DOI:
10.1039/D0QO01085E
(Review Article)
Org. Chem. Front., 2021,
8, 1026-1084
Stereoselective synthesis and applications of spirocyclic oxindoles
Received
11th September 2020
, Accepted 5th January 2021
First published on 6th January 2021
Abstract
The development of novel synthetic strategies to form new chemical entities in a stereoselective manner is an ongoing significant objective in organic and medicinal chemistry. This review analyses the development of new stereoselective approaches to spirocyclic oxindoles with spiro-3- to 8-membered rings. It highlights the importance of these structures for applications in medicinal chemistry, as intermediates or final products in total synthesis and as model compounds for the development of enantioselective catalytic methodologies.
Alexander J. Boddy | Alexander Boddy graduated from Durham University with an MChem with Industrial Training in 2016, including a final year placement at Infineum UK. He completed his PhD in the laboratory of Dr James A. Bull at Imperial College London in 2020. His PhD research, in collaboration with AstraZeneca, developed new synthetic methodologies to access saturated heterocycles for potential use in drug discovery. Alexander is now a Senior Scientist in Chemical Development at GlaxoSmithKline. |
James A. Bull | Dr James Bull is a University Research Fellow at Imperial College London. His research focuses on the development of synthetic and catalytic methods to access medicinally relevant structural motifs and heterocycles. He obtained his MSci degree from the University of Cambridge, then spent a year at GlaxoSmithKline. He returned to University of Cambridge for his PhD with Professor Steven Ley. In 2007 he joined Université de Montréal as a postdoc with Professor André Charette. He started a Ramsay Memorial Fellowship at Imperial College in 2009, an EPSRC Career Acceleration Fellowship in 2011, and in 2016 was awarded a Royal Society University Research Fellowship. |
Introduction
The application of spirocyclic structures in drug discovery has seen a dramatic increase in attention in recent years, alongside major developments in their synthetic chemistry.1 Defined as a bicycle connected by a single fully-substituted carbon atom, which is not connected by an adjacent atom, spirocycles are inherently highly 3-dimensional structures. The shared tetrahedral sp3-carbon atom positions the planes of the 2 rings orthogonally, despite the torsional strain this may impose on the substituents of the rings.2 Spirocyclic compounds can improve certain physicochemical properties such as lipophilicity, aqueous solubility and metabolic stability, in comparison to the respective monocyclic structure.3 Furthermore, they access relatively underexplored chemical space and novel intellectual property (IP) space. Saturated spirocycles provide a dense, rigid scaffold, with the potential to append more substituents, and so occupy an increased number of defined vectors compared to flat aromatic compounds.4 All of these factors have contributed to a greater uptake in medicinal chemistry and have demanded significant advances in organic synthesis to provide spirocycles in a controlled and stereoselective manner.5
This review focuses specifically on spirocyclic oxindoles (spirooxindoles or spiroindolones). These are a widespread motif within modern organic synthesis, drug discovery and natural product chemistry. Stereoselective synthetic methods towards this privileged class of spirocycles have seen enormous development in recent years. This review aims to combine the analysis of recent synthetic strategies with an overview of the importance of these scaffolds for medicinal chemistry and in natural product synthesis. Since 1950 there have been 6896 publications containing spirooxindoles, 3283 of these publications have appeared since 2012.15 Oxindoles are often used as rigid scaffolds for testing new asymmetric synthetic methodology and due to the demand of discovery chemistry for controlled and modular syntheses, and with the plethora of publications in this area, we will focus on stereoselective processes. This review examines spirocyclic oxindoles containing a spiro-(3 to 8)-membered ring, in turn, analysing carbocyclic then monoheteroatom nitrogen-containing and oxygen-containing spirocycles. The review will cover recent developments from 2013, following major work by Singh and Desta,6 until April 2020. Specific bioactivity and applications of each ring system will be discussed at the start of the relevant section and provide a reference work for the preparation of different spirocyclic patterns. Within each section, the discussion is split by the reaction type employed to construct the spirocycle.
Fig. 1 shows a representative set of each ring system, which will be covered in this review, as they feature in medicinal or natural products.7 Notable biological activity is indicated, including use as anti-cancer agents,8 and anti-viral agents.9 Some ring types are not represented in these bioactive compounds, i.e. aziridines, likely due to their instability relative to larger ring sizes, but will nonetheless be featured in the review.
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| Fig. 1 Bioactive and naturally occurring spirooxindoles. | |
Given the importance of this structural class, spirocyclic oxindoles have been featured in other reviews discussing their synthesis,10 including asymmetric synthesis,11 use of isatin starting materials12 or the synthesis of target product scaffolds.13 General reviews on spirocyclic compounds (i.e. spiroindolenes) also often contain spirocyclic oxindoles without specifically focusing on these.14 We expect the analysis presented in this review of the structural types, synthesis and applications to lead to further studies, and aid in the identification of future opportunities to expand the applications of this fascinating class of compounds.
Frequency analysis of spirooxindoles
To quantify the importance of spiroindolones in the medicinal chemistry and organic synthesis literature, we analysed publications which feature spiroindolones containing up to one heteroatom in the spirocycle between 1970–2020 (Fig. 2).15 The number of publications in which these structures feature has grown significantly over the last 50 years and has consistently reached numbers above 400 per year since 2013. Even accounting for the generalised increase in publications, this represents an extensive level of attention. The number of publications on 5- and 6-membered rings (silver and gold in Fig. 2) dominates the contribution to this total. However, in the last decade the relative contribution of 3-, 4- and 7-membered spirocycles (dark/light blues and orange) has increased.
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| Fig. 2 Incidence of 3-to 7-membered spirooxindoles in the literature up to April 2020. No. of heteroatoms in ring ≤1.15 | |
We also analysed the frequency of the different types of rings which feature in this review (Fig. 3). Considering 3-membered spirocycles, we can see that cyclopropane rings are much more common than their aziridine or epoxide analogues. Similarly, cyclobutanes far outnumber azetidines or oxetanes. Notably the number of oxetanes is surprisingly low, especially, when compared to azetidines. The position of the heteroatom has a significant influence on the frequency of a certain ring. This may generally correlate with ease of synthesis or lower complexity, i.e. 3,4′-spirotetrahydropyran oxindoles far outnumber the 3,2′- or 3,3′-analogues. 7-Membered rings are generally underrepresented when bridged examples are discounted (these will generally have been counted in the numbers for other ring sizes as these are a less significant contribution). There is only one example of a non-bridged mono-heteroatom containing 8-membered spirooxindole in the literature (synthesised as an analogue of cipargamin).16
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| Fig. 3 The spirocyclic rings covered in this review and the number of hits for each heteroatom position.15aBeta-lactams or derivatives thereof. bNumbers in brackets indicates bridged examples. | |
Although there will be a clear correlation between the number of publications for each ring size, we have tried to discuss each ring type on an equal basis, though inevitably the 5-membered nitrogen section is largest.
Three-membered rings
Spirocyclopropyl oxindoles
Three-membered ring containing spiroindolones feature in pharmaceutical compounds as well as being used as reactive intermediates, i.e. in ring opening reactions.17 These ring opening reactions can often be coupled with ring closing reactions to form spirocycles of larger ring size. There has recently been an excellent review on the catalytic enantioselective synthesis of polysubstituted spirocyclopropyl oxindoles by Cao and Zhou,18 as well as a review of transition metal-free strategies by Ashfeld.19
Applications.
Spirocyclopropyl oxindoles are featured in a wide variety of reports showing their bioactivity (see Fig. 1 for examples). These bioactivities include examples of antitumour agents,20 pain treatment,21 treatment of CNS disorders,22 antivirals,23 among others.24
Direct methylene cyclopropanation.
Direct cyclopropanation methodology with unprotected oxindoles has been a synthetic challenge which has seen many recent advances (Scheme 1). In 1987, a team at Lilly synthesised spirocycle 2 as a route to a phosphorodiesterase inhibitor (Scheme 1A).25 Since this low yielding and step-inefficient synthesis using strong base, Marini reported cyclopropanation using a vinyl selenone reagent in a domino Michael addition and cyclisation sequence (Scheme 1B).26 When aryl-substituted vinyl selenone reagents were used, high dr of the cyclopropane was observed with the aromatic rings in a cis-relationship. In 2017, Qian reported the use of a vinyl sulfonium salt in a zinc-mediated cyclopropanation (Scheme 1C).27 This reaction was notable for its broad functional group tolerance and application to late-stage functionalisation of complex scaffolds. Following Qian's report, Feng and Qu showed that a bromoethylsulfonium salt could be used in a similar process without the need for the Zn(OTf)2 additive (Scheme 1D).28 Recently, Hajra reported a domino Corey–Chaykovsky reaction for obtaining the spirocyclic oxindole from the corresponding isatin, spiroepoxide or spiroaziridine (Scheme 1E).29 Initially using standard Corey–Chaykovsky reaction conditions and generating the sulfur ylide from trimethyl sulfoxonium iodide, Hajra showed the ring opening of the epoxide followed by elimination to form the alkene and subsequent Corey–Chaykovsky reaction to the cyclopropane. In a similar manner, aziridines could be used as starting materials. Significantly the corresponding isatin could be used as starting material by increasing the equivalents of sulfoxonium iodide and sodium hydride. This works by generating the epoxide in situ followed by the optimised (ring opening/elimination) cyclopropanation reaction. All of these methods to access unprotected spirocyclic oxindoles also work with standard protecting groups in place.
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| Scheme 1 Summary of recent advances in direct cyclopropanation of unprotected oxindoles. | |
Cyclopropanation with diazo compounds.
A similarly active field is the direct cyclopropanation of 3-diazooxindoles. Diastereoselective cyclopropanations have been independently developed by Muthusamy, Subba Reddy and Padwa.30 The first enantioselective versions were developed at similar times by Arai (up to 74% ee using chiral Rh cat. 3),31 Zhou (up to 99% ee using Hg(OTf)2 and a chiral phosphine ligand 4)32 and Zhou with Ding (up to 95% ee using a Au catalyst with chiral phosphine ligand 5) (Scheme 2).33 Since 2013, Qiu and Xu used chiral Rh cat. 6 to achieve up to 99% ee in the enantioselective cyclopropanation reaction with high ee for allyl alkene examples which performed poorly in previous reports.34 Zhou and Ma have used the Au/5 system developed previously by Zhou for the cyclopropanation with alkenes bearing a difluoromethyl group.35 Iwasa used chiral Ru(II) complex 7 to generate spirocyclopropyl oxindoles with high ee.36 Ashfeld reported a cyclopropanation/ring expansion cascade reaction between 3-diazooxindoles and vinyl isocyanate, in the case when the temperature was reduced from 50 °C to rt, the cyclopropane intermediate could be isolated as one diastereomer.37
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| Scheme 2 Advances in enantioselective cyclopropanation of 3-diazooxindoles. | |
In 2014, Lu and Xiao showed a [3 + 2]-cycloaddition between 3-ylideneoxindoles and in situ generated 2,2,2-trifluorodiazoethane could afford a pyrazoline which upon heating under reflux in toluene would ring contract to afford 3,3′-cyclopropyl spirooxindoles.38 Using chemistry first developed by Carreira,39 sodium nitrite was used to oxidise 2,2,2-trifluoroethylamine·HCl to generate 2,2,2-trifluorodiazoethane which can undergo a [3 + 2]-cycloaddition with the electron deficient alkene followed by heating to liberate N2 and form the cyclopropane with high yield and dr (Scheme 3). Using a similar cycloaddition and ring contraction strategy, Babu demonstrated the synthesis of aryl substituted 3,3′-cyclopropyl spirooxindoles while Han and Chen have reported the synthesis of difluoromethyl substituted spirocyclic cyclopropanes.40,41 A significant advance in this methodology accesses enantioenriched spirocyclic cyclopropanes through a 1,3-dipolar cycloaddition between dimethyl (diazomethyl)phosphonate and 3-ylideneoxindoles followed by ring contraction mediated by NCS or NBS (this also caused chlorination/bromination by SEAr).42 Peng used thiourea catalyst 8 derived from a cinchona alkaloid to induce enantioselectivity in the pyrazoline formation and this ee was retained in the 5- to 3-membered ring contraction (Scheme 3).
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| Scheme 3 1,3-Dipolar cycloaddition followed by ring contraction to 3,3′-cyclopropyl spirooxindoles. | |
Cyclopropanation of 3-ylidene oxindoles.
He developed a phosphorus mediated reductive cyclopropanation of 3-ylideneoxindoles (Scheme 4).43 P(NMe2)3 in combination with α-ketoesters formed a Kukhtin–Ramirez adduct which behaves as a carbene surrogate and can undergo cyclopropanation via a reported Michael addition and intramolecular SN2 reaction liberating triphenylphosphine oxide and the cyclopropyl spirooxindoles in high dr. Lu and Xu developed a related reaction mediated by dialkyl phosphite to couple isatins and α,β-unsaturated ketones.44 In 2017, Xu reported the formation of Kukhtin–Ramirez adducts from isatins and their reactions with dienes to form spirocyclopropanes (Scheme 4).45
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| Scheme 4 P(NMe2)3-mediated reductive cyclopropanation via Kukhtin–Ramirez (K–R) adduct and K–R adduct reaction with diene activated by PPh3. | |
Du developed a Michael addition/alkylation cascade reaction between 3-chlorooxindoles and arylidenepyrazolones, alkenyl thiazolones (also developed by Sheng and Feng) or, more recently, 2,3-dioxopyrrolidines.46 In a quite distinct method, a Ni-catalysed enantioselective cyclopropanation developed by Feng utilised phenyliodonium ylides to generate a free carbene which can react with 3-ylideneoxindoles to generate 3,3′-cyclopropyl spirooxindoles in high yield, dr and ee (Scheme 5).47 More recently, Feng used a related system for the Mg catalysed reaction of 3-ylidene oxindoles and sulfonium ylides.48
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| Scheme 5 Ni-Catalysed enantioselective cyclopropanation with phenyliodonium derived ylides. | |
Other approaches.
In 2013 Charette described an intramolecular C–H arylation of cyclopropanes to access 3,3′-spirocyclopropyl spirooxindoles (Scheme 6).49 Using Pd(OAc)2 with PCy3 as a ligand in combination with K2CO3 and Ag3PO4 in toluene at 130 °C afforded high yields of the spirooxindole. When aryl substituted cyclopropanes were employed high dr was observed.
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| Scheme 6 Pd-Catalysed C–H arylation to form 3,3′-spirooxindoles. Cy = cyclohexane. | |
Wang reported an enantioselective Satoh–Miura type reaction using a RhIII catalyst 10 to perform a dual C–H activation forming an axially chiral spirocycle in high enantioselectivity (Scheme 7).50
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| Scheme 7 Enantioselective synthesis of axially chiral oxindoles by Rh catalysed dual C–H activation. | |
Spiroaziridinyl oxindoles
Spiroaziridines don't commonly feature in natural products or medicines, but are utilised in synthesis, and protected versions could be envisaged to be of use in biology.
From 3-bromooxindoles.
Zhang and Peng employed 3-bromooxindoles as nucleophiles in an enantioselective Mannich reaction catalysed by cinchona alkaloid derived cat. 11 (Scheme 8).51 Cyclisation mediated by silver nitrate afforded the aziridine in high yield and with retention of the ee induced in the prior step.
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| Scheme 8 Enantioselective Mannich reaction followed by cyclisation. | |
From 3-ylidene oxindoles.
Traditional, non-stereoselective approaches to aziridination employ ethyl nosyloxycarbamate and calcium oxide with 3-ylideneoxindoles.52 Xu and Wang, and Chen independently reported an aziridination of 3-ylideneoxindoles using hydroxycarbamate derivatives to afford a single diastereomer (Scheme 9).53
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| Scheme 9 Aziridination of 3-ylideneoxindoles with carbamate protected amines. TMG = 1,1,3,3-tetramethylguanidine. | |
From azirines.
In 2016, Xu and Yuan reported an asymmetric Neber reaction catalysed by (DHQD)2PHAL (Scheme 12).57 Good enantioselectivity was achieved in the Neber reaction to form the azirine. Sodium borohydride was used to reduce the azirine, although the er and dr of the resulting aziridine was not reported.
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| Scheme 12 Asymmetric Neber reaction followed by reduction to spiroaziridine. | |
Spiroepoxy oxindoles
Applications.
There are two recent examples of spiroepoxides in medicinal chemistry for antibacterial activity as well as activity in Neuroblastoma cell lines (Fig. 1).58 Spiro-epoxyoxindoles are also attractive synthetic building blocks.59
Epoxidation of isatins and isatin derivatives.
Though non-stereoselective, notable advances in the synthesis of spiro-epoxyoxindoles have been made recently by Wang and Zhang,60 and Pace.61 Diastereoselective epoxidations have been developed,62 notably the use of a trifluoroethylsulfonium salt in a Corey–Chaykovsky reaction by Cheng and Zhai.63 Lin and Jin recently developed a diastereoselective epoxidation mediated by visible light.64 Bencivenni was able to form axially enantioenriched 3-methylene oxindoles through a Knoevenagel condensation and, upon epoxidation, the high axially chiral enantioenrichment was maintained with a 5:1 dr.65
The first report of an enantioselective epoxidation to form a spiro-epoxyoxindole was by Metzner and Briere in 2007, though only one example with 30% ee was given.66 In 2011, Gasperi developed a moderately stereoselective epoxidation of 3-ylideneoxindoles using tert-butyl hydroperoxide with a prolinol catalyst.67 More recently, Gasperi reported a full study of this work and disclosed a highly enantioselective epoxidation reaction of this type, when the oxindole protecting group was Boc, though the diastereoselectivity was poor.68 In 2014, Xiao reported the use of camphor-derived sulfonium salts in an asymmetric epoxidation of isatins (Scheme 13).69 Substitution on the oxindole did not significantly affect the high enantioselectivity, though changing the R group on the sulfonium salt did reduce the enantioselectivity slightly. Feng described an enantioselective Darzens reaction to synthesise spiro-epoxyoxindoles using L-12 as a hydrogen bonding ligand to induce enantioselectivity in an aldol reaction which is followed by cyclisation to afford the three-membered ring (Scheme 13).70 Lower enantioselectivities were observed when the aryl group of the acyl bromides or the fused oxindole ring were substituted (ee <85%).
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| Scheme 13 Enantioselective epoxidations using Darzens reactions. | |
Improved enantioselectivity was achieved by Wong in 2017 in an asymmetric Darzens reaction using diazoacetamides (Scheme 14).71 High yields and enantioselectivities (up to 99% ee) were observed using a titanium/BINOL complex and this reaction had a broad scope without reduction in enantioselectivity.
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| Scheme 14 Asymmetric Darzens reaction developed by Wong. | |
Other approaches.
Recently, catalytic ring opening of spiroepoxides have been used to form enantioenriched products in a kinetic resolution. Sun, Hong and Wang used Bn-protected indole and napthols in an asymmetric phosphoric acid catalysed epoxide ring opening which resolved the racemic substrate to give one enantiomer in up to 99% ee.72 Zhou and Gao have developed a P(NMe2)3-mediated reductive epoxidation via a Kukhtin–Ramirez adduct similar to Scheme 4.73 High diastereoselectivity could be achieved in this coupling of isatins with aldehydes.
Four-membered rings
Spirocyclobutyl oxindoles
Applications.
Spirocyclobutane oxindoles have shown biological activity against a wide variety of targets and disease areas, including phosphodiesterase inhibition74 (for treatment of Schizophrenia, Parkinson's or Huntington's), bromodomain inhibition,75 progesterone receptor antagonists76 and antivirals (see Fig. 1 for example structures).77
Natural product synthesis.
Welwitindolinone A (Fig. 1) has inspired many approaches in total synthesis from the Baran78 and Wood laboratories.79
Advances in stereoselective spirocyclobutane oxindoles have been mainly limited to achievements in C–H activation chemistry and [2 + 2]-cycloadditions.
Metal-catalysed C–H activation/coupling.
Inspired by Overman's study of asymmetric Heck cyclisations to spirocyclic oxindoles,80 Sunoj and Kundig developed a Pd-catalysed enantioselective C–H arylation reaction to afford oxindole spirocycles of varying ring size (Scheme 15).81 The spirocyclic cyclobutane was formed in high yield, albeit with lower enantioselectivity than other ring sizes.
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| Scheme 15 Pd-Catalysed enantioselective C–H arylation. | |
Baudoin formed 3-cyclobutyl N-methyl-oxindole through C–H activation when trying to develop an arylation/electrocyclic cascade reaction.82,83 Xu could form the same unsubstituted cyclobutane, as well as 5- and 6-membered analogues, in an intramolecular 1,5-HAT using aryl iodides by visible light photoredox catalysis.84 Gouverneur recently developed a silyl radical-mediated hydrosulfamoylation using sulfonyl chlorides and could effect a cascade spirocyclisation (Giese-type addition followed by aryl C–H transfer) from cyclobutene 15, albeit with only poor diastereoselectivity (Scheme 16).85
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| Scheme 16 Visible light mediated cascade spirocyclisation. | |
[2 + 2]-Cycloaddition.
A significant advance in spirocyclobutyl oxindole synthesis was made by Wang and successively by Jørgensen in 2014/2015 in the field of organocatalytic [2 + 2]-cycloadditions of 3-ylideneoxindoles (Scheme 17). Wang reported a [2 + 2]-cycloaddition of 3-ylideneoxindoles and enals catalysed by α,α-diphenyl prolinol cat. 16.86 Jørgensen further developed this type of reaction using a similar prolinol cat. 17 to mediate a cyclopropane ring opening to form a proposed dienamine which can undergo the [2 + 2]-cycloaddition.87
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| Scheme 17 Advances in organocatalytic [2 + 2]-cycloaddition of 3-ylideneoxindoles with α,β-unsaturated aldehydes, either directly or in situ generated. | |
Yan in 2016 and then Guan and He in 2017 have independently published a photocatalysed [2 + 2]-cycloaddition of 3-ylideneoxindoles to form a bispirooxindole cyclobutane as a single diastereomer (Scheme 18).88 Out of a possible 8 diastereomers, one diastereomer was formed in the cycloaddition reaction.
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| Scheme 18 [2 + 2]-Photocycloaddition of 3-ylideneoxindoles. | |
Spiroazetidinyl oxindoles
There are very few examples of spirocyclic azetidinyl oxindoles. Indeed, an analysis of all N-containing 4-membered 3,2′-spiro oxindole structures shows that all of them are beta-lactams or derivatives. Whereas for the corresponding 3,3′-spirocycles only one out of 332 is a β-lactam or derivative thereof (yet these are typically symmetrical and easily installed via traditional methods and do not feature heavily in this section). β-Lactams dominate the nitrogen containing bioactive compounds. This may reflect the lack of synthetic methods towards the unsubstituted spiroazetidinyl oxindoles.
Applications.
Spiroazetidine/spiro-β-lactam oxindoles have shown activity as antivirals,89 antibacterials,90 antifungals91 and insecticides (Fig. 1).92
Natural product synthesis.
In terms of total synthesis, Weinreb explored the synthesis of chartelline A via the spiro-β-lactam oxindole as a key intermediate (Fig. 4).93
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| Fig. 4 Structure of chartelline A. | |
‘Traditional’ non-stereoselective methods.
Notable examples of non-stereoselective β-lactam formation are [2 + 2] cycloadditions between diazo compounds and isatin derived ketimines or reaction of bromoacetyl bromide or chloracetyl chloride with isatin derived ketimines.94
Annulations using NHC catalysis.
There have been significant advances in the stereoselective synthesis of β-lactam containing spirooxindoles by organocatalysed annulation of ketimine derived isatins. In 2014, Ye reported an asymmetric Staudinger reaction of ketenes with isatin derived ketimines catalysed by NHC 18 (Scheme 19A).95 In 2017, Xu and Ren developed an NHC catalysed asymmetric Mannich reaction between aldehydes and isatin derived ketimines using cat. 19 in combination with oxidant 20 (Scheme 19B).96 Both of these reports demonstrated Boc deprotection of the β-lactam using either silica gel in toluene under reflux or trifluoroacetic acid in 1,2-dichloroethane, affording the unprotected β-lactam in 95% and 98% ee respectively. In 2019, Deng reported an isothiourea (HBTM, 21) catalysed asymmetric Mannich reaction between ketimines and carboxylic acids (Scheme 19C).97 Deng's work does not use an NHC catalyst and uses a relatively more stable starting material while yielding the products in very high enantioselectivity.
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| Scheme 19 Organocatalysed beta-lactam formation from isatin derived ketimines. | |
Annulations using Cu/guanidinium catalysis.
In 2014, Shanmugam reported a copper-catalysed one-pot, three-component diastereoselective synthesis of 3-spiroazetidinimine-2-oxindoles as masked β-lactams (Scheme 20A).98 The spirocycle was built with high anti-diastereoselectivity.99 In 2018, Liu advanced this type of reaction in a highly diastereoselective and enantioselective variant using a chiral guanidinium ligand L22 (Scheme 20B).100
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| Scheme 20 Cu-Catalysed one-pot, three component synthesis of spiroazetidinimine oxindoles from isatin derived ketimines. | |
Azetidines from allene activation.
The two main advances in the synthesis of spiroazetidine oxindoles (non-2-azetidinone structures) are from the Silvani lab in 2016 and 2017 involving allene activation. In 2016, Silvani reported a DABCO catalysed annulation of tert-butyl sulfinyl ketimines with allenes to form spiroazetidinyl oxindoles in high dr (Scheme 21).101 This could be followed by HCl mediated deprotection of the Ellman auxiliary affording the spiroazetidine in 64% yield. In 2017, Silvani published a follow up study using cinchona derived organocatalyst 23 for the same reaction with a tBus protecting group instead of the Ellman auxiliary and generating the spiroazetidine in up to 83:17 er (Scheme 21).102
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| Scheme 21 Diastereoselective formal 2 + 2 annulation of N-sulfinylketimines and allenes by Silvani. Development of an enantioselective reaction employing a quinine derived nucleophilic catalyst with N-sulfonylketimines by the same authors. | |
By nucleophilic addition.
Other recent advances involve nucleophilic addition to isatin or isatin derived ketimines. In 2016, Xu developed an asymmetric Reformatsky reaction of tert-butyl sulfinyl isatin ketimines and ethyl bromoacetate to afford a disubstituted isatin in high yield with high diastereoselectivity (Scheme 22).103 Zhang developed an asymmetric allylboration of isatin mediated by a chiral amino alcohol (Scheme 22).104 Both Xu and Zhang showed how this diastereoselectivity could be converted to highly enantioenriched products in 4/5 steps. Noda and Shibasaki developed an asymmetric Mannich reaction mediated by a cinchona alkaloid dimer (Scheme 22).105 The enantioenriched product could be converted to a spirocyclic β-lactam in 2 steps involving Zn mediated N–O bond cleavage followed by lactamisation mediated by HCTU.
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| Scheme 22 Examples of enantioselective addition to ketimines or isatins followed by elaboration to β-lactam spirocycles. | |
Spirooxetanyl oxindoles
Applications.
Spirooxetanes have featured in only two recent reports for bioactivity in a Merck patent for kinase inhibitors,106 as well as in an SAR study (see below, ref. 109).
Non-stereoselective methods.
As developments in stereoselective formation of spirooxetanes have been limited since 2012 (with the lowest number of hits out of any of the structures considered in this review), it is worthwhile mentioning papers that form spirooxetanes without stereoselectivity. Zhang formed spirocyclobutanes from a cascade spirooxetane/cyclopropane ring opening reaction using BF3·Et2O.83 The oxetane starting materials were synthesised in a [2 + 2]-cycloaddition from the isatin and a tetrasubstituted alkene such as 1,1′-bi(cyclopropylidene).107 In 2019, Marini reported a domino reaction of 3-hydroxyindoles and phenyl vinyl selenone.108 Using KOH in aqueous conditions Marini showed that protected or unprotected isatins could be used to produce a variety of 3,2′-spirooxetanes in 34–73% yield. Lindsley synthesised 3,3′-spirooxetane 24 from the corresponding isatin in 3 steps in an SAR study to find a sub micromolar and selective M5 (muscarinic acetylcholine receptor 5) positive allosteric modulator for the treatment of a variety of neurological diseases.109 Final treatment of the diol with triflic anhydride afforded the oxetane in only 6% yield (Scheme 23).
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| Scheme 23 3-Step sequence to oxetane 24 in a SAR study towards a selective M5 positive allosteric modulator. | |
Lewis acid catalysed cycloaddition.
In 2014, Feng reported the reaction of isatins with ketenes catalysed by an N,N′-dioxide ligand and Sc Lewis acid to form spirooxetanones.110 In terms of optimisation, Feng reported that a N-Bn protecting group gave a significant improvement in ee compared to Me and molecular sieves increased the yield. The reaction was tolerant of a range of electronics on both aromatic rings giving high yield, dr and ee (Scheme 24).
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| Scheme 24 Enantioselective [2 + 2]-cycloaddition to form spirooxetanones. | |
Five-membered rings
Spirocylopentyl oxindoles
Applications.
Spirocyclopentyl oxindoles feature in many natural products and active pharmaceuticals (see Fig. 1 and 5). For example, neosurugatoxin is a specific antagonist of nicotinic acetylcholine receptors.111 This core scaffold has also been developed for treatment of migraine, which is discussed in the relevant section (ref. 139), as well as bromodomain inhibitors.75
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| Fig. 5 Selected cyclopentane spiroindolones in nature. | |
Natural product synthesis.
Spirocyclopentane oxindoles have been the focus of many total synthesis studies, with several of these appearing since 2013. Martin reported the total synthesis of (−)-citrinadin A, forming the spirocyclopentane oxindole in an epoxidation/semi-pinacol rearrangement cascade using Davis’ oxaziridine reagent (Scheme 25).112 Selective epoxidation of the indole C2C3 followed by stereoselective collapse of the epoxide results in spirocyclopentane formation. Sarpong, Simpkins, Sun and Li have reported total syntheses of numerous natural products using a similar spirocyclisation strategy employing various epoxidising reagents.113 A recent study of the biosynthetic spirocyclisation of the paraherquimides (related natural products) by Sherman and coworkers showed that this semi-pinacol rearrangement was the biosynthetic pathway to these spirooxindoles.114 Wood synthesised (+)-Citrinadin B forming the spirocyclopentane in a Pd-catalysed enyne cyclisation, initially developed by Trost.115 Trost has developed an asymmetric [3 + 2] Pd-trimethylenemethane (TMM) cycloaddition to form the spirocyclopentane core of Marcfortine B and C (Scheme 25).116 Lewis developed an efficient complexity generating spirocyclisation heating phenylenediamine and 26 to form the spirocyclopentane, by ring opening of the ester and ortho-alkylation by a Friedel–Crafts reaction, in 64% yield and 3.7:1 dr as a precursor to surugatoxin aglycone (Scheme 25, for structure of natural product see Fig. 5).117 Zhang and Jia recently described the total synthesis of similisines A and B (Fig. 5), enantiomeric trisindole structures containing a spirocyclopentane oxindole core, through a key acid-mediated Friedel–Crafts cyclisation, though this was low yielding and non-stereoselective.118
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| Scheme 25 Selected examples of spirocyclisation to cyclopentanes in total synthesis. | |
[3 + 2]-Cycloaddition.
A significant route for construction of cyclopentane spirooxindoles has been through [3 + 2] cycloaddition utilising Morita–Baylis–Hillman (MBH) carbonates, either to react with or situated on the isatin core.119,120 Recent highlights include Chen's demonstration of a [3 + 2]-cycloaddition between isatin derived MBH carbonates and 3-ylidene oxindoles to form bispirooxindole products in high diastereo- and enantiocontrol (Scheme 26A).121 In 2019, Chen described the [3 + 2] cycloaddition of isatin-derived MBH carbonates with β,γ-unsaturated α-keto esters using asymmetric nucleophilic catalyst 27 derived from quinidine (Scheme 26B).122,123
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| Scheme 26 Selected isatin derived MBH carbonates in a cycloaddition with 3-methyleneoxindoles and β,γ-unsaturated α-keto esters. | |
Further advances in this field have been made using asymmetric phosphorus catalysis to activate allenes, MBH carbonates or alkynones to form spirooxindoles.124,125 In Lu and Mei's 2019 report threonine derived cat. 28 was found to give the highest yield and enantioselectivity in Et2O for the [3 + 2] annulation of isoindigos and allenes (Scheme 27).126 Lu and Mei additionally showed unsymmetrical isoindigos in this process with high regiocontrol, as well as the formal syntheses of a number of complex natural products. Lu, with Ullah, then reported the annulation of pyrazoloneyldiene oxindoles with MBH carbonates using asymmetric phosphorus catalyst, SITCP 29 (Scheme 27).127 Both routes exploit the regioselective addition of the activated electrophile (MBH carbonate or allene) to the more electrophilic alkene carbon. Related reactions have been developed using isocyanides to activate similar electrophiles including allenes.128
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| Scheme 27 Lu and coworkers’ achievements in asymmetric phosphine catalysed activation of electrophiles to form spirocyclopentene scaffolds. | |
Domino Michael addition/aldol (or alternative cyclisation)
In 2011, Barbas III designed a bifunctional thiourea catalyst 30 for the domino Michael addition/aldol reaction to form bispirooxindoles from 3-substituted oxindoles and 3-methylene oxindoles (Scheme 28).129 Since, this Michael addition/cyclisation strategy based upon hydrogen bonding catalysis has been employed to access spirocyclopentane oxindoles on a large number of occasions.130 Notable examples include Kanger's use of 3-ylidene oxindoles undergoing asymmetric thiourea catalysed Michael addition alpha to the nitro group of a γ-nitroketone and spontaneous stereoselective aldol formation (determined by stereochemistry of the first step) to give the five-membered ring (for a related reaction see Scheme 75).131 Johnston and Cordova used a prolinol aminocatalyst to promote a Michael addition between an alkyne substituted oxindole and an α,β-unsaturated aldehyde followed by cyclisation to form an enantioenriched spirocyclopentane with moderate dr.132 Shi has utilised asymmetric phosphoric acid catalysts to employ various vinyl indoles to react with 3-ylidene oxindoles, formed in situ from 3-indolylmethanol, in a Michael/alkylation cascade.133
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| Scheme 28 Barbas III's seminal work on an enantioselective domino Michael/aldol cyclisation. | |
NHC catalysis.
In 2017, Wang reported a Michael addition/intramolecular aldol/lactonization cascade of enals with 3-methylene oxindoles using an azolium NHC catalyst.134,135 Up to 99% ee and >99:1 dr was achieved using cat. 31 and DIPEA for the spirooxindole products (Scheme 29A). Subsequently, Enders published a related study where fused β-lactam spirooxindoles could be formed (Scheme 29B).136 Enders also showed that using a different NHC catalyst (cat. 33), base and solvent, a different spirocyclopentane scaffold could be formed in good yield and high dr and er (Scheme 29C). This switchable reactivity occurs from the same intermediate formed by Michael addition. This intermediate can then undergo either (B) intramolecular Mannich reaction then lactamisation or (C) aza-Dieckmann type cyclisation and tautomerisation.
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| Scheme 29 Work by Zhang and Enders using NHC catalysis to synthesise diverse spirocylopentanyl oxindoles. | |
Phase transfer catalysis.
Zhao and Shang reported a tandem Michael/Michael addition sequence catalysed by an asymmetric phase transfer catalyst.137 Employing phosphonium phase transfer catalyst 34, deprotonation of the malonate initiates Michael addition to the 3-ylidene oxindole followed by subsequent Michael addition to the α,β-unsaturated ester (Scheme 30). Significant reduction in enantioselectivity was observed when attempting to form the six-membered analogue. Zhao and Zou also reported an ammonium phase transfer catalysed asymmetric vinylation of 3-phenyloxindoles which were shown to undergo Pd-catalysed Heck cyclisation and oxidative cleavage to give a spirocyclopentane oxindole with retention of ee.138
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| Scheme 30 Phase transfer catalysed enantioselective double Michael addition chemistry to spirocyclopentanes. | |
Spirocyclopentanyl oxindoles feature in a number of lead Calcitonin Gene-Related Peptide (CGRP) medicines developed by Merck, and more recently Sosei Heptares, for treatment of migraine (Fig. 6).139
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| Fig. 6 Selected developments in structures of CGRP inhibitors. | |
Towards an efficient asymmetric synthesis of the spirocyclopentane core of these compounds Merck developed an enantioselective phase transfer catalysed spirocyclisation.140 Using a doubly quaternised cinchona alkaloid derived phase transfer catalyst 35 up to 96% ee was achieved for the transformation of substrates such as 36 to 37 in quantitative yield which could conceivably be elaborated via the halogenated pyridine (Scheme 31). Merck subsequently collaborated with Houk to model how the novel phase transfer catalysts promote the reaction and induce enantioselectivity (Scheme 31).141 They proposed three key electrostatic interactions: (1) hydrogen bonding between the hydroxyl of the catalyst and the oxindole enolate; (2) a chloride–CH interaction activating the leaving group; (3) a π–π interaction between the pyridine of the formed cyclopentane and the quinicludine benzyl group. Merck also recently published on the monitoring of the reaction kinetics of these inherently complex, dual-phased reaction mixtures in an automated fashion.142 These studies remain a significant advance in asymmetric phase transfer catalysis, as well as in the synthesis of enantioenriched spirooxindoles.
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| Scheme 31 Merck's development of a phase transfer catalysed spirocyclisation and model for the enantioselectivity developed in collaboration with Houk. | |
Metal/Lewis acid mediated approaches.
Feng used a Mg/N,N′-dioxide catalyst system in a Michael/Friedel–Crafts/Mannich cascade of isocyanides to generate enantioenriched polycyclic spirocyclopentanes resembling strychnos alkaloids.143 Franz recently used an Sc/pybox system for the [3 + 2]-cycloaddition of allenes with 3-ylidene oxindoles.144 In a distinct strategy, Su and Yang developed a Pd-catalysed [3 + 2] annulation of spirovinylcyclopropyl oxindoles with α,β-unsaturated nitroalkenes (Scheme 32).145 Using Pd(OAc)2 and Xantphos in toluene the spirovinylcyclopropyl is ring opened to form a amphoteric π-allyl species which undergoes the [3 + 2] annulation in a diastereoselective manner, invoking a π-stacking between the aromatic ring of the oxindole and the aromatic substituent of the nitroalkene. Rios had previously developed a similar strategy showing one example with 76% ee using a prolinol catalyst with α,β-unsaturated aldehydes.146
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| Scheme 32 Pd-Catalysed [3 + 2] annulation of spirovinylcyclopropyl oxindoles. | |
C–H activation/cross-coupling.
Cross-coupling methodologies have been extensively utilised to access spirocyclopentane oxindoles.147 Related to Trost's development of Pd-catalysed cyclisations towards the Marcfortines (see Scheme 25), Córdova has developed an iminium catalysed asymmetric Michael addition/Pd-catalysed intramolecular allylic alkylation.148 Trost has continued to innovate in this field, developing new Pd-catalysed [3 + 2]-cycloadditions from allene and CF3-containing trimethylenemethane precursors with application to enantioenriched spirocyclopentane oxindoles.149
Taylor et al. reported a Cu(II)-mediated double C–H/Ar–H coupling of bis-anilides to form bispirooxindoles (Scheme 33).150 This strategy was notable for the trans-diastereoselectivity observed and the flexibility in increasing the size of the central ring. Larhed and co-workers, in collaboration with AstraZeneca, have built on their previous work on the Heck–Mizoroki reaction to generate functionalised cyclopentenes,151 to develop an intramolecular variant. Exploiting the selectivity of the Heck–Mizoroki reaction to afford spirocyclopentenes with high diastereocontrol (Scheme 33).152 García-López and others have reported C–H activation and carbene insertion procedures to afford spirocyclopentanes.153
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| Scheme 33 Selected C–H activation and cross-coupling procedures to access spirocyclopentane. | |
Related to these C–H activation approaches is the stereoselective oxidation of spirocyclopentane oxindole C–H bonds using Ru or Mn catalysis.154 Initially developed by Bach in 2014, selective oxidation of one of the enantiotopic carbons of the cyclopentane gave cyclopentanones in high er.
Other approaches.
Taylor and Unsworth have a program of work on the synthesis of diverse spirocycles. In 2016, they described the controlled synthesis of two diastereomers of a spirocyclopentanyl oxindole from the same intermediate.155 Treatment of a ketodiazo with Rh2(oct)4 in the presence of air afforded the diketone which under either acidic or basic conditions provided the opposite diastereomers of the spirocyclopentanol (Scheme 34).
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| Scheme 34 Taylor and Unsworth's approach using indole nucleophilicity. | |
Spiropyrrolidinyl oxindoles
Applications.
Spiropyrrolidine oxindoles are applied widely in medicinal chemistry. Indeed, many of the natural products featuring a 3,3′- or 3,2′-spiropyrrolidinyl motif display a wide variety of bioactivities.156 One of the most significant pharmaceuticals is MI-888 (Fig. 7), a 3,3′-spiropyrrolidine containing MDM2 inhibitor against tumour growth.157 The success of this ligand has inspired many other derivatives,158 including proteolysis targeting chimeras (PROTACs)159 and a molecular glue.160 Other applications of spiropyrrolidines include anticancer,161 treatment for Alzheimer's,162 diabetes,163 HIV164 and tuberculosis.165
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| Fig. 7 Selected examples of bioactive 3,3′-spiropyrrolidinyl oxindoles. | |
Natural product synthesis.
Spiropyrrolidinyl oxindoles, particularly spiro-3,3′-pyrrolidinyl oxindoles, have been the target and inspiration for many total syntheses.166 Horsifilene and coerulescine (Fig. 7) are undoubtedly the simplest spiropyrrolidinyl oxindoles in nature and have been the focus of short, elegant total syntheses.167 For more complex products, a general approach is to synthesise the corresponding annulated indole (termed a β-carboline, typically synthesised via a Pictet–Spengler reaction) and perform an oxidative rearrangement with tBuOCl. This reduces the problem down to the construction of the β-carboline (typically from tryptophan) and these products have received significant synthetic attention.168 This was the strategy used by Cook in his total syntheses of (iso)affinisine oxindole and (iso)alstonisine,169 Xu in the nine-step total synthesis of (−)-strychnofoline,170 Zhang in the synthesis of multiple spirotryprostatins171 and more recently in She's total synthesis of (−)-gardmultimine A (for structures see Fig. 7 and Scheme 35).172 Rhynchophylline and isorhynchophylline have been synthesised formally by Amat and more recently totally by Ip and Tong (Scheme 40).173
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| Scheme 35 Selected example from total synthesis of the application of an oxidative rearrangement of a β-carboline to a spirocyclopentane. | |
[3 + 2]-Cycloaddition
Dipolar cycloaddition.
For the synthesis of spiropyrrolidinyl oxindoles, particularly towards 3,3′-spiropyrrolidinyl oxindoles, there is a plethora of reports of the use of [3 + 2]-cycloaddition chemistry. To orientate the advances made in the recent decade it is important to include here Gong's seminal study from 2009. Gong reported the first one-pot catalytic enantioselective [3 + 2]-cycloaddition of 3-ylidene oxindoles with in situ generated azomethine ylides (Scheme 36).174,175 Gong used asymmetric phosphoric acid cat. 38 to afford spiropyrrolidines in high yield, dr and ee.
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| Scheme 36 Seminal report of catalytic enantioselective [3 + 2]-cycloaddition via azomethine ylides. | |
The utility of this approach by Gong has been demonstrated by the multitude of reports in this area since. These advances include the combination of an isatin derived dipole reacting with an external alkene dipolarophile,176 or other dipolaraphiles177 such as alkynes178 or allenes.179 Often these dipoles are derived from aminooxindoles180 or they could be malonitrile dipolarophiles,181 azomethine imines182 or pyridinium ylides.183 There are also many applications of this methodology for the synthesis of bispirooxindoles.184 Advances have also been made with related systems using copper catalysis.185 This azomethine ylide cycloaddition has been used by Hoffman-La Roche to synthesise MDM2 antagonist MI-888 (Fig. 7, ref. 157), including >100 g scale synthesis of the final enantiopure product by chiral resolution.186
For the construction of 3,2′-spiropyrrolidinyl oxindoles, isatin derived ketimines can be used.187N-2,2,2-Trifluoroethylisatin ketimines are very popular as a starting material because of the resultant inclusion of a CF3 group in the final product. In 2015, Yan, K. Wang and R. Wang demonstrated the first enantioselective [3 + 2]-cycloaddition of N-2,2,2-trifluorethylisatin ketimines using prolinol cat. 17 (Scheme 37A).188 The same authors subsequently reported a similar cycloaddition catalysed by a cinchona alkaloid derived squaramide catalyst (Scheme 37B).189 These reports were followed by many diastereoselective190 and enantioselective191 cycloadditions using N-2,2,2-trifluoroethylisatin ketimines as 1,3-dipole starting materials.
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| Scheme 37 Selected reports on the use of N-2,2,2-trifluoroethylisatin ketimines in [3 + 2]-cycloadditions. | |
Zhao and Shang developed an asymmetric phase transfer catalysed [3 + 2]-cycloaddition using a thiourea containing ammonium salt 40 with K2CO3 as base to form polysubstituted 3,3′-spiropyrrolidinyl oxindoles in up to 99% ee (Scheme 38).192
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| Scheme 38 Asymmetric phase-transfer catalysed [3 + 2]-cycloaddition. | |
Finally, Kürti demonstrated the utility of [3 + 2]-cycloaddition chemistry. Kürti demonstrated the total synthesis of natural isatindigoindoline C in short sequence from isatin through a diastereoselective [3 + 2]-cycloaddition followed by base mediated epimerisation (Scheme 39).193 The natural stereochemistry of isatindigoindoline C was thus confirmed as anti by comparison of the 1H NMR spectra.
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| Scheme 39 Short synthesis of isatindigoindoline C using a key [3 + 2]-cycloaddition of an isatin-derived azomethine ylide and a 3-ylidene oxindole. | |
Ring expansion.
A particularly important development in the synthesis of 3,3′-spiropyrrolidinyl oxindoles was reported by Carreira in 1999. Spirocyclopropyl oxindoles could be reacted with imines in a [3 + 2]-cycloaddition affording spiropyrrolidinyl oxindoles in good dr (up to 98:2) (Scheme 40).194 Carreira and others have used this ring expansion/cycloaddition strategy on multiple occasions to affect racemic and stereoselective syntheses of natural products,195 as well as being adapted.196 Recently, Ip and Tong employed Carreira's method as the key step in the first enantioselective total synthesis of Rhynchophylline and Isoryhnchophylline using a cyclic imine (Scheme 40).197
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| Scheme 40 Carreira's seminal ring expansion strategy and Ip and Tong's application of this methodology in total synthesis. | |
Budynina has performed a similar ring expansion in a sequential azide anion ring opening followed by a Staudinger/Wittig/Mannich reaction.198 Whereas Hajra has ring expanded 3-spiroaziridinyl oxindoles using malonitrile (Scheme 41).199 This type of ring expansion chemistry has also been carried out in an inverse fashion, i.e. Lu reacted a 3-ylidene oxindole with a vinyl aziridine (Scheme 41).200 In a related aziridine ring expansion, Hajra used Cu(OTf)2 as catalyst to ring expand an aziridine reacting with a 3-substituted isatin to form a 3,2′-spiropyrrolidine.201
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| Scheme 41 3,3′-Spiropyrrolidine oxindoles synthesised by aziridine ring expansion. | |
Budynina ring expanded a cyclopropane with an isatin derived ketimine (Scheme 42).202 Chu, He and Liu have recently reported an enantioselective cycloaddition of vinyl cyclopropanes with isatin derived imines using ligand 42, to form 3,2′-spiro-derivatives (Scheme 42).203
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| Scheme 42 Selected examples of 3,2′-spiropyrrolidine synthesis by cyclopropane ring expansion. | |
MBH carbonates.
As seen throughout this review, the use of isatin derived MBH carbonates is significant to form a 1,3-dipole as a three carbon synthon.204 In 2017, Chen demonstrated the use of isatin derived MBH carbonates in a [3 + 2]-cycloaddition with isatin derived ketimines catalysed by bifunctional DMAP/prolinol catalyst 43 in high yield and enantioselectivity (Scheme 43).205 In 2018, Han and Cui reported the diastereoselective [3 + 2]-cycloaddition of isatin derived MBH carbonates and electron-rich aldimines (Scheme 43).206
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| Scheme 43 Synthesis of 5-membered saturated nitrogen containing spirocycles from MBH carbonates. | |
NHC catalysis.
In 2015, Lu and Du reported an NHC catalysed [3 + 2] annulation of 2-bromoenals with 3-aminooxindoles (Scheme 44A).207 Using NHC cat. 44 Lu and Du achieved high enantioselectivity of the spiropyrrolidinone product. This report was followed by a similar reaction using NHC cat. 19 by Sun and Ye (Scheme 44B).208 Also, Hui and co-workers reported the [3 + 2] annulation of 3-bromoenals and isatin N-Boc ketimines (Scheme 44).209 Using azolium cat. 45 with DABCO in toluene afforded the spirocycles in good yield, high enantioselectivity and good scope. More recently, Enders reported an NHC catalysed Mannich reaction between isatin derived ketimines and α,β-unsaturated aldehydes.210 When the ketimine was protected with an ortho-phenol, which can bind the acyl-azolium intermediate allowing cyclisation, overall an enantioselective [3 + 2] cycloaddition was achieved.
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| Scheme 44 Selected examples of NHC catalysed [3 + 2]-cycloadditions. | |
Domino conjugate addition/cyclisation
Conjugate addition/cyclisation is a common tactic employed to access spiropyrrolidinyl oxindole scaffolds stereoselectively, and highlights the continuum between concerted [3 + 2]-annulation chemistry and stepwise sequences. Stepwise but simultaneous addition/cyclisation sequences will be dealt with first followed by discrete additions and sequential asynchronous cyclisations. Domino Michael addition/cyclisation reactions have been separated according to the isatin reactants: (A) 3-isothiocyanato oxindoles or (B) oxindoles with a nucleophilic C3 substituent reacting with olefins and (C) 3-ylidene oxindoles.
(A) 3-Isothiocyanato oxindoles.
The use of 3-isothiocyanato oxindoles to synthesise 3,2′-spiropyrrolidine structures in cascade Michael/cyclisation reactions has been extensively studied by the groups of Wang and Yuan, among others (Fig. 8).211 In 2013, Wang demonstrated the reaction of 3-isothiocyanato oxindoles with electron deficient olefins catalysed by cat. 44.212 Wang also showed cat. 45 could promote the reaction between the same oxindoles and with unsaturated pyrazolones.213 At a similar time, Yuan showed that quinine derived thiocarbamate cat. 46 could promote the reaction of 3-isothiocyanato oxindole with alkylidine azlactones, and quinine could promote the same reaction with 3-methyl-4-nitro-5-alkenyl isoxazoles.214 This spate of reports in 2013 was followed by the application of a similar strategy with other electron deficient olefins including notable further work by Yuan (Fig. 8).215 There has also been significant advances in using this chemistry for the synthesis of bispirooxindoles.216 Lindel has recently used this approach to construct the 3,2′-spiropyrrolidone core of cyanogramide.217
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| Fig. 8 Electrophiles and catalysts that have been developed for annulation of 3-isothiocyanato oxindoles. | |
(B) Nucleophilic C3 substituent.
The second significant strategy to access 3,2′-spiropyrrolidines is through domino Michael addition/cyclisation by a nucleophilic C3 substituent on the oxindole reacting with an olefin. In 2014, Yuan reported the reaction of acyl-protected 3-aminooxindoles with olefinic azlactones in good yield and diastereoselectivity using DBU as catalyst (Scheme 45).218 Yuan also showed a preliminary asymmetric variant of this reaction using cat. 56 to obtain the product in 61% ee. Xu and Yuan then further developed this chemistry with α,β-unsaturated acyl phosphonates as coupling partners, achieving high yield and enantioselectivity with cat. 57 (Scheme 45).219,220 With α,β-unsaturated aldehydes Wang used prolinol catalyst 17 to promote high enantioselectivity in the spirolactam product, albeit with moderate yields and diastereoselectivity (Scheme 45).221 Recently, Hua and Wang employed 3-aminooxindoles in a Michael/keto-imine/Friedel–Crafts cascade to form bispirooxindoles in high dr and ee.222 Related to these methods is the use of an electrophilic substituent instead of nucleophilic substituent at C3 of the oxindole i.e. Cl or Br. An example of this was Liu and Chen's use of 3-bromooxindoles in an enantioselective [4 + 1] annulation with azadienes using a cinchona alkaloid derived catalyst.223 As this strategy relies on the nucleophilic displacement by or with a component on the oxindole starting material it ultimately results in 3,2′-spiropyrrolidine products.
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| Scheme 45 Selected examples of conjugate Michael addition/cyclisation of oxindoles with a nucleophilic C3 substituent. * Unspecified stereochemistry/unknown absolute stereochemistry. | |
(C) 3-Ylidene oxindoles.
A third significant method of accessing spiropyrrolidines in a cascade Michael addition/cyclisation process is using 3-methylene oxindoles as starting materials.224 In 2016, Zhang described an enantioselective Michael addition catalysed by a thiourea-cinchona alkaloid derived catalyst followed by one-pot Mannich/lactamisation to afford 3,3′-spiro-(δ)-lactam oxindoles in high yield, ee and dr.225 Wang developed an iodine promoted Michael addition of 3-methylene oxindoles with enamino esters and concomitant DABCO mediated cyclisation to form 3,2′-spiropyrrolinyl oxindoles with good diastereoselectivity under ball-milling conditions.226 Combining strategies B and C, Xiang and Yang showed that the reaction of 3-aminooxindoles with 3-methylene oxindoles under basic conditions yielded a spirolactam which upon treatment with TsOH in one-pot cyclised to spirolactam 58 in high dr (Scheme 46).227 The C3 position of the aminooxindole was sufficiently nucleophilic under these conditions to undergo conjugate addition alpha to the ester, whereupon the free amine ring opens the oxindole. Du combined the use of acyl protected 3-aminooxindoles and 3-methylene oxindoles to form bispirooxindoles and Enders showed a Mannich/deprotection/aza-Michael cascade between isatin derived ketimines and 3-substituted oxindoles to bispirooxindoles.228
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| Scheme 46 Selected example of the combination of strategy B and C, using a nucleophilic C3 oxindole substituent and 3-ylidene oxindole. | |
A remarkable extension of strategies A and C with dipolar cycloaddition has been developed by Du where compounds containing a spiropyrrolidine oxindole and bispirooxindole were formed by a dual Michael/Mannich and Michael/cyclisation sequence (Scheme 47).229 Using dimeric squaramide cat. 59 the reaction between N-2,2,2-trifluoroethylisatin ketimine 60 and 3-methyleneoxindole 61 could be promoted, followed by the reaction between 3-isothiocyanato oxindole 62 and the pendant α,β-unsaturated amide on 61. The bispirooxindole-spirooxindole compounds with seven stereocentres were afforded in high yield, dr and ee, including on gram scale.
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| Scheme 47 Example of the use of strategies A and C for the stereoselective construction of seven stereocentres. | |
Domino Michael/Michael additions.
An excellent advance in 3,3′-spiropyrrolidine oxindole synthesis was made by Liu and at a similar time by Xie. Both teams independently developed a double Michael addition between oxindoles and alkynones with either a chiral guanidinium catalyst or a chiral N,N′-dioxide Sc(OTf)3 complex (Scheme 48).230
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| Scheme 48 Selected advances in Michael/Michael additions of alkynones. | |
Before this, Sasai had developed the same reaction using a chiral phosphine catalyst but with maximum 84% ee.231 More recently, Wu and Zhang used a chiral bisphosphine catalyst for the same reaction.232 A clear demonstration of the utility of these methods was given by Xie who showed the total synthesis of some strychnos alkaloids (Scheme 48). A related reaction has been developed by Miesch involving a copper catalysed hydroamination process.233 In a related strategy, Peng and Shao reported an asymmetric propargylation followed by iodocyclisation to construct polycyclic spirooxindoles in one-pot or as a discrete asymmetric coupling step followed by cyclisation.234
Discrete coupling strategies
In this section strategies where a discrete coupling followed by cyclisation will be discussed. A common strategy towards spiropyrrolidine oxindoles is an asymmetric Mannich reaction using ketimines followed by cyclisation. In 2012, Lu and then Li and Wang reported significant advances in enantioselective Michael addition and allylic alkylation of nitroalkanes using cinchona alkaloid derived catalysts.235 Reductive cyclisation of the nitro group in the product then afforded spirolactams in high ee. In 2015, Kobayashi developed a calcium/Pybox asymmetric Mannich reaction, which could be cyclised upon deprotection and basic cyclisation (Scheme 49).236,237 Using CaI2 with Pybox ligand 65 in CH2Cl2 at −78 °C afforded the Mannich product in high dr (trans product favoured) and excellent enantioselectivity. From acetal product 66, treatment with HCl followed by NEt3 afforded 3,3′-spiropyrrolinyl oxindole 67 in 65% yield and 92% ee.
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| Scheme 49 Enantioselective Mannich reaction followed by deprotection/cyclisation. | |
In 2016, Ooi used triazolium phase transfer catalyst 68 to effect the C–H amination of a hydroxylamine derivative in high ee for 5- and 6-membered saturated nitrogen heterocycles (Scheme 50).238 More recently, Du and Chen developed an asymmetric allylic alkylation from 3-phenyloxindoles using phase transfer catalyst 69 and Pd(OAc)2 with Na2CO3 as base (Scheme 50).239 This remarkable reaction afforded good yields of the 3,2′-spiropyrrolidine oxindole products in high ee. The products could be readily derivatised to numerous spirocycles including spirocyclohexanes, piperidines and pyrrolidines. Luo and Zhu developed a Heck/carbonylative cyclisation sequence to 3,3′-spiropyrrolidone oxindoles from non-isatin derived starting materials (Scheme 50).240 They employed chiral bidentate phosphine ligand L70 with Pd2(dba)3, K2CO3 and PivOH in toluene and a CO atmosphere to affect the Heck/carbonylation cascade. Notably, the methodology was limited to aryl protected lactams but high yields and enantioselectivities were observed when using the readily removable PMB group. The authors showed the application of this methodology to the synthesis of a CRTH2 receptor antagonist241 in 6 steps in 35% overall yield and 98% ee (Scheme 50).
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| Scheme 50 Selected examples of phase transfer catalysed or metal-catalysed cross-coupling strategies to spiropyrrolidines. PMB = para-methoxybenzyl. | |
In a clearly distinct strategy Zhao and Xia developed a cross-dehydrogenative coupling of pyridines with 3-substituted oxindoles.242 The pyridinium salts afforded could be reduced diastereoselectively with NaBH4 in order to access racemic corynoxine in a rapid fashion (Scheme 51). Although the pyridine scope was limited to electron withdrawing groups at C3, the reaction notably worked on unprotected oxindoles.
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| Scheme 51 Synthesis of spiropyrrolidine via pyridinium salts. | |
Addition to isatin derived ketimines is a common route to spiropyrrolidines. Liu reported a one-pot Mannich/hydroamination approach using isatin ketimines.243 Zhou used a triple catalysis cascade reaction to generate an isatin derived ketimine in situ which could then undergo Brønsted base catalysed 6π-electrocyclisation.244 Hajra developed an enantioselective tanden aza-Henry reaction-cyclisation of isatin-derived ketimines and nitroalkane mesylates to 3,2-spiropyrrolidine oxindoles (Scheme 52).245 These conditions were also applicable to piperidine derivatives with a chain extended nitro mesylate substrate. Xu reported a Rh-catalysed arylation of these ketimines, when using o-tolylboroxine, treatment of the product with NBS and Boc deprotection allowed cyclisation to product 72 (Scheme 52). More recently, Zhu and Zhang reported an enantioselective para-C–H functionalisation of N-monosubstituted anilines with isatin derived ketimines using cat. 73.246 The enantioenriched 3-aminoooxindoles were readily cyclised to spiropyrrolidines in good yield and high ee (Scheme 52).
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| Scheme 52 Synthesis of 3,2′-spiropyrrolidine oxindoles following enantioselective additions to isatin derived ketimines. | |
Other approaches.
Van der Eycken has described a post-Ugi reaction Pd-catalysed Buchwald–Hartwig/Michael reaction sequence to very quickly couple four components into 3,2′-spiropyrrolidinyl oxindoles.247 Taylor and Unsworth at York used their previously disclosed direct imine acylation methodology248 to furnish indoleninyl halide 74 which upon hydrolysis with aqueous HCl formed 3,3′-spiropyrrolidone oxindole 75 in high yield and dr (Scheme 53).249 Further recent advances towards 3,2′-spiropyrrolidine oxindoles have been made using diazo compounds as starting materials. In 2016, Moody at Nottingham University developed a diastereoselective NH insertion of diazooxindole 76 with β-aminoketones to afford spiropyrrolidine 77 (Scheme 53).250 Very recently, Anbarasan reported Pd-catalysed amination of 3-diazooxindoles with ortho-vinyl anilines.251
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| Scheme 53 Selected examples of diastereoselective synthesis of spiropyrrolidines using spirindoleninyl halides and diazooxindoles. | |
Photoredox.
Zhao and Jiang have reported a photoredox asymmetric phosphoric acid catalysed combination of α-amino radicals and 3-aryloxindole radicals (Scheme 54).252 The excited photoredox catalyst (dicyano-pyrazine (DPZ) derived) affects the decarboxylation of the aryl protected amino acid, generating an α-amino radical, which can combine with the 3-aryloxindole radical generated from 3-chlorooxindole with chirality induced by cat. 78. The intermediate then spontaneously cyclised in the case of the five-membered ring.
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| Scheme 54 Photoredox approach to enantioenriched 3,3′-spiropyrrolidinyl oxindoles. * After recrystallisation, initial ee = 87%. PMP = para-methoxyphenyl. | |
Spirotetrahydrofuranyl oxindoles253
Applications.
There are numerous bioactive spiroTHF oxindoles (Fig. 9). Of note is XEN402 (Funapide), developed by xenon and licensed by Teva (TV-45070) for treatment of pain (synthesis discussed below).254 Other applications of spiroTHFs include anti-tumour255 as well as antibacterial activity.256 Spring reported an example in a diversity-oriented synthesis of a library of drug-like macrocycles.257
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| Fig. 9 Selected examples of bioactive spirotetrahydrofuran oxindoles. | |
Natural product synthesis.
Garg demonstrated the importance of spirotetrahydrofuran oxindoles in the stereocontrolled total synthesis of N-methylwelwitindolinone D isonitrile.258 Late-stage installation of the key spiroTHF ring proved troublesome and an attempt to cyclise 79 (X = Br) under aerobic conditions afforded a spirocyclobutyl oxindole in high yield (Scheme 55). However, Garg and co-workers were able to develop two oxidative functionalisations of the oxindole C3 to afford the spirobutyrolactone 80 which was 5 steps from the natural product. The total synthesis of (±)-aspergilline A in 16 steps was developed by Wood and co-workers.259 More recently Jia reported a ten-step total synthesis of the related natural product Speradine C with a key oxidative spirocyclisation to form the spiroTHF ring at a late stage.260 Treatment of 81 with NCS formed a chloronium ion which was spontaneously attacked by the methyl ester to form 82 in 35% yield, which was one oxidative cyclisation step away from speradine C (Scheme 55). This use of the nucleophilicity of an indole is reminiscent of the strategy observed extensively for spiropyrrolidine synthesis (Scheme 35), indeed, Scheidt has synthesised (−)-coixspirolactam C (Fig. 9) from indole fused THPs (formed in an Oxa-Pictet–Spengler) by bromonium ion formation and rearrangement.261 Dixon synthesised the spiroTHF oxindole core of the tryptoquivalines using a stereoselective aldol cyclisation/acidic hydrolysis (for the THF ring) and a Cu-catalysed Buchwald type C–N bond formation (for the oxindole).262
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| Scheme 55 Selected examples of spiroTHF synthesis in total syntheses. | |
Cycloaddition
Iminium ion catalysis.
In 2012, Melchiorre reported the reaction of 3-hydroxyoxindoles with enals under iminium ion catalysis for the synthesis of chiral butyrolactones and the preparation of maremycin A.263 In 2013, Melchiorre was able to further develop this chemistry with dienals to favour 1,6-addition in favour of 1,4-addition by using prolinol catalyst 17 with dienal 83, where the β-substituent constrains the dienal in the S-cis conformation (Scheme 56).264
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| Scheme 56 SpiroTHF synthesis using iminium ion catalysis by Melchiorre. | |
NHC catalysis.
In seminal work, Ma reported an NHC catalysed [3 + 2] annulation of 3-bromoenals and isatins for the synthesis of spirotetrahydrofuranyl oxindoles (Scheme 57).265 Using NHC cat. 84 Ma achieved high enantioselectivity of the spirobutenolide oxindole products. This reaction occurred through NHC activation of the aldehyde to form a Breslow intermediate. This intermediate can then react through the carbon alpha to the bromo substituent to afford the oxindole alcohol which undergoes spirocyclisation. At a similar time, Glorius reported a similar annulation between isatins and enals, providing spirocycles with two contiguous quaternary stereocentres, which was highly diastereoselective and enantioselective when cat. 85 was used, importantly in conjunction with ortho-fluorobenzoic acid (Scheme 57).266 In 2017, Du reported a diastereoselective [3 + 2] annulation of oxindole derived aliphatic acids and isatins or α,α,α-trifluoroacetophenone with good diastereoselectivity using an NHC catalyst.267 Ye then developed a highly diastereoselective and moderately enantioselective [3 + 2]-annulation of 3-hydroxyoxindoles and enals, yielding similar products to the work of Glorius, reportedly by a radical pathway.268 Very recently, Hui showed the enantioselective oxidative annulation of acyl chlorides with 3-hydroxyoxindoles (Scheme 57).269 There have also been other significant advances in NHC catalysis expanding the starting materials used in conjunction with isatins.270
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| Scheme 57 Selected advances in NHC catalysed [3 + 2] annulations to spirolactones. | |
Cascade reactions.
As seen for the synthesis of spiropyrrolidines, the use of cascade Michael/cyclisation procedures is also common for spiroTHF oxindoles.271 Related to Yuan's use of phosphonates as leaving groups for the Michael addition/cyclisation (ref. 219), Du used N-acylated succinimides as leaving groups.272 There are a number of reports of coupling of 3-hydroxyoxindoles and malonitriles,273 of note is Pan's highly enantioselective Michael/Pinner cascade reaction using cat. 57 (Scheme 58).274 Deng reported an asymmetric Michael/lactonization procedure between 3-hydroxyoxindoles and 3-methylene oxindoles which resulted in ring opening of the oxindole coupling partner (Scheme 58).275,276 Similar to ref. 227 (Scheme 46), Chen and Yang reported a Michael addition/ring opening/ring closing cascade, however, the resultant aniline formed cyclised with the ester of the 3-methylene oxindole in the final step.277 In a distinct reaction but using a similar catalyst, Mei and Shi reported an enantioselective [4 + 1] annulation of 3-chlorooxindoles and ortho-quinone methides (Scheme 58).278 Again in a somewhat distinct cascade sequence, Quintavalla has developed an aldol/lactonization/elimination sequence catalysed by cat. 57 (Scheme 58).279 Other approaches include the use of quinone monoimines and multicomponent reactions of isonitriles, allenes and isatins.280
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| Scheme 58 Selected advances in annulations catalysed by bifunctional hydrogen bonding catalysts. | |
In 2016, Bisai reported an enantioselective aldol reaction of dimeric oxindoles which resulted in ring opening of one of the oxindoles, and in doing so developed a highly enantioselective thiourea catalysed aldol reaction with formaldehyde.281 The first process scale synthesis of TV-45070 (Fig. 9) employed a phase-transfer catalysed asymmetric alkylation using a Lygo phase transfer catalyst.282 Due to the requirement for multiple protecting groups in the first process scale synthesis of TV-45070, a new route was developed using a thiourea catalysed aldol reaction similar to the one developed by Bisai (Scheme 59). Only moderate enantioselectivity was observed using cat. 89 (up to 73% ee), but this could be improved by recrystallisation, followed by further two steps to afford the final API.
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| Scheme 59 Plant scale synthesis of TV-45070. | |
MBH carbonates.
A common precursor to these types of spirocycles is an MBH carbonate. In 2013, Xu and Wang reported a [3 + 2] annulation of 3-hydroxyoxindoles with MBH carbonates catalysed by quinidine affording spirolactone oxindoles in high yields and dr and ee (Scheme 60).283 In a one-pot reaction Zhou performed a MBH reaction/bromination/[3 + 2]-annulation sequence to access bispirooxindoles in exceptional ee.284 In 2014, Kesavan reported a one-pot alkylation/cyclisation of 3-OBoc-oxindoles with MBH carbonates with high enantiocontrol using cat. 27 (Scheme 60).285 Related to this, Shi reported an asymmetric phosphine catalysed [4 + 1] annulation of MBH carbonates (Scheme 60).286,287 Chen used EBX reagents to promote an alkynylation of MBH carbonates which could be cyclised to 5- or 6-membered oxygenated spirocycles.288
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| Scheme 60 Selected advances in the use of MBH carbonates to form spirolactone and spiroTHF oxindoles. | |
Metal/Lewis acid catalysis.
Yoda described an indium catalysed asymmetric allylation which depending on the substrate could spontaneously form spirocycle 92 or the alcohol product could be treated with acid to afford the cyclised product with retention of ee (Scheme 61).289,290 Feng has reported a Ni catalysed addition of vinyl hydrazones to isatins which upon acidic removal of the hydrazone and oxidative cleavage forms the antineoplastic agent 93 in high ee (Scheme 61).291 Trost first used Zinc catalysis to synthesise spiroTHF oxindoles in 2012.292 In 2019, Chang and Wang used a related Zn based system to promote a Michael/hemiketalisation/Friedel–Crafts cascade reaction to form bispiroTHF oxindoles.293 More recently, Hua and Wang reported a related reaction using α-hydroxyacetophenone (Scheme 61).294
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| Scheme 61 Recent advances in metal-mediated spirocyclisation methods to spiroTHF oxindoles. | |
Yin has developed a Pd-catalysed cascade reaction involving dearomatisation of furans to form the THF core of the spirocycle.295 Other metal-mediated approaches include the use of Cu-,296 Ti-,297 Ru-298 or Ni-catalysed299 spirocyclisations. Trost has also applied his development of Pd-allyl complexes previously discussed in the spiropyrrolidine section to the synthesis of spiroTHFs.300 Similar to Moody's use of diazo compounds to synthesise spiropyrrolidines, OH insertion/cyclisation could be used to synthesise spiroTHFs301 and there have been many other approaches using Rh- or Cu-catalysed decomposition of diazo compounds.302
Ring expansion of small-rings.
Using the ring strain of cyclopropanes or epoxides for [3 + 2] cycloadditions is a common strategy for the synthesis of five-membered oxygen heterocycles. In an interesting strategy, Shi and co-workers used vinylcyclopropanes with Pd2(dba)3 to form a Pd-allyl complex which reacted with isatin to form a spiroTHF oxindole with excellent dr and ee when using ligand 95 (Scheme 62).303 In 2019, Su incorporated the vinyl cyclopropane into the oxindole unit and reacted this with an isatin using Pd(OAc)2/XantPhos to afford bispirooxindole THFs diastereoselectively.304
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| Scheme 62 Use of vinyl cyclopropanes to construct spiroTHFs. | |
Hajra and Kumar have independently developed Lewis acid-mediated ring expansion of spiroepoxides with allylsilanes to afford spiroTHF oxindoles with moderate to good dr (Scheme 63).305 In 2016, Hajra had used spiroepoxy oxindoles in a regioselective Friedel–Crafts alkylation, the alcohol product could then undergo an Appel reaction and spontaneous cyclisation through the phenol to afford 2H-spirobenzofuran oxindoles.306
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| Scheme 63 Use of spiroepoxy oxindoles in a ring opening/closure cascade. | |
Use of hypervalent iodine reagents.
A clearly distinct strategy to access this type of spirocycle is the use of hypervalent iodine reagents.307 Building on the work of Gong for the synthesis of bispirooxindoles,308 Du developed an enantioselective spirocyclisation using catalytic chiral hypervalent iodine reagent 96 with mCPBA as oxidant (Scheme 64).309
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| Scheme 64 Chiral hypervalent iodine mediated asymmetric spirocyclisation. | |
Six-membered rings
Spirocylohexanyl oxindoles
Applications.
Satavaptan (Fig. 1) is a potent, selective Vasopressin V2 receptor antagonist for treatment of hyponatremia.310 Spirocyclohexane oxindoles also feature in a number of patents as anti-cancer,311 hepatitis C inhibitors312 and progesterone receptor modulators.313
Natural product synthesis.
Although not showing any notable bioactivity, gelsemine has proven to be an inspirational target within total synthesis (Fig. 10).314 Since 2013, there have been a couple of approaches to gelsemine, including an attempt by Vanderwal from a Zincke aldehyde and a Diels–Alder approach taken by Zhai and Qiu.315 Mehta described an approach to spindomycin B (Fig. 10) through a Michael addition/SNAr sequence.316
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| Fig. 10 Selected naturally occurring spirocyclohexane oxindole. | |
[4 + 2]-Cycloaddition.
By far the most significant route to spirocyclohexane oxindoles is [4 + 2]-cycloaddition. In 2013, Marinetti reported a PPh3 catalysed diastereoselective [4 + 2] cycloaddition of 3-methylene oxindoles and allenes.317 Chen has developed a similar but enantioselective reaction.318 Also in 2013, Ramachary reported the enantioselective [4 + 2] cycloaddition of alkynones and malonitrile oxindoles using cat. 97 (Scheme 65).319 Notably, under these conditions an aminoenyne was formed between the primary amine of the epi-quinine derived cat. 97 due to protonation of the more Lewis basic quinicludine nitrogen. There have been numerous related reports using malonitrile precursors320 and these reactions are also used to test new asymmetric ligands.321 There have been a number of reports of combining chromane scaffolds with spirocyclohexane oxindoles.322 Of note is Liu and Wang's use of 3-methylene oxindoles with a phenol substituent undergoing an Michael/aldol/oxa-Michael cascade under iminium catalysis (Scheme 65).323 There have been many other developments of this type of annulation involving Michael/aldol324 or more elaborate325 cascade reactions employing various catalysis modes. An interesting Michael/aldol example was recently reported by Peng and Han with diastereodivergency observed depending on the oxindole N-protecting group (Scheme 65).326
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| Scheme 65 Selected [4 + 2] annulations. * Indicates stereochemical relationship between OTMS and ester group on cyclohexane ring. | |
In 2011, Melchiorre and Barbas III reported asymmetric Diels–Alder reactions between 3-vinyl indoles and electron poor olefins using iminium ion catalysis and hydrogen bonding catalysis.327 These works laid the foundations for a body of work which provide tetrahydrocarbazoles fused with spirooxindoles.328 Notably, in 2014, Feng reported the asymmetric Diels–Alder reaction between 3-vinyl indoles and 3-methylene oxindoles using Ni catalysis (Scheme 66).329 Also, in 2015 Shi developed a similar reaction using 2-vinyl indoles using chiral phosphoric acid catalysis (Scheme 66).330 Oxygenated analogues of these tetrahydrocarbazoles, which could be produced by an Oxa-Pictet–Spengler reaction can undergo a Claisen rearrangement to spirocyclohexanes (which as we have seen can also form spiroTHF products).331
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| Scheme 66 Selected enantioselective [4 + 2] cycloadditions. | |
Antilla described the use of chiral Mg-phosphate catalysis for an asymmetric Diels–Alder reaction.332 For a related Diels–Alder reaction, Lin and Feng used Zn(OTf)2 complexed with L100 in up to 99% ee (Scheme 67).333,334 In 2019, Kesavan described an asymmetric Diels–Alder reaction between 2,4-dienals and 3-methylene oxindoles catalysed by prolinol cat. 101 (Scheme 67).335 Feng has recently reported Au-catalysed cycloisomerisation followed by Ni-catalysed Diels–Alder cycloaddition to enantioenriched spirocyclohexanes (Scheme 67).336 Feng and Dong have also disclosed a Dy(OTf)3-mediated ring-opening/[4 + 2]-cycloaddition of cyclobutenones and 3-methylene oxindoles.337
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| Scheme 67 Selected enantioselective Diels–Alder reactions to make spirooxindoles. | |
In terms of other cascade rearrangements, Kim has developed a diastereoselective 6π-electrocyclisation from MBH precursors.338 Kim further developed this to a one-pot PPh3 mediated coupling of MBH carbonates and enals where favourable disrotatory ring closure from the E,Z,E-isomer proceeds to the major diastereomer (Scheme 68).339 In a distinct complexity-generating reaction, Tanaka could form racemic intermediate 102 in a [4 + 1] annulation of 3-methylene oxindole and diketone 103 by treatment with TfOH (Scheme 68).340 In a Michael–Henry cascade reaction 102 could react with an electron-poor olefin (such as a nitroalkene) and form polycyclic spirocyclohexane oxindole containing product 104 with excellent enantioselectivity. The yields for these products were low due to only one enantiomer of 102 reacting, therefore, the reaction could also serve to furnish highly enantioenriched 102 in a kinetic resolution.
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| Scheme 68 Selected cycloadditions developed towards spirocyclohexane oxindoles. | |
Metal-mediated C–H activation approaches.
In 2015, Kim reported a Pd-catalysed Heck/C–H activation approach to spirocyclohexene oxindoles with moderate diastereoselectivity.341 More recently Lautens has developed a significant body of work using intercepted Pd-mediated spirocyclisations and in 2016 reported benzyne insertion to an alkylPdII intermediate formed by C–H activation (Scheme 69).342 This was followed by insertion of alkynes with high regioselectivity.343 These works were followed by Liang and Yang's report on the synthesis of 109 in a triple C–H activation approach where the alkylPdII intermediate is intercepted by 2 further equivalents of aryl iodide (Scheme 69).344 Another approach is Pd-catalysed migratory insertion of diazo compounds and Michael addition.345
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| Scheme 69 Selected metal-mediated C–H activation approaches via alkyl-PdII intermediates. | |
Chiral hypervalent iodine mediated.
In the sole example of the application of asymmetric hypervalent iodine mediated dearomative spirocyclisation, Gong synthesised spirooxcyclohexene oxindoles in moderate yields but high enantioselectivity (Scheme 70).346 Generally, electron-rich oxindoles were used i.e. phenylfused oxindoles, however, the enantioselectivity was highest for the synthesis of oxindole 110 using cat. 111.
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| Scheme 70 Chiral iodine mediated spirocyclohexene oxindole formation. | |
Spiropiperidinyl oxindoles
Applications.
In the last decade spiropiperidinyl oxindoles have been synthesised for medicinal chemistry applications against cancer,347 CNS disorders,348 renal failure,349 treatment of Dengue virus infection350 as well as other applications.351 Surugatoxin related to neosurugatoxin is also a potent human toxin (Fig. 1).352 Most prominently cipargamin (NITD609 or KAE609) has been developed as an anti-malarial agent.353 Shibasaki used a key asymmetric alkynylation of an isatin ketimine to synthesise cipargamin.354 Liu and Feng synthesised cipargamin in an aza-Diels–Alder process employing 3-vinyl indoles and Ni catalysis (Scheme 71).355
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| Scheme 71 Concise synthesis of anti-malarial cipargamin. | |
Similar to other ring sizes we have considered, there have been a number of efforts made towards the synthesis of rings with more than one heteroatom, here we only consider the synthesis of piperidines or δ-lactam scaffolds.356 Wei and Shi developed a [4 + 2]-cycloaddition of vinyl ketones and α,β-unsaturated imines derived from isatins catalysed by a bifunctional asymmetric phosphorus-thiourea catalyst (Scheme 72, R = 2,4,6-triisopropyl phenyl).357 In metal-mediated approaches, gold catalysed spirocyclisation of in situ generated indoles and isatins was reported by Subba Reddy.358 Related to Liu and Feng's reaction (ref. 355), Kumar developed an enantioselective aza-Diels Alder reaction catalysed by Dy(OTf)3 and a ligand similar to 112 where Ar = 2,6-iPr2C6H4.359 Feng, Li and Xiao have independently developed 1,5-hydride transfer reactions to spiropiperidines.360 More recently, Shi developed a Pd-catalysed decarboxylative [4 + 2] cycloaddition strategy using vinyl benzoxazinanones and 3-methylene oxindoles (Scheme 72).361
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| Scheme 72 Selected enantioselective [4 + 2]-cycloadditions. | |
NHC catalysis.
In 2013, Chi reported the NHC catalysed [3 + 3] annulation of α-aryl esters and isatin derived α,β-unsaturated ketimines to afford spirocyclic-δ-lactams in moderate diastereoselectivity in up to 62% ee with an asymmetric NHC.362 Yang, Zeng and Zhong used asymmetric cat. 115 to make 3,4′-spiropiperidine oxindoles from isatin derived α,β-unsaturated aldehydes and imines (Scheme 73).363 This reaction proceeds through imine conversion to the corresponding enamine to avoid unwanted [3 + 2] cycloaddition with the enal. Ye reported a [4 + 2] cycloaddition of α,β-unsaturated carboxylic acids (via the dienolate) and isatin ketimines to form 3,2′-spiro-δ-lactam oxindoles using NHC cat. 116 (Scheme 73).364 Xu generated ortho-quinodimethanes to undergo [4 + 2] annulation with isatin ketimines using cat. 19 producing β-carboline spirooxindoles (Scheme 73).365 More recently, Xu and Ren reported a [4 + 2] annulation of aliphatic aldehydes and oxindole derived α,β-unsaturated ketimines catalysed by an NHC catalyst.366 Enders also recently reported related [3 + 3] annulations of isatin derived enals and cyclic N-sulfonyl ketimines.367
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| Scheme 73 NHC catalysed cycloadditions to spiro-δ-lactams. | |
Cascade reactions.
Shi and Tu reported an enantioselective Povarov reaction using asymmetric phosphoric acid cat. 117 affording 3,2′-spiropiperidine scaffolds in up to 97% ee.368,369 Initial formation of a ketimine between the aniline and isatin is followed by an acid catalysed vinylogous Mannich reaction and Friedel–Crafts alkylation closes the ring (Scheme 74). This report was followed by a related reaction by Zhou and Shi using 3-vinyl indoles in place of the ortho-vinyl phenol.370 Zhu employed ortho-vinyl phenols and 3-methylene oxindoles to react in a Michael addition/Friedel–Crafts cascade catalysed by (DHQD)2PHAL to form 3,3′-spiropiperidine oxindoles (Scheme 74).371 In a related Michael addition/Friedel–Crafts sequence, Yuan utilised electron rich pyrroles to react with an iminium formed from an α,β-unsaturated aldehyde to form pyrrole-fused 3,2′-spiropiperidine oxindoles.372 Related reactions include aza-Michael/Michael addition, Michael/Mannich reaction, Michael addition/Pictet–Spengler, Michael/aldol, Mannich/hemi-aminalisation cascade reactions.373 He and Han developed a [2 + 2 + 2] annulation via a Michael/aza-Henry cascade reaction and evaluated the products ability to inhibit proliferation of cancer cell lines.374 Due to the importance of cipargamin, synthesis of similar β-carboline spirooxindoles is very popular.375 Also, due to the number of bioactive compounds containing the spirodihydropyridine oxindole scaffold, there has been a significant amount of work aimed at racemic synthesis,376 of note is Shi's enantioselective [3 + 3] annulation.377 Very recent advances include a copper catalysed aza-Henry reaction by Wang and Zhou378 and HFIP mediated C(sp3)–H functionalisation by hydride transfer.379
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| Scheme 74 Selected examples of phosphoric acid catalysed cascade reactions. | |
Stepwise strategies.
There are also a number of related works where an asymmetric reaction is followed by consequent deprotection/cyclisation steps. For example, Pedro developed an aza-Henry reaction between isatin ketimines and 4-nitrobutyrate catalysed by a Cu(II)-Box system, which could be deprotected to undergo spontaneous cyclisation to the 3,2′-spiropiperidine oxindole (Scheme 75).380 Hajra described an organocatalytic addition of a nitroalkyl goup followed by intramolecular alkylation (Scheme 52).245 Meng and Li, and more recently Nakamura, reported enantioselective vinylogous Mannich reactions to generate intermediates which could be deprotected and cyclised to spirolactam products (Scheme 75).381 Han has also developed an enantioselective Mannich reaction which upon deprotection of the generated Boc-protected amine undergoes lactamisation to the six-membered spirocycle.382
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| Scheme 75 Selected advances in asymmetric Mannich reactions followed by elaboration to six-membered spirocycles. | |
Spirotetrahydropyranyl oxindoles
Applications.
SpiroTHP oxindoles have found application in induction of apoptosis,383 as anti-malarials,384 among others.385
Natural product synthesis.
Trost cyclised 120 to give cyclolactone 121 in 92% yield as one diastereomer as an intermediate for the total synthesis of communesin F and perophoramide (Scheme 76).386 Gong reported the first total synthesis of (+)-trigolutes B utilising an enantioselective substitution reaction to form 122 which in 7 steps could be transformed to the natural product (Scheme 76).387,388
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| Scheme 76 Selected examples of spiroTHP oxindole synthesis in total synthesis. | |
Cycloaddition/cascade.
Liang and Xu employed thiourea cat. 123 in a double Michael addition cascade between N-methyl oxindole and 124 (Scheme 77).389 Using thiourea cat. 125 Enders developed an oxa-Michael/1,6-addition reaction to form 3,3′-spiroTHP oxindoles in high yield an enantioselectivity (Scheme 77).390 Zeng and Zhong reported an enantioselective Michael/aldol/hemiacetalisation process using iminium catalysis.391 Han has developed an enantioselective vinylogous aldol/cyclisation/ring-opening cascade of 3-methylene oxindoles and isatins.392 Wu reported an enantioselective Michael/cyclisation reaction between dimedone and isatylidene malonitriles with high yields and enantioselectivities, the trityl protecting group on the isatin was important.393,394 More recent examples include a Michael/aldol/cyclisation cascade to form 5- or 6-membered oxygenated spirocycles by Zhang and a vinylogous aldol reaction/transesterification by Yuan, both using thiourea catalysts (Scheme 77).395 Some of these Michael/cyclisation procedures can be deemed formal hetero-Diels–Alder reactions.396 Recently, Xiao has used ortho-quinone methides derived in situ from oxindole ortho-hydrooxybenzyl alcohols by acid in [4 + 2] annulations with 2,5-dialkylfurans or 1,3-diketones as dienophiles.397 These starting materials can also be used in a bis-electrophile coupling in a [4 + 2] annulation (as well as [4 + 1] annulation if a pyridinium salt is used instead of a bromide leaving group).398 THP fused indoles have been synthesised by enantioselective aldol/chloroetherification/aromatisation, as well as C–O coupling.399 MBH carbonates have also been used for [4 + 2]-annulations.400
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| Scheme 77 Selected cascade reactions catalysed by thiourea catalysts. | |
NHC catalysis.
Yao developed the [4 + 2] annulation of isatins with the HOBt ester of α,β-unsaturated carboxylic acids, achieving good enantioselectivity with cat. 19 (Scheme 78).401 Lu and Du reported the NHC catalysed [3 + 3] annulation of isatin derived α,β-unsaturated acids and α-ketoesters with up to 74% ee.402 In a similar reaction, Xu reported the annulation of 3-ylidene oxindoles with 1,3-dicarbonyls (Scheme 78).403 In an excellent application of dual NHC and Cu-catalysis, Song and Gong used ethylethylene carbonates in a [3 + 3]-annulation of 3-ylidene oxindoles (Scheme 78).404
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| Scheme 78 Selected NHC catalysed cycloadditions. | |
Stepwise approaches.
Feng has employed a Mg/chiral N,N′-dioxide catalyst system for a hetero Diels–Alder reaction.405 Li has recently reported a Bi/chiral phosphoric acid 77 catalysed allylation of isatins which could be further elaborated to spiroTHP products (Scheme 79).406 Arai has employed a Ts-PyBidine-Ni complex to catalyse the asymmetric addition of indole to 3-ylidene oxindoles and a highly diastereoselective iodocyclisation to 6-membered products was developed using cat. 77 (Scheme 79).407
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| Scheme 79 Selected examples of stepwise synthesis of spiroTHP oxindoles by nucleophilic addition. | |
In other approaches, Subba Reddy has developed a BF3·OEt2 mediated Prins cascade cyclisation between aldehydes and butanamides to furnish spiroTHP oxindoles in high yield and good dr.408 Hu used Rh-carbenes generated from 3-diazooxindoles to undergo C–H insertion/aldol condensation to afford spiroTHP oxindoles in high yield and diastereoselectivity.409 Another example of C–H activation has been shown by Messaoudi with glycosides.410 The intramolecular Co-catalysed Pauson–Khand cyclisation of 1,7-enynes generated 3,2′-spiroTHPs with high diastereoselectivity.411
Seven-membered rings
Applications
Natural products containing seven-membered spirocyclic oxindoles are predominantly bridged carbocyclic examples of gelsemium alkaloids.412 There are not many examples of these rings in medicinal chemistry, though nitrogen containing examples do feature in some patents.413 A spiroazepane oxindole was synthesised as a cipargamin analogue with antimalarial activity,16 and an example with activity against a prostate cancer target (Fig. 1).414 While natural products tend to favour bridged carbocyclic seven-membered rings (Fig. 11) and there are some methodologies to synthesise bridged seven-membered rings, this section will focus on non-bridged examples.415 Additionally, we have grouped the methodologies in terms of similarity rather than into C/N/O-containing rings due to the small number of publications, the vast majority of which are aimed at spiroazepane synthesis.
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| Fig. 11 Selected bioactive seven-membered rings. | |
Natural product synthesis
Total synthesis efforts centre around the synthesis of gelsemium alkaloids. Carreira has described elegant approaches to gelsemoxonine (see Fig. 11 for structure).416 Ferreira constructed the oxindole of gelsenicine with an oxidative cyclisation of a Weinreb amide with an aromatic ring.417 Fukuyama and Ma have independently described divergent syntheses to many gelsedine type alkaloids.418 Takayama recently described an asymmetric synthesis of (−)-14-hydroxygelsenicine and six other gelsemium alkaloids.419 The spirooxindole was constructed in a diastereoselective Heck cyclisation (Scheme 80).
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| Scheme 80 Pd-Catalysed Heck reaction as key step in the total synthesis of (−)-14-hydroxygelsedilam. | |
NHC catalysis
In 2016, Enders pioneered the use of NHCs for the [3 + 4]-cycloaddition of isatin derived enals with aza-o-quinone methides or azoalkenes to form spiro-benzazepinones or spiro-diazepinones (Scheme 81).420 Using cat. 128 with Cs2CO3 to form the aza-o-quinone methide in situ from the N-(o-chloromethyl)aryl amide in EtOAc gave high enantioselectivity and atroposelectivity. Switching starting material in order to make diazepinones was highly stereoselective using cat. 129.
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| Scheme 81 [4 + 3]-Cycloadditions with 3-ylidene oxindoles for 7-membered ring synthesis. | |
Li developed an NHC catalysed enantioselective synthesis of spirobenzoxepinones in a [4 + 3] cycloaddition of isatin derived enals and quinone methides (Scheme 82).421 High enantioselectivity (up to >99% ee and >20:1 dr) was achieved using triazolium cat. 130 in combination with NaOAc in 1,2-dichloroethane. Enders published a similar reaction a month after Li's study, which employed cat. 131 to achieve up to 95:5 er and good dr.422 This was followed by work by Yan Li and Ye on a related [4 + 3]-cycloaddition of isatin derived enals and aurone-derived azadienes.423 Using a similar NHC catalyst interesting spiroazepinones were formed with high enantioselectivity and diastereoselectivity. The compounds exhibited moderate cytotoxicity against cancer cell lines.
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| Scheme 82 Isatin-derived enals in [4 + 3] cycloaddition reactions. | |
More recent advances include Fu and Huang's NHC catalysed [4 + 3]-annulation of α,β-unsaturated aldehydes and amine substituted oxindoles (oxotryptamines, Scheme 83).424 Song and Gong's previously discussed excellent Cu/NHC dual catalysis could be used with ethynyl benzoxazinanones to construct chiral azepines.404
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| Scheme 83 Selected [4 + 3]-annulation reaction of oxotryptamines. | |
MBH carbonates
Chen and coworkers reported a [4 + 3] cycloaddition of a bromo-substituted MBH derivative and an aza-o-quinone methide precursor (Scheme 84).425 Chen used tri-(4-fluoro)phenyl phosphine as a Lewis base to form an allylic ylide from the MBH precursor and Cs2CO3 as base to generate the aza-o-quinone methide. Xu published a related reaction at a similar time,426 using tributyl phosphine as Lewis base catalysis with a related MBH precursor and a Boc protected aza-o-quinone methide precursor to generate seven-membered spirocycles in good yields, including on gram-scale. In a similar fashion, Du recently employed ortho-quinone methides in combination with an isatin derived MBH precursor to affect a [4 + 3]-cycloaddition.427 Using DABCO as Lewis base catalyst in MeCN, high diastereoselectivity with electron-rich ortho-quinone methides was observed (Scheme 84).
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| Scheme 84 Selected [4 + 3]-cycloadditions to 7-membered spirocycles using MBH carbonates or MBH precursors. | |
Du and Chen have collaboratively reported an asymmetric Ir catalysed [4 + 3]-cycloaddition between an MBH carbonate and π-allyl precursor (Scheme 85).428 The π-allyl precursor includes a vinylogous leaving group i.e. vinyl-OBoc, ethylene oxazinanones or vinyl aziridines (for six-membered rings) which forms an asymmetric Ir-allyl complex to react with the DABCO activated MBH carbonate.
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| Scheme 85 Reaction of MBH carbonates with π-allyl precursors. | |
Other approaches to spiroazepanes include a desymmetrising Cu-catalysed C–N bond formation in high ee (Scheme 86).429 Budynina has used azide anion ring opening of spirocyclopropyl oxindoles (ref. 198) in a Staudinger, domino Michael/aza-Wittig and reduction sequence.430 Yang developed a Pd-NHC catalysed allylic alkylation, the products of which could readily elaborated to a spiroazepinone.431
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| Scheme 86 Cu-Catalysed desymmetrising cross-coupling reaction. | |
Eight-membered rings
As with seven-membered spiro-oxindoles there are very few examples of syntheses capable of accessing the eight-membered analogues. Shi and Zhao independently published the Pd-catalysed [5 + 3]-cycloaddition of N-2,2,2-trifluoromethylisatin ketimines and vinylethylene carbonates (Scheme 87).432 Shi employed (Pd2dba3)·CHCl3 and Xantphos as a ligand for the decarboxylative allylic substitution and a racemic phosphoric acid catalyst to effect the cyclisation. Meanwhile, Zhao used Pd(PPh3)4 in combination with PPh3 as ligand and pyridine as base for the cyclisation. Both procedures afford the anti-product as the major product in high yields and dr. Shi demonstrated a preliminary result for the enantioselective allylation using tBu-RuPhos as ligand affording the eight-membered spirocycle in 63% ee. Furthermore, Shi showed that epoxidation of the endogenous double bond with mCPBA would lead to spontaneous epoxide ring opening to form spiropyrrolidine 134 (Scheme 87A).
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| Scheme 87 [5 + 3]-Cycloaddition towards 8-membered spiroindolones. | |
Summary and conclusions
We have reviewed the developments in state-of-the-art stereoselective spiroindolone synthesis between 2013 and 2020. The progress of synthetic methodology for each ring size (3- to 8-) has been discussed. The importance of these advances should not be understated, with reference to the significant potential of many of these structures in medicinal chemistry, which we have highlighted with numerous examples. The trends we have observed within this review can be summarised as follows:
1. Spirooxindoles represent a very important class of structures within medicinal chemistry, featuring in approved medicines with a large variety of biological activity, as well as acting as the structural core in a significant number of natural products (egFig. 1). Where possible we have highlighted how the synthetic methodologies discussed in this review have influenced the process scale synthesis of these pharmaceuticals, for example in Scheme 59.
2. Spirooxindoles serve as a benchmark in asymmetric synthesis. Many of the methods reviewed here have made substantial advances in asymmetric catalysis. This may be due to the fused backbone of the indolone providing a flat and rigid platform for construction of 3D spirocycles. These advances are doubly valuable because they fulfill the object of advancing asymmetric methodology while making biologically relevant scaffolds for screening against biologically relevant targets.
3. The advances that have been observed in spirooxindole synthesis generally reflect the advance of organic synthesis since 2013. While there has been a significant rise in the number of publications on this topic, there are a growing number of excellent and innovative reports targeting these scaffolds (Fig. 2). This review has covered advances in stereoselective NHC catalysis, chiral acid catalysis, aminocatalysis, metal catalysis including cross-coupling, hydrogen bonding catalysis and phase transfer catalysis. We have also highlighted total syntheses of natural products containing these core structures.
There will likely be sustained interest in these scaffolds because of the trends observed in recent years coupled with the success of many of the pharmaceutical agents. We envisage that future developments may be targeted to the following objectives:
1. More general methods to access multiple ring sizes. Currently, there are few methodologies that can access multiple ring sizes with simple changes i.e. to starting material structure. For example, ring expansion strategies making use of small rings are useful to access more than one ring size. Ideal methods could also access more than one heteroatom pattern on the spirocyclic ring and be able to control ring substitution.
2. A wider variety of synthetic targets through asymmetric synthesis. Unsubstituted rings can often be synthesised as racemates using traditional methods. Yet, asymmetric synthesis of unsubstituted rings is a challenge and though there are examples within this review there is still a requirement to access the unsubstituted scaffold.
3. Small and larger ring spirocycles. As could be seen from the analysis of the publication numbers (Fig. 2) and reflected in the number of strategies discussed in this review, there is a plethora of methods for 5- and 6-membered rings. Future endeavours in this area should seek to synthesise small or larger rings, eg azetidines and oxetanes are increasingly useful for medicinal chemistry and have not received the same level of attention. Furthermore, 7- and 8-membered rings have not received significant attention due to the difficulty in accessing these structures and we envisage that synthetic advances seen in this review will likely be applied to larger ring synthesis. 8-Membered ring spirocycles, as the first member of the medium rings, may require significant new method development. Higher medium ring homologues were not within the scope of this review, but could pose interesting targets for medicinal chemistry. New syntheses of these smaller and larger ring spirocycles will lead to improved access to this valuable and underexplored chemical space.
We hope that this review will serve as a reference for medicinal and synthetic chemists aiming to synthesise this type of ring structure and inspire future advances in the synthesis of spirooxindoles.
Conflicts of interest
There are no conflicts to declare.
Acknowledgements
We gratefully acknowledge The Royal Society for funding [University Research Fellowship, UF140161 (to J. A. B)], and AstraZeneca and EPSRC for iCASE studentship funding.
Notes and references
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(a) J. Peng, G. Y. Ran, W. Du and Y. C. Chen, Tertiary-Amine-Catalyzed Asymmetric [3 + 2] Annulations. of Morita-Baylis-Hillman Carbonates of Isatins with Nitroolefins to Construct Spirooxindoles, Synthesis, 2015, 47, 2538 CrossRef CAS;
(b) G. Y. Ran, P. Wang, W. Du and Y. C. Chen, α-Regioselective [3 + 2] annulations with Morita-Baylis-Hillman carbonates of isatins and 2-nitro-1,3-enynes, Org. Chem. Front., 2016, 3, 861 RSC;
(c) G. Zhan, M.-L. Shi, Q. He, W.-J. Lin, Q. Ouyang, W. Du and Y.-C. Chen, Catalyst-Controlled Switch in Chemo- and Diastereoselectivities: Annulations of Morita-Baylis-Hillman Carbonates from Isatins, Angew. Chem., Int. Ed., 2016, 55, 2147 CrossRef CAS;
(d) Z. H. Wang, C. W. Lei, X. Y. Zhang, Y. You, J. Q. Zhao and W. C. Yuan, Asymmetric domino 1,6-addition/annulation reaction of 3-cyano-4-alkenyl-2H-chromen-2-ones with isatin-derived MBH cyclopentenylspirooxindoles bearing 2H-chromen-2-ones, Org. Chem. Front., 2019, 6, 3342 RSC;
(e) J. Q. Zhao, L. Yang, X. J. Zhou, Y. You, Z. H. Wang, M. Q. Zhou, X. M. Zhang, X. Y. Xu and W. C. Yuan, Organocatalyzed Dearomative Cycloaddition of 2-Nitrobenzofurans and Isatin-Derived Morita-Baylis-Hillman Carbonates: Highly Stereoselective Construction of Cyclopenta[b]benzofuran Scaffolds, Org. Lett., 2019, 21, 660 CrossRef CAS.
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- Work by Miao and co-workers on phosphorus promoted [3 + 2] cycloaddition of alkynes and 3-methylene oxindoles with moderate enantioselectivity achieved:
(a) J. Zhang, C. Cheng, D. Wang and Z. Miao, Regio- and. Diastereoselective Construction of Spirocyclopenteneoxindoles through Phosphine-Catalyzed [3 + 2] Annulation of Methyleneindolinone with Alkynoate Derivatives, J. Org. Chem., 2017, 82, 10121 CrossRef CAS. For related non-stereoselective activation by phosphorus catalysts see:
(b) L. Zhang, H. Lu, G.-Q. Xu, Z.-Y. Wang and P.-F. Xu, PPh3 Mediated Reductive Annulation Reaction between Isatins and Electron Deficient Dienes to Construct Spirooxindole Compounds, J. Org. Chem., 2017, 82, 5782 CrossRef CAS. Also see:
(c) D. B. Ramachary, C. Venkaiah and P. M. Krishna, Stereoselective Synthesis of Five-Membered Spirooxindoles through Tomita Zipper Cyclization, Org. Lett., 2013, 15, 4714 CrossRef CAS;
(d) C. Gomez, M. Gicquel, J. C. Carry, L. Schio, P. Retailleau, A. Voituriez and A. Marinetti, Phosphine-Catalyzed Synthesis of 3,3-Spirocyclopenteneoxindoles from g-Substituted Allenoates: Systematic Studies and Targeted Applications, J. Org. Chem., 2013, 78, 1488 CrossRef CAS.
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(a) X. Li, Y. M. Li, F. Z. Peng, S. T. Wu, Z. Q. Li, Z. W. Sun, H. Bin Zhang and Z. H. Shao, Highly Enantioselective One-Pot Synthesis of Spirocyclopentaneoxindoles Containing the Oxime Group by Organocatalyzed Michael Addition/ISOC/Fragmentation Sequence, Org. Lett., 2011, 13, 6160 CrossRef CAS;
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(f) W. Sun, L. Hong, G. Zhu, Z. Wang, X. Wei, J. Ni and R. Wang, An Organocatalytic Michael-Michael Cascade. for the Enantioselective Construction of Spirocyclopentane Bioxindoles: Control of Four Contiguous Stereocenters, Org. Lett., 2014, 16, 544 CrossRef CAS;
(g) L. Z. Ding, T. S. Zhong, H. Wu and Y. M. Wang, Highly Enantioselective Construction of Spirocyclopentaneoxindoles Containing Four Consecutive Stereocenters. through an Organocatalytic Iminium-Enamine Cascade Reaction, Eur. J. Org. Chem., 2014, 5139 CrossRef CAS;
(h) J. Zhou, Q. L. Wang, L. Peng, F. Tian, X. Y. Xu and L. X. Wang, An organocatalytic domino Michael-alkylation reaction: highly enantioselective construction of spiro-cyclopentaneoxindoles and tetronic acid scaffolds, Chem. Commun., 2014, 50, 14601 RSC;
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(l) R.-Y. Yang, J. Sun, G. Jin and C.-G. Yan, Synthesis of functionalized dispiro[indoline-3,1′-cyclopentane-3′,3′′-indolines] via cyclodimerization of 3-phenacylideneoxindolines with benzoylhydrazides and arylhydrazines, Mol. Diversity, 2018, 22, 21 CrossRef CAS;
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(n) Y. Lin, B.-L. Zhao and D.-M. Du, Bifunctional Squaramide-Catalyzed Asymmetric [3 + 2] Cyclization of 2-(1-Methyl-2-oxoindolin-3-yl)malonitriles with Unsaturated Pyrazolones To Construct Spirooxindole-Fused Spiropyrazolones, J. Org. Chem., 2019, 84, 10209 CrossRef CAS;
(o) S. Xu, X. Liu, X. Zuo, G. Zhou, Y. Gong, X. Liu and Y. Zhou, Oxindole-chromones C3 Synthons Directed Stereocontrolled Construction of Five Contiguous Stereocenters on Spiro[tetrahydrocyclopenta[b]chromanone-oxindole]s, Adv. Synth. Catal., 2019, 361, 5328 CrossRef CAS;
(p) S. S. Vagh, P. Karanam, C. Liao, T. Lin, Y. Liou, A. Edukondalu, Y. Chen and W. Lin, Enantioselective Construction of Spirooxindole-Fused Cyclopenta[c]chromen-4-ones Bearing Five Contiguous Stereocenters via a Stepwise (3 + 2) Cycloaddition, Adv. Synth. Catal., 2020, 362, 1679 CrossRef CAS.
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(a) D. B. Ramachary, C. Venkaiah and R. Madhavachary, Asymmetric Synthesis of Druglike Six-Membered Spirooxindoles through an Amino Enyne Catalysis, Org. Lett., 2013, 15, 3042 CrossRef CAS. For a related reaction using 3-methylene oxindoles to react with malonitriles under Mg catalysis see:
(b) H. Mei, L. Lin, B. Shen, X. Liu and X. Feng, Highly enantioselective desymmetrization of prochiral cyclic α,α-dicyanoalkenes via the direct vinylogous Michael/cyclization domino reaction, Org. Chem. Front., 2018, 5, 2505 RSC. For reaction of related malonitrile oxindoles with allenes:
(c) R. Chen, X. Fan, Z. Xu and Z. He, Facile Synthesis of Spirooxindole-Cyclohexenes via Phosphine-Catalyzed [4 + 2] Annulation of α-Substituted Allenoates, Chin. J. Chem., 2017, 35, 1469 CrossRef CAS.
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(a) H. Huang, M. Bihani and J. C. G. Zhao, Stereoselective synthesis of spirooxindole derivatives using an organocatalyzed tandem Michael-Michael reaction, Org. Biomol. Chem., 2016, 14, 1755 RSC;
(b) Z. Zhou, Q. He, Y. Jiang, Q. Ouyang, W. Du and Y. C. Chen, Double Thiol-Chiral Brønsted Base Catalysis: Asymmetric Cross Rauhut-Currier Reaction and Sequential [4 + 2] Annulation for Assembly of Different Activated Olefins, Org. Lett., 2019, 21, 7184 CrossRef CAS.
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(a) X. L. He, H. R. Zhao, X. Song, B. Jiang, W. Du and Y. C. Chen, Asymmetric Barton-Zard Reaction To Access 3-Pyrrole-Containing Axially Chiral Skeletons, ACS Catal., 2019, 9, 4374 CrossRef CAS;
(b) L. Peng, K. Li, C. Xie, S. Li, D. Xu, W. Qin and H. Yan, Organocatalytic Asymmetric Annulation of ortho-Alkynylanilines: Synthesis of Axially Chiral Naphthyl-C2-indoles, Angew. Chem., Int. Ed., 2019, 58, 17199 CrossRef CAS.
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(a) X. Zuo, X. L. Liu, J. X. Wang, Y. M. Yao, Y. Y. Zhou, Q. Di Wei, Y. Gong and Y. Zhou, Organocatalytic Reaction of Chromone-Oxindole Synthon: Access to Chromanone-Based Spirocyclohexaneoxindoles with Five Adjacent Stereocenters, J. Org. Chem., 2019, 84, 6679 CrossRef CAS;
(b) X. L. Liu, G. Zhou, Y. Gong, Z. Yao, X. Zuo, W. H. Zhang and Y. Zhou, Stereocontrolled Synthesis of Bispirooxindole-Based Hexahydroxanthones with Five Contiguous Stereocenters, Org. Lett., 2019, 21, 2528 CrossRef CAS;
(c) S. Q. Chang, X. Zou, Y. Gong, X. W. He, X. L. Liu and Y. Zhou, Stereocontrolled construction of six vicinal stereogenic centers on a hexahydroxanthone framework through a formal [2 + 1 + 3] annulation, Chem. Commun., 2019, 55, 14003 RSC;
(d) X. L. Liu, Q. Di Wei, X. Zuo, S. W. Xu, Z. Yao, J. X. Wang and Y. Zhou, Organocatalytic Michael/Michael Cycloaddition Enabled Asymmetric Construction of Hexahydroxanthones with Skeletal Diversity, Adv. Synth. Catal., 2019, 361, 2836 CrossRef CAS;
(e) X. L. Liu, Y. Gong, S. Chen, X. Zuo, Z. Yao and Y. Zhou, Bifunctional oxindole-chromone 4C building block directed asymmetric synthesis of bispirocyclic hexahydroxanthones featuring five contiguous stereocenters and two side-by-side oxindoles, Org. Chem. Front., 2019, 6, 1603 RSC;
(f) M. Zhang, J. X. Wang, S. Q. Chang, X. L. Liu, X. Zuo and Y. Zhou, Highly efficient enantioselective synthesis of bispiro[benzofuran-oxindole/benzofuran-chromanone]s through organocatalytic inter-/intramolecular Michael cycloaddition, Chin. Chem. Lett., 2020, 31, 381 CrossRef CAS.
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(a) A. K. Ghosh and B. Zhou, Enantioselective synthesis of spiro[cyclohexane-1,3′-indolin]-2′-ones containing multiple stereocenters via organocatalytic Michael/aldol cascade reactions, Tetrahedron Lett., 2013, 54, 2311 CrossRef CAS;
(b) S. Roy, M. Amireddy and K. Chen, Organocatalytic formal [5 + 1] annulation: diastereoselective cascade synthesis of functionalized six-membered spirocyclic indane-1,3-diones/oxindoles via Michael-aldol reaction, Tetrahedron, 2013, 69, 8751 CrossRef CAS;
(c) S. Xu, C. Li, X. Jia and J. Li, AlCl3-Promoted Selective Michael Addition with Allenoate and Methyleneindolinone: Synthesis of Spirocyclic Oxindole by Using Allenoate as a Four-Carbon Component Building Block, J. Org. Chem., 2014, 79, 11161 CrossRef CAS;
(d) M. Vishwanath, P. Vinayagam, V. P. R. Gajulapalli and V. Kesavan, Asymmetric Organocatalytic Assembly of Oxindoles Fused with Spiro-3,4-dihydropyrans with Three Contiguous Stereocenters Consisting of Vicinal Quaternary Centers, Asian J. Org. Chem., 2016, 5, 613 CrossRef CAS. For a desymmetrising aldol reaction see:
(e) B. B. Sun, Y. F. Zhang, J. Q. Zhang, S. J. Yin, W. T. Fan, H. Y. Li and X. W. Wang, Cinchona Alkaloid Derived Primary Amine Catalyzed Intramolecular Desymmetrizing Aldolization Reaction of Diacetonyloxindoles, Eur. J. Org. Chem., 2017, 2871 CrossRef CAS.
- These examples include reactions with more than 2 steps or conjugate additions followed by a different cyclisation mode:
(a) B. Zhou, Y. Yang, J. Shi, Z. Luo and Y. Li, Synthesis of Six-Membered Spirocyclic Oxindoles with Five Consecutive Stereocenters in an Asymmetric Organocatalytic One-Pot Michael/Michael/Aldol Addition Sequence, J. Org. Chem., 2013, 78, 2897 CrossRef CAS;
(b) Z. Zhou, X. Feng, X. Yin and Y. C. Chen, Direct Remote Asymmetric Bisvinylogous 1,4-Additions of Cyclic 2,5-Dienones to Nitroalkenes, Org. Lett., 2014, 16, 2370 CrossRef CAS;
(c) R. Zhou, Q. Wu, M. Guo, W. Huang, X. He, L. Yang, F. Peng, G. He and B. Han, Organocatalytic cascade reaction for the asymmetric synthesis of novel chroman-fused spirooxindoles that potently inhibit cancer cell proliferation, Chem. Commun., 2015, 51, 13113 RSC;
(d) Q. S. Sun, H. Lin, X. Sun and X. W. Sun, Highly efficient synthesis of enantioenriched fully-substituted spirocyclohexane oxindoles via a Michael-Michael-aldol cascade reaction, Tetrahedron Lett., 2016, 57, 5673 CrossRef CAS. Radical pathway:
(e) H. R. Wu, L. Cheng, D. L. Kong, H. Y. Huang, C. L. Gu, L. Liu, D. Wang and C. J. Li, FeCl3-Mediated Radical Tandem Reactions of 3-Benzyl-2-oxindoles with Styrene Derivatives for the Stereoselective Synthesis of Spirocyclohexene Oxindoles, Org. Lett., 2016, 18, 1382 CrossRef CAS.
- B. Wang, X. H. Wang, W. Huang, J. Zhou, H. P. Zhu, C. Peng and B. Han, Protecting Group-Directed Diastereodivergent Synthesis of Chiral Tetrahydronaphthalene-Fused Spirooxindoles via Bifunctional Tertiary Amine Catalysis, J. Org. Chem., 2019, 84, 10349 CrossRef.
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(a) Y. Liu, M. Nappi, E. Arceo, S. Vera and P. Melchiorre, Asymmetric Catalysis of Diels-Alder Reactions with in Situ Generated Heterocyclic ortho-Quinodimethanes, J. Am. Chem. Soc., 2011, 133, 15212 CrossRef CAS;
(b) B. Tan, G. Hernández-Torres and C. F. Barbas, Highly Efficient Hydrogen-Bonding Catalysis of the Diels-Alder Reaction of 3-Vinylindoles and Methyleneindolinones Provides Carbazolespirooxindole Skeletons, J. Am. Chem. Soc., 2011, 133, 12354 CrossRef CAS.
- Hydrogen bonding catalysis:
(a) L. J. Huang, J. Weng, S. Wang and G. Lu, Organocatalytic Diels-Alder Reaction of 2-Vinylindoles with Methyleneindolinones: An Efficient Approach to Functionalized Carbazolespirooxindoles, Adv. Synth. Catal., 2015, 357, 993 CrossRef CAS;
(b) J. W. Ren, J. Wang, J. A. Xiao, J. Li, H. Y. Xiang, X. Q. Chen and H. Yang, L-Pyroglutamic, Sulphonamide as Hydrogen-Bonding Organocatalyst: Enantioselective Diels-Alder Cyclization to Construct Carbazolespirooxindoles, J. Org. Chem., 2017, 82, 6441 CrossRef CAS. TfOH catalysed domino reactions:
(c) R. Y. Yang, J. Sun, Y. Tao, Q. Sun and C. G. Yan, TfOH-Catalyzed One-Pot Domino Reaction for Diastereoselective Synthesis of Polysubstituted Tetrahydrospiro[carbazole-1,3′-indoline]s, J. Org. Chem., 2017, 82, 13277 CrossRef CAS;
(d) R. Y. Yang, J. Sun, Q. Sun and C. G. Yan, Selective Synthesis of 3-(9H-Carbazol-2-yl)indolin-2-ones and Spiro[tetrahydrocarbazole-3,3′-oxindoles] via a HOTf Catalyzed Three-Component Reaction, J. Org. Chem., 2018, 83, 5909 CrossRef CAS;
(e) J. Guo, X. Bai, Q. Wang and Z. Bu, Diastereoselective Construction of Indole-Bridged Chroman Spirooxindoles through a TfOH-Catalyzed Michael Addition-Inspired Cascade Reaction, J. Org. Chem., 2018, 83, 3679 CrossRef CAS. Ag catalysed aminoenyne formation:
(f) P. Sharma, N. P. Kumar, N. H. Krishna, D. Prasanna, B. Sridhar and N. Shankaraiah, Silver(I)-catalysed domino alkyne-annulation/Diels-Alder reaction: a mild synthetic approach to tetrahydrospiro[carbazole-4,3′-indoline] scaffolds, Org. Chem. Front., 2016, 3, 1503 RSC. Iminium ion catalysis:
(g) Z. H. You, Y. H. Chen, Y. Tang and Y. K. Liu, Organocatalytic Asymmetric Synthesis of Spiro-Bridged and Spiro-Fused Heterocyclic Compounds Containing Chromane, Indole, and Oxindole Moieties, Org. Lett., 2018, 20, 6682 CrossRef CAS. Cu mediated 3-component reaction:
(h) S.-C. Zhan, J. Sun, R.-Z. Liu and C.-G. Yan, Diastereoselective construction of carbazole-based spirooxindoles via the Levy three-component reaction, Org. Biomol. Chem., 2020, 18, 163 RSC.
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(a) J. Zheng, L. Lin, K. Fu, H. Zheng, X. Liu and X. Feng, Synthesis of Optically Pure Spiro[cyclohexane-oxindoline] Derivatives via Catalytic Asymmetric Diels-Alder Reaction of Brassard-Type Diene with Methyleneindolines, J. Org. Chem., 2015, 80, 8836 CrossRef CAS. Also see:
(b) Y. F. Zhang, S. J. Yin, M. Zhao, J. Q. Zhang, H. Y. Li and X. W. Wang, Dinuclear zinc-catalyzed desymmetric intramolecular aldolization: an enantioselective construction of spiro[cyclohexanone-oxindole] derivatives, RSC Adv., 2016, 6, 30683 RSC.
- For a related diastereoselective reaction mediated by AcOH see: R. Y. Yang, J. Sun and C. G. Yan, HOAc-Mediated Domino Diels-Alder Reaction for Synthesis of Spiro[cyclohexane-1,3′-indolines] in Ionic Liquid [Bmim]Br, ACS Omega, 2018, 3, 5406 CrossRef CAS.
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(a) S. Muthusamy and V. Kesavan, Asymmetric Cycloaddition Reactions of Oxindole α-Keto Esters via Cascade Dienamine-Enamine and Trienamine Strategies, Eur. J. Org. Chem., 2019, 4046 CrossRef CAS. For a similar reaction of 2,4-dienals see:
(b) A. S. Marques, J. Marrot, I. Chataigner, V. Coeffard, G. Vincent and X. Moreau, In Situ Generation of Cyclopentadienol Intermediates from 2,4-Dienals. Application to the Synthesis of Spirooxindoles via a Domino Polycyclization, Org. Lett., 2018, 20, 792 CrossRef CAS.
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(a) B. K. Min, D. Y. Seo, J. Y. Ryu, J. Lee and J. N. Kim, Synthesis of Spirocyclohexadieneyl-2-Oxindoles by 6π-Electrocyclization of Trienes Derived from Wittig Reaction of Morita-Baylis-Hillman Carbonates and α,β-Unsaturated Aldehydes, Bull. Korean Chem. Soc., 2018, 39, 115 CrossRef CAS. For related reaction to bispirooxindoles:
(b) B. K. Min, S. Lee, H. J. Roh, J. Y. Ryu, J. Lee and J. N. Kim, Synthesis of dispirocyclohexadiene bisoxindole from Morita-Baylis-Hillman carbonate of isatin, Tetrahedron Lett., 2017, 58, 3251 CrossRef CAS.
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(a) J. R. Huang, M. Sohail, T. Taniguchi, K. Monde and F. Tanaka, Formal (4 + 1) Cycloaddition and Enantioselective Michael-Henry Cascade Reactions To Synthesize Spiro[4,5]decanes and Spirooxindole Polycycles, Angew. Chem., Int. Ed., 2017, 56, 5853 CrossRef CAS. For work on related oxygenated heterocycles see:
(b) M. Sohail and F. Tanaka, Dynamic stereoselective annulation via aldol-oxa-cyclization cascade reaction to afford spirooxindole pyran polycycles, Commun. Chem., 2019, 2, 73 CrossRef.
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(a) H. Yoon, A. Lossouarn, F. Landau and M. Lautens, Pd-Catalyzed Spirocyclization via C-H Activation and Benzyne Insertion, Org. Lett., 2016, 18, 6324 CrossRef CAS;
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(a) H. Yoon, M. Rölz, F. Landau and M. Lautens, Palladium-Catalyzed Spirocyclization through C−H Activation and Regioselective Alkyne Insertion, Angew. Chem., Int. Ed., 2017, 56, 10920 CrossRef CAS;
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(a) W. Cao, X. Liu, J. Guo, L. Lin and X. Feng, Asymmetric Tandem 1,5-Hydride Shift/Ring Closure for the Synthesis of Chiral Spirooxindole Tetrahydroquinolines, Chem. – Eur. J., 2015, 21, 1632 CrossRef CAS;
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(c) S. S. Li, S. Zhu, C. Chen, K. Duan, Q. Liu and J. Xiao, Hydride Transfer Involved Redox-Neutral Cascade Cyclizations for Construction of Spirocyclic Bisoxindoles Featuring a [3,4]-Fused Oxindole Moiety, Org. Lett., 2019, 21, 1058 CrossRef CAS.
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(a) Q. Liu, X. Y. Chen, S. Li, K. Rissanen and D. Enders, N-Heterocyclic, Carbene Catalyzed Asymmetric Synthesis of Pentacyclic Spirooxindoles via [3 + 3] Annulations of Isatin-Derived Enals and Cyclic N-Sulfonyl Ketimines, Adv. Synth. Catal., 2019, 361, 1991 CrossRef CAS. For a further example see:
(b) H. Lu, C. Y. Tan, H. X. Zhang, J. L. Zhang, J. Y. Liu, H. Y. Li and P. F. Xu, Participation of β-Ketothioamides in N-Heterocyclic Carbene-Catalyzed [3 + 3] Spiroannulation: Asymmetric Synthesis of Functionalized Spiro-piperidinone Derivatives, J. Org. Chem., 2018, 83, 15245 CrossRef CAS.
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(a) H. Gao, J. Sun and C. G. Yan, Povarov Reaction of β-Enamino Esters and Isatin-3-imines for Diastereoselective Synthesis of Spiro[indoline-3,2′-quinolines], Synthesis, 2014, 46, 489 Search PubMed;
(b) G. Bianchini, P. Ribelles, D. Becerra, M. T. Ramos and J. C. Menéndez, Efficient synthesis of 2-acylquinolines based on an aza-vinylogous Povarov reaction, Org. Chem. Front., 2016, 3, 412 RSC.
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(a) H. H. Zhang, X. X. Sun, J. Liang, Y. M. Wang, C. C. Zhao and F. Shi, Catalytic asymmetric Povarov reaction of isatin-derived 2-azadienes with 3-vinylindoles, Org. Biomol. Chem., 2014, 12, 9539 RSC. Also see:
(b) Z. Mao, F. Mo and X. Lin, Diastereo- and Enantioselective Assembly of Spirooxindole Tetrahydroquinoline Skeletons through Asymmetric Binary Acid Catalyzed Hydride Transfer-Cyclization, Synlett, 2016, 27, 546 CAS.
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(a) Y. You, B. D. Cui, M. Q. Zhou, J. Zuo, J. Q. Zhao, X. Y. Xu, X. M. Zhang and W. C. Yuan, Organocatalytic Asymmetric Michael/Friedel-Crafts Cascade Reaction of 3-Pyrrolyl-oxindoles and α,β-Unsaturated Aldehydes for the Construction of Chiral Spiro[5,6-dihydropyrido[1,2-a]pyrrole-3,3′-oxindoles], J. Org. Chem., 2015, 80, 5951 CrossRef CAS. Also see:
(b) W. T. Fan, N. K. Li, L. Xu, C. Qiao and X. W. Wang, Organo-Catalyzed Asymmetric Michael-Hemiketalization-Oxa-Pictet-Spengler Cyclization for Bridged and Spiro Heterocyclic Skeletons: Oxocarbenium Ion as a Key Intermediate, Org. Lett., 2017, 19, 6626 CrossRef CAS;
(c) Z. Gao, J. Zhang, H. Yang and G. Jiang, Brønsted Acid-Promoted Friedel-Crafts Alkylation/Cyclization of (7-Hydroxynaphthalenyl)pyrrole or (2-Hydroxyphenyl)pyrroles
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(d) N. K. Li, W. T. Fan, J. Q. Zhang, B. B. Sun, J. B. Chen and X. W. Wang, Diastereodivergent synthesis of bispirooxindoles via asymmetric Friedel-Crafts/aldol cascade reaction: co-catalyst effects on diastereoselective outcomes, Chem. Commun., 2018, 54, 2260 RSC.
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(a) W. Yang and D.-M. Du, Cinchona-based squaramide-catalysed cascade aza-Michael-Michael addition: enantioselective construction of functionalized spirooxindole tetrahydroquinolines, Chem. Commun., 2013, 49, 8842 RSC;
(b) Y. M. Huang, C. W. Zheng and G. Zhao, Organocatalyzed aza-Michael-Michael cascade reactions to construct spirooxindole tetrahydroquinolines with all-carbon chiral centers, RSC Adv., 2013, 3, 16999 RSC;
(c) Y. Tan, E. L. Feng, Q. S. Sun, H. Lin, X. Sun, G. Q. Lin and X. W. Sun, Enantioselective synthesis of spirooxindole benzoquinolizines via organo-catalyzed cascade reactions, Org. Biomol. Chem., 2017, 15, 778 RSC;
(d) W. Dai, H. Lu, X. Li, F. Shi and S. J. Tu, Diastereo- and Enantioselective Construction of a Bispirooxindole Scaffold Containing a Tetrahydro-β-carboline Moiety through an Organocatalytic Asymmetric Cascade Reaction, Chem. – Eur. J., 2014, 20, 11382 CrossRef CAS;
(e) Y. Liu, J. Xue, Z. Sun, D. Liu, Y. Xing and Y. Li, Substituent-Controlled Selective Synthesis of Spirooxindoles and Oxazolyloxindoles via Two Tandem Reactions, Asian J. Org. Chem., 2016, 5, 43 CrossRef CAS;
(f) Q. Zhao, C. Peng, H. Huang, S. J. Liu, Y. J. Zhong, W. Huang, G. He and B. Han, Asymmetric synthesis of tetrahydroisoquinoline-fused spirooxindoles as Ras-GTP inhibitors that inhibit colon adenocarcinoma cell proliferation and invasion, Chem. Commun., 2018, 54, 8359 RSC.
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(a) Y. Liao, M. Bai, S. Yu, M. Zhang, F. Hu, X. Xu, W. Yuan and X. Zhang, Construction of Novel Tetrahydro-β-carboline-1-thione Spirooxindoles by Brønsted Acid Mediated Formal [3 + 3] Cyclization of 3-Indolylmethanols with 3-Isothiocyanato Oxindoles, J. Heterocycl. Chem., 2017, 54, 1311 CrossRef CAS;
(b) S. Kawamura, K. Dosei, E. Valverde, K. Ushida and M. Sodeoka, N-Heterocycle-Forming, Amino/Carboperfluoroalkylations of Aminoalkenes by Using Perfluoro Acid Anhydrides: Mechanistic Studies and Applications Directed Toward Perfluoroalkylated Compound Libraries, J. Org. Chem., 2017, 82, 12539 CrossRef CAS;
(c) L. Qi, H. Hou, F. Ling, L. Fang, W. Luo and W. Zhong, Cinchona Alkaloid Thiourea Catalyzed Asymmetric Synthesis and Anticancer Activity Evaluation of Tetrahydro-β-spirooxindoles, Heterocycles, 2018, 96, 1119 CrossRef CAS;
(d) G. Zhan, M. L. Shi, W. J. Lin, Q. Ouyang, W. Du and Y. C. Chen, Direct Asymmetric Aza-Vinylogous-Type Michael Additions of Nitrones from Isatins to Nitroalkenes, Chem. – Eur. J., 2017, 23, 6286 CrossRef CAS.
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(c) M. Esmaeilpour, A. R. Sardarian and H. Firouzabadi, Theophylline Supported on Modified Silica-Coated Magnetite Nanoparticles as a Novel, Efficient, Reusable Catalyst in Green One-Pot Synthesis of Spirooxindoles and Phenazines, ChemistrySelect, 2018, 3, 9236 CrossRef CAS;
(d) Q. Niu, J. Xi, L. Li, L. Li, C. Pan, M. Lan and L. Rong, Isatins 3-C annulation vs ring-opening: Two different pathways for synthesis of spiro compounds via multicomponent reactions, Tetrahedron Lett., 2019, 60, 151181 CrossRef CAS.
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(a) Q. N. Zhu, Y. C. Zhang, M. M. Xu, X. X. Sun, X. Yang and F. Shi, Enantioselective Construction of Tetrahydroquinolin-5-one-Based Spirooxindole Scaffold via an Organocatalytic Asymmetric Multicomponent [3 + 3] Cyclization, J. Org. Chem., 2016, 81, 7898 CrossRef CAS;
(b) P. Zhou, B. Hu, L. Lu, R. Huang and F. Yu, One-Pot Synthesis of Functionalised 4-Spiro-1,4-Dihydropyridines Via [1 + 2 + 1 + 2]-Cyclisation, J. Chem. Res., 2017, 41, 513 CrossRef CAS.
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(a) Y. Zhu, Y. Li, Q. Meng and X. Li, An organocatalytic enantioselective vinylogous Mannich reaction of α,α-dicyanoolefins with isatin N-Boc ketimines, Org. Chem. Front., 2016, 3, 709 RSC;
(b) S. Nakamura, K. Matsuzaka, T. Hatanaka and Y. Funahashi, Enantioselective Vinylogous Mannich Reaction of Acyclic Vinylketene Silyl Acetals with Ketimines Using Chiral Bis(imidazoline)-Cu(II) Catalysts, Org. Lett., 2020, 22, 2868 CrossRef CAS. For a phase transfer catalysed version see:
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(a) K. Zhao, Y. Zhi, T. Shu, A. Valkonen, K. Rissanen and D. Enders, Organocatalytic Domino Oxa-Michael/1,6-Addition Reactions: Asymmetric Synthesis of Chromans Bearing Oxindole Scaffolds, Angew. Chem., Int. Ed., 2016, 55, 12104 CrossRef CAS. For a recent diastereoselective oxa-Michael reaction see:
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