2-Aminoalcohol groups

Blocking of 2-aminoalcohol groups s. 11, 328 l,2,4-Oxadiazolid-5-ones from alkylidenecarbamic acid esters... 

The latter effect has been demonstrated by Meijer et al., who attached chiral aminoalcohols to the peripheral NH2-groups of polypropylene imine) dendrimers of different generations [100]. In the enantioselective addition of diethyl-zinc to benzaldehyde (mediated by these aminoalcohol appendages) both the yields and the enantioselectivities decreased with increasing size of the dendrimer (Fig. 28). The catalyst obtained from the 5th-generation dendrimer carrying 64 aminoalcohol groups at its periphery showed almost no preference for one enantiomer over the other. This behavior coincides with the absence of measurable optical rotation as mentioned in Sect. 3 above. The loss of activity and selectivity was ascribed to multiple interactions on the surface which were... 

Reactions of enamines with aluminum hydrogen dichloride (540,541) (UAIH4 and AICI3) or aluminum hydrogen dialkyl compounds (542) led to organoaluminum intermediates which could be hydrolyzed to tertiary amines or oxidized to aminoalcohols. The formation of olefins by elimination of the tertiary amine group has also been noted in these reactions. 

Treatment of the piperidine 74, obtainable from an aminonitrile such as 73, under N-methylation conditions leads to the dimethylamino derivative 75. The carbobenzoxy protecting group is then removed by catalytic hydrogenation. Reaction of the resulting secondary amine 76 with cyclohexene oxide leads to the alkylated trans aminoalcohol. There is thus obtained the anti-arrhythmic agent transcainide (77) [18]. 

Aminoalcohols are an important class of compounds in medicinal chemistry because many drugs contain this structure. For their resolution, there are two possibilities acylation of amino function or an enzymatic transesterification with vinyl esters through the hydroxyl group. However, the amino or hydroxyl group must be protected, because if the starting material is the free aminoalcohol, the O- and N-acylation can take place, and in addition, there are migrations obtaining... 

The synthesis of aldehydes and ketoamides was performed on solid phase as well as in solution (Scheme 2.2). A semicarbazone linker (6) was employed for the assembly of the aldehydes on solid phase whereas the corresponding aminoalcohol was coupled in solution to the tripeptide and oxidized to the aldehyde, which produced epimeric mixtures [137]. For the synthesis of the ketoamides, hydroxyester THP resins were used as solid support ((7), Scheme 2.2) [138]. In solution the peptide bond was formed using an aminohydroxycarboxylic acid building block [138, 147]. Oxidation of the free hydroxyl group yielded the final inhibitors ((8), Scheme 2.2). 

Fig. 7.4. Tricyclic transition structures for aminoalcohol catalysts syn and anti refer to the relationship between the transferring group and the bidentate ligand cis and trans refer to the relationship between the aldehyde substituent and the coordinating zinc. Reproduced from J. Am. Chem. Soc., 125, 5130 (2003), by permission of the American Chemical Society.

The stereochemistries of the reactions between 0-aryl 0-methyl phosphonochloridothioates and nucleophiles have been studied in relation to the synthesis of 1,3,2-oxazaphospholidines. No displacement of chlorine takes place on treatment of O-methyl 0-4-nitrophenyl phosphonochloridothioate with 2-methoxyethanol, and in the presence of 1-phenylethylamine, it is only the latter which reacts. In addition, when the same phosphonochloridothioate is treated with sodium ethoxide, it is the 4-nitrophenoxy group, rather than chlorine, which is displaced. Both displacements were shown to occur with inversion of configuration at phosphorus. The use of such an acid chloride as a two-step 1cyclophosphorylating1 agent of 2-aminoalcohols to give 1,3,2-oxazaphospholidines (209), is illustrated. ... 

In the reaction of an aminoalcohol with a methyl imidazole-AT-carboxylate or tert-butyl imidazole-AT-peroxycarboxylate, selective acylation of the amino function can be achieved11903 to give the carbamate and peroxycarbamate, respectively, the hydroxy groups of which can be further acylated ... 

Insertion of a C=0, C=S or S=0 group between an amino and a hydroxy function of a 1,2-aminoalcohol produces a five-membered heterocycle with O and N as ring heteroatoms linked by -CO-, -CS- and -SO-groups. Although the reaction proceeds in two steps, it can often be carried out as a one-pot process. 

In analogy to the preceding Section 7.1.5 the insertion of a C=0 or C=S group between an amino and a hydroxy function of 1,3-aminoalcohols using CDI or ImCSIm yields six-membered heterocycles with a carbamate or thiocarbamate structure. 

The addition of ammonia to excess methyl acrylate (a linear monomer), followed by amidation with excess ethylenediamine afforded the resultant cascade molecule, and thus Tomalia [37] created the commercially available PAMAM starburst series of dendrimers (2, Fig. 2). Related core molecules such as ethylenediamine and aminoalcohols and other functionalizable groups such as thiol moieties were used to prepare similar dendrimers [38]. This methodology is applicable to most primary amines, resulting in a 1 —> 2 branching pattern. Recently, examples of related Si-, [39] P-, [40] and metallo systems [41], which follow this linear monomer protocol have been reported. 

In one example of this type of cyclization aminoalcohol, 288, which was obtained by conjugate addition of racemic 2-(2-hydroxyethyl)piperidine to allyl phenyl sulfone, was converted into the corresponding chloride and cyclized in the presence of LDA to give 289 as a single diastereomer (Scheme 63) <2003JOC9389>. In a related approach, the primary alcohol group was activated for a similar cyclization by transformation into a mesylate <20010L2957>. 

A number of groups have reported the preparation and in situ application of several types of dendrimers with chiral auxiliaries at their periphery in asymmetric catalysis. These chiral dendrimer ligands can be subdivided into three different classes based on the specific position of the chiral auxiliary in the dendrimer structure. The chiral positions may be located at, (1) the periphery, (2) the dendritic core (in the case of a dendron), or (3) throughout the structure. An example of the first class was reported by Meijer et al. [22] who prepared different generations of polypropylene imine) dendrimers which were substituted at the periphery of the dendrimer with chiral aminoalcohols. These surface functionalities act as chiral ligand sites from which chiral alkylzinc aminoalcoholate catalysts can be generated in situ at the dendrimer periphery. These dendrimer systems were tested as catalyst precursors in the catalytic 1,2-addition of diethylzinc to benzaldehyde (see e.g. 13, Scheme 14). 

We saw that reaction of amines with aldehydes or ketones led to imine formation, rather than the simple aminoalcohol addition prodnct (see Section 7.7.1). This was because, in acidic solntion, the protonated aminoalcohol had two possible leaving groups, and water rather than the amine was the better leaving group. Dehydration occurs, leading to the imine. 

Reduction of the carbonyl group by means of sodium borohydride goes in a straightforward manner to give the aminoalcohol, quinterenol (17). It is a reasonable assumption that the heterocyclic system in this case simply serves as a surrogate benzene ring. 

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