Transformation scheme

Different azanthraquinones 390-392 were prepared from 3-amino-4-imino-4//-pyrido[l,2-a]pyrazines 373 with 1,4-quinones in one pot reactions via [4-1-2] cycloaddition and the subsequent ring transformation (Scheme 9) (97T5455). 

Contrary to the expectation that a sulfur-containing substituent will be a catalyst poison, a phenylthio group serves as an effective selectivity control element in TMM cycloadditions. A single regioisomer (30) was obtained from the carbonate precursor (31) in good yield. The thermodynamically more stable sulfide (32) is readily accessible from (30) via a 1,3-sulfide shift catalyzed by PhSSPh. A wide array of synthetically useful intermediates could be prepared from the sulfides (30) and (32) with simple transformations (Scheme 2.10) [20]. 

Trimethylsilyldiazomethane reacts under similar conditions with N-tosylimines in the presence of (ft)-Tol-BINAP, with better enantiocontrol, but the process does not live up to the standards expected of modern asymmetric transformations (Scheme 4.28) [34],... 

The most important types of these methods are the isomerizing rearrangements. According to whether the reaction occurs at the sulfone site or at the carbon site on the one hand, or at both sites on the other, one should distinguish between unifold and twofold transformations (Schemes 2 and 3). 

Monomers contained terminal phenylacetylenes protected with trimethyl-silyl groups and aryl iodides masked as N,hT-dialkyltriazenes. A typical PAM synthesis involved three basic transformations (Scheme 12) ... 

Asymmetric conjugate addition of dialkyl or diaryl zincs for the formation of all carbon quaternary chiral centres was demonstrated by the combination of the chiral 123 and Cu(OTf)2-C H (2.5 mol% each component). Yields of 94-98% and ee of up to 93% were observed in some cases. Interestingly, the reactions with dialkyl zincs proceed in the opposite enantioselective sense to the ones with diaryl zincs, which has been rationalised by coordination of the opposite enantiofaces of the prochiral enone in the alkyl- and aryl-cuprate intermediates, which precedes the C-C bond formation, and determines the configuration of the product. The copper enolate intermediates can also be trapped by TMS triflate or triflic anhydride giving directly the versatile chiral enolsilanes or enoltriflates that can be used in further transformations (Scheme 2.30) [110],... 

A New Improved Synthesis of Tricycle Thienobenzazepines Apphcation of chemistry recently developed by Knochel" combined with the well-described halogen dance (HD) reaction, allowed preparation of our key intermediate A in only three synthetic transformations (Scheme 6.4). In this respect, treatment of 2-bromo-5-methylthiophene with hthium diisopropylamide followed by dimethylformamide afforded aldehyde 11 in good yield, lodo-magnesium exchange with conunercial 4-iodo-3-nitro anisole followed by reaction with 11 afforded the thiophene catbinol 12. Dehydroxylation of 12 provided our key intermediate A which presented the requisite functionality to examine our approach to the construction of the seven-member ring system. 

In order to prepare multi-kilogram quantities of 1 our efforts were strictly focused on the development of an asymmetric route. Our retrosynthetic approach was centered on the preparation of cyclopentenone 27 which, we envisioned, could be elaborated to chiral hydroxy acid 26 through a series of asymmetric transformations (Scheme 7.4). Etherification of the hydroxy group of 26 with benzylic alcohol 25 followed by installation of (P)-nipecotate 23 at the acid position of 24, would furnish the drug candidate 1. This section will address the following ... 

It initially appeared that it should be feasible to carry out the asymmetric hydrogenation using bromo-enamide 39 and to introduce the nitrile group as the final chemical transformation (Scheme 9.29). 

When deciding on the type of the reactor required for a particular chemical or physical transformation, the first question that needs to be addresses is whether the cavitation enhancement is the result of an improved mechanical process (due to enhanced mixing). If this is the case, then cavitation pretreatment of a slurry may be all that is required before the system is subjected to conventional type transformation scheme and the scale up of the pretreatment vessel would be a relatively simpler task. 

The [l,3]thiazino[3,2-//]quinazoline 314, on heating in DMSO/EtOH, underwent ring contraction to the thiazolo-quinazoline 324 which was further transformed (Scheme 48) <2003CHE640>. 

Finally, it is important to mention that there are other related publications in which porphyrin macrocycles are not directly used as dipolarophiles but are transformed into new derivatives that can react with carbonyl ylides via ACE (alkene cyclobutene epoxide) reactions. This idea arose in 1997, when Russell and co-workers found that fused ester-activated cyclobutene epoxides 86 can be ring-opened to give carbonyl ylides 87, and that these can be trapped stereospecifically by ring-strained alicyclic dipolarophiles, such as 2,5-norbomadiene, to form hetero-bridged norbomanes 88 in good yields, through ACE transformations (Scheme 31) <97CC1023>. 

A few years later, the same group extended this strategy in order to access metabolically stable C-glycosyl clusters containing long-arm spacers via a sequence of transition metal-catalyzed transformations (Scheme 11).93 In this context, crossmetathesis reactions of various C-glycosyl compounds with alkenes having available... 

The concept of performing microwave synthesis in room temperature ionic liquids (RTIL) as reaction media has been applied to several different organic transformations (Scheme 4.18), such as 1,3-dipolar cycloaddition reactions [54], catalytic transfer hydrogenations [55], ring-closing metathesis [56], the conversion of alcohols to alkyl halides [57, 58], and several others [59-61],... 

Various alkyl- and aryl-substituted [3]radialenes could be prepared from 1,1-dihaloal-kenes using organometallic pathways. Hexamethyl-[3]radialene (25), the first [3]radialene to be synthesized, was obtained in a very low yield by treatment of l,l-dibromo-2-methyl-1-propene (22) with butyllithium8,9. The lithium carbenoid 23 and the butatriene 24 are likely intermediates of this transformation (Scheme 2), the former being the source of an unsaturated carbene moiety which is transferred onto the latter. However, the outer double bonds of 24 are more readily cyclopropanated than the central one. 

Reactions of Cyclic Conjugated Ene Nitroso Acetals with Nucleophiles The reaction of six-membered cyclic ene nitroso acetals (475) with nucleophiles has a high potential and will probably provide the basis for a promising procedure for the synthesis of polyfunctional compounds from very simple precursors, the more so that the configurations of stereocenters in the starting nitronate (475) can be retained in particular transformations (Scheme 3.253). Unfortunately, the available data (264) are insufficient to elucidate the complete mechanism of this process. 

Titanacyclobutanes also serve as useful synthetic intermediates the titanacycle 43, prepared by the intramolecular reaction of the alkenylidene complex 44, affords the a-dike-tone 45 and the other functionalized cyclic compounds by further transformations (Scheme 14.20) [35]. 

An unusual rearrangement has been observed when fra r-a,/3-unsaturated ester 260 on treatment with MCPBA gave a mixture of three products in 80% yield. The most abundant product was identified as the bicyclic 7-lactam 261 (45%) and the minor constituents were identified as the epoxides 262 (19%) and 263 (17%) (Equation 40) <2003T241>. A mechanism has been postulated to explain this transformation (Scheme 39). 

The dilithiated species 97 can be used to obtain a Ge=Sn doubly bonded species (Equation (182)), which undergoes a thermal isomerization involving migration of the bulky Tip group (Equation (183)).184 The germa-nium/tin compound 108, which contains a fluoride functionality at tin, can be prepared from Mes2GeH2 (Equation (184)), and this can subsequently be converted into the doubly bonded species 109 which can undergo several additional transformations (Scheme 33).226... 

Figure 2.17. Structural model of transformation scheme of PAN to carbon...

A synthetic application of the sonolysis of iron carbonyls is the preparation of useful ferrilactones. The alkenyl epoxides (2, R = H, Ph, 1-hexanyl) are smoothly converted to the corresponding ferrilactone complexes (3) on reaction with Fe2(CO)9 suspended in THF and sonicated at room temperature [53]. Such complexes undergo several synthetically useful transformations (Scheme 3.7) including oxidation with Ce(IV) as a route to P-lactone natural products or P-lactam antibiotics and reaction with CO to afford 5-lactones [54]. Somewhat surprisingly this reaction is efficient even in diethyl ether, a volatile solvent which delivers low cavitation energy. 

Thanks to their ambident character, acceptor-substituted dienes can provide several isomeric products in copper-mediated Michael additions, therefore making it particular important to control not only the regioselectivity but also the stereoselectivity of these transformations (Scheme 4.1). 

The efficient and selective catalysis of some Diels-Alder reactions by lanthanide P-diketonate complexes has been known since 1975 [226, 227]. The fluorinated p-diketonate complexes Ln(fod)3 (cf. Scheme 12.5) selectively catalyze the Danishefsky transformation (Scheme 12.23) as a consequence of their mild Lewis acidity. Importantly, zeolites and Lewis acid modified silica or alumina also catalyze Diels-Alder reactions [228-232]. 

The assembling of the hydroazulene AB-ring system 210 set out with three consecutive C/C connecting transformations (Scheme 31). Copper catalysed... 

The enantiopure complex 35 has since been employed as an atropos asymmetric catalyst for a variety of synthetic transformations (Scheme 8.33)." In addition, the hetero Diels-Alder reaction of glyoxylate could also be catalyzed by enantiopure... 

In the initial screening of various Cinchona alkaloids, the addition of diethyl phosphate 41 to IV-Boc imine 40 in toluene revealed the key role of the free hydroxyl group of the catalyst. Replacing the C(9)-OH group with esters or amides only results in poor selectivity. Quinine (Q) was identified as an ideal catalyst. A mechanistic proposal for the role of quinine is presented. Hydrogen-bonding by the free C(9)-hydroxyl group and quinuclidine base activation of the phosphonate into a nucleophilic phosphite species are key to the reactivity of this transformation (Scheme 9). 

A synthetically more challenging C-H acid that represents a method for the glyoxylation of a,P-unsaturated aldehydes is aminonitrile 62 [104], Conjugate addition of 62 catalysed by diarylprolinol ether 30 (20 mol%) provides adducts 63. Reduction, protection and hydrolysis of these adducts leads to the glyoxylates 64 showing the impressive functional group tolerance of these transformations (Scheme 26). 

During the past decades, the scope of Lewis acid catalysts was expanded with several organic salts. The adjustment of optimal counter anion is of significant importance, while it predetermines the nature and intensity of catalytic Lewis acid activation of the reactive species. Discovered over 100 years ago and diversely spectroscopically and computationally investigated [131-133], carbocations stiU remain seldom represented in organocatalysis, contrary to analogous of silyl salts for example. The first reported application of a carbenium salt introduced the trityl perchlorate 51 (Scheme 49) as a catalyst in the Mukaiyama aldol-type reactions and Michael transformations (Scheme 50) [134-142]. 

---