Synthesis of Weinreb and their Derivatives (A Review)
Maher Khalid*, Shireen Mohammed and Amin Kalo
Department of Chemistry, Faculty of Science, Zakho University, Duhok street, 42002 Kurdistan – Region,Iraq.
Corresponding Author E-mail: maher-333@hotmail.de
DOI : http://dx.doi.org/10.13005/ojc/360201
Article Received on : 22 Feb 2020
Article Accepted on : 22 Apr 2020
Article Published : 29 Apr 2020
Due to the largely and an efficient usage of Weinreb amides or N-methoxy-N-methylamides as are remarkable intermediate in the organic synthesis field, the recent review paper provides a considerable development literature survey on the Weinreb amides synthesis. The direct transformation of carboxylic acids,acid chlorides, and esters to aldehydes or ketones employing organometallic reagents do not lead in high yields, since the high reactivity of ketone intermediates toward the organometallic reagents. While, the conversion to the appropriate Weinreb Amides, followed by treatment with the organometallic regent, result the stable expected ketones as the stable initial adduct toward further reactions. Furthermore, Weinreb amides undergo nucleophilic addition and produce a unique and steady five-membered cyclic intermediate which protects the over-addition, leading to a serious transformation.
Grapic Abstract
KEYWORDS:Organometallic Reagents; Weinreb Amides; Weinreb Benzamide; β-Trifiuoromethylated Enaminones; α-Amino Aldehydes.
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Introduction
N-methoxy-N-methylamides or Weinreb amides become a worthy synthetic precursor in organic synthesis1.The first synthesis of Weinreb moiety was reported in 19812which performed via treatment of N,O-dimethyl hydroxylamine with AlMe3 as a coupling reagent. Thereafter, several methods for Weinreb amide synthesis have been reported, like direct transformation of carboxyl group into the corresponding aldehyde or ketone. Exceptionally, the efficiency of Weinreb structure to subject a unique substitution reaction with excess of organometallic reagents in the laboratory and industrial synthesis processes 3.Weinreb structure reacts closely with organolithium4, Grignard reagents5, LiAlH46and Wittig reagents to produce aldehydes orketones7. Currently, much effort has been devoted to develop their soft and universal synthesis. Such, Weinreb amides can be synthesized from carboxylic acids8, acid chlorides9, amides10, esters11, lactones12, and anhydrides13.Due to the fast evolution of Weinreb amides synthesis and their applications in the last twenty years, it was interesting to review commonalty issue papers in the duration from 2001 to 2009 and detail several neoteric developments of these strategy processes.
In 2001, Giacomelli and co-workers14, described a flexible process for the synthesis of hydroxamates, Weinreb amides4 and hydroxamic acids (Scheme 1). The procedure is used coupling agents like triazine derivatives, carboxylic acids and N-protected amino acids as reactants for preparation of N-methoxy-N-methyl amides (Weinreb amides). However, the organic compound like hydroxamic acids can be formed from the transformation of hydroxamates and Weinreb amides as O-benzyl and O-silyl hydroxamates. In addition, handling of reactant for example carboxylic acid 1 with 2-chloro-4,6-dimethoxy-triazine (CDMT) 2 and N-methylmorpholine (NMM) in THF. Subsequently, treatment with N,O-dimethylhydroxylamine 3, yields the desired N-methoxy-N-methylamide products 4(Weinreb amide and O-benzyl- or tert-butyldiphenylsilyl hydroxylamine for hydroxamates).
Scheme 1: Synthesis of Weinreb amides4 and hydroxamic acids Click here to View Scheme |
While, Fehrentz and co-workers 15 detailed a facile synthesis of lipopeptides via using Weinreb (N-methoxy,N-methyl) amide as an aldehyde function precursor on the side chains of Asp or Glu residues(Scheme 2). The reducing of amide 5 by LiAlH4 produce the reactive aldehyde function 6. Subsequently, the latter can undergo reaction with yilde 7to form unsaturated or saturated side8 chains or with various nucleophiles to yield non-coded amino acid residues incorporated into the sequence. Lastly, racemization by enol formation cannot take place when aldehyde function is formed in position of γ or δ. This condition is not like form of α-amino aldehydes.
Scheme 2 |
In parallel, Jeong group16 reported a novel approach to the synthesis of β-trifluoromethyl enaminones with good yields (Scheme 3). Here, the protocol focused on the treatment of N-methoxy-N-methylbenzamide10 (1.0 eq.) with trifluoropropynyl9 (4.0 eq.)at -78°C with cooling of water and warming to 0°C, followed by quenching with H2O in the presence of a variety of amines 11. Furthermore, using of hydrazine or benzamidine as an amine source in this reaction, afforded the expected pyrazole or pyrimidine products.
Scheme 3 |
Furthermore, Lete and co-workers17revealed the efficient role of N-(O-iodobenzyl)-pyrrole-2-carboxyamides as internal electrophiles induced proximity effect (CIPE)in Parham-type cyclization reactions, allowing the efficient construction of the indolizinone nucleus(Scheme 4).So, Li-iodine exchange 14i could be selected firstly due to the coordination between organolithium and amide group and secondly the stabilization of the aryllithium moiety. Under reaction condition, Weinreb amides 13have also been successful applied as internal electrophiles in cyclization reactions of organo-lithiums educed from alkyliodides and accessing cyclic ketones 14. Furthermore, this cyclization process, delivered the effective build of the fused pyrrolo[1,2-b]isoquinolines, thieno-[2,3-f]indolizinones, and pyrrolo[1,2-b]acridinones in high yields. This protocol has also been widespread to heteroaryllithums, allowing a flexible direction to heterocyclic frameworks with prospective pharmacological features that could compete with previously reported strategies.
Scheme 4 |
Independently, Lee and co-worker18 illustrated the synthesis of various enantiomericallypure 2-acylaziridinederivatives(Scheme 5). Generally, this method started firstly through reaction between N,O-dimethylhydroxylamine hydrochloride 16 and readily available N-[(R)-(+)-α-methylbenzyl]-2(S)-aziridinecarboxylic acid menthol ester 15 using AlMe3as a coupling reagent in DCM affords the Weinreb’s amide 17 in excellent yields. Furthermore, the latter was then reacted with different organometallic reagents 18 to provide the expected ketone products 19 with higher yields. Applying this protocol, (1R,2S)-N-Boc-norephedrine, N-Boc-safingol, N-Boc-D-erythro-sphinganine, and N-Boc-spisulosine have been prepared in high yields.
Scheme 5 Click here to View Scheme |
In 2004, Fehrentz and co-workers19described the synthesis of α-amino aldehydes linked to the support by their amine function(Scheme 6). This method was completed by reduction with LiAlH4 of the corresponding Weinreb amide linked to the resin. The aldehydes procured were then implicated in Wittig or reductive amination processes. Moreover, the two-step methods, including the conversion of N-protected α-amino acids 21to the corresponding Weinreb amides 22then reduction by LiAlH4, is an effective process for the synthesis of N-protected α-amino aldehyde23.
Scheme 6 Click here to View Scheme |
Furthermore, kunishima and co-workers20illustrated the synthesis of Weinreb amides through the reaction of carboxylic acids with N,O-dimethylhydroxylamine hydrochloride in the presence of 4-(4,6-dimethoxy-1,3,5-triazin-2-yl)-4-methylmorpholinium chloride (DMT-MM) in different solvents such as alcohols and acetonitrile, that can dissolve DMT-MM(Scheme 7). In this context, the preparation of Weinreb amides was doneby converting carboxylic acids 24to the desired Weinreb amide products26in higher yields by easily combined with DMT-MM and N,O-dimethylhydroxylamine hydrochloride substrates25.
Scheme 7 Click here to View Scheme |
Later, Jeong and co-workers21declared amodern and efficient method for the synthesis of β-trifluoromethylated enone derivatives via reaction of Weinreb amides with trifluoropropynyl lithium, then treated with H2O in the mediation of amine derivatives (Scheme 8). Essentially, this method afforded stereo-selectively β-trifiuoromethylated enaminones with very good yields. The latter was reacted with satirically less hindered amine derivatives to produce amine products with high stereo specifically. In addition, the reaction mixture of N-methoxy-N-methylbenzamide 28(1 eq.) and trifluoropropynyl lithium 27(2 eq.) at -78 ᵒC then 0 ᵒC, followed by addition of H2O in the mediation of amine derivatives29, β-trifiuoromethylated enaminone products30 were resulted with perfect stereo-specifically.
Scheme 8 |
Moreover, Franck and co-workers22examined the cycloaddition of Weinreb amide bearing nitrile oxide/nitrones functional groups with a scope of dipolarophiles (Scheme 9).However, there are two synthetic route options for the synthesis of Weinreb amide nitrile oxide 39and nitrones41. Firstly, Weinreb amide nitrile oxide 39was prepared by reaction of trans-cinnamic acid 31in two procedures. Cinnamic acids33 is displayed to ozonolysis to give the expected compound separated as the mixture of aldehyde 33 and its hemiacetal, in methanol as a co-solvent for this process. This mixture of the expected products, anyway, was simplyisolated from benzaldehyde through flash chromatography. Handling of aldehyde34 with hydroxylamine hydrochloride 35gave with quantitative yield of the crude Weinreb amide-oxime 36. The latter38can be transformed to nitrile oxide39through the classical chlorination method in the presence ofNCS37thenelimination of HCl usesEt3N(Synthetic Option 1). Subsequently, the Weinreb amide-nitrone 41was prepared by reaction between Weinreb aldehyde 34andN-benzyl hydroxylamine hydrochloride40.The crude nitrone 41was directly used in the cycloaddition process without additional purification(Synthetic Option 2).
Scheme 9 |
While Dake and co-workers23 described an appropriate strategy for the transformation of bulky carboxylic acids 42to N-methoxy-N-methylamides45. Therefore, this transformation can be efficiently completed with of methanesulfonyl chloride43(1.1 eq.), triethylamine (3 eq.), and N-methoxy-N-methylamine44(1.1 eq.) (Scheme 10).The percentage yields for this process range were up to88%. Remarkable, removal of, N-methoxy-N-methylmethanesulfonamide as the major byproduct in such reactions, was done by set it under vacuum for overnight.Furthermore, this process was necessaryfor dissolving their individual synthetic problem, and could demonstrate valuable for other practitioners of organic chemistry.
Figure 10 Click here to View Scheme |
In 2005, Lee and co-workers24provided a novel preparation of N-methoxy-N-methylamides through the reaction ofS-2-Pyridyl Thiocarbamate with Grignard reagents (Scheme 11). The authors suggested to prepare N-methoxy-N-methylamides 50in the convenience of one step operation, and also can be recently made through the reaction of S-2-pyridyl Thiocarbamate 48with Grignard reagents 49under mild conditions. Subsequently, preparation of S-2-Pyridyl Thiocarbamate 48throughreaction ofN,O-dimethylhydroxylamine hydrochloride 47withS,S-di(2-pyridyl) dithiocarbonate 46 in the presence of triethylaminein DCM at 0 oC, However, the successful synthesis of N-methoxy-N-methylamides 50using S-2-PyridylThiocarbamate reliesbroadly on the selective of 2-thiopyridyl group in the substitution reaction.
Scheme 11 Click here to View Scheme |
Later, Davis and co-workers25reported innovative strategy for the preparation of N-Sulfinylβ-Amino carbonyl compounds (Scheme 12). Here, an inclusive methodology protocol has been submitted by the addition of the potassium enolate of N-methoxy-N-methylacetamide 52to sulfinimines 51or by handling N-sulfinyl β-amino esters 53with lithium N,O-dimethylhydroxyamine54,produce the related N-sulfinyl β-amino Weinreb amide products with high diastereo selectivity. This new method reveal as a common resolution to the problem of β-amino carbonyl compounds 57synthesis, via reaction with different organometallic compounds56which are significantly moieties and ingredients of natural products. Additionally, this methodology performed a universal solution to the matter of β-amino carbonyl syntheses, which are remarkable chiral frameworks and components of natural products.
Scheme 12 Click here to View Scheme |
Murphy and co-workers26demonstrated the direct transformation of Weinreb Amides(N-methoxy-N-methylamides) to the related ketones through unusual Wittig reaction (Scheme 13). Moreover, this reaction proceeds through treatment of N-methoxy-N-methylamides58 with alkylidenetriphenylphosphoranes 59,followed by one-pothydrolysis of the intermediate to produce the corresponding ketone products 60.Furthermore, this conversion takes place in a way which prevent the quite reactivity of organometallic reagents. Finally, the reaction conditions were considerably reasonable than the transformation route in the presence of organometallic reagents. In addition Its chemo selectivity is mostly observed in the pure conversions of cyano- or halo-substituted substrates.
Scheme 13 |
Moreover, Conrad and co-workers27, revealed An effective one-pot method for α-amino ketone 63synthesis through the arylation of Weinreb amides whereas retaining chirality of the main amide(Scheme 14). Actually, this reaction improved quietness when i-PrMgCl (2.5 eq.) was straightway added into the solution of Weinreb amide61 and 3,5-bis (trifluoromethylbromobenzene 62at 10 °C. The method, distinctly proves that the Knochel magnesiztions are kinetically going slower than deprotonating comparing to organolithium transmetallations.
Scheme 14 Click here to View Scheme |
In 2006, Pelkey and co-workers28have reported a functional synthetic path to 3,4-disubstituted pyrrole-2-carboxaldehydes and 3-pyrrolin-2-ones starting from Pyrrole Weinreb Amides (Scheme 15). Here, aregion-controlled preparation of 3,4-disubstituted pyrrole-2-carboxaldehydes was achieved over two main steps using acyclic substrates. (i) Barton-Zard pyrrole method through reaction betweenN-methoxy-N-methyl-2-isocyanoacetamide 66and β-nitroacetates64orα-nitroalkenes65, providing pyrrole Weinreb amides67; (ii) reduction reaction step of pyrrole-2-carboxaldehydes68; and (iii) the regioselective oxidation step of 3-pyrrolin-2-ones69. Remarkably, this method licensed to the preparation of non-syn metrical pyrrole-2-carboxaldehydes68 and 3-pyrrolin-2-ones 69with estimate to substituent’sexisting in the α-positions, and this could demonstrate helpful for the synthesis of oligopyrrole compounds.
Scheme 15 Click here to View Scheme |
In parallel John A. Murphy and co-workers29detailed the efficient transformation of Weinreb amides of formic acid to aldehyde products 72under Wittig reaction conditions (Scheme 16). Under the optimal reaction conditions, treatment of phosphorus on the Weinreb amide of formic acid 70with organometallics like organolithium or Grignard reagents69. The qualification of this method is imputed to the stability of tetrahedral intermediate, that does not undergo fragmentation to the expected aldehyde product 72until work-up.
Scheme 16 |
Furthermore, Buchwald and co-workers30developed the efficient protocol for the synthesis of Weinreb amides through Pd-catalyzed aminocarbonylation of aryl bromide substrates at atmospheric pressure(Scheme 17). The reaction is the transformation of aryl bromides 73to the corresponding Weinreb amide products76under 1 atm. of CO75 and catalytic conditions. A wide range of functional groups, including electron-deficient, -neutral, and -rich aryl bromides 72were tested and shown their effectiveness transformation to the desired products76.
Scheme 17 Click here to View Scheme |
Meanwhile, Collum and co-workers31described acylation mechanism of Weinreb amide with Lithium phenylacetylide (Scheme 18). The protocol here described the reaction of dimeric lithium acetylide via a mono solvated monomer-based transition structure. The sturdy tetrahedral intermediate stylesconsecutive a C1 2:2 mixed tetramer in the presence of excess lithium acetylide 78and a 1:3 (alkoxide-rich) mixed tetramer. The stabilization of the mixed tetramers iscompatible with a declared auto inhibition. In addition, the tetrahedral intermediate reacts with lithium phenylacetylide (PhCCLi) 78in the presence of Weinreb amide 77as a reagent to form ketone compound derivative79.
Scheme 18 Click here to View Scheme |
Independently, John Nielsen and co-workers32detailed the preparation of (E)-N-methoxy-N-methyl-β-enaminoketoesters and also novel synthetic pioneers for the region-selective synthesis of heterocyclics(Scheme 19). First, Weinreb amides 81treat with the Li- or Na- acetylide of ethyl propynoate 80in a hitherto acyl substitution−conjugate addition series to produce (E)-N-methoxy-N-methyl-β-enaminoketoesters82, second, this protocol affords a variety access to violently functionalized heterocyclics, inclusive pyrazoles 84through region-selective cyclo-condensations with hydrazine compounds83applying microwave-assisted reaction.
Scheme 19 Click here to View Scheme |
In 2007, Davis and co-workers33reported the asymmetric preparation of syn–α-substituted β-amino acidsthrough a reaction of pro-chiral lithium enolates of Weinreb amides and sulfinimines (N-sulfinyl imines)(Scheme 20). The protocol here first focused on the reaction of sulfinimine-derived α-substituted β-amino Weinreb amide with organometallic compounds. While the direct synthesis of major α-substituted β-amino Weinreb amide products 87 proceeded through the addition of a prochiral Weinreb amide enolate 86to a sulfinimine 85. Moreover, the sulfinimine-derived chiral building blocks are considered as significant pioneers of syn–α-substituted β-amino acid derivatives, through hydrolysis, reduction, and reaction with Grignard reagents, individually.
Scheme 20 Click here to View Scheme |
Though, Kim and co-workers34suggested a novel and effective procedure for the transformation of different carboxylic acids to their analogical Weinreb amides employing triphosgene as an acid activator (Scheme 21). This reaction encompasses the treatment of carboxylic acid 89with triphosgene 90to give an acid chloride or anhydride, followed by handling with N,O-dimethylhydroxylamine 91to produce the expected Weinreb amide92. The current method afforded high yields, short reaction time, and workable accessibility.
Scheme 21 Click here to View Scheme |
While, Jeong and his group35reported dynamic one-pot preparation of unusual α, β-dichloro-β-trifluoromethylated enones (Scheme 22). The stages of protocol start with the reaction of Weinreb benzamides 94 and trifluoropropynyllithium 93in THF at -78 to 0 °C, followed by handling with trifluoromethanesulfonyl chloride 95to produce α, β-dichloro-β-trifluoromethylated enones 96 in moderate yields. While the reaction of α, β-dichloro-β-trifluoromethylated enones96with substitute amidines 98or hydrazinereagents102in reflux mixture of 1,4-dioxane/CH3CN produced trifluoromethylated chloropyrimidines 99 and chloropyrazoles 103 in acceptable yields. Furthermore, the coupling reactions of trifluoromethylated chloropyrimidines 99 with substituted phenylstannane and allylstannane 100in CH3CN using Pd(PPh3)4catalyst under microwave-assisted conditions, provided the desired phenyl and allyl substituted pyrimidine products101in very good yields. While the same conditions were applied with chloropyrazoles103, but did not lead to the product 104.
Scheme 22 Click here to View Scheme |
In 2008, Prandi and co-workers36described the preparation of newfangled species of heterocyclic Weinreb amides through aminocarbonylation reaction of heterocyclic-derived triflates in the presence of Pd catalyst (Scheme 23).This reaction proceeded through the straight forward conversion of lactone-, thiolactone and lactam-derived triflates 105into the corresponding morpholineor N-methoxy-N-methyl Weinreb amides 107. The protocol here suggested to proceed through using CO 75 under mild conditions. However, the amides steadily reacted with nucleophiles 108to yieldthe desired heterocycle products109. This new protocol discloses the outlet to important dynamically heterocyclic scopes that are favorable as building blocks in total syntheses, and the suggested methodology could be convenient profit for the dienone synthesis, as helpful moieties for Nazarov cyclization.
Scheme 23 Click here to View Scheme |
Next, Somfai and co-workers37 reported an efficient and diastereoselective synthesis of aryl glycines 112from Weinreb amides employing α-arylation process(Scheme 24). In such reaction, a novel α-arylation reaction proceeds smoothly through the reaction between amideas electrophile110andaryl Grignard reagents as nucleophile111in the presence of LDA as a base in THF at low temperature. The mechanism of this reaction starts with deprotonating and the generation of enolate, followed by elimination tBuO. While the nucleophilic addition of the Grignard reagent to form amide.
Scheme 24 Click here to View Scheme |
Recently, Li and co-workers38, described the synthesis of diverse chiral N-phosphonyl β-amino Weinreb amides 115viareaction of chiral N-phosphonyl imines 113with the lithium enolate of N-methoxy-N-methylacetamide114employing mild conditions(Scheme 25). Generally, the deprotonation base and presence of protection groups on chiral N-phosphonyl imines were the pivotal success of such reactions. Commonly, N-phosphonyl imines uses as electrophiles 113 for some nucleophilic addition reactions, like aza-Darzens, aza-Henry reaction, and allylmagnesium bromide based addition, various wide of Weinreb amides were prepared in excellent yields (up to98%) with high diastereoselectivities. Furthermore, the ultimate structures were uniquely specified by the transformation the products into original samples and equal their optical rotation assessments.
Scheme 25 Click here to View Scheme |
Meanwhile, Huet al39reported a wonderful reagent, P[NCH3(OCH3)]3, for the direct synthesis of Weinreb amides 120from carboxylic acids 119(Scheme 26).So firstly, treatment N,O-dimethylhydroxylaminehydrochloride 116 withPCl3116in Et2O uses triethylamine as a base to give P[NCH3(OCH3)]3118in 67% yield. Secondly, P[NCH3(OCH3)]3118can be utilized for the conversion of various kinds ofcarboxylic acids includedaliphatic, aromatic, stericallyhindered, and dioic acids in toluene into the expected Weinrebamide products in excellent yields employing soft conditions.
Scheme 26 Click here to View Scheme |
Conclusion
Newly, assorted investigations have itemized the utilization of Weinreb amide developments as an awesome intermediate in natural blend reaction. In this sheet, we displayed this side of the written works, including an abnormal preparation of Weinreb amides and their employments by explaining convention instances of these procedures. Besides, this paper contains a definitive finish of the specialists and conveniently outfits reaction data for the exceedingly significant reaction and numerous indications to the regional literature.
Acknowlegement
We acknowledge the University of Zakho, Faculty of Science, Department of Chemistry for providing all the facilities.
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