Cbz protection

Nakajima and Okawa prepared cysteine (250 Scheme 3.92) by treating aziridine 127a with dry H2S gas in the presence of a catalytic amount of BF3 Et20 [141]. The resulting thiol 248 was then oxidized with iodine to afford disulfide 249 in 70% overall yield. Removal of the Cbz protecting group afforded cysteine (250). 

S,3R)-Aziridine-2-carboxylic amide 258 (Scheme 3.95) has been used in the synthesis of the cyclic guanidino amino acid, L-epicapreomycidine (260) [145]. Treatment of 258 with saturated ammonia in methanol at 30 °C for 4 days in a pressure bottle resulted in the aziridine ring-opening product, which afforded 259 in 52 % yield after removal of the Cbz protecting group. 

CBz-protected benzimidazole gave primarily oxazinone [31], while 3/f-indoles incorporated two equivalents of imine (Eq. 4) [32]. In these cases it appears that the initially formed zwitterionic ketene-imine adduct could not close, and reacted with additional photo activated carbene or substrate. 

Treatment of intermediate 31 with 2.2 equiv of 4-FB A in EtOH at 72 °C afforded 35 as a white crystalline solid in 90% isolated yield (Scheme 6.9). Hydrogenation in the presence of 5% of Pd/C and 1 equiv of MsOH, efficiently removed the Cbz-protected group. MsOH was used to prevent fluoride reduction resulting in low levels of the des-fluoro by-product. Catalyst filtration, followed by neutralization of the crude reaction mixture with NaOH, afforded free amine 36 as a white crystalline product in 99% isolated yield. Free-amine 36 was isolated as a dihydrate which necessitated drying prior to coupling with oxadiazole chloride 2. 

The deprotection of the Cbz protected amino acid proceeds via a two step mechanism (Figure 1). The first step comprises the catalytic hydrogenolysis of the benzyloxy group of the Cbz-protected amino acid (1). Toluene (3) is formed from the O-benzyl group as well as an unstable carbamic acid intermediate (2). This intermediate decomposes to form the unprotected amino acid (4) and carbon dioxide (5). 

Figure 1 Reaction scheme for the hydrogenolysis of a Cbz-protected amino acid.

Next, we investigated the experimental parameters for hydrogenolysis of Cbz-protected amino acids. It is important to carefully select the experimental parameters so that the reactions are not limited by diffusion of hydrogen to the catalytically active sites. The diffusion of hydrogen can be affected by temperature, agitation speed, as well as the number of catalytically active sites... 

The removal of a carbobenzyloxy group can be separated into two steps (Figure 1). The first step comprises the hydrogenolysis of the benzyl oxygen bond of the Cbz-protected amino acid 1 to form a carbamic acid intermediate 2 and toluene 3. The carbamic acid intermediate decaiboxylates to give the deprotected amino acid 4 and one equivalent of carbon dioxide 5. 

Figure 2 Formation of carbon dioxide during the deprotection of CBz protected phenylalanine (with and without ethylenediamine) in the presence of 5%Pd/C.

In addition to the already known inhibiting effect of N-containing bases on debenzylation reactions we have shown that similar modifiers can increase the rate of hydrogenolysis of a CBz protected amino acid. As these reactions are carried out on industrial scale the addition of certain modifiers can increase the reaction rate, thus leading to shorter reaction times and higher productivity. 

The deprotection of carbobenzyloxy protected phenylalanine was carried out in a low-pressure test unit (V= 200 ml) equipped with a stirrer, hydrogen inlet and gas outlet. The gas outlet was attached to a Non Dispersive InfraRed (NDIR) detector to measure the carbon dioxide. During the reaction the temperature was kept at 25 °C at a constant agitation speed of 2000 rpm. In a typical reaction run, 10 mmol of Cbz protected phenylalanine and 200 mg of 5%Pd/C catalyst were stirred in a mixture of 70 ml ethanol/water (1 1). The Cbz protected phenylalanine is not water-soluble but is quite soluble in alcoholic solvents conversely, the water-soluble deprotected phenylalanine is not very soluble in alcoholic solvents. Thus, the two solvent mixture was used in order to keep the entire reaction in the solution phase. Twenty p.1 of the corresponding modifier was added to the reaction mixture, and hydrogen feed was started. The hydrogen flow into the reactor was kept constant at 500 ml/minute and the progress of the reaction was monitored by the infrared detection of C02 in the off-gas. 

Carbamates Both O-Bn and N-Cbz protecting groups have been removed by transfer hydrogenolysis (Scheme 4.59). 

The described approach also allows a simple access to indole alkaloids of the vallesiachotamine type. In this process, the Cbz-protected secondary amino function in the formed cycloadducts such as ent-2-805 is deprotected by hydrogenolysis. There follows an attack at the lactone moiety to form a lactam. In this way, the indole alkaloid (-)-dihydroantirhin (2-797) was prepared [400, 401]. 

Protected pyrazoline derivatives 429 can be transformed by conventional ozonolysis methodology to the corresponding aldehydes 430, then the Cbz protecting group is removed and the intramolecular reductive amination using... 

Photo-induced conversions are also important synthetically. The photocycloaddition of 5-substituted uracils 69 with ethylene has been used for the synthesis of 2-aminocyclobutanecarboxylic acids. The addition reaction worked well with carbon and fluorine substituents and also with a Cbz-protected amino. However, uracils with other 5-nitrogen substituents (NH2, NHBn and NO2) failed, only starting material being recovered. The sequence also worked for the 6-isomers but somewhat less consistently <06SL1394>. 

Another microwave-mediated intramolecular SN2 reaction forms one of the key steps in a recent catalytic asymmetric synthesis of the cinchona alkaloid quinine by Jacobsen and coworkers [209]. The strategy to construct the crucial quinudidine core of the natural product relies on an intramolecular SN2 reaction/epoxide ringopening (Scheme 6.103). After removal of the benzyl carbamate (Cbz) protecting group with diethylaluminum chloride/thioanisole, microwave heating of the acetonitrile solution at 200 °C for 2 min provided a 68% isolated yield of the natural product as the final transformation in a 16-step total synthesis. 

To increase the load of liposomes and micelles with reporter metals, we designed a new family of amphiphilic single-terminus modified polymers containing multiple chelating groups that could be incorporated into the hydrophobic domains of liposomes and micelles. The approach is based on the use of CBZ-protected polylysine (PL) with a free terminal amino group, which is derivatized into a reactive form with subsequent deprotection and incorporation of DTPA residues. This was initially suggested by us for heavy metal load on proteins and antibodies [17]. 

Figure 2 Chemistry of the polymeric chelates used for loading liposomes and micelles with multiple reporter metal atoms, (a) Synthesis of a single terminus-PDP-activated chelating polymer (DTPA-polylysine) starting from CBZ-protected polylysine and SPDR...

The key step in the approach of Jurczak et al. [59] was a chelation-con-trolled addition of allyltrimethylsilane to the AT-Cbz-protected phenylalani-nal 88 in the presence of SnCl4 (Scheme 24). The preussin C-3/C-4 bond was... 

After epoxidation of the terminal olefin in syn-89 the pyrrolidine 91 was formed by reductive cleavage of the Cbz-protection and concomitant Sn2 cyclization of the free amine to epoxide 90. In five additional steps (+)-preus-sin (2) was synthesized with an overall yield of 19%. After AT-methoxycar-bonylation and oxidation of the alcohol to an aldehyde the alkyl side chain was introduced by a Wittig reaction. 

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