Of primary alcohol function

We have developed an efficient and practical method for clean oxidation of starch (21-23) resulting in the oxidation of primary alcohol function in Ce position and the cleavage of vicinal diols in C2 and C3 position (Figure 30.2). We used small amounts of cheap iron tetrasulfophthalocyanine catalyst, pure water as reaction medium and H2O2 as clean oxidant to achieve a one-pot conversion of starch resulting in the introduction of aldehyde and carboxyl functions in polymer chains. The iron content... 

A. Bianco, M. Brufani, C. Melchioni, and P. Romagnoli, A new method of regioselective protection of primary alcoholic function with rare earths salts,... 

Frechet JMJ, Haque KE (1975) Use of polymers as protecting groups in organic synthesis. II. Protection of primary alcohol functional groups. Tetrahedron Lett 16 3055-3056... 

A review has been published on the oxidation of carbohydrates to carboxylic acids, with particular emphasis on catalytic oxidation of primary alcohol functions to uronic acids by use of molecular... 

Free 1975b Frechet, J.M.J. and Haque, K.E., Use of Polymers as Protecting Groups in Organic Synthesis. II. Protection of Primary Alcohol Functional Groups, Tetrahedron Lett., (1975) 3055-3056. 

The reaction of aldoses with nitric acid leads to the formation of aldaric acids by oxidation of both the aldehyde and the terminal primary alcohol function to carboxylic acid groups Aldaric acids are also known as saccharic acids and are named by substi tutmg aric acid for the ose ending of the corresponding carbohydrate... 

In 2009, Tu et al. developed a novel iron-catalyzed C(sp )-C(sp ) bond-forming reaction between alcohols and olefins or tertiary alcohols through direct C(sp )-H functionalization. A series of primary alcohols were treated with alkenes or tertiary alcohols as their precursors, using the general catalysis system FeCls (0.15 equiv)/ 1,2-dichloroethane (DCE) (Scheme 36) [46]. 

Alcohols are commonly converted into the corresponding halogen on treatment with agents such as thionyl chloride in order to provide suitable sites for further variation in functionality. For example, treatment of primary alcohol 81 with thionyl chloride leads to chloro derivative 82 (Equation 16) <1997JME2196>. 

Both the second and third processes in Scheme 13 can also be used for the functionalization of a-silylated alkyl phenyl sulfides [74] when oxidizing the latter in the presence of primary alcohols. First, the cleavage of the C—Si bond (equivalent to deprotonation) and then that of the S—C bond occurs to give... 

Uronic acids are found in nature, but they are formed enzymically by selective oxidation of the primary alcohol function of a sugar. Oxidation takes place not on the free sugar, but on UDPsugar... 

In animals, ascorbic acid is synthesized in the liver from o-glucose, by a pathway that initially involves specific enzymic oxidation of the primary alcohol function, giving o-glucuronic acid (see Section 12.8). This is followed by reduction to L-gulonic acid, which is effectively reduction of the carbonyl function in the ring-opened hemiacetal. 

Early electrochemical processes for the oxidation of alcohols to ketones or carboxylic acids used platinum or lead dioxide anodes, usually with dilute sulphuric acid as electrolyte. A divided cell is only necessary in the oxidation of primary alcohols to carboxylic acids if (he substrate possesses an unsaturated function, which could be reduced at the cathode [1,2]. Lead dioxide is the better anode material and satisfactory yields of the carboxylic acid have been obtained from oxidation of primary alcohols up to hexanol [3]. Aldehydes are intermediates in these reactions. Volatile aldehydes can be removed from the electrochemical cell in a... 

In another procedure, oxidation is carried out in the presence of chloride ions and ruthenium dioxide [31]. Chlorine is generated at the anode and this oxidises ruthenium to the tetroxide level. The reaction medium is aqueous sodium chloride with an inert solvent for the alkanol. Ruthenium tetroxide dissolves in the organic layer and effects oxidation of the alkanol. An undivided cell is used so that the chlorine generated at the anode reacts with hydroxide generated at the cathode to form hypochlorite. Thus this electrochemical process is equivalent to the oxidation of alkanols by ruthenium dioxide and a stoichiometric amount of sodium hypochlorite. Secondary alcohols are oxidised to ketones in excellent yields. 1,4- and 1,5-Diols with at least one primary alcohol function, are oxidised to lactones while... 

The next phase focused on the goal of elaboration of the side chain in the desired sense. The primary alcohol function at C7 was unveiled by hydrogenolysis (Pd(OH)2/EtOAc-MeOH). Oxidation of the resultant compound 13 with chromic oxide pyridine afforded aldehyde 14, which was now to be elongated through some variation of a Homer-Emmons type of reaction. Shortly before tiiese investigations were launched. Still had demonstrated the use of phosphonate 15 as a device to achieve the two-carbon extension of an aldehyde to a Z-enoate (12). Happily, application of the Still method to compound 14 afforded the desired 16, mp 120-121° C, in 80% yield as a 20 1 mixture of Z E enoates. 

The hydrogenation step following hydroformylation serves two important purposes. It reduces the aldehyde intermediate product to the desired primary alcohol functional group, which is the primary site of reactivity of the polyol with isocyanates. It also reduces the residual olefins in the FAMEs to saturated hydrocarbons, thus eliminating the pathway to Hock degradation and odor development, which is inherent to other processes that leave fatty acid unsaturation in the polyols. This step eliminates the typical vegetable oil odor from the final namral oil polyols of this process. 

The prominent role of alkyl halides in formation of carbon-carbon bonds by nucleophilic substitution was evident in Chapter 1. The most common precursors for alkyl halides are the corresponding alcohols, and a variety of procedures have been developed for this transformation. The choice of an appropriate reagent is usually dictated by the sensitivity of the alcohol and any other functional groups present in the molecule. Unsubstituted primary alcohols can be converted to bromides with hot concentrated hydrobromic acid.4 Alkyl chlorides can be prepared by reaction of primary alcohols with hydrochloric acid-zinc chloride.5 These reactions proceed by an SN2 mechanism, and elimination and rearrangements are not a problem for primary alcohols. Reactions with tertiary alcohols proceed by an SN1 mechanism so these reactions are preparatively useful only when the carbocation intermediate is unlikely to give rise to rearranged product.6 Because of the harsh conditions, these procedures are only applicable to very acid-stable molecules. 

Abstract This is one of the most important classes of oxidation effected by Ru complexes, particnlarly by RnO, [RuO ] , [RnO ] and RuCljCPPhj), though in fact most Ru oxidants effect these transformations. The chapter covers oxidation of primary alcohols to aldehydes (section 2.1), and to carboxylic acids (2.2), and of secondary alcohols to ketones (2.3). Oxidation of primary and secondary alcohol functionalities in carbohydrates (sugars) is dealt with in section 2.4, then oxidation of diols and polyols to lactones and acids (2.5). Finally there is a short section on miscellaneous alcohol oxidations in section 2.6. 

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