Amide, phosphine derived

Figure 17.18 The Staudinger ligation reaction uses a modified phosphine derivative containing an electrophilic group that acts as a trap for the nucleophilic nitrogen in the intermediate aza-ylide. The resultant shift yields an amide bond derivative between the phosphine-containing molecule and the azide-containing molecule.

Figure 17.22 Certain unique phosphine derivatives can be used in the design of modification or conjugation reagents to create a traceless Staudinger ligation process, wherein the phosphine group is lost and an amide bond between an azide-containing molecule and the phosphine-containing molecule results.

Figure 18.11 NHS-PEG4-azide can be used to modify an amine-containing molecule to create an amide derivative terminating in azido groups. The azide modifications then can be used in a click chemistry reaction that forms a triazole linkage with an alkyne-containing molecule. Alternatively, the azide derivative can be used in a Staudinger ligation reaction with a phosphine derivative, which results in an amide bond linkage.

Other selected reactions of (Re)+ derivatives include the deprotonation of S-bound DMSO, S(CH2R)2 (R = sp or sp C) complexes at the Ca atom that are followed by stereospecific rearrangements the deprotonation/reprotonation of [(Re)-()]2-CH2=CHR)]+ to give [(Re)(=CHCH2R)]+ deprotonation of amine and phosphine derivatives [(Re)(EHR2)] " to the amides and phosphides [(Re)(ER2)] epimerization of secondary alcohols catalyzed by [(Re)-(OMe)] unprecedented transformation of N-bound pyrrolyl to C-bound pyrrolyl species. 

Reactions between diethyl hydrogenphosphonate and ArX (X = I or Br) to give diethyl arylphosphonates have been carried out in the presence of a phase transfer catalyst. Bis(trimethylsilyl) phenylphosphonite reacts with alkyl halides to give [(ar)alkylphenyl]phosphinic derivatives, and it also adds to a,P-unsaturated carboxylic esters (as well as to nitriles and amides) to give (2-functionalized-l-alkyl)phosphinic derivatives. ... 

The first bisphosphine calixarenes that have been used in catalysis are di(amide)-phosphine hybrids calix[4]ar-ene. Reaction of [RhCl(norbornadiene)]2 with these calixarene derivatives gave an organometallic complex whose norbornadiene-rhodium moiety lies above the cavity defined by the four substituents of the calixarene and between the two amide functionalities. This complex was applied in the hydroformylation reaction of styrene. The rather low reaction rate observed (7.5 turnovers per Rh per hour) has been attributed to a partial encapsulation of the metal center preventing the approach of the substrate. Indeed, the metal center may be viewed as located in a hemispherical ligand environment. 

Like phosphonous and phosphinous derivatives (Chapter 4.1), phosphoramidites and phosphoro-diamidites exist in equilibrium with phosphonamidates and phosphinic amides, respectively. 

Squaric acid forms salts with aluminium, gallium, and indium. Amidation of squaric acid gives not only the 1,3- but also, the 1,2-diamides, which can be further acylated on the nitrogen. The amides, esters, and chlorides can be transformed into thiosquarates by the action of HS and cyclobutene dications can be obtained from the l,2-dithio-3,4-diamide. Neuse and Green have examined further arylation reactions of squaryl chlorides from which a variety of substituted cyclo-butenones may be obtained. Phosphine derivatives of the squarate system have also been reported. ... 

In the course of this study, the authors determined /Lvalues for dibenzyl, methyl phenyl, methyl p-nitrophenyl, di-p-tolyl, di-isopropyl and tetramethylene sulphoxides and for diethyl, dipropyl and dibutyl sulphites. The /Lscales are applied to the various reactions or the spectral measurements. The /Lscales have been divided into either family-dependent (FD) types, which means two or more compounds can share the same /Lscale, family-independent (FI) types. Consequently, a variety of /Lscales are now available for various families of the bases, including 29 aldehydes and ketones, 17 carboxylic amides and ureas, 14 carboxylic acids esters, 4 acyl halides, 5 nitriles, 10 ethers, 16 phosphine oxides, 12 sulphinyl compounds, 15 pyridines and pyrimidines, 16 sp3 hybridized amines and 10 alcohols. The enthalpies of formation of the hydrogen bond of 4-fluorophenol with both sulphoxides and phosphine oxides and related derivatives fit the empirical equation 18, where the standard deviation is y = 0.983. Several averaged scales are shown in Table 1588. 

Tervalent organophosphorus compounds containing one single P-N bond with the valency of each atom saturated by protons or carbons (but no other heteroatoms) have been known since their discovery by MichaeUs more than one century ago [ 1 ] and named indistinctly as aminophosphanes, phosphanamines, phosphazanes, or phosphinous amides. This last chemical nomenclature is the one used by the Chemical Abstracts Service (CAS) for indexing these compounds and is also the one that best delimits the scope of this review those species derived from the parent H2P-NH2 (phosphinous amide in CAS nomenclature) by partial or total substitution of protons by hydrocarbon radicals (Table 1). 

Also covered by this review are those compounds bearing two or three phosphane units at the same N atom, that is those derived from (H2P)2NH (N-phosphino phosphinous amide in CAS nomenclature) and from (H2P)3N, NJsl-bis(phosphino) phosphinous amide, but not those bearing more than one amino... 

These phosphinous amide anions are presumably responsible for the formation of the by-products AT-phosphino phosphinous amides 11 and mono-phosphazenes derived from diphosphanes 12 in the sequential treatment of primary amines with n-BuLi and chlorophosphanes for preparing NH phosphinous amides [75,88] (Scheme 14). Compounds 11 and 12 are presumably derived from anions 9 and 10, respectively, generated by deprotonation of the newly formed phosphinous amide with the lithiated amine R NHLi. In solution, 9 can establish a metallotropic equilibrium with 10. 

A number of NH phosphinous amides have been P-alkylated by previous conversion to their corresponding anions [59,74]. A particular case of double alkylation takes place with the anion derived from the AT-phosphino phosphinous amide NH(PPh2)2 yielding the diphosphonium salt 17 [102] (Scheme 17). When neutral, its methylation is reported to give the P-H phosphazene-phos-phonium salt 18 [103]. 

Occasionally, attempts at introducing a new PR2 group on the nitrogen atom of an NH phosphinous amide, with the aim of preparing Ar,AT-bis(phosphino) phosphinous amides, result in the generation of monophosphazenes derived from diphosphanes, as seen in the preparation of 20 which occurs by P-P bond formation [74] (Scheme 20). The authors of this work claimed that the electron-... 

The stable P-unsubstituted phosphinous amide H2PN(SiMe3)2 has been shown to suffer the nucleophilic displacement of the disilazane moiety by the action of thiols R-SH giving the phosphinous thioesters R-S-PH2 [13]. For the sake of brevity we shall not comment on other relevant reactions of AT-silyl phosphinous amides, such as the anionic P-silylation [115] and P-alkylation [22], the consecutive dialkylation of PH derivatives [18] and the fluorodesily-lation of P-fluoro-JV-silyl derivatives [140]. 

In recent years, the catalytic asymmetric hydrogenation of a-acylamino acrylic or cinnamic acid derivatives has been widely investigated as a method for preparing chiral a-amino acids, and considerable efforts have been devoted for developing new chiral ligands and complexes to this end. In this context, simple chiral phosphinous amides as well as chiral bis(aminophosphanes) have found notorious applications as ligands in Rh(I) complexes, which have been used in the asymmetric hydrogenation of a-acylamino acrylic acid derivatives (Scheme 43). 

The design and the rich chemistry of phosphinous amides are described in Chap. 3 by M. Alajarin, C Lopez-Leonardo, and P. Llamas-Lorente. Important applications of these derivatives as metals ligands in the area of catalysis are also emphasized. 

Phosphides and amides are closely related, as a synthetic route is based on metathesis of metal amides, especially the respective trimethylsilyl amides, with the appropriate free acidic phosphine or an anion derived therefrom. Reaction of metal halides and trisilylphosphines is an alternative for preparing metal phosphides. 

Diboratacarbazole heterocycles 137 are obtained in 60% isolated yield by heating the phosphine-stabilized 2,2 -diborabiphenyl derivative 138 with primary amines in toluene for 20h (Scheme 55). Further double deprotonation of the heterocycle 137 (Ar = Ph) with a lithium amide leads to the dianionic 9,11-diboratacarbazole derivative 139 (98%, S nB 31.71 ppm). Structures 137 (Ar = Ph) and 139 were characterized by X-ray crystallography <20040M3085>. 

Figure 17.19 An azido-sialic acid derivative that gets incorporated into glycans in cells can be labeled specifically with a biotin-phosphine tag using the Staudinger ligation process. The result is an amide bond linkage with the glycan.

The phosphanes useful in this process are built from acyl derivatives of compounds such as those shown in Figure 17.22. During the Staudinger ligation process, once the azide reactant forms the aza-ylide with the phosphine, electrophilic attraction induces the nitrogen to attack the electron deficient carbonyl, which in turn causes release of the phosphonium group and forms the amide bond (Figure 17.23). 

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