Selectfluor-Mediated Simultaneous Cleavage of C–O and C–C Bonds

deacetylative synthesis of 3-hydroxy quinoline. Parul Chauhan , Makthala Ravi , Ruchir Kant , Prem. P. Yadav. Organic & Biomolecular Chemistry 201...
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Selectfluor-Mediated Simultaneous Cleavage of C−O and C−C Bonds in α,β-Epoxy Ketones Under Transition-Metal-Free Conditions: A Route to 1,2-Diketones Heng Wang, Shaobo Ren, Jian Zhang, Wei Zhang, and Yunkui Liu* State Key Laboratory Breeding Base of Green Chemistry-Synthesis Technology, College of Chemical Engineering, Zhejiang University of Technology, Hangzhou 310014, People’s Republic of China S Supporting Information *

ABSTRACT: Selectfluor-mediated simultaneous cleavage of C−O and C−C bonds in α,β-epoxy ketones has been successfully achieved under transition-metal-free conditions. The reaction gives 1,2-diketone compounds in moderate to good yields involving a ring-opening/benzoyl rearrangement/ C−C bond cleavage sequence under oxidative conditions. Our findings originated from our recent research interest in Cu(0)/Selectfluor system-mediated tandem reactions.9 When we subjected α,β-epoxy ketone 1a to the Cu(0)/Selectfluor system (Cu(0) powder: 5 mol %; Selectfluor: 2.0 equiv) in acetonitrile at 80 °C for 6 h, an unexpected product, 1,2diketone 2a, was obtained in 53% yield (entry 1, Table 1). 1,2Diketone compounds serve as important biologically active candidates as well as synthetic intermediates for various chemical transformations.10,12 Our particular interest in the novel transformation of α,β-epoxy ketones to 1,2-diketones as well as the curiosity of the mechanism for the C−C bond cleavage stimulated us to further optimize the reaction conditions (Table 1). It was found that the employment of other Lewis acid catalysts, such as CuBr, CuCl2·2H2O, PdCl2, FeCl3, Ph3PAuCl, and Ph3PAuNTf2, did not significantly improve the yield of 2a (entries 2−7, Table 1). Surprisingly, the reaction gave an even better result when no transition-metal catalyst was used (entry 8, Table 1). The employment of 2 equiv of Selectfluor was indispensable, otherwise, the conversion of 1a to 2a would be low (entry 9, Table 1). A range of other oxidants were investigated and all displayed lower effectiveness than Selectfluor (entries 10−14, Table 1), demonstrating the unique role of Selectfluor in the reaction. Note that the addition of 0.5 equiv of KHCO3 slightly increased the yield of 2a (67%, entry 15, Table 1). However, other base additives, such as K2CO3, Na2CO3, NaHCO3, and Et3N, could not increase the yield of 2a (entries 16−19, Table 1). A series of solvents were screened for the reaction, 100:1 (v/v) acetonitrile−water has proven to be the best choice for the transformation (entries 15, 24, 26, 27 vs 20, Table 1). An attempt to conduct the reaction at a lower temperature only gave a reduced yield of 2a (50 °C, 47%, entry 25, Table 1). The addition of several strong Lewis acids, such as Zn(OTf)2,

C

arbon−carbon bonds represent the most ubiquitous chemical bond in organic molecules. However, achieving efficient and selective cleavage of carbon−carbon single bonds for chemical transformations remains one of the most challenging tasks faced by chemists.1 In the past few decades, transition-metal-mediated reactions have been widely adopted to accomplish this goal (e.g., transition-metal-catalyzed oxidative addition, β-carbon elimination, and decarbonylation reactions, and so forth).1,2 Recently, the cleavage of C−C single bonds under transition-metal-free conditions has received increasing attention because such procedures generally have obvious advantages in terms of cost, nontoxicity, and environmental compatibility.3 Therefore, it is highly desirable to develop facile and transition-metal-free approaches for C−C single bond cleavage. Epoxide derivatives are a class of three-membered cyclic ethers that can serve as important and versatile building blocks in organic synthesis.4 To date, the dominant research on the application of epoxides in organic synthesis generally focuses on ring-opening reactions via facile C−O bond cleavage.4 However, reactions involving the C−C bond cleavage of epoxide motifs are much more difficult and have been less documented due to the harsh conditions required.5−8 Several limited examples are (1) Lewis acid-catalyzed cycloaddition reactions of epoxide derivatives with certain dipolar reagents involving carbonyl ylide or 1,4-dipole intermediates (Scheme 1a),6 (2) iron-promoted tandem reaction of styrene oxides with anilines to give 3-arylquinolines involving C−C bond cleavage (Scheme 1b),7 and (3) copper-catalyzed aniline-assisted oxidative cleavage of C−C bonds in epoxides leading to aryl ketones (Scheme 1c).8 As part of our ongoing research interest on C−C bond cleavage,9a we present herein Selectfluormediated simultaneous cleavage of C−O and C−C bonds in α,β-epoxy ketones leading to 1,2-diketone compounds in moderate to good yields under transition-metal-free conditions (Scheme 1d).10,11 © XXXX American Chemical Society

Received: April 17, 2015

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DOI: 10.1021/acs.joc.5b00857 J. Org. Chem. XXXX, XXX, XXX−XXX

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The Journal of Organic Chemistry Scheme 1. Reactions Involving C−C Bond Cleavage in Epoxide Derivatives

dicarbonyl compounds 4, the formation of diketo ester 5 led us to speculate that 1,2,3-trione might be an intermediate for the generation of diketone 2 from α,β-epoxy ketones 1. To test the above speculation, we synthesized 1,2,3-trione 6 according to the reported procedure.13 Note that there is also an equilibrium between 6 and its hydrate form 6′. When the mixture of 6 and 6′ was subjected to the standard reaction conditions, 2a was indeed produced in 62% yield (eq 1, Scheme 3), thus confirming that 1,2,3-trione was an intermediate for the formation of 2. In addition, an O18-labeling experiment was conducted using CH3CN-H2O18 (100:1, v/v) as the solvent and mono-O18-incorporated product 2a-O18 was obtained in 81% yield (eq 2, Scheme 3; see also the Supporting Information), suggesting that one of the oxygen atoms in 2a originated from water. Furthermore, the addition of TEMPO, a radical scavenger,14 to the reactants showed no effect on the final outcome (eq 3, Scheme 3), suggesting that no radical pathway was involved in the reaction. On the basis of the above mechanistic studies and previous reports,15−18 a plausible mechanism for the Selectfluormediated simultaneous cleavage of C−O and C−C bonds in epoxy ketone 1a leading to diketone 2a is depicted in Scheme 4. It was reported that Selectfluor could serve as an efficient Lewis acid catalyst for the hydrolysis of acetals, dithia-acetals, and tetrahydropyranyl ethers15 as well as for the ring-opening of epoxides with thiocyanates.16 Thus, for the first step, the reaction may undergo ring-opening of 1a with water promoted by Selectfluor, leading to an intermediate I.16 Subsequent oxidation of I by Selectfluor gave 1,2,3-trione intermediate 6.13,17 Then, 6 may undergo a 1,2-Wagner−Meerwein-type rearrangement of a benzoyl group through F+- or H+-assisted activation of the carbonyl group in 6 to yield intermediate II.18 Finally, a carbon monoxide was released from intermediate II followed by a proton abstraction with a base from resulting

In(OTf)3, and Yb(OTf)3, to the reaction mixture did not increase the yield of 2a (entries 21−23, Table 1). With the optimized reaction conditions established, we began to investigate the generality and scope of this method for the synthesis of diketones (Table 2). As seen from Table 2, a wide range of α,β-epoxy ketones 1 bearing aryl rings with various substitution patterns (ortho-, meta-, or para-) were able to undergo C−C bond cleavage and reassemble into diketones 2 in moderate to good yields (40−85%, entries 1−26, Table 2). It was found that both electron-donating and -withdrawing substituents in the aryl ring of α,β-epoxy ketones 1 were compatible with the reaction conditions, among which include methyl, halo (F, Cl, Br), aryl, and nitro groups. Note that epoxy ketone 1l bearing a heterocycle was also well-tolerated under the reaction conditions, and the corresponding diketone was obtained in 57% yield (entry 12, Table 2). It seemed that the steric hindrance on the aryl ring of 1 had no obvious effect on the reaction outcome. For example, epoxy ketone 1o possessing a large [1,1′-biphenyl]-2-yl group also worked well to give the desired product in moderate yield (61%, 2o, entry 15, Table 2). Epoxy ketone 1m derived from aryl aldehyde and aliphatic ketone was also a suitable substrate for the reaction (63%, 2i, entry 13, Table 2), whereas epoxy ketone 1za derived from aliphatic aldehyde and acetophenone failed to give the desired product (entry 27, Table 2). The inertness of 1w may be ascribed to the large steric hindrance of the t-butyl group to allow the reaction as well as the requirement for nonenolizable substrates in the present reaction. When we subjected aryloxiranyl carboxylates 3 to the standard reaction conditions, the reaction only gave a trace amount of 1,2-dicarbonyl compounds 4, whereas a mixture of diketo ester 5 and its hydrate form 5′ were isolated as the predominant products (R = H, 5a/5′a: 85%; R = 4-Cl, 5b/5′b: 77%; Scheme 2).13 Although these reactions failed to give 1,2B

DOI: 10.1021/acs.joc.5b00857 J. Org. Chem. XXXX, XXX, XXX−XXX

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The Journal of Organic Chemistry Table 1. Optimization of Reaction Conditionsa

entry

catalyst

oxidant

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27

Cu(0) CuBr CuCl2·2H2O PdCl2 FeCl3 Ph3PAuCl Ph3PAuNTf2

Selectfluor Selectfluor Selectfluor Selectfluor Selectfluor Selectfluor Selectfluor Selectfluor Selectfluor F1 F2 F3 PhI(OAc)2 DDQ Selectfluor Selectfluor Selectfluor Selectfluor Selectfluor Selectfluor Selectfluor Selectfluor Selectfluor Selectfluor Selectfluor Selectfluor Selectfluor

Zn(OTf)2 In(OTf)3 Yb(OTf)3

base

solvent

yield (%)

KHCO3 K2CO3 Na2CO3 NaHCO3 Et3N KHCO3 KHCO3 KHCO3 KHCO3 KHCO3 KHCO3 KHCO3 KHCO3

CH3CN CH3CN CH3CN CH3CN CH3CN CH3CN CH3CN CH3CN CH3CN CH3CN CH3CN CH3CN CH3CN CH3CN CH3CN CH3CN CH3CN CH3CN CH3CN CH3CN:H2O = 100:1 CH3CN:H2O = 100:1 CH3CN:H2O = 100:1 CH3CN:H2O = 100:1 solventc CH3CN:H2O = 100:1 CH2Cl2:H2O = 100:1 toluene:H2O = 100:1

53 47 43 49 51 52 50 64 43b 34 19 0 trace 40 67 56 51 54 trace 83 80 79 83