3-Acetoxy-2-amino

Die hier beschriebenc Art der Oxyaminierung ist hoch stereospezifisch so erhalt man z. B. aus ( )- bzw. (Z)-2-Buten mit Dimethylamin als Amin-Komponente (nach reduktiver Deacetylierung des primar gebildeten 3-Acetoxy-2-amino-butans mit Lithium-alanat) threo- bzw- erythro-2-Dimethylconino-3-hydroxy-butan in jeweils 99%iger Reinheit2. 

OrganometaUics and organometaHoids that yield peroxides in this manner include those in which Q is aluminum, antimony, arsenic, boron, cadmium, germanium, lead, phosphoms, siUcon, and tin and in which X is chlorine, bromine, alkoxy, acetoxy, cyano, oxide, hydride, hydroxyl, amino, alkyl, and boron tetrafluoride (28,33,44,60) (see Table 3). 

In contrast to the 3-amino derivatives, 3-hydroxy-2,l-benzisoxazoles are relatively labile. With nitrous acid they undergo ring fission to anthranilic add. Its 3-acetoxy derivative (258) reacts with primary amines to form the quinazolone (259) (67AHC(8)277, p. 297). 

Chroman-4-one, 5-acetoxy-3-hydroxy-2,2-dimethyl-synthesis, 3, 857 Chroman-4-one, 3-amino-synthesis, 3, 855 Chroman-4-one, 3-benzylidene-synthesis, 3, 829 Chroman-4-one, 3-bromo-... 

Furan, 3-acetoxy-2,4,5-triphenyl-synthesis, 4, 659 Furan, 2-acetyl-isopropylation, 4, 607 rotamers, 4, 544 synthesis, 4, 665 toxicity, 1, 136 Furan, 3-acetyl-bromination, 4, 604 Furan, 3-acetyI-2-amino-reactions, 4, 74 Furan, 2-acetyl-3,5-dimethyl-synthesis, 4, 691 Furan, 2-acetyl-5-ethyl-synthesis, 4, 691 Furan, 2-acetyl-3-hydroxy-synthesis, 4, 649... 

Dieckmann reaction, 4, 471 Indolizidine alkaloids mass spectra, 4, 444 Indolizidine immonium salts reactions, 4, 462 Indolizi dines basicity, 4, 461 circular dichroism, 4, 450 dipole moments, 4, 450 IR spectra, 4, 449 reactivity, 4, 461 reviews, 4, 444 stereochemistry, 4, 444 synthesis, 4, 471-476 Indolizine, 1-acetoxy-synthesis, 4, 466 Indolizine, 8-acetoxy-hydrolysis, 4, 452 synthesis, 4, 466 Indolizine, I-acetyl-2-methyI-iodination, 4, 457 Indolizine, 3-acyloxy-cyclazine synthesis from, 4, 460 Indolizine, alkyl-UV spectra, 4, 449 Indolizine, amino-instability, 4, 455 synthesis, 4, 121 tautomerism, 4, 200, 452 Indolizine, 1-amino-tautomerism, 4, 38 Indolizine, 3-amino-synthesis, 4, 461, 470... 

Reductive methylation of the tetrahydropyranyl ether of 17o -acetoxy-3/3-hy-droxypregn-5-en-20-one, 56 Replacement of aromatic amino groups by fluorine, 450... 

Aminosodium salt and acylated with 1 H-tetrazole-1 -acetyl chloride. The acetoxy group is then displaced by reaction with 5-methyl-1,3-4-thi-adiazole-2-thiol in buffer solution. The product acid is converted to the sodium salt by NaHCOa. 

In chlorinations either a substitution or an addition process can occur with the ultimate reaction pathway(s) determined by a combination of factors, which include the reaction conditions, the positions and natures of any substituents present, and the catalyst used. Uncatalyzed chlorination of benzothiadiazole is an exothermic reaction that gives rise to a mixture of isomeric tetrachloro addition products. These are converted in basic medium into 4,7-dichloro-2,1,3-benzothiadiazole (70RCR923). When an iron(III) catalyst is present 4- and 7-chloro substitution becomes the dominant process. Chlorination of a number of 4-substituted 2,1,3-benzothiadiazoles (43) using an oxidative process gave a combination of chlorinated and oxidized products. The 4-hydroxy, 4-amino-, 4-methyl-amino, and 4-acetoxy derivatives of 43 all formed the chloroquinones (44) (40-61% yields). With the 4-aIkoxy substrates both 44 and some 5,7-dichlorinated product were obtained (88CHE96). 

C2H4N2 143-37-3) see Thiamine a-acetamido-4-acetoxy-3-methoxycinnamic acid (C14H15NO4 32954-47-9) see Levodopa S-acetamido-O-acetylsalicylic acid (CjiHiiNOj 6376-29-0) see Parsalmide 5-acetamido-(7-acetylsalicyloyl chloride (Ci H ()C1N04 6393-S6-S) see Parsalmide a-acetamido-3-amino-S-iodo-4-(p-methoxyphenoxy)cin-namic acid methyl ester... 

Benzaldehyde dimethyl acetal 121 reacts, for example, with the silylated allylic alcohol 645, in the presence of SnCl2-MeCOCl, via an intermediate analogous to 641, to the 3-methylenetetrahydrofuran 646 and methoxytrimethylsilane 13 a [182], whereas benzaldehyde dimethyl acetal 121 reacts with the silylated homoallylalco-hol 640 in the presence of TMSOTf 20 to afford exclusively the ds 4-vinyltetrahy-drofuran 647 and 13 a [183]. A related cyclization of an a-acetoxy urethane 648 containing an allyltrimethylsilane moiety gives the 3-vinylpyrrohdine 649 in 88% yield and trimethylsilyl acetate 142 [184, 185]. Likewise, methyl 2-formylamido-2-trimethylsilyloxypropionate reacts with allyltrimethylsilane 82 or other allyltri-methylsilanes to give methyl 2-formamido-2-aUyl-propionate and some d -unsatu-rated amino acid esters and HMDSO 7 [186] (Scheme 5.56). 

A second strategy is to attach a linker (also referred to as a handle or anchor) to the resin followed by assembly of the molecule. A linker is bifunctional spacer that serves to link the initial synthetic unit to the support in two discrete steps (Fig. 3). To attach a linker to a chloromethyl-PS resin, a phenol functionality such as handle 4 is used to form an ether bond (Fig. 4). To attach the same handle to an amino-functionalized support, acetoxy function 5 or a longer methylene spacer of the corresponding phenol is applied to form an amide bond. Both of these resins perform similarly and only differ in their initial starting resin [4], An alternative approach is to prepare a preformed handle in which the first building block is prederivatized to the linker and this moiety is attached to the resin. For peptide synthesis, this practice is common for the preparation of C-terminal peptide acids in order to reduce the amount of racemization of the a-carbon at the anchoring position [5],... 

Hydroxymethyl-4,8-dimethylfuro[2,3-/z]chromen-2-one was realized in an efficient manner via a Claisen rearrangement of 4-(hydroxybut-2-ynyloxy)-4-methylchromen-2-one as depicted in the following scheme. Other examples with substitution of hydroxyl and with other substituents, such as chloro, amino, acetoxy were also reported <06JHC763>. A new approach for the synthesis of oxygenated benzo[fe]furans was developed via epoxidation and cyclization of 2 -hydroxystilbene <06T4214>. 

The reaction has been improved to a satisfactory process by modifying the reaction conditions. A remarkable effect of the addition of amines on the reaction was observed (49). For example, the reaction of butadiene (4 moles) and acetic acid (4 moles) in the presence of 2-(N,/V-dimethyl-amino)ethanol (4 moles) using Pd(acac)2 (3 mmoles) and PPh3 (3 mmoles) at 90°C gave complete conversion after 2 hours. The product was found to consist of 8-acetoxy-1,6-octadiene (47) (71%), 3-acetoxy-1,7-octadiene (48) (21%) and 1,3,7-octatriene (16) (8%). Various tertiary amines, such as triethylamine, )V-methylmorpholine, Af,Af,N, N -tetramethyl-1,3-bu-tanediamine, and triethylenediamine, showed the same favorable effect. Other basic salts, such as sodium and potassium acetate, accelerate the reaction, especially at high concentrations (50, 51). The selection of solvents is also important. Arakawa and Miyake found that electron-donating type solvents (e.g., THF and triethylamine) are good solvents... 

This strategy also gives access to a variety of non-natural a-amino acids. Furthermore, rhodium-DuPHOS complexes catalyse the asymmetric reduction of enol esters of the type PhCH = CH — C(OCOCH3) = CH2 to give (R)-2-acetoxy-4-phenylbut-3-ene (94% ee)[64]. 

The enzyme can also catalyze the transfer of an acetyl group from an N-acetylated hydroxylamine (hydroxamic acid) to form an acetoxy product, i.e., an N to O transacetylation and this pathway does not require acetyl Co-A (12). A-hydroxy-4-acetylaminobiphenyl provides an example of this conversion as shown in Figure 7.7. The significance of this pathway is that it leads to the activation of the hydroxamic acid because acetoxy derivatives of aromatic amines are chemically reactive and many are carcinogens such as the heterocyclic amines formed when meat is heated to a high temperature, e.g., 2-amino-1-mcthyl-6-phenylirnidaz()[4,5-i ]pyri(linc. 

Amino alkenols have been prepared by palladium-catalyzed chloroacetoxylation and allylic amination of 1,3-dienes. 1,4-Acetoxychlorination is stereospecific and cyclic dienes give an overall cis- 1,4-addition12. Acetoxychlorination of 6-acetoxy-l,3-cycloheptadiene afforded only one isomer as shown in equation 8. Sequential substitution of the allylic chloro group can occur with either retention or inversion, thereby allowing complete control of the 1,4-relative stereochemistry (equation 9). 

T. Komano worked with him. The work accomplished at that time included the following N-debenzyloxycarbonylation of 1,3,4,6-tetra-0-acetyl-2-(benzyloxycarbonyl)amino-2-deoxy-D-hexopyranoses in the conversion of a,/3-acetoxy to glycosyl bromide (1961) oxidative cleavages of 1,2-diamino sugars and their significance in the mechanism of the aminocarbonyl reactions (1962) and synthesis of 2-amino-2-deoxy-/3-o-glucosides via 3,4,6-tri-D-acetyl-2-benzylsulfonamido-2-deoxy-a-D-glu-copyranosyl bromide (1962). 

Scheme 25 Sammakia s chiral alcohol catalyzed KR of a-acetoxy- and a-(At-trifluoroacetyl) amino acid-At-acyloxazolidinethiones [231, 232]...

Reaction of the silyl derivative of quinoline with 2-acetoxyethyl acetoxy-methyl ether in dichloroethane with stannic chloride gave a cyclonucleoside. Removal of both the acetyl and ethyl ester groups in NaOH afforded the fully deprotected nucleoside 788. Acylation of 788 could be carried out with different esters in the presence of amino Ps lipase [91SC1477 92JCR(S)216]. The 4-quinolones showed no significant antiviral activity (91SC1477). 

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