Retrosynthetic analysis approach

However, as we will see below, twistane has been used as a model for testing the validity of the retrosynthetic analysis approach [2], as well as the soundness and/or limitations of the "strategic bond" concept. 

The first problem will prepare 4-bromoaniline (168) from benzene. Syntheses that transform one aromatic compound into another aromatic compound, such as this one, do not lend themselves to the retrosynthetic analysis approach presented in Chapter 25. Most of these syntheses involve functional group transformations. For the sake of continuity, a retrosynthesis is shown in which the amino group is removed to generate bromobenzene, which is obtained directly from benzene. The NH2 unit probably comes from reduction of a nitro group (Section 21.6.2), so the first precursor is 4-bromonitrobenzene (59) and disconnection of the C-N bond leads to the preparation of 59 by reaction of bromobenzene (35) with nitric acid/sulfuric acid. Bromobenzene is prepared directly from benzene as shown in the illustration. 

To recognize the different levels of representation of biochemical reactions To understand metabolic reaction networks To know the principles of retrosynthetic analysis To understand the disconnection approach To become familiar with synthesis design systems... 

The Japanese program system AlPHOS is developed by Funatsu s group at Toyo-hashi Institute of Technology [40]. AlPHOS is an interactive system which performs the retrosynthetic analysis in a stepwise manner, determining at each step the synthesis precursors from the molecules of the preceding step. AlPHOS tries to combine the merits of a knowledge-based approach with those of a logic-centered approach. 

The retrosynthetic analysis of a target compound is a systematic approach in developing a synthesis plan starting with the target structure and working backward to available starting materials. 

When planning the synthesis of a compound using an organometallic reagent or indeed any synthesis the best approach is to reason backward from the product This method is called retrosynthetic analysis Retro synthetic analysis of 1 methylcyclohexanol suggests it can be prepared by the reaction of methylmagnesmm bromide and cyclohexanone... 

Estrone (54, Chart 6) contains a full retron for the o-quinonemethide-Diels-Alder transform which can be directly applied to give 55. This situation, in which the Diels-Alder transform is used early in the retrosynthetic analysis, contrasts with the case of ibogamine (above), or, for example, gibberellic acid (section 6.4), and a Diels-Alder pathway is relatively easy to find and to evaluate. As indicated in Chart 6, retrosynthetic conversion of estrone to 55 produces an intermediate which is subject to further rapid simplification. This general synthetic approach has successfully been applied to estrone and various analogs. ... 

The most important connective transforms in retrosynthetic analysis are the family of C=C cleavage transforms, including one-step (e.g. ozonolytic) or two-step (e.g. OSO4 followed by Pb(OAc)4) (Chart 25). There are many elegant syntheses of challenging molecules which depend on such processes. Two examples will provide an idea of the underlying retrosynthetic approach. 

Scheme 1 outlines the retrosynthetic analysis of the Woodward-Eschenmoser A-B variant of the vitamin B12 (1) synthesis. The analysis begins with cobyric acid (4) because it was demonstrated in 1960 that this compound can be smoothly converted to vitamin B12.5 In two exploratory corrin model syntheses to both approaches to the synthesis of cobyric acid,6 the ability of secocorrinoid structures (e. g. 5) to bind metal atoms was found to be central to the success of the macrocyclization reaction to give intact corrinoid structures. In the Woodward-Eschenmoser synthesis of cobyric acid, the cobalt atom situated in the center of intermediate 5 organizes the structure of the secocorrin, and promotes the cyclization... 

Scheme 15. Retrosynthetic analysis of brevetoxin B (1) the first-generation approach.

The second edition of this extremely successful guidebook for planning organic syntheses is addressed to advanced undergraduate, graduate and research chemists. Retrosynthetic analysis and the synthon approach are presented. This new, extensively revised and enlarged edition takes account of recent developments, such as nanometer-size architecture, while emphasizing the essentials. 

Scheme 2.5 Second approach retrosynthetic analysis of common precursor 14.

Porco, Jr. and coworkers also used this biomimehc domino approach for the synthesis of the quinone epoxide dimer torreyanic acid 7-151 as racemic mixture [67]. This natural product, isolated from the fungus Pestalotiopsis microspora, shows a pronounced cytoxicity to tumor cells. Its retrosynthetic analysis leads to the 2H-pyran 7-152 (Scheme 7.40). As substrate for the domino process, the epoxide... 

Scheme 4.117 Retrosynthetic analysis of heptaglucan phytoalexin synthesis achieved using an iterative approach.

Much of the recent work on the use of anodic amide oxidation reactions has focused on the utility of these reactions for functionalizing amino acids and for synthesizing peptide mimetics [13]. For example, in work related to the cyclization strategy outlined in Scheme 3, the anodic amide oxidation reaction has been used to construct a pair of angiotensin-converting enzyme inhibitors [14]. The retrosynthetic analysis for this route is outlined in Scheme 4. In this work, the anodic oxidation reaction was used to functionalize either a proline or a pipercolic add derivative and then the resulting methoxylated amide used to construct the bicyclic core of the desired inhibitor. A similar approach has recently been utilized to construct 6,5-bicyclic lactam building blocks for... 

In contrast to Nicolaou s synthetic plan, the retrosynthetic analysis of Holton s approach preserves the non-synthetically significant B ring and proceeds through disconnection of bonds which are involved in the D and C rings, to arrive finally to the bicyclo[5.3.1]undecane derivative 32, as the starting material. 

The retrosynthetic analysis of the 2-oxygenated carbazole alkaloids, 2-methoxy-3-methylcarbazole (37) and mukonidine (54), based on an iron-mediated approach, led to the iron-complexed cation 602 and the arylamines 655 and 656 as precursors (Scheme 5.48). 

The retrosynthetic analysis of the 2-oxygenated carbazole alkaloids, 2-methoxy-3-methylcarbazole (37), O-methylmukonal (glycosinine) (38), 2-hydroxy-3-methylcar-bazole (52), and mukonal (53) based on the molybdenum-mediated approach led to the molybdenum-complexed cation (663) and 3-methoxy-4-methylaniline (655) as precursors (Scheme 5.51). The cationic molybdenum complex, dicarbonyl (ri -cyclohexadiene)(r -cyclopentadienyl)molybdenum hexafluorophosphate (663), required for the electrophilic substitution, was easily prepared quantitatively through known literature procedures (586,587). 

Retrosynthetic analysis of the 2,7-dioxygenated carbazole alkaloids, 7-methoxy-O-methylmukonal (48), clausine H (clauszoline-C) (50), clausine K (clauszoline-J) (51), and clausine O (72), based on an iron-mediated approach, led to 2-methoxy-substituted iron complex salt 665 and 3-methoxy-4-methylaniline (655) as precursors (588) (Scheme 5.53). 

Retrosynthetic analysis of girinimbine (115) and murrayacine (124), based on our molybdenum-mediated approach, provides the molybdenum complex salt 577 and the 5-aminochromene 1044 as potential precursors (660) (Scheme 5.159). 

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