Alcohols unprotected

A following benzylation of the alcohol at C-3 yields 40. Conversion of 40 into 43 with the primary alcohol functionality protected is realized with sodium cyanoborohydride (NaBHsCN). Reduction with diisobutylaluminum hydride (DIBAH) 42 furnishes 44 leaving the C-6 alcohol unprotected. 

Primitive people very likely encountered vinegar-like Hquids in hoUows in rocks or downed timber into which berries or fmit had fallen. Wild yeasts and bacteria would convert the natural sugars to alcohol and acetic acid. Later, when eady peoples had learned to make wines and beers, they certainly would have found that these Hquids, unprotected from air, would turn to vinegar. One can postulate that such eady vinegars were frequendy sweet, because the fmit sugars would have been acted on simultaneously by both bacteria and yeast. Only since the middle 1800s has it been known that yeast and bacteria are the cause of fermentation and vinegar formation. 

Note that in this case the primary alcohol was left unprotected. ... 

Strong Alcoholic Beverages. Products such as whiskey, cognac, brandy, etc. cause undesired reactions with unprotected aluminum. The attack causes pitting corrosion and formation of a floculent precipitate of aluminum hydroxide while the beverage itself becomes discolored, and the flavor is also affected (22). The action of liqueurs is not so... 

As for the synthesis of 5-e/j/-KDG, compound 6 seemed to be a suitable precursor of the methyl ester of 5-deoxy-KDG 20 since only the C-5 hydroxyl was unprotected. In this case the key step was not the epimerization but the removal of that hydroxyl. Our attempts of radicalar deoxygenation of 6 were unsuccessful because the intermediate radical was intramolecularly trappy by the C-2.C-3 double bound. Therefore we first reduced the double bond and then converted the resulting diastereoisomeric alcohols 14 into the corresponding triflates 15 which were submitted to the action of sodium iodide. Finally the iodides 16 Aus obtained were hydrogenolyzed in the presence of diisopropylethylamin to give 17. 

Smokes 2 packs per day drinks alcohol (beer) daily Admits to having unprotected sex frequently... 

Alkyne-nitrile cyclotrimerization is a powerful synthetic methodology for the synthesis of complex heterocyclic aromatic molecules.118 Recently, Fatland et al. developed an aqueous alkyne-nitrile cyclotrimerization of one nitrile with two alkynes for the synthesis of highly functionalized pyridines by a water-soluble cobalt catalyst (Eq. 4.62). The reaction was chemospecific and several different functional groups such as unprotected alcohols, ketones, and amines were compatible with the reaction.119 In addition, photocatalyzed [2+2+2] alkyne or alkyne-nitrile cyclotrimerization in water120 and cyclotrimerization in supercritical H2O110121 have been reported in recent years. 

Fournier and Charette proposed a new gem-dizinc carbenoid, IZnCHIZnI 279, for alkene cyclopropanation.389 They reported that EtZnI reacted with CHC13 to form unstable 279, which was capable of reacting with the Unprotected allylic alcohols 280a-c. The final step of the reaction sequence was quenching the Zn-containing intermediate 281a-c with an electrophile (Scheme 147). 

The ruthenium carbene catalysts 1 developed by Grubbs are distinguished by an exceptional tolerance towards polar functional groups [3]. Although generalizations are difficult and further experimental data are necessary in order to obtain a fully comprehensive picture, some trends may be deduced from the literature reports. Thus, many examples indicate that ethers, silyl ethers, acetals, esters, amides, carbamates, sulfonamides, silanes and various heterocyclic entities do not disturb. Moreover, ketones and even aldehyde functions are compatible, in contrast to reactions catalyzed by the molybdenum alkylidene complex 24 which is known to react with these groups under certain conditions [26]. Even unprotected alcohols and free carboxylic acids seem to be tolerated by 1. It should also be emphasized that the sensitivity of 1 toward the substitution pattern of alkenes outlined above usually leaves pre-existing di-, tri- and tetrasubstituted double bonds in the substrates unaffected. A nice example that illustrates many of these features is the clean dimerization of FK-506 45 to compound 46 reported by Schreiber et al. (Scheme 12) [27]. 

Subsequent deprotection of the desired z-isomer (39a) afforded desoxye-pothilone B (epothilone D), which had previously been epoxidized to epothilone B (5) [14b]. Alcohol 37 did not undergo RCM using 1 or 3 [14b]. The failure of initiator (1) to effect this transformation may be due to its incompatibility with unprotected hydroxyl groups [19]. 

It is interesting to note that the two reactions involving allyl acetate and the unprotected alcohol, but-3-en-l-ol, failed when the molybdenum catalyst was used. The failure of the Schrock catalyst to tolerate unprotected alcohols has also been observed in ring-closing metathesis [40], where a tertiary alcohol has proved to be the only success [41]. 

Related catalytic enantioselective processes It is worthy of note that the powerful Ti-catalyzed asymmetric epoxidation procedure of Sharpless [27] is often used in the preparation of optically pure acyclic allylic alcohols through the catalytic kinetic resolution of easily accessible racemic mixtures [28]. When the catalytic epoxidation is applied to cyclic allylic substrates, reaction rates are retarded and lower levels of enantioselectivity are observed. Ru-catalyzed asymmetric hydrogenation has been employed by Noyori to effect the resolution of five- and six-membered allylic carbinols [29] in this instance, as with the Ti-catalyzed procedure, the presence of an unprotected hydroxyl function is required. Perhaps the most efficient general procedure for the enantioselective synthesis of this class of cyclic allylic ethers is that recently developed by Trost and co-workers, involving Pd-catalyzed asymmetric additions of alkoxides to allylic esters [30]. 

The process is initiated by a double Grignard reaction of 4-pentynoic acid 153, first with 3-butenyl magnesium bromide and subsequently magnesium acetylide followed by silylation of the formed ter-tiaiy hydroxyl function. The cobalt induced polycy-clization leads directly to the fenestrane 157 interestingly, the reaction halts at the stage of 156 when employing the unprotected alcohol. 

The cyclic sulfites were first found to react with lithium phenoxides as nucleophiles in DMF in a one-pot procedure commencing from the unprotected diol [357]. Subsequent work opened up this class of donor to alcohol nucleophiles in conjunction with the use of a Lewis add, such as Yb(OTf)3 or Ho(OTf)3, to activate the donor in refluxing toluene (Scheme 4.57) [314,358,359]. The very high degree of P-selec-tivity observed in these reactions is consistent with an SN2-like displacement of the sulfite oxygen. 

Coupling of excess (Z)-l,2-dichloroethene (217) with propargyl alcohol first led to the enyne 218, which, when subjected to a second Pd-catalyzed coupling step with trimethylsilylacetylene, provided the mixed diacetylene 219. With all carbon atoms assembled, the allene function was generated by first producing the (unprotected) hydrazine derivative 220, which on treatment with either diethyl azodicarboxylate (DEAD) or 4-methyl-l,2,4-triazoline-3,5-dione (MTAD) under anaerobic conditions at 0 °C yielded the hydrocarbon 27. According to mechanistic studies, the latter process leads first to a mixture of ( )- and (Z)-diazenes. Sigmatropic elimination of... 

The cyanation reactions with (19) (extremely toxic and requires essentially nonacidic reaction conditions) can also he carried out with unprotected aldehydes in good yields but with higher charge consumption (88-97%, 0.15-0.45 F). For ketones, the products are isolated as trimethylsilyl ethers, whereas for aldehydes the sdyl ethers are hydrolyzed to alcohols [33]. 

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