Silyl group removal with

The first reported synthesis of hydroxyurea (24) consists of the condensation of hy-droxylamine with potassium cyanate (Scheme 7.14) [87]. Condensation of hydroxy-lamine with ethyl carbamate also gives pure hydroxyurea in good yield after recrystallization (Scheme 7.14) [88]. Nitrogen-15 labeled hydroxyurea provides a useful tool for studying the NO-producing reactions of hydroxyurea and can be prepared by the condensation of N-15 labeled hydroxylamine with either potassium cyanate or trimethylsilyl isocyanate followed by silyl group removal (Scheme 7.14) [89, 90]. Addition of hydroxylamine to alkyl or aryl isocyanates yields alkyl or aryl N-hydroxyureas (Scheme 7.14) [91, 92]. The condensation of amines with aromatic N-hydroxy carbamates also produces N-substituted N-hydroxyureas (Scheme 7.14) [93]. 

A similar behavior was observed in the synthesis of (5)-2-methylenecyclopropanemethanol (8). Cleavage of the j8-sulfonyl silyl group, together with removal of the tert-butyldimethyl-silyl protecting group from the alcohol, was accomplished in one step in 35% yield. With the alcohol protected as the benzyl ether and subsequently converted to a cyano group, however, elimination proceeded in 86% yield. 

Fluoride ion has a particularly high nucleophilicity towards silicon and other electrophilic centres involving second row elements this is attributed to efficient overlap of two orthogonal filled lone pair orbitals on fluoride with two empty silicon d orbitals. Although the more reactive silyl derivatives can be removed by hydrolysis, therefore, many protocols for mild silyl group removal involve fluoride ion. 

Enone 121a was reduced with DIBAL-H and the resulting ally lie alcohol protected using benzyl bromide to afford 122 in an 80% yield overall. The major diastereomer was oxidatively cleaved and the silyl group removed, thereby affording alcohol 123 in 70% yield (two steps). 

Monosubstitution of acetylene itself is not easy. Therefore, trimethylsilyl-acetylene (297)[ 202-206] is used as a protected acetylene. The coupling reaction of trimethylsilylacetylene (297) proceeds most efficiently in piperidine as a solvent[207]. After the coupling, the silyl group is removed by treatment with fluoride anion. Hexabromobenzene undergoes complete hexasubstitution with trimethylsilylacetylene to form hexaethynylbenzene (298) after desilylation in total yield of 28% for the six reactions[208,209]. The product was converted into tris(benzocyclobutadieno)benzene (299). Similarly, hexabutadiynylben-zene was prepared[210j. 

The silyl group directs electrophiles to the substituted position. That is, it is an ipso-directing group. Because of the polarity of the carbon-silicon bond, the substituted position is relatively electron-rich. The ability of silicon substituents to stabilize carboca-tion character at )9-carbon atoms (see Section 6.10, p. 393) also promotes ipso substitution. The silicon substituent is easily removed from the c-complex by reaction with a nucleophile. The desilylation step probably occurs through a pentavalent silicon species ... 

The N-9 position of adenine was protected by formylation with basic formalin followed by silylation with TBDMSCl in Pyr, 86% yield. This group is removed with TFA/H2O, 20°, 2 h. ... 

This is followed by hydrolysi.s of the ester moieties with potassium carbonate and reesterification of the carboxy moiety with diazomethane to produce intermediate 65. The solitary free alcoholic hydroxyl at C-9 is oxidized with Collins reagent and the silyl ether groups are removed with acetic acid to give enprostil (63) [15]. 

At this point, completion of the total synthesis required removal of the three acetonides and the two silyl protecting groups (Scheme 18). Removal of the silyl groups with TBAF and subsequent treatment to acidic deprotection conditions led to complete deprotection of 110, but failed to provide filipin III. It was sus-... 

In order to ameliorate the problem of solvolytic degradation, compound 109 was treated with TIPSOTf, to provide silyl ether 113 in 72% yield (Scheme 19). The acetonides were removed with PPTS in warm MeOH to provide a mixture of compounds in which the TBS groups were also partially removed. Exposure of this mixture to HF-pyridine successfully generated filipin III (114), in 39 % overall yield from 113. 

The role of the trimethylsilyl group is to stabilize the enolate formed in the conjugate addition. The silyl group is then removed during the dehydration step. Methyl 1-trimethylsilylvinyl ketone can be used under aprotic conditions that are compatible with regiospecific methods for enolate generation. The direction of annulation of unsymmetrical ketones can therefore be controlled by the method of enolate formation. 

Oxidative addition of a silyl-protected 4-(bromomethyl)phenol precursor to (tme-da)Pd(II)Me2 (tmeda = tetramethylethylenediamine), followed by ethane reductive elimination, resulted in formation of the benzylic complex 16 (Scheme 3.10). Exchange of tmeda for a diphosphine ligand (which is better suited for stabilizing the ultimate Pd(0) QM complex), followed by removal of the protecting silyl group with fluoride anion, resulted in the expected p-QM Pd(0) complex, 17, via intermediacy of the zwitterionic Pd(II) benzyl complex. In this way a stable complex of p-BHT-QM, 17b, the very important metabolite of the widely used food antioxidant BHT20 (BHT = butylated hydroxytoluene) was prepared. Similarly, a Pd(0) complex of the elusive, simplest /)-QM, 17a, was obtained (Scheme 3.10). 

Compared to the cyclic ketones, the coupling of aliphatic aldehydes to prepare 3-substituted indoles was less successful, except for phenyl acetaldehyde, which afforded 3-phenyl indole 83 in 76% yield (Scheme 4.22). The lack of imine formation or the instability of the aliphatic aldehyde towards the reaction conditions may be responsible for the inefficiency of these reactions. Therefore, a suitable aldehyde equivalent was considered. With the facile removal of a 2-trialkylsilyl group from an indole, an acyl silane was tested as a means of preparing 3-substituted indoles. Indeed, coupling of acetyl trimethylsilane with the iodoaniline 24 gave a 2 1 mixture of 2-TMS-indole 84 and indole (85) in a combined 64% yield. Evidently, the reaction conditions did lead to some desilylation. Regardless, the silyl group of 84 was quantitatively removed upon treatment with HC1 to afford indole (85). 

An efficient route to 4-aryloxy pyrazoles 74 bearing a trifluoromethyl group has been developed from 4-hydroxypyrazole 72 under basic conditions with 3,5-dicyanofluorobenzene 73 with concomitant removal of the silyl group to give pyrazoles 75 <06SL1404>. Fries-type... 

The synthesis of chiral liquid-crystalline allenes was reported by Tschierske and co-workers (Scheme 4.10) [14]. An asymmetric reduction of 41 with Alpine borane was a key step to an enantioenriched allene 44. After removal of the silyl group, the allenic alcohol was etherified by the Mitsunobu method to give 45, the first liquid-crystalline allene derivatives. 

Syntheses of diastereomerically pure racemates of himachalene derivatives started from cycloheptanone G (Fig. 9). The sequence to I involved dimethyla-tion to yield H followed by bromination/dehydrobromination and conjugate methylation using cuprate chemistry. The sequence furnishing L and M follows a Robinson-annelation type Reaction of I with 3-(trimethylsilyl)but-3-en-2-one yielded K. Refluxing K with potassium hydroxide in ethanol removed the silyl group and cyclized the diketone to form a 97 3 mixture of racemic L and M. Occurring as a volatile in A.flava, L served as a versatile intermediate in the syntheses of other Aphthona compounds. 

The tosyl protecting group of 4a is removed with sodium naphthalide at -60 °C, and an intramolecular nucleophilic attack of the nitrogen lone pair to the epoxide takes place spontaneously to afford the pyrrolidine hydroxy ester as a labile reaction product, which is immediately protected as the corresponding silyl ether 3a in 68%... 

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