2.4 Cascade Transformations Involving Allenylation Process

Nucleophilic addition with allenoic ester or its isomeric compound is generally used synthetic strategy for the expeditious construction of highly functionalized carbocycle or heterocycle structures ^{[24][25][26][27][28][29][30][31][32]}[24-32]. Thus, a variety of inter- or intramolecular cascade reactions have been developed through different nucleophilic addition processes of the allene derivatives generated from cross-coupling between alkynes and copper carbenes.

In 2011, a one-pot synthesis of phenanthrenes 81 via ligand-free CuBr₂-catalyzed coupling reaction/intramolecular cyclization of terminal alkynes 23 with N-tosylhydrazones 79 derived from o-formyl biphenyls was developed by Wang and co-workers ^[33] [33]. Allene intermediates 85 were initially generated in this cascade reaction through a cross-coupling reaction of N-tosylhydrazones 79 with terminal alkynes 23, followed by a 6π-cyclization and isomerization deliver the phenanthrene products 81 with broad functional group compatibility (Scheme 19).

Scheme 19. Copper-catalyzed allenylation followed by 6π-cyclization.

Later in the same year, instead of using

o

-aryl substituted

N

-tosylhydrazones,

o

-hydroxy- or

o

-amino-substituted

N

-tosylhydrazones were introduced by the same group as carbene precursors in an analogous cascade transformation, a ligand-free CuBr-catalyzed coupling reaction/intramolecular cyclization sequence, achieving the synthesis of benzofuran or indole derivatives

84

in moderate to excellent yields [34]. The initially formed allene intermediates

83

were trapped through a nucleophilic addition by the embedded

o

-hydroxy- or

o

-amino group to afford the cyclized products

84

(Scheme 20).

Scheme 20. Copper-catalyzed allenylation followed nucleophilic addition.

In 2011, a similar catalytic strategy was developed by Balakishan’s group. They reported a simple procedure for synthesizing aza- and oxacycles

via

a copper-catalyzed coupling reaction of functionalized terminal alkynes

85

with diazoesters

86

[35]. Initially, the allene intermediates were formed in the presence of CuI, followed by an intramolecular aza- or oxa-Michael cycloaddition and isomerization to generate the cyclized five- or six-membered products

87

in generally good yields (Scheme 21).

Scheme 21. Copper-catalyzed allenylation followed by cyclization.

In 2015, a stereo-divergent synthesis of five-membered heterocycles was developed by Sun’s group ^[36]. The proposed reaction mechanism involves trapping

In 2015, a stereo-divergent synthesis of five-membered heterocycles was developed by Sun’s group [36]. This work described a copper-catalyzed cross-coupling reaction and annulation cascade reaction of amino alkynes 88 with diazo compounds 15. The proposed reaction mechanism involves trapping

in situ

formed allene intermediates, yielding 2-methylenes

89

(when PG = Bn) and 2,3-dihydropyrroles

90

(when PG = Ts) in good yields with broad functional group tolerance under mild conditions. Control experimental results show that

N

-benzyl amino alkynes were more likely to form 2-methylenespyrroles derivatives

89

through

5-exo-dig

cycloaddition, while 2,3-dihydropyrroles

90

generated from

N

-tosylamino alkynes through

5-endo-dig

cycloaddition would be more favorable (Scheme 22).

Scheme 22. Copper-catalyzed allenylation followed by divergent annulation.

In 2018, Sun and co-workers expanded the above chemistry to synthesize the four- to six-membered heterocycles with

N

-substituted prop-2-yn-1-amines

91

and diazoacetates

15

[37]. Generated allenoic species

92

have been proven as the key intermediates for the subsequent diverse annulations under optimized conditions toward functionalized heterocycle in moderate to good yields. Treatment of allenoates

92

with sodium phenolates led to six-membered products

93

; silver nitrate and triethylamine yielded five-membered products

94

; what’s more, four-membered products

95

were generated under lithium

tert

-butoxide conditions (Scheme 23).

Scheme 23. Divergent synthesis of four- to six-membered heterocycles involving an allenylation process.

In addition to the cyclization through addition with a heteroatom, carbon-based nucleophilic species could also be served as the nucleophile to addition with these allenes, forming the C-C bond instead of the C-X bond ^[38][39]. In 2015, Kumaraswamy’s group developed a cooper catalyzed cross-coupling reaction/intramolecular Michael addition cascade reaction ^[40], achieving the formation of indene and dihydronaphthalene derivatives

In addition to the cyclization through addition with a heteroatom, carbon-based nucleophilic species could also be served as the nucleophile to addition with these allenes, forming the C-C bond instead of the C-X bond [38,39]. In 2015, Kumaraswamy’s group developed a cooper catalyzed cross-coupling reaction/intramolecular Michael addition cascade reaction [40], achieving the formation of indene and dihydronaphthalene derivatives

97

in good yields with broad functional group tolerance (Scheme 24a). Later in 2017, Sun’s group reported an analogous approach toward five- or six-membered carbo-/heterocycles with diazo compounds

15

and alkyne-substituted malonates

98

[41]. In this reaction, the ligand  significantly enhanced the reaction yields and inhibited the Conia-ene side reaction. As a result, the polyfunctionalized cyclohexenes, tetrahydropyridines, and dihydropyrans have been prepared in moderate to high yields under mild reaction conditions (Scheme 24b).

Scheme 24. Copper-catalyzed allenylation followed by Michael addition.

In 2015, a Cu(I)-catalyzed denitrogenative annulation reaction of pyridotriazoles

100

with terminal alkynes

10

was developed by Gevorgyan’s group [42]. Initially, 

α

-pyridyl copper carbenes were generated from pyridotriazoles

100

in the presence of the copper catalyst, followed by a cross-coupling reaction with terminal alkyne to form either propargylic or allenoic intermediates

101

, which were terminated by copper-catalyzed cycloisomerization to furnish the indolizines

102

in moderate to excellent yields (Scheme 25).

Scheme 25.

Copper-catalyzed allenylation followed by cycloisomerization.

In 2018, Wang and co-workers reported a copper-catalyzed geminal difunctionalization reaction of terminal alkynes [43]. The key step in this cascade reaction is trapping the

in situ

generated allenoic species

105

with a sulfonyl anion to form the carbon-sulfur bond, providing a variety of vinyl sulfones

106

in good yields with excellent stereoselectivities under mild reaction conditions. It was noted that the excellent stereoselectivities might be due to the influence of steric hindrance, and no ligand and additive were required in this transformation (Scheme 26).

Scheme 26. Copper-catalyzed allenylation followed by sulfonylation.

Recently, Sun and co-workers demonstrated a copper-catalyzed three-component reaction of terminal alkynes with diazo compounds and B

₂

pin

₂

for the synthesis of trisubstituted alkenylboronates [44]. Copper catalysts played dual roles in these alkynes’ difunctionalizations. Initially, copper catalyzed the cross-coupling to form an allenoic intermediate, followed by a copper-catalyzed stereoselective boration reaction with B

₂

pin

₂

. When diazo compounds

53

were used as carbene precursors, the steric interaction forced the boron group to attack the

β

-carbon from the opposite side of the

γ

-phenyl group on the allenoic species

107

, leading to the favored  (

Z

)-isomers

108

as major products. Whereas, in the case with

N

-tosylhydrones

51

as carbene precursors, the addition of Cu-Bpin complex to corresponding allenoic species

109

provided allyl copper intermediate, which was more favored to form a six-membered ring transition state with the association of MeOH, finally furnishing the more thermodynamically stable (

E

)-products

110 (Scheme 27).

(Scheme 27).

Scheme 27. Copper-catalyzed allenylation followed by boroalkylation.

3. Copper Carbene Intermediate Addition onto C-C Triple Bond

3.1 Cyclopropenation

Cyclopropenation is a well-known reaction of metal carbene intermediate with alkynes. This widely used reaction could be catalyzed by rhodium ^{[45][46][47][48][49]}, cobalt ^[50], gold ^[51], silver ^[52][53] and many others ^[54][55][56]. Herein, selected examples related to copper catalysis will be discussed.

Cyclopropenation is a well-known reaction of metal carbene intermediate with alkynes. This widely used reaction could be catalyzed by rhodium [45-49], cobalt [50], gold [51], silver [52,53] and many others [54,55,56]. Herein, selected examples related to copper catalysis will be discussed.

In 2010, a new tridentate coordination copper complex, Cu[Ms(CH

₂

SCN)

₃

]BAr'

₄

(BAr'4 = tetra(3,5-bis(trifluoromethylphenyl)borate), was designed by Miguel and co-workers by using [Cu(OTf)]

₂

•C

₆

H

₆ and an alkylthiocyanate ligand ^[57]. This catalyst promoted the cyclopropenation of ethyl diazoacetate

and an alkylthiocyanate ligand [150]. This catalyst promoted the cyclopropenation of ethyl diazoacetate

34

(EDA) with a wide range of internal alkynes

111

, providing cyclopropenes

112

in moderate yields (Scheme 28). The same cyclopropenation work was achieved by Dias, unique   bis(pyrazolyl)borate ligand supported [(CF

₃

)

₂Bp]Cu(NCMe) catalyst was used, yielding cyclopropene products in moderate to high yields ^[58].

Bp]Cu(NCMe) catalyst was used, yielding cyclopropene products in moderate to high yields [57].

Scheme 28. Copper/alkylthiocyanate complex catalyzed cyclopropenation.

In 2016, a Cu(I)/

N

-heterocyclic carbene (CuNHC) complex catalyzed cyclopropenation of internal alkynylsilanes

113

with diazoacetate

15 was reported by Coleman’s group ^[59]. A series of 1,2,3-trisubstituted and 1,2,3,3-tetrasubstituted cyclopropenylsilane compounds

was reported by Coleman’s group [58]. A series of 1,2,3-trisubstituted and 1,2,3,3-tetrasubstituted cyclopropenylsilane compounds

114

were isolated in moderate to good yields (Scheme 29). An interesting regioselective and chemodivergent reaction pathway occurred furnished a

tetra-substituted furan through an intramolecular cyclopropene ring-opening transformation in the case of electron-rich diazoacetate.

-substituted furan through an intramolecular cyclopropene ring-opening transformation in the case of electron-rich diazoacetate.

Scheme 29. Copper/N-heterocyclic carbene (CuNHC) complex catalyzed cyclopropenation.

3.2 Cascade Reaction Involving Carbene/Alkyne Metathesis Process

Carbene/alkyne metathesis (CAM) refers to the processes where a metal carbene reacts with an alkyne, generating a new vinyl metal carbene intermediate, which was difficult to access with other carbene precursors ^[60][61][62]. This

Carbene/alkyne metathesis (CAM) refers to the processes where a metal carbene reacts with an alkyne, generating a new vinyl metal carbene intermediate, which was difficult to access with other carbene precursors [59,60,61]. This

in situ generated vinyl metal carbene intermediate could be involved in typical metal carbene reactions, such as [3+2]-cycloaddition ^[63], cyclopropanation ^[64][65][66], C-H bond insertion ^{[67][68][69][70]}, and others ^[71][72][73].

generated vinyl metal carbene intermediate could be involved in typical metal carbene reactions, such as [3+2]-cycloaddition [156], cyclopropanation [62,63,64], C-H bond insertion [65-68], and others [69-71]. Herein, we summarized recent works on the copper-mediated cascade transformations involving carbene/alkyne metathesis.

It’s a general protocol for the synthesis of furan derivatives through transition metal-catalyzed formal [3+2] cycloaddition of

α-diazocarbonyl compounds with alkynes ^{[74][75][76][77]}. However, the cases under copper carbenes mediated were limited. In 2014, Wang’s group developed a copper-catalyzed formal [3+2] cycloaddition reaction of terminal alkynes with

-diazocarbonyl compounds with alkynes [72-75]. However, the cases under copper carbenes mediated were limited. In 2014, Wang’s group developed a copper-catalyzed formal [3+2] cycloaddition reaction of terminal alkynes with

β

-keto

α

-diazoesters

115

(X = O), offering an operationally simple and applicable method for the synthesis of trisubstituted furans

116 (X = O) with a wide substrate scope (Scheme 30a) ^[78]. This reaction has also been applied to ethyl (

(X = O) with a wide substrate scope (Scheme 30a) [76]. This reaction has also been applied to ethyl (

E

)-2-diazo-3-(methoxyimino)butanoate

115

(X = NOMe) for the synthesis of 2,3,5-trisubstituted

N

-methoxypyrroles (X = NOMe). Later in 2016, a Cu(I)-catalyzed cycloaddition of diazoacetates

15

with electron-rich internal aryl alkynes

117 was discovered by Coleman and co-workers ^[79]. Tetra-substituted furans

was discovered by Coleman and co-workers [77]. Tetra-substituted furans

118 were generated in moderate isolated yields with high chemoselectivities and regioselectivities (Scheme 30b).

were generated in moderate isolated yields with high chemoselectivities and regioselectivities (Scheme 30b).

Scheme 30. Copper-catalyzed carbene/alkyne metathesis for the synthesis of furan derivatives.

In 2016, Xu’s group developed a chemo-divergent copper-catalyzed cascade reaction of alkynyl-tethered

α

-iminodiazoacetates

119, providing polycyclic and multi-substituted pyrroles in high yields with a broad substrate scope ^[80]. Especially, the

, providing polycyclic and multi-substituted pyrroles in high yields with a broad substrate scope [78]. Especially, the

tetra

-substituted 3-formylpyrroles

124

, which were difficult to access by alternate approaches. Mechanistic studies indicated that the

α

-imino carbene

120

is the key common intermediate in this divergent reaction, which was generated by metal-catalyzed carbene/alkyne metathesis of the alkynyl-tethered diazo compounds

121

. When R

¹

, R

²

was imbedded with an aromatic ring, polycyclic pyrroles

122

were formed as the major products through a [3+2]-cyclization and aromatization process. Whereas, substrates with a methoxy group on the nitrogen (R

²

= OMe), the carbene intermediate underwent an

N

–O insertion/alkoxy migration/alcoholysis sequence, giving the 3-formylpyrrole products

124

in generally good to excellent yields (Scheme 31).

Scheme 31. Copper-catalyzed carbene/alkyne metathesis for the synthesis of pyrroles.

At the same time, Xu and co-workers have also developed a copper-catalyzed carbene/alkyne metathesis cascade reaction with alkyne-tethered diazo compounds

125 ^[81]. This transformation provided rapid access for the construction of multi-substituted 4-carboxyl quinoline derivatives

[79]. This transformation provided rapid access for the construction of multi-substituted 4-carboxyl quinoline derivatives

127

in high to excellent yields. In this cascade reaction, one C═N and one C═C bond were formed with the assistance of the copper catalyst under mild reaction conditions (Scheme 32a). Later in 2017, Ye’s group reported an analogous protocol by using ynamides

128 as carbene precursor ^[82]. In this work, a copper carbene was generated in situ through a catalytic oxidation process in the presence of quinoline

as carbene precursor [80]. In this work, a copper carbene was generated in situ through a catalytic oxidation process in the presence of quinoline

N

-oxide, followed by a CAM process and terminated by carbene reaction with an embedded azide group, providing a wide range of pyrrolo[3,4-

c

]quinolin-1-ones

130 in good yields. Those works represented practical methods for the dual functionalization of alkynes (Scheme 32b).

in good yields. Those works represented practical methods for the dual functionalization of alkynes (Scheme 32b).

Scheme 32. Copper-catalyzed carbene/alkyne metathesis for the synthesis of quinolines.

In addition to the nucleophilic addition of the

in situ

formed copper carbene intermediates, electrophilic aromatic substitution or C(sp

²

)–H bond functionalization is another useful terminating transformation for the direct construction of polycyclic fused frameworks. In 2017, Doyle’s group reported a copper-catalyzed intramolecular cascade reaction of diazo compounds

131

, this transformation went through a CAM process followed by a carbene C(sp

²

)–H bond functionalization cascade, yielding the fused indeno-furanone derivatives

133 in excellent yields under mild reaction conditions (Scheme 33a) ^[83]. Instead of terminating reaction in C-H functionalization, a selective Buchner insertion reaction occurred as the terminating step in Xu’s work when the

in excellent yields under mild reaction conditions (Scheme 33a) [81]. Instead of terminating reaction in C-H functionalization, a selective Buchner insertion reaction occurred as the terminating step in Xu’s work when the

ortho

-aniline substituted propargyl diazoacetates

134

were employed, selectively affording the dihydrocyclohepta[

b

]indole derivatives

136 in moderate to high yields (Scheme 33b). Notably, this reaction described a rare example of the Buchner reaction with donor/donor type metal carbene species ^[84].

in moderate to high yields (Scheme 33b). Notably, this reaction described a rare example of the Buchner reaction with donor/donor type metal carbene species [82].

Scheme 33. Copper-catalyzed carbene/alkyne metathesis for the synthesis of tri-cyclic molecules.

In 2018, Xu and co-workers developed an intermolecular copper-catalyzed formal CAM process ^[85], which underwent a copper promoted [3+2] cycloaddition/dinitrogen exclusion/nucleophilic addition process, providing a direct and effective access to 2

In 2018, Xu and co-workers developed an intermolecular copper-catalyzed formal CAM process [83], which underwent a copper promoted [3+2] cycloaddition/dinitrogen exclusion/nucleophilic addition process, providing a direct and effective access to 2

H

-chromene derivatives

139

in generally good to high yields. Mechanistic studies indicated that the 3

H

-pyrazole

138 is the key intermediate in this cascade transformation, and this critical intermediate was isolated and confirmed by single-crystal X-ray diffraction and spectroscopy analysis for the first time (Scheme 34).

is the key intermediate in this cascade transformation, and this critical intermediate was isolated and confirmed by single-crystal X-ray diffraction and spectroscopy analysis for the first time (Scheme 34).

Scheme 34. Copper-catalyzed formal carbene/alkyne metathesis for the synthesis of 2H-chromene derivatives.

Based on a similar protocol, a copper-catalyzed formal [1+2+2]-annulation of alkyne-tethered diazo compounds

140

with pyridines

141 has been reported by Xu’s group recently ^[86]. In contrast to the previously reported cascade reaction that was terminated the copper carbene intermediate on the carbonic center, a vinylogous addition of vinyl carbene intermediate with pyridine derivatives was occurred in this reaction, followed by an intramolecular annulation to form cycloadducts

has been reported by Xu’s group recently [84]. In contrast to the previously reported cascade reaction that was terminated the copper carbene intermediate on the carbonic center, a vinylogous addition of vinyl carbene intermediate with pyridine derivatives was occurred in this reaction, followed by an intramolecular annulation to form cycloadducts

146

, which underwent a decarboxylative aromatization process to form the desired polycyclic fused indolizine derivatives

147

in good to high yields (Scheme 35, path a), although direct formal [3+2]-cycloaddition

via pyridinium ylide pathway could not be ruled out so far (Scheme 35, path b).

pyridinium ylide pathway could not be ruled out so far (Scheme 35, path b).

Scheme 35. Copper-catalyzed formal carbene/alkyne metathesis for the synthesis of polycyclic indolizines.

4.4 Conclusions

This review has summarized the recent progress of catalytic alkyne functionalization involving copper carbene intermediates. Copper carbene species derived from different carbene precursors have been introduced to react with alkynes through two distinguished reaction models: cross-coupling reaction of copper carbene intermediates with terminal alkynes and addition of copper carbene intermediates onto the C-C triple bond. The former reaction involves alkynoate or allenoate copper intermediates, followed by protonation, nucleophilic substitution, electrophilic addition, or elimination process, yielding functionalized alkynes and allenes, respectively. The latter version includes cyclopropenation and cascade reaction via carbene/alkyne metathesis process. Although substantial progress has been realized in this field, challenges remain, e.g., the carbene precursors are still mainly limited to the diazo compounds; the catalytic efficiency could be further improved, especially in the asymmetric catalysis; synthetic applications of this chemistry are still under exploration. Therefore, the synthetic potential of this chemistry could be envisioned through the introduction of a variety of readily accessible carbene precursors and with the development of robust copper catalysts/ligands, including novel methodology discovery for the catalytic alkyne functionalization, and expeditious assembly of molecules with structural complexity and diversity for the leading compound development.