include the reaction of a selenolate with a diazonium salt, the SrnI reactions described earlier, and the reaction of aryUithiums with aryl selenocyanates (ArSeCN). A different approach employs the reaction of alcohols with aryl selenocyanates or N-(phenylseleno)phthalimide (see Section 6) in the presence of tri-n-butylphosphine. Similar conditions can also be used to convert carboxylic acids to selenoesters (8). These reactions are illustrated in Scheme 3. 

Conversion of alcohols into amines. The reaction of phthalimide (1) with various alcohols and triphenylphosphinc-diethyl azodicarboxylatc gives N-alkylphthalimides (2) in yields of 60 90%. Since they are converted into amines by treatment with hydrazine hydrate (1,442), the reaction provides a means of converting alcohols into amines. 

A detailed account of the photobehaviour of the phthalimide (311) with alkenes has supplemented earlier reports. The reactions encountered are either a 2tt+2ct addition yielding benzazepinediones or electron transfer from the alkene to the phthalimide followed by intermolecular trapping. " In another study TV methylphthalimide derivatives (312) undergo electron transfer reactions on irradiation in alcoholic solution. Reaction between the radical anion and radical cation yields adducts e.g. (313) as well as the more conventional products of addition to the carbonyl group. The identity of these new structures was verified by X-ray crystallography. ... 

Theil et al. developed a method for chemoenzymatic synthesis of both enantiomers of cispentacin [89]. frans-2-Hydroxymethylcyclopentanol, obtained by the sodium borohydride reduction of ethyl 2-oxocyclopentanecarboxylate, was monosilylated with tert-butyldimethylsilyl (TBDMS) chloride to afford 55. Lipase PS-catalysed transesterification with vinyl acetate in /erf-butyl methyl ether furnished the ester 56 and the alcohol 57. The deacetylated 58 was obtained by the Mitsunobu reaction with phthalimide, triphenylphosphine and diethyl azodicarboxylate (DEAD) to furnish the cis oriented 59 with inversion of configuration (not retention as mentioned in the original article) (Scheme 9). Desilylation, Jones oxidation and subsequent deprotection with aqueous methylamine gave the ( R,2S) enantiomer 5 [89]. The (15, 2/f) enantiomer was prepared by the same route from the silyl alcohol 57. 

The complex formed between diethyl azodicarboxylate and triphenylphosphine is a very useful reagent for condensation reactions. The reaction of alcohols with phthalimides, in the presence of diethyl azodicarboxylate and triphenylphosphine, resulted in the formation of the corresponding AT-alkylphthalimide in good yield. The reaction proceeds stereospecifically with complete inversion, as shown by conversion of (5 )-(+)-2-octanol to )-2-octylamine, isolated by treatment of the initially formed phthalimide with hydrazine hydrate. Condensation between alcohols and other active-hydrogen compounds using the same reagents has also been described (Scheme 1). Phosphorylation of alcohols by initial activation... 

Another method for the conversion of an alkene into an allylic alcohol, but with a shift in the position of the double bond, proceeds from the corresponding p-hydroxyselenide. The p-hydroxyselenide can be obtained from the epoxide by reaction with phenylselenide anion or directly from the alkene by addition of phenylselenenic acid, phenylselenenyl chloride in aqueous MeCN, or by acid-catalysed reaction with A-phenylseleno-phthalimide. The hydroxyselenide does not need to be isolated, but can be oxidized directly with tert-BuOOH to the unstable selenoxide, which spontaneously eliminates phenylselenenic acid to form the E-allylic alcohol. For example, 4-octene gave 5-octen -ol (6.15). Elimination takes place away from the hydroxy group to give the allylic alcohol no more than traces... 

Conversion of the phthalimide to the amine was confirmed by a peak at (5 3.2 ppm corresponding to the hydrogen adjacent to the amine group. The functionalization reaction was also monitored by MALDI-TOF MS. Characterization of the phthalimide-functionalized polymer confirmed the conversion of the bromide group. Characterization of the amine-functionalized polymer showed the presence of the desired product, but other side products were also observed. Upon hydrolysis of the phtha-limide-functionalized polymer, a transesterification reaction occurs converting the initiator moiety (ethyl-2-bromoisobuty-rate) from an ethyl ester to a t-butyl ester due to reaction with t-butyl alcohol. One drawback of this reaction is that the Gabriel reaction is only effective for primary alkyl halides and would not be useful for methyl methacrylates or methyl acrylates. 

Isomannide (80) was the core for a hexahydrofurofuran library." Primary amines were loaded onto solid-support by reductive amination and acylated with bromoacetic acid to give bromides 79 (Scheme 7.16). Alkylation of bromides 79 on solid-support with isomannide (80) gave the solid-supported alcohols 81. A Mitsunobu reaction with phthalimide (82) proceeded to furnish amines 83 in excellent yield and purity after removal of the protecting group." " Support-bound primary amines 83 were converted to secondary amines by stepwise imine formation with aldehydes 84 and reduction with sodium borohydride." The hindered secondary amines 85 were acylated with acid chlorides, sulfonyl chlorides, isocyanates, and isothiocyanates to yield 87 after cleavage from solid-support. 

Mitsunobu-type N-AIkylation of l,2,4-Dithiazolidine-3,5-dione (1). Despite its high acidity suggesting that it should be an excellent nucleophile in Mitsunobu displacement reactions of alcohols (cf. phthalimide. " ), the parent heterocycle 1 is degraded by the triphenylphosphine used in this process (see later). Similar stereoselective displacement reactions of alcohols with 1 can, however, be mediated using the readily prepared betaine reagent 7. ... 

Yields are largely comparable with standard Mitsunobu reactions between alcohols and phthalimide, with enantiomeric excesses varying from 69 to 97%, depending on the alcohol substrate. For example, using 5-metbyl lactate (8), 6a was obtained in a 52% yield, the product 6a exhibiting an ee of 92% (eq8). 

Scheme 10.23. Use of the Mitsunobu protocol (alcohol, triphenylphosphine, diethyl azodi-carboxylate, and phthalimide in THF) in reaction with (5)-(+)-2-octanol to produce (R)-(-)-2-octylamine. See Corelli, F. Summa, V. Brogi, A. Monteagudo, EBotta, M. J. Ore. Chem., 1995,60,2008.

Imides (e.g. phthalimide) can be purified by conversion to their potassium salts by reaction in ethanol with ethanolic potassium hydroxide. Hie imides are regenerated when the salts are hydrolysed with dilute acid. Like amides, imides readily crystallise from alcohols and, in some cases (e.g. quinolinic imide), from glacial acetic acid. 

Various electrophilic selenium reagents such as those described in Scheme 4.3 can be used. V-Phenylselenylphthalimide is an excellent reagent for this process and permits the formation of large ring lactones." The advantage of the reagent in this particular application is the low nucleophilicity of phthalimide, which does not compete with the remote internal nucleophile. The reaction of phenylselenenyl chloride or V-phenylselenenylphthalimide with unsaturated alcohols leads to formation of (3-phenylselenenyl ethers. 

While reaction of the acetate 40 as well as the acetyl- and phthalimide derivatives of chiral amine (41b and 41c) proceeded with erythro diastereoselectivity (in accordance with the classical cis effect, minimization of 1,3-allyhc strain) (Table 6, entries 8, 10, 11), for the allylic alcohols 39, primary allyhc amine 41a, silyl enol ethers 42 and enol ether 43 threo selectivity was observed (Table 6, entries 1-7, 9, 12-14) (see also Scheme 24). For allyhc alcohols with an alkyl group R cis to the substituent carrying the hydroxyl group, diastereoselectivity was high (Table 6, entries 1-7) in contrast, stereoselection was low for allylic alcohols which lack such an R cis) substituent (substrates 39h and 39i, see Figure 4). 

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