Michael possible

Both are possible but we are more used to (1) since we can use a Michael acceptor and cyanide ion for the two synthons. How would you actually do a s mthesis this way ... 

Class (2) reactions are performed in the presence of dilute to concentrated aqueous sodium hydroxide, powdered potassium hydroxide, or, at elevated temperatures, soHd potassium carbonate, depending on the acidity of the substrate. Alkylations are possible in the presence of concentrated NaOH and a PT catalyst for substrates with conventional pX values up to - 23. This includes many C—H acidic compounds such as fiuorene, phenylacetylene, simple ketones, phenylacetonittile. Furthermore, alkylations of N—H, O—H, S—H, and P—H bonds, and ambident anions are weU known. Other basic phase-transfer reactions are hydrolyses, saponifications, isomerizations, H/D exchange, Michael-type additions, aldol, Darzens, and similar... 

Unsubstituted 2,1-benzisoxazoles undergo C(3)-proton abstraction with base to give an intermediate iminoketene which can undergo further reaction with nucleophiles. However, alternative Michael addition pathways are possible and these have been discussed (81AHC(29)l,p.56). 

The stereochemical outcome of the Michael addition reaction with substituted starting materials depends on the geometry of the a ,/3-unsaturated carbonyl compound as well as the enolate geometry a stereoselective synthesis is possible. " Diastereoselectivity can be achieved if both reactants contain a stereogenic center. The relations are similar to the aldol reaction, and for... 

With the use of chiral reagents a differentiation of enantiotopic faces is possible, leading to an enantioselective reaction. The stereoselective version of the Michael addition reaction can be a useful tool in organic synthesis, for instance in the synthesis of natural products. 

Another important feature of the Nef reaction is the possible use of a CH-NO2 function as an umpoled carbonyl function. A proton at a carbon a to a nitro group is acidic, and can be abstracted by base. The resulting anionic species has a nucleophilic carbon, and can react at that position with electrophiles. In contrast the carbon center of a carbonyl group is electrophilic, and thus reactive towards nucleophiles. 1,4-Diketones 4 can for example be prepared from a-acidic nitro compounds by a Michael additionfNef reaction sequence " ... 

The best method to achieve a high regioselectivity is the use of preformed enolates. A double annulation reaction is possible if, for example, a diketone such as 11 is used as starting material. The product of the Michael addition 12 can undergo two subsequent aldol condensation reactions to yield the tricyclic dienone 13 ... 

This type of reaction usually gives good yields here the possible iV-alkylation is reversible—through a retro-Michael-type reaction ... 

Michael acceptors and 1,4-addiiion of alkyl group is a normal process. The reaction mechanism is not clear, but the process via addition of alkyl radicals and subsequent elimination of NO radical is one of the possible routes. Recently, several related reactions have been reported, as shown in Eq. 4.76, Eq. 4.77, and Eq. 4.78, in which alkyl radicals are involved. The reaction of trialky Igalliiim compounds with nitrostyrene gives also a similar snbsdtiidon product fEq. 4.791. ° ... 

The high acidity of ct-nitroketones makes it possible to perform the Henry reacdons or Michael addidons under extremely rruld condidons The reacdon proceeds in the presence of catalydc amounts of Ph-vP to give the C-C bond formadon products under nearly neutral condidons Thus, 1,5-dicarbonyl compounds and ct-methylenecarbonyl compounds are prepared by the denitradon of ct-nitroketones, as shown in Eqs 7 67 and 7 68, respecdvely... 

Several electrical scientists in the early part of the nineteenth century, influenced at least in part by their understanding of German natiirplnlosophie, expected forces of nature to be intimately connected to each other, and some of them spent extraordinary amounts of time looking for the relationship. One of these was a Dane, Hans Christian Oersted, who, after an exhaustive series of experiments, in 1820 found that electricity could indeed produce a magnetic effect. Further experiments by Michael Faraday demonstrated, in 1821, that by proper orientation of an electric current and a magnetic field it was possible to produce continuous motion in what soon would be called a motor. It took an additional ten frustrating years for him to prove what he instinctively felt to be true, that, in a fashion inverse to what... 

Heaviside made a significant contribution to electrical communications when he advocated the introduction of additional inductance in long-distance telephony cables although there was then no practical means to add it. His idea was eventually patented in 1904 by Michael Campbell of AT T after Heaviside and George Pupin of Columbia University had shown it was possible to apply inductance in the form of uniformly spaced loading coils. By 1920 engineers had installed such loading on thousands of miles of cable, particularly in the United States. 

In the same period, James Prescott Joule, son of a Manchester brewery owner, had been carrying out a series of experiments to determine the relationship between work done and heat produced. In the wake of Michael Faraday s electrical researches, electromagnetic engines appeared as a possible future rival... 

Four different orientations are possible when the enantiofaces of (E)- and (Z)-enolates and an ( )-enone combine via a closed transition state, in which the olefinic moieties of the donor and the acceptor are in a syn arrangement. It should be emphasized that, a further four enan-tiomorphous orientations of A-D are possible leading to the enantiomers 2 and 3. On the basis of extensive studies of Michael additions of the lithium enolates of esters (X = OR) and ketones (X = R) to enones (Y = R) it has been concluded ... 

Diastereoselective preparation of a-alkyl-a-amino acids is also possible using chiral Schiff base nickel(II) complexes of a-amino acids as Michael donors. The synthetic route to glutamic acid derivatives consists of the addition of the nickel(II) complex of the imine derived from (.S )-,V-[2-(phenylcarbonyl)phenyl]-l-benzyl-2-pyrrolidinecarboxamide and glycine to various activated olefins, i.e., 2-propenal, 3-phenyl-2-propenal and a,(f-unsaturated esters93- A... 

The enolate of the 1,4-adduct, obtained after the stereoselective Michael addition step, as discussed in the previous sections, may be quenched in situ with various electrophiles. The fact that additional stereogenic centers may be formed via such tandem Michael addition/quench-ing procedures, giving products with high diastereoselectivity in many cases, extends the scope of these methods substantially. Furthermore these procedures occasionally offer the possibility of reversing the syn/anti diastereoselection. In the next sections pertinent examples of diastereoselective inter- and intramolecular quenching reactions will be discussed. 

Base-induced eliminative ring fission, in which both the double bond and the sulfone function take part, has been observed in thiete dioxides253. The reaction can be rationalized in terms of initial Michael-type addition to the double bond of the ring vinyl sulfone, followed by a reverse aldol condensation with ring opening. The isolation of the ether 270c in the treatment of 6c with potassium ethoxide (since the transformation 267 -> 268 is not possible in this case) is in agreement with the reaction mechanism outlined in equation 101253. 

Three possible mechanisms may be envisioned for this reaction. The first two i.e. 1) Michael addition of R M to the acetylenic sulfone followed by a-elimination of LiOjSPh to yield a vinyl carbene which undergoes a 1,2 aryl shift and 2) carbometallation of the acetylenic sulfone by R M followed by a straightforward -elimination, where discarded by the authors. The third mechanism in which the organometallic reagent acts as an electron donor and the central intermediates is the radical anion ... 

A common reaction sequence is shown in the schemes printed above. The sulfosuccinate monoesters are produced by a two-step reaction. In the first step 1 mol of maleic anhydride is reacted with a hydroxyl group-bearing component. In the second step the monoester is reacted with sodium sulfite (or sodium bisulfite) to form the disodium alkyl sulfosuccinate. At the so-called halfester stage, there are two possibilities for an electrophilic attack [61] (Michael-type reaction) at the double bond (Scheme 6). Reactivity differences between the two vinylic carbons should be very small, so that probably an exclusive formation of one single regioisomer can be excluded. 

In principle, numerous reports have detailed the possibility to modify an enzyme to carry out a different type of reaction than that of its attributed function, and the possibility to modify the cofactor of the enzyme has been well explored [8,10]. Recently, the possibility to directly observe reactions, normally not catalyzed by an enzyme when choosing a modified substrate, has been reported under the concept of catalytic promiscuity [9], a phenomenon that is believed to be involved in the appearance of new enzyme functions during the course of evolution [23]. A recent example of catalytic promiscuity of possible interest for novel biotransformations concerns the discovery that mutation of the nucleophilic serine residue in the active site of Candida antarctica lipase B produces a mutant (SerlOSAla) capable of efficiently catalyzing the Michael addition of acetyl acetone to methyl vinyl ketone [24]. The oxyanion hole is believed to be complex and activate the carbonyl group of the electrophile, while the histidine nucleophile takes care of generating the acetyl acetonate anion by deprotonation of the carbon (Figure 3.5). 

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