Addition pathway

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). 

In other work Rozen added molecular fluorine to a steroidal ene-one dissolved in ethanol at low temperatures to produce a vicinal difluonde in a cleaner, better yield reaction than previously obtainable [55] Although the reaction was not general, the stereoselectivity was very high, and contrary to addition of other halogens, addition was r>ii, characteristic of an electrophilic addition pathway... 

Aldehydes and unhindered ketones undergo a nucleophilic addition reaction with HCN to yield cyanohydrins, RCH(OH)C=N. Studies carried out in the early 1900s by Arthur Eapworth showed that cyanohydrin formation is reversible and base-catalyzed. Reaction occurs slowly when pure HCN is used but rapidly when a small amount of base is added to generate the nucleophilic cyanide ion, CN. Alternatively, a small amount of KCN can be added to HCN to catalyze the reaction. Addition of CN- takes place by a typical nucleophilic addition pathway, yielding a tetrahedral intermediate that is protonated by HCN to give cyanohydrin product plus regenerated CN-. 

Step 2 of Figure 29.3 Conjugate Addition of Water The a,(3-unsaturated acyl CoA produced in step 1 reacts with water by a conjugate addition pathway (Section 19.13) to yield a jG-hydroxyacyl CoA in a process catalyzed by enoyl CoA hydratase. Water as nucleophile adds to the 3 carbon of the double bond, yielding an enolate ion intermediate that is protonated on the a position. 

Synthetic polymers can be classified as either chain-growth polymen or step-growth polymers. Chain-growth polymers are prepared by chain-reaction polymerization of vinyl monomers in the presence of a radical, an anion, or a cation initiator. Radical polymerization is sometimes used, but alkenes such as 2-methylpropene that have electron-donating substituents on the double bond polymerize easily by a cationic route through carbocation intermediates. Similarly, monomers such as methyl -cyanoacrylate that have electron-withdrawing substituents on the double bond polymerize by an anionic, conjugate addition pathway. 

In phenomenological terms, the presence of a distribution of traps is equivalent to an increase of the number of tail states of the DOS and, concomitantly, opens additional pathways to the relaxation of charge earners towards sleeper states. A zero order analytic description of the effect can be based upon the Hocsterey and Letson [75] formalism. The latter is premised on the argument that the carrier mo-... 

Since the double-bond configuration is established in the final elimination step from a /t-silicon-(or tin-) substituted carbenium ion in a conformation of lowest energy, often high E selectivity is observed. In reactions of allylstannanes, catalyzed by tin(TV) chloride or titanium(IV) chloride, occasionally a metal exchange occurs, followed by the pericyclic addition pathway leading to the iwti-diastereomers17 19. A more detailed discussion is given in Section D.1.3.3.3.5. 

An additional pathway leading to very efficient EFN-(3 responses involves one of the Toll-like-recqDtors (TLR), TLR3 which also senses dsRNA and is mainly expressed in dendritic cells (DC) and macrophages. Signal transduction then proceeds via the adaptor molecule TICAM/TRIF associated with the TER.-domain of... 

P2 is generated from PtdIns(4)P by the enzymatic activity of phosphatidylinositol 4-phosphate 5-kinase (PDP5K) (Fig. 1). Additional pathways are likely to be discovered. 

Radical 27 can react with cupric chloride by two pathways, one of which leads to addition and the other to substitution. Even when the addition pathway is taken, however, the substitution product may still be formed by subsequent elimination of HCl. 

An important additional pathway is indicated in reactions I and II of Figure 47-9. This involves enzymes destined for lysosomes. Such enzymes are targeted to the lysosomes by a specific chemical marker. In reaction I, a residue of GIcNAc-1-P is added to carbon 6 of one or more specific Man residues of these enzymes. The reaction is catalyzed by a GIcNAc phosphotransferase, which uses UDP-GlcNAc as the donor and generates UMP as the other product ... 

In total, there are three barrierless entrance pathways frontside and backside addition of hydrogen atom to vinyl, and abstraction of the cis hydrogen. All the pathways discussed so far are on the singlet PES. There are also addition pathways on the triplet surface, but these are impeded by small barriers and are not expected to be important compared to the singlet surface. 

The accelerating effect of nitrate ions (over the range 10 to 1.0 M, at /i = 3.68 A/) has also been studied . An additional pathway involving the species TlNOj ", ... 

Thiocyanate ion also provides additional pathways for exchange, viz. 

The presence of phosphoric acid also provides an additional pathway... 

Lageveen et al. [41] showed that the monomer composition of aliphatic saturated poly(3HAMCL) produced by P. oleovorans is depended on the type of n-alkane used. It appeared that the n-alkanes were degraded by the subsequent removal of C2-units and it was therefore proposed that the /1-oxidation pathway was involved in poly(3HAMCL) biosynthesis. Preusting et al. [42] confirmed these results but also showed that with hexane as substrate some 3-hydroxyoctanoate and 3-hydroxydecanoate were produced, indicating that additional pathways were involved in poly(3HAMCL) biosynthesis (Table 1). 

When ene-nitrile oxidoisoquinolium betaine 131 was heated as a dilute solution in toluene to 120 °C (Scheme 1.15), near quantitative conversion to the cycloadduct 133, resulting from the undesired regioselectivity, was observed. While the near complete conversion to cycloadduct 133 of oxidoisoquinolinium betaine 131 indeed demonstrated complete avoidance of the conjugate addition pathway in favor of cycloaddition, initial production of undesired isomeric cycloadduct 133 (instead of 136) was disappointing. Notably, cycloadduct 133 is expected to be less kinetically favored based on frontier molecular orbital (FMO) analysis (assuming dipole HOMO-controlled cycloaddition) of the putative transition state. This result stands in contrast to the cycloaddition of nitroalkene oxidoisoquinolinium betaine... 

This would render an overall process of Sn2 addition in an inverted fashion. In addition, from the model, it appeared that if such an anchimeric assistance indeed existed, Sn2 addition could proceed faster, whereas the SN2 addition pathway could be slowed or even suppressed because the ct c o (of the oxonium bond) is not aligned with the system of the C5a-C5 exo-cyclic olefin in the conformation assumed by 90 (see model). The following experiment would actually support this assertion. 

FIGURE 14-3 Synthesis and metabolism of histamine. Solid lines indicate the pathways for histamine formation and catabolism in brain. Dashed lines show additional pathways that can occur outside the nervous system. HDC, histidine decarboxylase HMT, histamine methyltransferase DAO, diamine oxidase MAO, monoamine oxidase. Aldehyde intermediates, shown in brackets, have been hypothesized but not isolated. 

For the oxidative addition pathway, however, it is not obvious why the C-H bond cleavage reaction should be more facile if the hydrocarbon first binds in the coordination sphere of the metal (Scheme 5, c). One argument could be that the equilibrium between the Pt(II) alkane complex and the five-coordinate Pt(IV) alkyl hydride has an intrinsically low activation barrier. Insight into this question together with detailed information about the mechanisms of these Pt(II) a-complex/Pt(IV) alkyl hydride interconversions has been gained via detailed studies of reductive elimination reactions from Pt(IV), as discussed below. 

In a study of the methane complex [(diimine)Pt(CH3)(CH4)]+ (diimine = HN=C(H)-C(H)=NH), relevant to the diimine system experimentally investigated by Tilset et al. (28), theoretical calculations indicate preference for the oxidative addition pathway (30). When one water molecule was included in these calculations, the preference for oxidative addition increased due to the stabilization of Pt(IV) by coordinated water (30). The same preference for oxidative addition was previously calculated for the ethylenediamine (en) system [(en)Pt(CH3)(CH4)]+ (151). This model is relevant for the experimentally investigated tmeda system [(tmeda)Pt(CH3)(solv)]+ discussed above (Scheme 7, B) (27,152). For the bis-formate complex Pt(02CH)2, a a-bond metathesis was assumed and the energies of intermediates and transition states were calculated... 

Unfortunately the potential alternative of an oxidative addition pathway was not investigated in this work. 

Given the discussion above detailing that in many systems C-H activation at Pt(II) occurs via an oxidative addition pathway, it is perhaps not surprising that Pt(II) species capable of C-H activation need not be very electrophilic. On the contrary, it might be intuitively expected that electron-rich Pt(II) centers are more suitable to oxidatively add a hydrocarbon molecule. Theoretical analyses, in contrast, seem to suggest rather that electron-poor Pt(II) centers add hydrocarbon molecules more favorably (see above, Section III.F). A recent experimental study... 

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