Aldehydes unmodified

Other Rhodium Processes. Unmodified rhodium catalysts, eg, 1 14(00)22 [19584-30-6] have high hydroformylation activity but low selectivity to normal aldehydes. 

The cationic polymerization of cardanol under acidic conditions has been referred to earlier [170,171], NMR studies [16] indicated a carbonium ion initiated mechanism for oligomerization. PCP was found to be highly reactive with aldehydes, amines, and isocyates. Highly insoluble and infusible thermoset products could be obtained. Hexamine-cured PCP showed much superior thermal stability (Fig. 12) at temperatures above 500°C to that of the unmodified cardanol-formaldehyde resins. However, it was definitely inferior to phenolic resins at all temperatures. The difference in thermal stability between phenolic and PCP resins could be understood from the presence of the libile hydrocarbon segment in PCP. 

After secretion from the cell, certain lysyl residues of tropoelastin are oxidatively deaminated to aldehydes by lysyl oxidase, the same enzyme involved in this process in collagen. However, the major cross-links formed in elastin are the desmosines, which result from the condensation of three of these lysine-derived aldehydes with an unmodified lysine to form a tetrafunctional cross-hnk unique to elastin. Once cross-linked in its mature, extracellular form, elastin is highly insoluble and extremely stable and has a very low turnover rate. Elastin exhibits a variety of random coil conformations that permit the protein to stretch and subsequently recoil during the performance of its physiologic functions. 

Organic-Base Catalyzed. Asymmetric direct aldol reactions have received considerable attention recently (Eq. 8.98).251 Direct asymmetric catalytic aldol reactions have been successfully performed using aldehydes and unmodified ketones together with chiral cyclic secondary amines as catalysts.252 L-proline and 5,5-dimethylthiazolidinium-4-carboxylate (DMTC) were found to be the most powerful amino acid catalysts for the reaction of both acyclic and cyclic ketones as aldol donors with aromatic and aliphatic aldehydes to afford the corresponding... 

Cobalt carbonyls are the oldest catalysts for hydroformylation and they have been used in industry for many years. They are used either as unmodified carbonyls, or modified with alkylphosphines (Shell process). For propene hydroformylation, they have been replaced by rhodium (Union Carbide, Mitsubishi, Ruhrchemie-Rhone Poulenc). For higher alkenes, cobalt is still the catalyst of choice. Internal alkenes can be used as the substrate as cobalt has a propensity for causing isomerization under a pressure of CO and high preference for the formation of linear aldehydes. Recently a new process was introduced for the hydroformylation of ethene oxide using a cobalt catalyst modified with a diphosphine. In the following we will focus on relevant complexes that have been identified and recently reported reactions of interest. 

The principal product of the hydroformylation which is most desired in industrial applications is a linear aldehyde. The unmodified, cobalt-catalyzed processes produce a mixture of linear and branched aldehydes, the latter being mostly an a-methyl isomer. For the largest single application—propylene to butyraldehydes—the product composition has an isomer ratio (ratio of percent linear to percent branched) of (2.5 t.0)/l. The isobutyraldehyde cannot be used to make 2-ethylhexanol, and iso-... 

As anticipated, 33 binds in the desired manner, capturing the thiol by the aldehyde group (Scheme 5). Unexpectedly, 33 binds with only a twofold improved affinity when compared to the parent dipeptide derivative containing the unmodified pTyr residue [137]. 

Direct asymmetric aldol reactions, that is between aldehydes and unmodified ketones has been accomplished using a lanthanum trilithium tri(binaphth-oxide) complex1 281. 

Y. M. A Yamada, N. Yoshikawa, H. Sasai, M. Shibasaki, Direct Catalytic Asymmetric Aldol Reactions of Aldehydes and Unmodified Ketones, Angew. Chem. Int. Ed EngL 1997, 36,1871-1873. 

This method can also be applied to silyl enol ethers of homologous unsaturated ketones as well as of unsaturated aldehydes or esters [85-87]. While unmodified unsaturated esters give only the corresponding aldehydes without cyclization under tandem hydroformylation/aldol reaction conditions, the corresponding silylated ester enolates smoothly cyclize in a tandem hy-droformylation/ Mukaiyama aldol reaction (Scheme 32) [85-87]. 

The TAR RNA target sequence, the 2 -amino RNA library and the appended aldehydes were subjected to the DCC SELEX system. The screen selected a 19-nt sequence with U-NH appended at position 9 and unmodified at positions 6 and 7 (Eig. 3.20). Importantly, it was shown that different sequences were identified when control selections were carried out in the absence of aldehydes, proving that the imino-conjugated nucleic acids are being selected. 

Trost s group reported direct catalytic enantioselective aldol reaction of unmodified ketones using dinuclear Zn complex 21 [Eq. (13.10)]. This reaction is noteworthy because products from linear aliphatic aldehydes were also obtained in reasonable chemical yields and enantioselectivity, in addition to secondary and tertiary alkyl-substituted aldehydes. Primary alkyl-substituted aldehydes are normally problematic substrates for direct aldol reaction because self-aldol condensation of the aldehydes complicates the reaction. Bifunctional Zn catalysis 22 was proposed, in which one Zn atom acts as a Lewis acid to activate an aldehyde and the other Zn-alkoxide acts as a Bronsted base to generate a Zn-enolate. The... 

The reversibility of the hydride migration in unmodified rhodium catalysts has been studied intensively by Lazzaroni et al. [56]. Reversible hydride migration will result in aldehydes containing deuterium at the a-carbon, whereas irreversible hydride migration will result in exclusive deuteration of the aldehyde and P-carbon. Mutual reversible alkene coordination and hydride migration ivill result in the formation of deuterated alkenes. Reversible formation of the branched rhodium alkyl will place deuterium at Cl and reversible formation of the linear alkyl complex will provide deuterium at C2 (Scheme 6.4). 

Of the isomeric aldehydes indicated in Eq. (7.1), the linear aldehyde corresponding to anti-Markovnikov addition is always the main product. The isomeric branched aldehyde may arise from an alternative alkene insertion step to produce the [RCH(Me)Co(CO)3] or [RCH(Me)Rh(CO)(PPh3)2] complexes, which are isomeric to 2 and 8, respectively. Alternatively, hydroformylation of isomerized internal alkenes also give branched aldehydes. The ratio of the linear and branched aldehydes, called linearity, may be affected by reaction conditions, and it strongly depends on the catalyst used. Unmodified cobalt and rhodium carbonyls yield about 3-5 1 mixtures of the normal and iso products. 

Aldol-type reactions comprise one of the most important classes of synthetic reactions. Although direct enantioselective condensation of aldehydes and unmodified ketones is not easy (280), it is highly desirable. A partly successful example is given in Scheme 115 (281). 

The hydroformylation of conjugated dienes with unmodified cobalt catalysts is slow, since the insertion reaction of the diene generates an tj3-cobalt complex by hydride addition at a terminal carbon (equation 10).5 The stable -cobalt complex does not undergo facile CO insertion. Low yields of a mixture of n- and iso-valeraldehyde are obtained. The use of phosphine-modified rhodium catalysts gives a complex mixture of Cs monoaldehydes (58%) and C6 dialdehydes (42%). A mixture of mono- and di-aldehydes are also obtained from 1,3- and 1,4-cyclohexadienes with a modified rhodium catalyst (equation ll).29 The 3-cyclohexenecarbaldehyde, an intermediate in the hydrocarbonylation of both 1,3- and 1,4-cyclo-hexadiene, is converted in 73% yield, to the same mixture of dialdehydes (cis.trans = 35 65) as is produced from either diene. 

Small peptides - simple di- and tri-peptides with a primary amine at the N-terminus -catalyse the aqueous aldol between unmodified ketones and aldehydes with up to 86% ee.121 This is dramatically different from the corresponding amino acid-catalysed reaction, suggesting that peptide formation may have been significant in the evolution of asymmetric synthesis. Addition of a-cyclodextrin raised the ee further through the hydrophobic effect. 

The catalytic application of L-proline in the asymmetric Michael addition of unmodified aldehydes or ketones with nitroalkenes in ionic liquids has been studied. The ... 

Hydrogenation of a, p- unsaturated aldehydes Oxidation Catalysis Pt/Al203 (unmodified)... 

Other direct asymmetric Mannich reactions that use preformed imines and unmodified ketones, aldehydes, malonates, and /i-kctocstcrs have been described by the groups of Shibasaki [12], Trost [13], Barbas [11, 14], and Jorgensen [15]. As two-component reactions, these processes are not included here but have been reviewed elsewhere [16]. 

Extension of this reaction toward a one-pot asymmetric Mannich-hydrocyanation reaction sequence was also reported by the Barbas group [29]. In this one-pot two-step process proline-catalyzed asymmetric Mannich reaction of unmodified aldehydes with the a-imino glyoxylate was performed first, then diastereoselective in situ cyanation. The resulting /i-cyanohydroxymethyl a-amino acids were obtained with high enantioselectivity (93-99% ee) [29]. Another one-pot two-step reaction developed by Barbas et al. is the Mannich-allylation reaction in which the proline-catalyzed Mannich reaction is combined with an indium-promoted allylation [30], This one-pot synthesis was conducted in aqueous media and is the first example of a direct organocatalytic Mannich reaction in aqueous media [28, 30]. 

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