Maruoka catalysts

Yamamoto et al. have also reported an asymmetric catalytic ene reaction, which employs chloral as the enophile using the 3,3 -bissilylated BINOL aluminum catalyst Maruoka, K., Hoshino, Y, Shirasaka, T, Yamamoto, H. Annual Meeting of the Chemical Society of Japan, Tokyo, April 1-4, 1988 Abstract No. 1X1IB27 Maruoka, K., Hoshino, Y., Shirasaka, T., Yamamoto, H. (1988) Tetrahedron Lett. 29, 3967-3970. 

In the following example, although the synthesis of the azoniaspirocycle does not involve an acyclic compound, the reaction itself is very similar to those described in this section, hence its inclusion here (Equation 34). Maruoka and co-workers have designed a C2-symmetric chiral quarternary ammonium salt, which is then employed as a phase-transfer catalyst in an enantioselective alkylation <1999JA6519, 2001JFC(112)95, 2004TA1243>. 

More recently, Maruoka and co-workers have reported several new phase-transfer catalysts one of which incorporates a morpholine ring as part of an azoniaspirocyclic core 161 <2007TL4675>. These were employed in the catalytic enantioselective conjugate addition of a-benzylcyanoacetate to acetylenic methyl ketone under phase transfer conditions. 

T. Ooi, M Kameda, K Maruoka, Molecular Design of a C2-Symmetric Chiral Phase-Transfer Catalyst for Practical Asymmetric Synthesis of a-Amino Acids , J. Am Chem Soc, 1999,121, 6519-6520. 

Aldol and Related Condensations As an elegant extension of the PTC-alkylation reaction, quaternary ammonium catalysts have been efficiently utilized in asymmetric aldol (Scheme 11.17a)" and nitroaldol reactions (Scheme ll.lTb) for the constmction of optically active p-hydroxy-a-amino acids. In most cases, Mukaiyama-aldol-type reactions were performed, in which the coupling of sUyl enol ethers with aldehydes was catalyzed by chiral ammonium fluoride salts, thus avoiding the need of additional bases, and allowing the reaction to be performed under homogeneous conditions. " It is important to note that salts derived from cinchona alkaloids provided preferentially iyw-diastereomers, while Maruoka s catalysts afforded awh-diastereomers. 

A chiral dinuclear Ti(IV) oxide 20 has been successfully designed by Maruoka and coworkers and can be used for the strong activation of aldehydes, thereby allowing a new catalytic enantioselective allylation of aldehydes with allyltributyltin (Scheme 12.18). ° The chiral catalyst 20 can be readily prepared either by treatment of bis(triisopropoxy)titanium oxide [(/-Pr0)3Ti-0-Ti(0/-Pr)3] with (S)-BINOL or by the reaction of ((5)-binaphthoxy)isopropoxytitanium chloride with silver(I) oxide. The reaction of 3-phenylpropanal with allyltributyltin (1.1 equiv) under the influence of 20 (10 mol%) gives l-phenyl-5-hexen-3-ol... 

Maruoka has found that simple alcohols can also be used in the oxy-Michael reaction [107], Using the axially chiral biaryl catalyst 67 (1 mol%) the conjugate addition of methanol, ethanol and aUyl alcohol to a, 3-unsaturated aldehydes was examined (Scheme 29). Despite moderate yields (55-83%) and enantioselectivities (16-53% ee), the high activity of this catalyst suggests that further optimisation... 

In 2007, Maruoka et al. introduced chiral dicarboxylic acids consisting of two carboxylic acid functionalities and an axially chiral binaphthyl moiety. They applied this new class of chiral Brpnsted acid catalyst to the asymmetric alkylation of diazo compounds withA-Boc imines [91]. The preparation of the dicarboxylic acid catalysts bearing aryl groups at the 3,3 -positions of the binaphthyl scaffold follows a synthetic route, which has been developed earlier in the Maruoka laboratory [92]. 

Maruoka reported the use of the didentate catalyst 8 for double electrophilic activation of carbonyl compounds [70], but since no comparison with monofunctional phenolates was given it is not clear whether having two aluminium centres in the same catalyst offers any special advantages. They used this catalyst to effect transfer hydrogenation between remote aldehyde and alcohol groups in the same molecule [71], but again it is not clear whether the transfer is truly intramolecular or in any way different from that of reduction by an external alcohol using 8 or a monuclear aluminium catalyst. 

Enantioselective aldol reactions also can be used to create arrays of stereogenic centers. Two elegant ot-amino anion approaches have recently been published. Fujie Tanaka and Carlos F. Barbas III of the Scripps Institute, La Jolla, have shown (Org. Lett. 2004,6,3541) that L-proline catalyzes the addition of the aldehyde 6 to other aldehydes with high enantio- and diastereocontroJ. Keiji Maruoka of Kyoto University has developed (J. Am. Chem. Soc. 2004,126,9685) a chiral phase transfer catalyst that mediates the addition of the ester 9 to aldehydes, again with high enantio- and diastcrcocontrol. 

Maruoka s group also developed the extremely active aluminium compound 68,38 which in a proportion as low as 1 mol% is able to promote the oxidation of alcohols with pivalaldehyde or acetone at room temperature. Oppenauer oxidations employing catalyst 68 succeed in a variety of secondary and primary alcohols, providing yields of aldehydes and ketones above 80% in a consistent way. Only lineal primary aliphatic alcohols fail to be cleanly oxidized to the corresponding aldehydes. 

In 1999, in consideration of the readily structural modifications and fine-tuning of catalysts to attain sufficient reactivity and selectivity, Maruoka and coworkers designed and prepared the structurally rigid, chiral spiro ammonium salts of type 1 derived from commercially available (S)- or (R)-1,1 -bi-2-naphthol as a new C2-symmetric chiral phase-transfer catalyst, and successfully applied this to the highly efficient, catalytic enantioselective alkylation of N-(diphenylmethylene)glycine tert-butyl ester under mild phase-transfer conditions (Scheme 5.1) [7]. 

Although the conformationally rigid, N-spiro structure created by two chiral binaphthyl subunits represents a characteristic feature of 1 and related catalyst 9, Maruoka and coworkers have generally used their (S,S)- and (R,R)-isomers. Surprisingly, however, when the diastereomeric (R,S)-lc was used for asymmetric benzyla-tion of 2, the reaction was found to proceed very slowly, such that even after 60 h the... 

On the other hand, Maruoka and coworkers were intrigued with the preparation of symmetrical N-spiro-type catalysts to avoid the independent synthesis of two different binaphthyl-modified subunits required for 1. Along this line, 4,4, 6,6 -tetra-arylbinaphthyl-substituted ammonium bromide (S, S)-13 was assembled through the reaction of aqueous ammonia with bis-bromide (S)-14 on the basis of previous studies on the substituent effect of this type of salt. The evaluation of (S,S)-13 as a chiral phase-transfer catalyst in the alkylation of 2 uncovered its high catalytic and chiral efficiency (Scheme 5.9) [9]. 

The Maruoka group s further efforts toward simplification of the catalyst have led to the design of new, polyamine-based chiral phase-transfer catalysts of type 15, with expectation of the multiplier effect of chiral auxiliaries, as illustrated in Scheme 5.10 [13]. The chiral efficiency of such polyamine-based chiral phase-transfer catalysts (S)-15 was examined by carrying out an asymmetric alkylation of glycine derivative 2 under phase-transfer conditions. Among various commercially available polyamines, spermidine- and spermine-based polyammonium salts were found to show moderate enantioselectivity. In particular, the introduction of a 3,4,5-trifluor-ophenyl group at the 3,3 -positions of chiral binaphthyl moieties showed excellent asymmetric induction. 

Recently, Maruoka and coworkers have expressed interest in the development of C2-symmetric phase-transfer catalysts which consist of two chiral biphenyl units, as a new, easily modifiable subunit for further elaboration. To this end, chiral phase-... 

Upon facing the difficulty of stereochemical control in peptide alkylation events, Maruoka and coworkers envisaged that the chiral phase-transfer catalyst should play a crucial role in achieving an efficient chirality transfer, and consequently examined the alkylation of the dipeptide, Gly-L-Phe derivative 57 (Scheme 5.28) [31]. When a mixture of 57 and tetrabutylammonium bromide (TBAB, 2 mol%) in toluene was treated with a 50% KOH aqueous solution and benzyl bromide at 0°C for 4h, the corresponding benzylation product 58 was obtained in 85% yield with the diastereo-meric ratio (DL-58 LL-58) of 54 46 (8% de). In contrast, the reaction with chiral quaternary ammonium bromide (S,S)-lc under similar conditions gave rise to 58 with 55% de. The preferential formation of LL-58 in lower de in the reaction with (R,R)-lc indicated that (R,R)-lc is a mismatched catalyst for this diastereofacial differentiation of 57. Changing the 3,3 -aromatic substituent (Ar) of the catalyst 1 dramatically increased the stereoselectivity, and almost complete diastereocontrol was realized with (S,S)-lg. 

Access to enantioenriched carbonyl compounds of high value which possess quaternary a-carbon stereocenters containing hetero-functionalities represents one of the most challenging tasks in phase-transfer-catalyzed asymmetric alkylation. In due course, Maruoka and coworkers devised the asymmetric alkylation of cyclic a-amino-P-keto esters 67 with C2-symmetric phase-transfer catalyst lh as a means of obtaining aza-cyclic amino acids with quaternary stereocenters (Scheme 5.32) [33]. 

Recently, Maruoka and coworkers addressed the importance of dual-functioning chiral phase-transfer catalysts such as 70a for obtaining a high level of enantio-selectivity in the Michael addition of malonates to chalcone derivatives (Scheme 5.35) [37]. For instance, the reaction of diethyl malonate with chalcone in... 

As an extension of this research, Maruoka and coworkers succeeded in the catalytic asymmetric conjugate addition of nitroalkanes to cyclic a,[S-unsaturated ketones under phase-transfer conditions (Scheme 5.40) [39]. Here, the use of 3,5-bis(3,4,5-trifluorophenyl)phenyl-substituted catalyst (S,S)-lj is crucial for obtaining the high enantioselectivity. 

Asymmetric conjugate addition of a-substituted-oc-cyanoacetates 77 to acetylenic esters under phase-transfer conditions is somewhat of a challenge, because of the difficulty encountered in controlling the stereochemistry of the product. In addition, despite numerous examples of the conjugate additions to alkenoic esters, no successful asymmetric conjugate additions to acetylenic esters have been reported to date. In this context, Maruoka and coworkers recently developed a new morpholine-derived phase-transfer catalyst (S)-76 and applied it to the asymmetric conjugate additions of a-alkyl-a-cyanoacetates 77 to acetylenic esters, as indicated in Table 5.11 [40], In this asymmetric transformation, an all-carbon quaternary stereocenter can be constructed with a high enantiomeric purity. 

Maruoka and coworkers recently developed an efficient, highly diastereo- and enantioselective direct aldol reaction of glycine Schiff base 2 with a wide range of aliphatic aldehydes under mild phase-transfer conditions employing N-spiro chiral quaternary ammonium salt li as a key catalyst, as shown in Table 5.12 [41a]. 

Maruoka and coworkers designed a new and highly efficient chiral N-spiro-type quaternary ammonium salt (S)-70 with dual functions for the asymmetric epoxidation of various enone substrates (Scheme 5.44) [45]. The exceedingly high asymmetric induction is ascribable to the molecular recognition ability of the catalyst toward enone substrates by virtue of the appropriately aligned hydroxy functionality, as well as the chiral molecular cavity. Indeed, the observed enantioselectivity depends heavily... 

Currently, the chiral phase-transfer catalyst category remains dominated by cinchona alkaloid-derived quaternary ammonium salts that provide impressive enantioselec-tivity for a range of asymmetric reactions (see Chapter 1 to 4). In addition, Maruoka s binaphthyl-derived spiro ammonium salt provides the best results for a variety of asymmetric reactions (see Chapters 5 and 6). Recently, some other quaternary ammonium salts, including Shibasaki s two-center catalyst, have demonstrated promising results in asymmetric syntheses (see Chapter 6), while chiral crown ethers and other organocatalysts, including TADDOL or NOBIN, have also found important places within the chiral phase-transfer catalyst list (see Chapter 8). 

A new class of suitable optically active organocatalyst for enantioselective alkylations has recently been developed by Maruoka and co-workers [le, 33-37]. This catalyst is not based on an alkaloid-related quaternary ammonium salt but consists of a C2 -symmetric compound of type 29 (or derivatives thereof bearing other types of substituent on the 3,3 positions of the binaphthyl unit) [33, 34], In the presence... 

Maruoka and co-workers developed an elegant solution by creating phase-transfer-catalysts of type 30 [36], For example, the C2-symmetric N-spiro organocatalyst (S,S)-30, which contains a conformationally flexible biphenyl subunit, efficiently catalyzed the alkylation of glycinate 18 with benzyl bromide, with formation of the product (R)-20b in 95% yield and with 92% ee (Scheme 3.10) [36],... 

Very recently, Maruoka and co-workers described a new N-spiro quaternary ammonium bromide with two chiral biphenyl structures as easily modifiable subunits [37]. These phase-transfer catalysts with biphenyl subunits, containing methyl groups in the 6,6 -position for inducing chirality, and additionally bulky substituents in the 4-position, efficiently catalyzed the alkylation of protected glycinate with high enantioselectivity of up to 97% ee. The substrate range is broad, for example (substituted) benzyl bromide and allylic and propargylic bromides are tolerated [37]. 

The Maruoka group have reported further application of N-spiro phase-transfer catalysts of type 29 to the diastereoselective a-alkylation of N-terminal di-, tri-, and tetrapeptides [52]. The reactions proceed with high diastereoselectivity, furnishing a diastereomeric ratio (d.r.) of up to 99 1 for the resulting dipeptide products. 

The Maruoka group recently reported an alternative concept based on a one-pot double alkylation of the aldimine of glycine butyl ester, 44a, in the presence of the chiral ammonium salt 29 as chiral phase-transfer catalyst (the principal concept of this reaction is illustrated in Scheme 3.18, route 2) [58], Under optimized reaction conditions products of type 43 were obtained in yields of up to 80% and with high enantioselectivity (up to 98% ee). A selected example is shown in Scheme 3.20. 

The best selectivity in the Michael addition of 2-carboxycyclopentanones to an enone or enal were recently achieved by Maruoka et al. [9]. As shown in Scheme 4.5, as little as 2 mol% of the binaphthyl-derived phase-transfer catalyst 10 - in the presence of 10 mol% solid potassium carbonate - enabled the highly efficient... 

In the field of asymmetric organocatalytic alkylation (see also Section 3.1) impressive examples with enantioselectivity > 99% ee have been reported by the Corey group, the Park and Jew group, and the Maruoka group [15-17]. Different types of catalyst have been used, with amounts of catalyst in the range 0.2 to 10 mol%. High enantioselectivity (99%) has also been achieved for asymmetric halogenation reactions (see also Section 3.4). This has been demonstrated for chlorination and bromination reactions by Lectka and co-workers [18]. 

Not surprisingly, B(C6F5)3 is an effective catalyst for allylation of carbonyl functions. In a provocative 7. Am. Chem. Soc. communication, Maruoka and co-workers reported the chemoselective allylstannation of oTt/io-anisaldehyde in the presence of para-anisaldehyde as mediated by B(C6F5)3 (Scheme 36).263 By way of rationale, they proposed that the ortho substituted substrate is selectively activated by the LA through chelation at boron this explanation was also used to explain the high diastereoselectivity observed for X = O in the hydrostannation of PhC(0)CH(CH3)XCH3 but not for X = CH2. 

Birman has also shown that trans-cinnamyl type allylic sec-alcohols can be efficiently resolved using his CF3-PIP catalyst 25 (s = 6-26) or Cl-PIQ catalyst 26 (s = 17-57 see Scheme 8.5) [107]. Additionally, as noted earlier, Maruoka s NHC catalyst 29b was shown to resolve two trans-cinnamyl-type allylic sec-alcohols efficiently (s = 16 and 22 see Scheme 8.8). 

Recently, Maruoka described the novel dual function catalyst 26 bearing hydroxyl groups which were incorporated to allow hydrogen bonding to the enolate intermediate. Indeed, 26 was found to catalyze enone epoxidation with 89-99% tt [67]. Interestingly - and unlike some other systems - alkyl substitution is tolerated (Scheme 12.14). 

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