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Nucleophilic substitution aliphatic and aromatic

Aliphatic and aromatic nucleophilic substitutions with p Fjfluoride are usually performed either on an immediate precursor of the target molecule (direct labelling using a one-step process) or on an indirect precursor followed by one or more chemical steps leading to the target radiotracer. The first approach, if highly desirable, is in fact rarely practicable. The reaction conditions are often not compatible with the structure or with the various chemical functions borne by the radiopharmaceutical. It is therefore common that the radiosynthesis comprises at least two chemical steps first the introduction of fluorine-18 followed by what is often a (multi)deprotection step. It is not unusual either that fluorine-18 is first incorporated into a much simpler and chemically more robust molecule which is then coupled to a more sensitive entity under milder conditions, possibly still followed by a final deprotection step. Suchlike multi-step procedures are possible thanks to the favourable half-life of fluorine-18. However, the more complicated the process, the more chance of side reactions and complicated final purifications (see also Section 2.3), which may seriously hamper the automation of the process. [Pg.28]

Both aliphatic and aromatic nucleophilic substitution procedures involve first pre-activation of cyclotron-produced, no-carrier-added, aqueous [ Fjfluoride. [Pg.28]

The chemistry of fluorine-18 radiopharmaceuticals, the reagents employed in electrophilic and nucleophilic fluorination methods and in aliphatic and aromatic nucleophilic substitutions, for the period 1977-1986 have been reviewed by Berridge and Tewson1. The earlier 18F-chemistry has been reviewed by Palmer, Clark and Goulding2. [Pg.405]

Aliphatic and aromatic nucleophilic substitution reactions are also subject to micellar effects, with results consistent with those in other reactions. In the reaction of alkyl halides with CN and S Oj in aqueous media, sodium dodecyl sulfate micelles decreased the second-order rate constants and dodecyltrimethylammonium bromide increased them (Winters, 1965 Bunton, 1968). The reactivity of methyl bromide in the cationic micellar phase was 30 to 50 times that in the bulk phase and was negligible in the anionic micellar phase a nonionic surfactant did not significantly affect the rate constant for n-pentyl bromide with S2O3-. Micellar effects on nucleophilic aromatic substitution reactions follow similar patterns. The reaction of 2, 4-dinitrochlorobenzene or 2, 4-dinitrofluorobenzene with hydroxide ion in aqueous media is catalyzed by cationic surfactants and retarded by sodium dodecyl sulfate (Bunton, 1968, 1969). Cetyltrimethylammonium bromide micelles increased the reactivity of dinitrofluorobenzene 59 times, whereas sodium dodecyl sulfate decreased it by a factor of 2.5 for dinitrochlorobenzene, the figures are 82 and 13 times, respectively. A POE nonionic surfactant had no effect. [Pg.201]

Solid-liquid phase transfer catalyst 2 for aliphatic and aromatic nucleophilic substitution synergistic effect with Cu in Ullmann synthesis as ligand in homogeneous hydrogenation catalysis (see 1st edition). [Pg.348]

Sodium Iodide This is the simplest, and the only commercial, form of iodine. It is extensively used in aliphatic and aromatic nucleophilic substitutions. It is the iodinating agent in melts, for nucleophilic substitution, and the starting point for the preparation of all other iodinating agents. [Pg.743]

Compound 40 has not yet been synthesized. However, there is a large body of synthetic data for nucleophilic substitution reactions with derivatives of 41 [synthesized from aliphatic and aromatic aldehydes, pyridine, and trimethylsilyl triflate (92S577)]. All of these experimental results reveal that the exclusive preference of pathway b is the most important feature of 41 (and also presumably of 40). [Pg.198]

In Part 2 of this book, we shall be directly concerned with organic reactions and their mechanisms. The reactions have been classified into 10 chapters, based primarily on reaction type substitutions, additions to multiple bonds, eliminations, rearrangements, and oxidation-reduction reactions. Five chapters are devoted to substitutions these are classified on the basis of mechanism as well as substrate. Chapters 10 and 13 include nucleophilic substitutions at aliphatic and aromatic substrates, respectively, Chapters 12 and 11 deal with electrophilic substitutions at aliphatic and aromatic substrates, respectively. All free-radical substitutions are discussed in Chapter 14. Additions to multiple bonds are classified not according to mechanism, but according to the type of multiple bond. Additions to carbon-carbon multiple bonds are dealt with in Chapter 15 additions to other multiple bonds in Chapter 16. One chapter is devoted to each of the three remaining reaction types Chapter 17, eliminations Chapter 18, rearrangements Chapter 19, oxidation-reduction reactions. This last chapter covers only those oxidation-reduction reactions that could not be conveniently treated in any of the other categories (except for oxidative eliminations). [Pg.381]

Sulfur atom as internal nucleophile. In this area, it has been shown that the reaction of 8-bromo-l,3-dimethyl-7-(2,3-epithiopropyl)xanthine 147 with a range of aliphatic and aromatic amines generates efficiently 2-amino-substituted 2,3-dihydro-thiazolo[2,3-/]xanthine derivatives 148. The process involves a sequential amine-induced thiirane ring opening followed by thiolate z/MYi-substitution of chlorine atom (Equation 66) <1994PCJ647>. [Pg.153]

Zirconium tetrachloride promotes a tandem nucleophilic addition and aldol-type condensation reaction of methyl propynoate, or /V,/V-dimethylpropynamidc, with aldehydes, or ketones, in the presence of tetra-n-butylammonium iodide (Scheme 6.13) [8] with a high selectivity towards the formation of Z-isomers. A similar reaction occurs between aliphatic and aromatic aldehydes and penta-3,4-dien-2-one to yield 1-substituted 2-acetyl-3-iodobut-3-enols (50-75%) [9]. [Pg.260]

In order to clarify the different behavior of anion 2 and 3 (Scheme 4.10) toward DMC, various anions with different soft/hard character (aliphatic and aromatic amines, alcohoxydes, phenoxides, thiolates) were compared with regard to nucleophilic substitutions on DMC, using different reaction conditions. Results were in good agreement with the hard-soft acid-base (HSAB) theory. Accordingly, the high selectivity of monomethylation of CH2 acidic compounds and primary aromatic amines with DMC can be explained by two different subsequent reactions, which are due to the double electrophilic character of DMC. The first... [Pg.90]

Only a small amount of work has been done in this area, compared to the vast amount done for aliphatic nucleophilic substitution and aromatic electrophilic substitution. Only a few conclusions, most of them sketchy or tentative, can be drawn.35... [Pg.578]

The Paal-Knorr method can be applied to the synthesis of a variety of 1-substituted pyrroles using commercially available 2,5-dialkoxytetrahydrofurans as a butane-1,4-dial equivalent. When an appropriate tetrahydrofuran derivative is available, the reaction can be used for more highly substituted pyrroles. Aliphatic and aromatic amines react readily and even weakly nucleophilic sulfonamides undergo cyclization (equation 66) (73SC303). [Pg.330]

The most common preparations of amines on insoluble supports include nucleophilic aliphatic and aromatic substitutions, Michael-type additions, and the reduction of imines, amides, nitro groups, and azides (Figure 10.1). Further methods include the addition of carbon nucleophiles to imines (e.g. the Mannich reaction) and oxidative degradation of carboxylic acids or amides. Linkers for primary, secondary, and tertiary amines are discussed in Sections 3.6, 3.7, and 3.8. [Pg.263]

Non-activated aryl bromides (but not fluorides) can be used as substrates for palla-dium(0)-catalyzed aromatic nucleophilic substitutions with aliphatic or aromatic amines. These reactions require sodium alcoholates or cesium carbonate as a base, and sterically demanding phosphines as ligands. Moreover, high reaction temperatures are often necessary to achieve complete conversion (Entries 7 and 8, Table 10.4 Experimental Procedure 10.1). Unfortunately, the choice of substituents on the amine... [Pg.270]

It has been proposed for aliphatic and aromatic halides that the photochemical initiation involves a charge-transfer complex (etc) between the nucleophile and the substrate in which the substitution takes place, and that it is photochemically energized so that complete transfer of one electron occurs (equation 11)6,9,30. [Pg.1398]


See other pages where Nucleophilic substitution aliphatic and aromatic is mentioned: [Pg.271]    [Pg.362]    [Pg.526]    [Pg.271]    [Pg.362]    [Pg.526]    [Pg.205]    [Pg.154]    [Pg.157]    [Pg.202]    [Pg.163]    [Pg.768]    [Pg.860]    [Pg.152]    [Pg.481]    [Pg.158]    [Pg.68]    [Pg.192]    [Pg.250]    [Pg.43]    [Pg.28]    [Pg.791]    [Pg.652]    [Pg.107]    [Pg.348]    [Pg.241]    [Pg.270]    [Pg.272]    [Pg.415]    [Pg.56]    [Pg.60]    [Pg.202]    [Pg.417]   


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Aliphatic and aromatic

Aliphatic—aromatic

And nucleophilic aromatic substitution

And nucleophilic substitution

Aromatic nucleophiles

Aromatic substitution nucleophilic

Nucleophile aromatic substitution

Nucleophilic aliphatic

Nucleophilic aromatic

Nucleophilic aromatic substitution nucleophiles

Substitution nucleophilic aliphatic

Substitution, aromatic, and

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