Open access peer-reviewed chapter

N,N-Dialkyl Amides as Versatile Synthons for Synthesis of Heterocycles and Acyclic Systems

Written By

Andivelu Ilangovan, Sakthivel Pandaram and Tamilselvan Duraisamy

Submitted: September 18th, 2019 Reviewed: December 23rd, 2019 Published: May 13th, 2020

DOI: 10.5772/intechopen.90949

Chapter metrics overview

677 Chapter Downloads

View Full Metrics


N,N-Dialkyl amides such as N,N-dimethylformamide (DMF), N,N-dimethylacetamide (DMA), are common polar solvents, finds application as a multipurpose reagent in synthetic organic chemistry. They are cheap, readily available and versatile synthons that can be used in a variety of ways to generate different functional groups. In recent years, many publications showcasing, excellent and useful applications of N,N-dialkyl amides in amination (R-NMe2), formylation (R-CHO), as a single carbon source (R-C), methylene group (R-CH2), cyanation (R-CN), amidoalkylation (-R), aminocarbonylation (R-CONMe2), carbonylation (R-CO) and heterocycle synthesis appeared. This chapter highlights important developments in the employment of N,N-dialkyl amides in the synthesis of heterocycles and functionalization of acyclic systems. Although some review articles covered the application of DMF and/or DMA in organic functional group transformations, there is no specialized review on their application in the synthesis of cyclic and acyclic systems.


  • amination
  • amidation
  • amidoalkylation
  • aminocarbonylation
  • cyanation
  • dialkyl amides
  • formylation
  • heterocycles

1. Introduction

The great advantage of DMF, DMA and other N,N-dialkylamides are their versatility as reaction medium, polar and aprotic nature, high boiling point, cheap and ready availability. DMF can react as electrophile or a nucleophile and also act as a source of several key intermediates and take a role in reactions as a dehydrating agent, as a reducing agents [1] or as a catalyst [2, 3, 4, 5], stabilizer [6, 7, 8, 9, 10]. For the synthesis of metallic compounds DMF can be an effective ligand. N,N-dialkylamides could be considered as a combination of several functional groups such as alkyl, amide, carbonyl, dialkyl amine, formyl, N-formyl and highly polar C-N, C〓O, and C-H bonds. Due to flexible reactivity of N,N-dialkylamides, during the past few years, chemists have succeeded in developing reactions, where DMF and DMA could be used to deliver different functional groups such as amino (R-NMe2), formyl (R-CHO), methylene (R-CH2), cyano (R-CN), amidoalkyl (CH2N(CH3)-C(〓O)CH3-R) aminocarbonyl(R-CONMe2), carbonyl(R-CO), methyl (-Me), a single atoms such as C, O, H etc. (Figure 1). Similarly, DMF and DMA could be used in the preparation of heterocyclic compound through formylation of active methylene groups, conversion of methyl groups to enamines, and formylation of amino groups to amidines. Further, it can also be utilized as an intermediate in the modification of heterocyclic compounds [11].

Figure 1.

DMF and DMA as a synthon for the various reactions.

A non-exhaustive seminal review by Muzart [1], highlighted different roles of DMF inorganic synthesis covered literature up to 2009, another comprehensive review by Ding and Jiao appeared in 2012 [12] which covered aspects of DMF as a multipurpose precursor in various reactions. Further, specialized review by Batra et al. [13], and other reviews dealing with recent applications of DMF and DMA as a reagent [14] and triple role of DMF as a catalyst, reagent and stabilizer also appeared [15].

In this book chapter we summarized developments on applications of DMF and DMA in reactions such as amination (R-NMe2) [16], formylation (R-CHO) [17, 18], as a single carbon source (R-C), methylene group (R-CH2) [19], carbonylation (R-CO), as well as newer reactions such as amidoalkylation (-CH2N(CH3)-C(〓O)CH3-R) [20], metal catalyzed aminocarbonylation (R-CONMe2) [21], cyanation (R-CN) [22, 23], and formation heterocycles, took place during the past few decades and up to October 2019. Heterocycles are important compounds finding excellent applications as useful materials and medicinally important compounds. Thus unlike other reviews appeared on this subject [1, 12, 13, 14, 15], we provided special emphasis on synthesis of heterocyclic compounds and reactions involving DMF and DMA. Thus, first part of this book chapter will cover synthesis of construction of cyclic system, especially heterocycles, the next part will cover the formation of open chain compounds. Although DMF can serve as a reagent in organic reactions such as Friedel-Crafts [24] and Vilsmeier-Haack [25] reactions the actual reagent is derivative of DMF, hence we did not cover such subjects. We hope this book chapter will stimulate further research interest on the application of DMF and DMA in organic synthesis.


2. DMF and DMA as synthon in synthesis of heterocycles

2.1 Construction of pyridine ring

Guan and co-workers reported synthesis of symmetrical pyridines from ketoxime carboxylates using DMF as a one carbon source in the presence of ruthenium catalyst and NaHSO3 as an additive (Figure 2). A series of ketoxime acetates 2 reacted smoothly with DMF to give corresponding pyridine derivatives 3. Replacement NaHSO3 with other oxidants led to decrease in the yield. The reaction condition was optimized by use of various additives and catalysts. The desired product was obtained in good yield, in the presence of NaHSO3, Ru(cod)Cl2 and at 120°C. Both electron withdrawing and electron donating group attached to the aryl rings gave the corresponding symmetrical pyridines. But the yield decreased due to steric effect by the orthosubstituents.

Figure 2.

Pyridine ring formation by DMF using Ru-catalyzed cyclization of aryl ethyl ketoxime acetates.

A possible mechanism for the reaction was proposed. Oxidation of DMF by Ru(II) gives an iminium species A and Ru(0). Followed by which oxidative addition of ketoxime acetate to Ru(0) generates an imino-Ru(II) complex B, undergoes tautomerization to afford enamino-Ru(II) complex C. Then, nucleophilic addition of C to species A produces an imine intermediate D. Condensation of imine intermediate D with a second ketoxime acetate gives intermediate E. Nucleophilic substitution of E by NaHSO3 followed by intramolecular cyclization of the intermediate F forms a dihydropyridine intermediate G. Finally, Ru-catalyzed oxidative aromatization of G by oxygen provided the product H [26].

Su et al., reported cyclisation of 4-(phenylamino)-2H-chromen-2-ones to give novel functionalized 6H-chromeno[4,3-b]quinolin-6-ones (Figure 3) in the presence of Cu(OAc)2.H2O/TBPB catalytic system (Figure 3). In this reaction, DMF served as the source of methine group.

Figure 3.

DMF as a methine source in pyridine ring formation via cyclization of 4-(phenylamino)-2H-chromen-2-ones.

The reaction proceeded smoothly with electron-donating and electron-withdrawing substituents on the aniline ring and the expected products were obtained in good yields. A plausible mechanism was proposed by the author in. Initially, DMF is converted into iminium ion A with the help of Cu/TBPB via radical pathway. Next, reaction of 4-(phenylamino)-2H-chromen-2-ones with active iminium ion B gives intermediate C. Further, removal of MeNHCHO group afforded D which is attacked by NaHSO3 followed by an intramolecular cyclization to afford desired product 5 [27].

In 2015, Deng and co-workers reported the Ru catalyzed multi-component reaction of acetophenones 6, ammonium acetate (N source) and DMF (one carbon source) to get 2,4-diarylsubstituted-pyridines 7 under O2 atmosphere (Figure 4).

Figure 4.

Ru-catalyzed cyclization of acetophenones with NH4OAc.

In this reaction DMF, in the presence of Ru/O2 catalyst, acted as a single carbon source. For better understanding of reaction mechanism, several control experiments were carried out [28] (Figure 4). Acetophenone was converted into a methyl ketene intermediate A by homo-condensation, which immediately converts into imine intermediate B, with the aid of NH4OAc. Further, tautomerization of imine intermediates lead to the formation of intermediate C, which reacted smoothly with iminium species D to give intermediate E then this can be oxidized by Ru/O2 to afford intermediate F, which further undergoes 6π electron cyclization followed by methylamide elimination to give the desired pyridine.

2.2 Construction of pyrimidine ring

Jiang and co-workers developed the first example of employing N,N-dimethylformamide (DMF) as a dual synthon, a one-carbon atom and amide source. A multi-component reaction between amidines 8, styrene 9, and N,N-dimethylformamide (DMF) took place in the presence of palladium-catalyst (Figure 5) to form pyrimidine carboxamide 10.

Figure 5.

DMF as a dual synthon in synthesis of pyrimidine carboxamide.

The desired product was obtained in good yield under the optimal reaction condition Pd(TFA)2 (5 mol%), Xantphos (5 mol%) and 70% TBHP (3.0 equiv) in 1.0 mL DMF at 120°C. Benzamidine salts containing electron-releasing or electron-withdrawing group on the benzene ring gave their desired product in moderate to good yield. Addition of radical scavenger, such as TEMPO (2,2,6,6-tetramethylpiperidine-1-oxyl), BHT (2,6-di-tert-butyl-4-methylphenol), and DPE (1,1-diphenylethylene) led to no desired product formation, which indicates the radical pathway is involved in this transformation [29].

Xiong et al., reported a general and highly selective method for annulation of amidines 15 (Figure 6).

Figure 6.

DMF as a one carbon source in Cu-catalyzed annulations of amidines.

This is an efficient copper catalyzed synthesis of quinazolines 12 through C-N bond formation reaction between N-H bonds of amidines and C(sp3)-H bond adjacent to sulfur or nitrogen atoms. In addition to DMF and DMA, DMSO, NMP and TMEDA could be used as solvent and as one carbon synthon [30]. This method avoids pre-functionalization of substrates.

In 2017, Fan et al., reported an efficient method for the synthesis of pyrimidines 13 from amidines 8 and ketones 12 through [3 + 2 + 1] type intermolecular cycloaddition reaction, under metal free condition (Figure 7). The reaction condition was optimized with different parameters and the suitable condition for multicomponent synthesis of pyrimidines was found to be, treatment of amidines (0.25 mmol), ketone (0.30 mmol), 70% TBHP (3.0 equiv), Cs2CO3 (2.0 equiv) in DMF (1.0 mL) at 120°C [31]. Both substituted amidines and substituted ketones worked well under standard condition to give pyrimidines in moderate to good yield. The reaction progressed well with d7-DMF and the desired isotopic labeled product was obtained. This is evidence that the carbon atom comes from the DMF.

Figure 7.

DMF in multicomponent synthesis of pyrimidines from amidines.

2.3 Construction of quinazolinone ring

In 2016, Das et al., reported Pd/Ag catalyzed direct carbonylation of sp2C-H bonds of 14 and 16 by employing DMF as one carbon source under oxygen for the synthesis of biologically important motifs pyrido-fused quinazolinone 15 and phenanthridinone 17, respectively (Figure 8).

Figure 8.

Pd/Ag catalyzed pyrido carbonylation of N-phenylpyridin-2-amine.

The reaction was examined using different metal catalyst systems such as Pd-Ag, Cu-Ag, Co-Ag, Ni-Ag and finally Pd-Ag catalytic system was found to be suitable for this transformation [32]. When labeled DMF (CO18) was used as the solvent it has been found that product found not to contain O18. From these results, it can be concluded that incorporated carbonyl group is coming from the methyl group of DMF. Reaction under argon instead of oxygen lead to the poor yield, which indicates “O” atom is coming from oxygen environment.

In 2015, Wu et al., reported C-H bond activation of arenes 14 followed by cyclization wherein DMF was used as the CO synthon, in the presence of Pd(OAc)2-K2S2O8 catalytic system under carbon monoxide atmosphere (Figure 9). The reaction works at autoclave free condition for the formation of H-pyrido[2,1b]quinazolin-11-ones 15.

Figure 9.

DMF as CO source in Pd-catalyzed carbonylation.

The reaction was optimized using different oxidant and catalysts under different temperature condition and the desired product was obtained in good yield in the presence of Pd(OAc)2-K2S2O8 and DMF/TFA solvent system at 140°C under O2 atmosphere. When the reaction was conducted with 13CO-labeled DMF (1a), the formation of 13C product was detected using gas chromatography (GC). This indicates CO gas has been generated from the carbonyl of DMF with acid as the promoter. This protocol is simple, has broad substrate scope and the products are obtained in excellent yields [33].

2.4 Construction of dihydropyrroline indolone ring

In 2017, Chang and coworkers reported metal, ligand free, base promoted cascade reaction of DMF with N-tosyl-2-(2-bromophenylacetyl)pyrroles (17) for the synthesis of dihydropyrrolizino[3,2-b]indol-10-ones 16 (Figure 10) [34].

Figure 10.

Synthesis of dihydropyrrolizino[3,2-b]indol-10-one.

2.5 Construction of acyl indole ring

Deng et al., reported a metal free approach for the synthesis of 3-acylindoles 18 through a cascade reaction between 2-alkenylanilines 19 with N,N-dimethylformamide (DMF) as a one-carbon source (Figure 11). This methodology worked with O2 as a terminal oxidant as well as oxygen donor. The 2-alkenylanilines containing different substitution such as, tosyl groups and other sulfonamides gave the desired 3-acylindoles in low to good yields. Unluckily, the substrate with a primary amine group failed to provide the desired product.

Figure 11.

Formation of 3-acylindoles from 2-alkenylanilines.

To prove the synthetic utility of this transformation gram scale experiment was conducted under optimized condition, wherein the yield of the corresponding product decreased slightly. Control experiments revealed that DMF acts as carbon source and O2 is the source of the oxygen. When deuterium labeled DMF was used as solvent, the labeled product was observed. Meantime, to probe the source oxygen atom in the final product a reaction has implemented with 18O-DMF and only non-labeled product was obtained. Thus, author justified that O2 is the source of the oxygen atom in the final product [35].

2.6 Construction of benzothiazole ring

Liu et al., developed a methodology for the synthesis of N-containing heterocycles including benzothiazoles, benzomidazoles, quinazolinone and benzoxazole using combination of B(C6F5)3, atmospheric CO2 and Et2SiH2 (Figure 12). This catalytic system was found to be highly effective for the cyclization of 2-aminobenzenethiol 20 or o-phenylenediamine 23 with N,N-dimethylformamide 1a, utilizing CO2 in this process. The reaction condition was optimized with different parameters and the corresponding product was obtained in the presence of 2-aminothiophenol (0.5 mmol), B(C6F5)3 (5 mol%), Et2SiH2 (2 mmol), DMF (1 mL), CO2 at 120°C.

Figure 12.

The cyclization of 2-aminothiophenol with DMF.

To understand the role of CO2 in this reaction, isotopic labeling reaction were carried out using 13CO2, the non-labeled benzothiazole was observed in excellent yield [36]. When this cyclization reaction was carried out using d7-DMF instead of DMF, deuterated benzothiazole was obtained. This experiment revealed that DMF served as the formylating reagent CO2 as the promoter.

2.7 Construction of benzimidazole ring

Yadav et al. developed a cost effective synthetic protocol with 100% conversion of o-nitroaniline to benzimidazole using DMF as in-situ source of dimethylamine and CO. Herein, DMF undergoes water gas shift reaction in the presence of CuFe2O4 as catalyst to produce hydrogen (Figure 13). It mainly involves two steps the reduction of o-nitroaniline 22 to o-phenylenediamine 24 followed by cyclization. The ratio of DMF:water affects the conversion of o-nitroaniline to benzimdazole 24 hence the optimized ratio is 2:1 for the best conversion and selectivity. Homogeneous catalyst (CuCl2) didn’t show any conversion, CuO showed diminished activity and CuFe2O4 exhibited better activity. Optimum temperature for the reaction condition was 180°C [37].

Figure 13.

One-pot synthesis of benzimidazole.

A possible mechanism was proposed by author. Thermal degradation of DMF in the presence of water provides CO, which undergoes water gas shift reaction in the presence of catalyst to release hydrogen gas. This H2 reduces nitro group to form amine group. The formation of o-phenylenediamine was confirmed with the help of GC-MS and HPLC analysis and compared with standard samples. Further, formylation of one of the amine groups took place in the presence CO, then intramolecular cyclisation takes place to give benzimidazole.

2.8 Construction of coumarin ring

Ohshita et al. developed method for the synthesis of coumarins 29 from ortho-quinone methide 26 formed via [2 + 2] cycloaddition of aryne 25 with DMF. Compound 26 reacted effectively with ester enolates 27 or ketenimine 28via [4 + 2] cycloaddition to provide different coumarins 29 (Figure 14) [38].

Figure 14.

Synthesis of different coumarin derivatives.

2.9 Construction of cyclic ether

Yamamoto and coworkers synthesized exocyclicdiene-type α,β,γ,δ-unsaturated amides 31 from hydrocarbamoylative cyclization of 1,6-diynes 30 with formamides under Ru-catalyst with complete stereoselectivity (Figure 15) [39].

Figure 15.

Hydrocarbamoylative cyclization of 1,6-diynes with DMF.


3. Amidation

Having covered literature on construction of cyclic system, especially heterocycles using DMF or DMA as a next part we cover literature on the formation of open chain compounds.

An excellent method to access benzamides 33via aminocarbonylation of aryl and alkenyl iodides 32, with DMF as amide source, in the presence of Pd/POCl3 catalytic system, was demonstrated by Hiyama et al. (Figure 16) [40].

Figure 16.

Metal catalyzed aminocarbonylation of aryl halides using DMF.

Similarly, Indolese et al. reported aminocarbonylation of aryl halides 32 with Pd catalyst, triphenylphosphine ligand in CO atmosphere under pressure. DMAP is used as base for this reaction and the yield obtained is very high [41]. It is an important synthetic method since it can also be applied to pyridine and thiophene halides (Figure 16).

Furthermore, Lee and co-workers demonstrated the same reaction between aryl bromides/iodides 32 and DMF with the help of inexpensive Nickel acetate tetrahydrate as catalyst and using phosphite ligand and sodium methoxide as base in dioxane solvent (Figure 16) [42].

Wang et al., reported a metal-free radical amidation of thiazoles and oxazoles 34 with a series of formamides and tert-butyl perbenzoate (TBPB) as radical initiator. By this method, synthesis of high yields of amidated azoles 35 were easily achieved (Figure 17) [43].

Figure 17.

DMF as a source for aminocarbonylation of azoles.

Wang et al., demonstrated direct amidation of alcohols 36 with formamides in the presence of an I2/TBHP with sodium hydroxide as a base and DMF as amide source (Figure 18) [44]. The same author reported amidation of benzyl amine 38 under the acidic condition [45].

Figure 18.

DMF as a source for aminocarbonylation of alcohol and amines.

Feng and coworkers proposed green protocol for the synthesis of α-ketoamides 41 through TBAI catalyzed sp3 C-H oxidative radical/radical cross-coupling. This method is applicable for broad range of substrates [46]. The only by product is water and no CO or CO2 emission is observed (Figure 19).

Figure 19.

DMF as aminocarbonylation source in synthesis of α-ketoamides.

Similarly, the synthesis of α-ketoamides 41 was achieved with readily available aryl methyl ketones 42 using inexpensive N,N-dialkylformamides in the presence of nBu4NI and aq.TBHP as catalyst and oxidant for radical oxidative coupling process (Figure 19). This strategy is a green and metal-free approach developed by Mai et al. [47].

In 2016, Xiao and his team developed a simple and efficient technique for the synthesis of amides 33 by cross coupling of carboxylic acids 43 with N-substituted formamides in the presence of Ru catalyst and the desired amide was obtained after the release of CO2 (Figure 20). The carbonyl group in the amide product came from benzoic acid and not from N-substituted formamides. This synthetic method is stable, inexpensive, low toxicity and eco-friendly. This method works well with different carboxylic acid derivatives and N-substituted formamides [48].

Figure 20.

DMF in Ru-catalyzed amidation of carboxylic acids.

Similarly, Tortoioli and co-workers demonstrated one-pot synthesis of dialkyl amides under metal free condition through the reaction between benzoic acid and DMF in presence of propyl phosphonic anhydride (T3P) with acid additives [49]. This mild method has been applied to the synthesis of dihydrofolate reductase inhibitor, triazinate (Figure 21).

Figure 21.

Amidation of benzoic acid with DMF.

Bhat et al. reported direct carbamoylation of heterocycles 44via direct dehydrogenative aminocarbonylation under transition metal-free condition 45 (Figure 22). Persulfate which is played the role of an efficient oxidant, good radical initiator, mild and eco-friendly low cost reagent and formamides NMF and DMF acted as reagent to form primary to tertiary carboxamides [50].

Figure 22.

DMF as source for aminocarbonylation of quinoline.

Bhisma et al. gave an efficient copper catalyzed synthesis of phenol carbamates 47 from dialkylformamides as aminocarbonyl surrogate and phenols possessing directing groups such as benzothiazoles, quinoline and formyl at ortho-position (Figure 23). It’s a cheap and eco-friendly reaction with tolerance of wide range of functional groups and phosgene free route to carbamates [51].

Figure 23.

Carbamate synthesis from phenols and formamides.

Phan and coworkers under oxidative condition synthesized organic carbamates 49 through C-H activation using metal organic framework Cu2(BPDC)2(BPY) (BPDC = 4,4′-biphenyldicarboxylative, BPY = 4,4′-bipyridine) as heterogeneous catalyst for cross dehydrogenative coupling of DMF with 2-substituted phenols 48 (Figure 24). This catalyst has higher catalytic activity and it is easily recoverable and reusable [52].

Figure 24.

CDC reaction of phenol with DMF.

Yuan et al., synthesized S-phenyldialkylthiocarbamate 51 compounds under solvent free conditions through TBHP promoted radical pathway, in which direct oxidation of acylC-H bond of formamides took place in the presence of Cu(OAc)2 to form the reaction intermediate for oxidative coupling reaction of formamides with thiols 50 (Figure 25) [53]. This protocol is efficient and green.

Figure 25.

Synthesis of S-phenyldialkylthiocarbamate.

Kamal and coworkers proposed an efficient and greener methodology for the synthesis of selenocarbamates 53 by oxidative coupling reaction between formamides and diselenides 52 under metal free conditions (Figure 26). By using simple reaction condition, a metal-free approach to direct C-Se bond formation occurred at carbonyl carbon by using TBHP and molecular sieves. It uses non-functionalized substrate which is an advantage of this reaction [54].

Figure 26.

Oxidative C-Se coupling of formamides and diselenides.

Reddy and coworkers synthesized chiral symmetrical urea derivatives 54 through copper catalyzed C-H/N-H coupling of formamides (both mono and di) with different amines 53 (primary, secondary and substituted aromatic amines) using TBHP as an oxidant and it involves a radical pathway (Figure 27). The importance of this green reaction is, it avoids the use of pre-functionalized substrates, atom economical [55].

Figure 27.

Synthesis of chiral symmetrical urea derivatives from DMF.

3.1 Amination

Chang et al., reported that benzoxazoles 34 on treatment with N,N-dimethylformamide (DMF) using the Ag2CO3 as catalyst in the presence of an acid additive, 2-aminated benzoxazole 55 was obtained as a single product in moderate yield (Figure 28).

Figure 28.

Amidation of benzoxazole using Ag2CO3 catalyst.

Interestingly, this method is also suitable for the optically active formamide, the desired product was obtained in better yield without racimization [56].

Li et al., gave a method for the synthesis of 2-aminoazole derivatives 58 in which construction of C-N bond of azoles 34 either by decarboxylative coupling with formamides as nitrogen source or by a direct C-H amination with secondary amines as nitrogen source by the use of inexpensive Cu catalyst, O2 or air as oxidant is green and benzoic acid has its main role in the release of amine from amides by decarbonylation other than C-H activation [57].

Similarly, Yu et al., developed a decarbonylative coupling between azoles and formamides. The iron catalyzed direct C-H amination of azoles at C2 took place in the presence of formamides and amines as nitrogen source (Figure 29). Easily accessible iron (II) salts acted as Lewis acid which activated the C2 position of benzoxaoles 34 and oxidant and imidazole was used as an additive in the catalyst under air. This direct azole amination was catalyzed by inexpensive and environmentally benign reagents. The reaction was also carried with amines in the presence of acetonitrile [58].

Figure 29.

Amidation of benzoxazole using Cu or Fe catalyst.

Peng and coworkers developed a facile and efficient route for one pot synthesis of 2-acyl-4-(dimethylamino)-quinazoline 57 through direct amination of 2-aryl quinazoline-4(3H)ones 56 with DMF in which 4-toluene sulfonyl chloride acted as C-OH bond activator (Figure 30). KOtBu was used as base which leads to the formation of tosylate which attacks DMF which in turn undergoes hydrolysis to give aminated product 59. This reaction is inexpensive and uses easy to handle reagents [59].

Figure 30.

Direct amination of 2-aryl quinazoline-4(3H)ones with DMF.

Eycken et al. demonstrated a convenient microwave-assisted de-sulfitative dimethylamination of 5-chloro-3-(phenylsulfanyl)-2-pyrazinones 58 using DMF as a dimethylamine source and sodium carbonate as an essential (Figure 31). The solvent system used for this reaction is DMF:H2O in 1:1 ratio and the corresponding de-sulfitative aminated product 59 was obtained in good yield. Finally, the utility of this methodology was also examined on oxazinone in place of pyrazinones under the optimized conditions and the desired products were formed in good yield [60].

Figure 31.

De-sulfitative amination of 2(1H) pyrazinone.

Hongting et al. developed an efficient, atom-economic and eco-friendly approach for synthesizing enamines 61 by intermolecular hydroamination of activated alkynes (Figure 32). The reaction was carried out under solvent free condition using a catalyst at room temperature. Primary or secondary amines 53 were added to triple bonds 60 without generating any waste products. DMF pretreated with metal Na was used for synthesis of (E)-ethyl-3-(dimethylamino)acrylate and a new way for synthesis of quinolines was given [61].

Figure 32.

Intermolecular hydroamination of activated alkynes.

Li et al., developed hypervalent iodine mediated reaction between carboxylic acids 43 and N,N-dimethylformamide which occur under mild conditions at room temperature to provide novel O-aroyl-N,N-dimethyl hydroxyl amines 62 in good yields (Figure 33), which are important electrophilic amination reagents. The process shows good functional group compatibility, air and moisture tolerance [62].

Figure 33.

Synthesis of O-aroyl-N,N-dimethyl hydroxyl amines.

Liang and coworkers gave a simple and efficient one-pot multicomponent reaction of chalcones 63, malononitrile 64 and DMF in the presence of NaOH for the synthesis of functionalized 4-oxobutanamides 65 (γ-ketoamides) from simple α,β-unsaturated enones (Figure 34). This reaction has a high atom economy, easily available starting materials, operational simplicity with mild conditions, broad substrate scope and good tolerance with diverse functional groups [63].

Figure 34.

Synthesis of γ-ketoamide.

Xia and coworkers proposed a simple and green approach for the synthesis of sulfonamides through t-BuOK mediated direct S-N bond formation from sodium sulfinates 66 with formamides (Figure 35). This reaction undergoes in a metal-free conditions and formamides are used as amine source. It avoids pre-functionalized starting materials and forms an alternative method for the synthesis of sulfonamids 67 [64].

Figure 35.

Synthesis of sulfonamides using DMF as a amine source.

Gong et al., reported a base-promoted amination of aromatic halides 32 using a limited amount of N,N-dimethylformamide or amine as an amino source. Various aryl halides, including F, Cl, Br, and I, have been successfully aminated 68 in good to excellent yields (Figure 36) [65]. This protocol is valuable for industrial application due to the simplicity of operation, the unrestricted availability of amino sources and aromatic halides.

Figure 36.

A base-promoted amination of aromatic halides.

3.2 Methylenation

In recent past several methods were developed for using DMF as a methylene source.

Wang et al., developed a new method for the synthesis of vinylquinolines 70 from methyl quinolines 69 (Figure 37) using DMF as a methylene source. The synthesis was carried out via an iron-catalyzed sp3 C-H functionalization and a subsequent C-N cleavage using TBHP as a radical initiator. This method is simple and effective for synthesis of large number of vinyl substituted quinoline derivatives in excellent yield. It also avoids the usage of organometallic compounds as reagents [66].

Figure 37.

Synthesis of vinyl quinolones using DMF with iron catalyst.

Qian Xu and coworkers developed an eco-friendly iron-catalyzed benzylic vinylation which transfers the carbon atom in N,N-dimethyl group from DMA or DMF to 2-methyl azaarenes 71 to generate 2-vinyl azaarenes 72 (Figure 38). The reaction of N,N-dimethyl amides as one carbon source proceeded via radical mechanism [67].

Figure 38.

DMA or DMF Synthesis of vinyl 2-vinylazaarenes.

Miura et al., demonstrated an effective way for α-methylenation of benzyl pyridines 73 using copper catalyst. In the methylenation, N-methyl group of DMA was incorporated as the one-carbon source to produce α-styrylpyridine 74 derivatives (Figure 39), which are famous for their unique biological properties [68].

Figure 39.

α-methylenation of benzylpyridines using DMA.

Li et al., developed an iron-catalyzed α-methylenation of aryl ketones 75 by using N,N-dimethylacetamides as a one-carbon source to form α, β-unsaturated carbonyl compounds (Figure 40). Potassium persulfate is used as oxidant and this method acts as an excellent synthetic method for synthesis of α, β-unsaturated carbonyl compounds 76 [69].

Figure 40.

α-methylenation of acetophenones.

In 2019, Wang et al., reported a one-pot procedure for the synthesis of 3-indolyl-3-methyl oxindoles 78via C(sp3)-H methylenation of 2-arylacetamides 77 using DMF/Me2NH-BH3 as the methylene source (Figure 41) [70].

Figure 41.

α-methylenation of 2-arylacetamides with DMF.

Liu and coworkers reported a method for the synthesis of diindolylmethane 80 and its derivatives which is done through copper catalyzed C-H activation of indole 79 where in DMF was used as a methylenating reagent. CuCl was mainly used as a catalyst which affords high regioselectivity and TBHP as oxidant. The reaction utilizes readily available copper catalyst and inexpensive DMF as carbon source and it has a broad scope of substrates with relatively mild reaction conditions (Figure 42) [71].

Figure 42.

Cu-catalyzed synthesis of diindolylmethane.

In 2014, Xue and co-workers developed methylation of ketones 42 with DMF, control experiment studies indicate that DMF plays dual functions as the source of carbon for methylation and source of hydrogen in the rhodium-catalyzed reduction of the methylene into a methyl group (Figure 43) [72].

Figure 43.

Rh-catalyzed direct methylation and hydrogenation of ketones using DMF.

A possible mechanism was proposed as shown in Figure 44. Initially, persulfate oxidizes DMF to give a reactive iminium intermediate. The intermediate A generated by attack of enolate is converted to intermediate B followed by C-N bond cleavage to generate unsaturated ketone intermediate C. Afterwards, the intermediate C is reduced, which is probably generated by using DMF via dehydrogenation with the aid of [Cp*RhCl2]2, which results in the formation of methylated product.

Figure 44.

A possible mechanism for methylation and hydrogenation of ketone.

3.3 Amidoalkylation

Li et al., reported direct oxidative thiolation of sp3 C-H bond next to a nitrogen atom 83 with disulfides 82 under metal free condition for the synthesis of several N, S containing compounds (Figure 45).

Figure 45.

Thiolation of sp3 C-H bond next to a nitrogen atom.

In this oxidative thiolation reaction, thiol group was successfully coupled with sp3 C-H bond of N,N-dialkyl amides in the presence of TBHP/Molecular sieves through the formation of radical intermediate.

It is noteworthy that various benzothiazole and a fipronil analogs could also be synthesized through this methodology (Figure 46) [73].

Figure 46.

TBHP-mediated synthesis of benzothiazoles.

Stephenson et al., developed Friedel-Craft amidoalkylation of alcohols and electron rich arenes as potent nucleophile with alkyl amides 1bvia thermolysis and oxidative photocatalysis (Figure 47). The FC amidoalkylated product 85 was obtained by oxidation of N,N-dialkyl amides with the aid of persulfate and photocatalyst. On the other hand, persulfate at 55°C also afford amidoalkylated product.

Figure 47.

FC amidoalkylation using alkyl amides.

In this method inexpensive and efficient persulfate was used as oxidant for the construction of C-O and C-C bonds. Most of the time, photo catalysis provided better selectivity and good yields for the Friedel-Crafts reactions as compared with the thermolytic reaction conditions [74].

Li et al., gave a transition metal-free method for amidation of sp3 C-H bond in amides through cross dehydrogenative coupling process by using iodide anion as catalyst and TBHP as oxidant (Figure 48). It proceeds through free radical intermediate which is confirmed by TEMPO and the products has an potential bioactivity 87. This is an efficient method for direct C-N bond formation because of its mild conditions and readily available reagents [75].

Figure 48.

Amidoalkylation under metal free condition using DMA.

In 2017, Chen and coworkers demonstrated copper-catalyzed C-N bond formation of triazoles via cross dehydrogenative coupling (CDC) of NH-1,2,3-triazoles 88 with N,N-dialkylamides to construct N-amidoalkylated triazoles 89 (Figure 49). When the reaction was performed with 4-aryl-substituted NH-1,2,3-triazoles the desired N2-substituted 1,2,3-triazoles was obtained and small amount of N1 products were also observed. This method is useful for the synthesis of N2-substituted 1,2,3-triazolesselectively [76].

Figure 49.

Copper-catalyzed C-N bond formation of triazoles.

Zhu and Co-Workers discovered a new methodology for the synthesis of 2-amidoalkylated benzothiazole and 3-amidoalkyl substituted indolinone derivatives using N,N-dialkylamides and potassium persulfate as an oxidant under metal free condition (Figure 50). The corresponding amidoalkylation products were formed selectively using simple N,N-dialkyl amides including formamides [77].

Figure 50.

Amidoalkylation of benzothiazoles with DMA.

3.4 Cyanation

It is interesting to note that dialkylamides could undergo reaction to generate cycano group. In 2011 Ding et al., reported a novel and another kind of pathway to produce the aryl nitriles through the Pd-catalyzed cyanation of indoles 79 and benzofurans by functionalization of C-H bond using DMF as a source of CN and control experiments revealed that N and C of the cyano group are generated from DMF [78].

Similarly, in 2015, Chen and co-workers developed a selective copper-catalyzed C3-cyanation of indole under an oxygen atmosphere with DMF as a safe CN source and as a solvent (Figure 51) [79].

Figure 51.

Cyanation of indole and benzofuran.

Wang et al., demonstrated a copper catalyzed cyanation of indoles 82 using DMF as a single surrogate of CN (Figure 52). Electron rich arenes and aryl aldehydes can be transformed to acyl nitriles. Acyl aldehydes is the key intermediate for this transformation. The mechanism of this reaction involved C-H activation with the help of copper catalyst then followed by carbonylation. 3-cyanoindoles have attracted much great extend owing to their importance in medicinal field especially in the preparation of therapeutic estrogen receptor ligand [80].

Figure 52.

Cyanation of indole with DMF.

Chang et al., reported a new approach for the synthesis of Aryl nitriles 93. Cyanation of aryl halides 32 catalyzed with copper acetate and Ag as an oxidant, in combination of ammonium bicarbonate as N source and DMF as a C source for cyanide functional group (Figure 53). With respect to the key roles of Cu(II) species in the in-situ formation of CN units and followed by cyanation of aryl halides, Ag2CO3 re-oxidizes the resultant Cu(I) species under copper-catalyzed oxidative conditions. This strategy is a practical and safe method and capable of providing nitriles in moderate to good yields [81].

Figure 53.

Cyanation of arylhalides and plausible mechanism.

Ushijima et al., reported the synthesis of aromatic nitriles 93 from electron-rich aromatics 40 under metal free one pot reaction condition. When the combination of molecular iodine in aqueous ammonia, with POCl3 and DMF (Figure 54).

Figure 54.

Conversion of electron-rich aromatics into aromatic nitriles.

A possible mechanism for this reaction was given in Figure 54. When treated with ammonia, the iminium salt can be transformed into the aromatic imine. Then molecular iodine serves as an oxidizing agent and reacts with the aromatic imine to provide the corresponding aromatic N-iodoimine, which generates the aromatic nitrile through elimination in aqueous ammonia [82].

However, the need of highly electron-rich aromatics in the formation of aromatic N,N-dimethyl iminium salts limits the scope of this transformation. So, the authors should develop more convenient methods for this transformation. Following this work, they reported a novel one-pot method for the preparation of aromatic nitriles from aryl bromides and arenes through the formation of aryl lithium and their DMF adducts (Figure 55) [83].

Figure 55.

Conversion of electron-rich aromatics into aromatic nitriles and plausible mechanism.

Followed by the treatment with molecular iodine in aqueous ammonia. Similarly, the same author reported synthesis of aryl nitriles from aryl bromides in the presence of Mg [84].

3.5 Formylation

Further, dialkylamides were also used as a formylation source. Wang et al., transformylated different amines, primary or secondary, aromatic or alkyl cyclic or linear, mono- or di-amine with DMF as formylation reagent to obtain corresponding formamides 95 with CeO2 catalyst and the reaction does not require any homogeneous acidic or basic additives and it is tolerant to water.

The best part about the CeO2 catalyst is the strong basicity and medium water-tolerant acidity (Figure 56) [85].

Figure 56.

Transformylation of amines with DMF.

In 2017, Jagtap and coworkers reported highly efficient Ni(II) metal complex catalyzing N-formylation 96 and N-acyltion 97 of amines using N,N-dimethylformamide and N,N-dimethylacetamide as acyl source (CHO) in the presence of imidazole at a temperature of 150°C in a homogeneous medium (Figure 57). It has a broad substrate scope to aliphatic, aromatic and heterocyclic compounds.

Figure 57.

Formylation and acylation of amines using N,N-dialkylamides.

The importance of this reactions are cost-effective, easily available starting material, high reactivity and inertness toward air and water [86].

Larsen et al., developed a convenient method for the synthesis of α,β-acetylenic aldehydes 101, acetylides that are initially transformed to lithium acetylides with the aid of n-BuLi (Figure 58). The formylation of lithium acetylides was accomplished in the presence of DMF and followed by α-aminoalkoxide with 10% aqueous KH2PO4 to provide desired product with good yield [87].

Figure 58.

Synthesis of α,β-acetylenic aldehydes.

Jeon and co-workers reported methyl benzoate 102 promoted N-formylation of different primary and secondary amines 38 employing DMF as a formylating agent under microwave irradiation (Figure 59). Key advantage of this methodology is selective N-formylation in the presence of a hydroxyl group [88].

Figure 59.

N-formylation of various 1° and 2°.

3.6 Hydrogenation

Dialkylamides have ability to acts as hydrogen source and it has been used in several functional group transformations. It is advantageous to use hydrogen gas in situ generated from dialkylamides rather than handling easily flammable hydrogen gas.

Hua et al. reported triruthenium dodecacarbonyl [Ru3(CO)12] catalyzed stereo divergent semi-hydrogenation of diaryl alkynes 104 with N,N-dimethylformamide/water as hydrogen source for the synthesis of cis-105 and trans 106-stilbenes (Figure 60). When the HOAc was used excellent stereoslectivity was observed in favor of formation of cis-product. Surprisingly, the stereochemical preference changed to trans-isomer, with TFA as additive. This strategy is useful for the synthesis of analogs of natural products such as cis-combretastatin A-4 and trans-resveratrol [89].

Figure 60.

Stereodivergent [Ru3(CO)12] catalyzed semihydrogenation of diaryl alkynes.

Chan et al., reported a hydrogenation reaction catalyzed by cobalt porphyrins which hydrogenated C-C bond of [2.2] paracyclophane 107 (PCP) with DMF as solvent as well as hydrogen atom transfer agent (Figure 61). Metalloradical Co(II) porphyrins attacks the C-C sigma bond of PCP and the resultant benzyl radical abstracts a hydrogen atom from DMF to afford the hydrogenated product 108. Results obtained from various control experiment revealed that the presence of benzyl radical intermediates in undergoing hydrogen atom transfer from DMF [90].

Figure 61.

DMF as hydrogenating reagent for benzylic positions.

In 2017, Liu and coworkers synthesized α-arylketothioamides 110via copper oxide and iodine mediated direct redox reaction from acetophenones 78, elemental sulfur 109 and DMF under the nitrogen atmosphere (Figure 62). The elemental sulfur acts as a nucleophilic building block while DMF act as solvent and as the source of amino group (dimethylamine). This reaction tolerates a wide range of functional groups and proceeded in a redox efficient manner [91].

Figure 62.

Synthesis of α-arylketothioamides.

3.7 Carbonylation

Carbonylation is another important reaction in which the poisonous “CO” gas is generated from dialkylamides in the presence of suitable catalysts. Thus carbonylation reaction using dialkylamides is highly advantageous.

Gunanathan and coworkers developed a new mode of bond activation which is used effectively for the synthesis of simple and functionalized symmetrical and unsymmetrical urea derivatives from amines using DMF as CO source (Figure 63). Activation of N-H bond of amines by Ruthenium pincer complex and after that CO insertion from DMF with the liberation of hydrogen. Nucleophilicity of amines is essential for urea formation. The significance of this reaction occurs in an open condition, it avoids side products, doesn’t require any pressure setup [92].

Figure 63.

Carbonylation of amines with DMF.

Furthermore, Chen and co-workers reported a unique and highly effective method for the formation of imidazolinones 112 from carbene complexes 111 through oxygen atom insertion reaction of NHC copper complexes in the presence of DMF as the source of oxygen (Figure 64) [93].

Figure 64.

Formation of complicated imidazolinones with DMF.


4. Conclusion

It is noteworthy that, the utilization of DMF as a precursor in heterocyclic synthesis was important development in the field of synthetic organic chemistry. With advent of new reagents, catalytic systems and need for development of efficient synthetic protocols it could be predicted that dialkyl amides will continue to find new applications in organic synthesis. So far dialkyl amides have been mainly utilized as a synthon through mono functionalization of one of the groups. Further, there is a lot of scope for its utilization as a difuctionalization, for example, alkyl group attached to carbonyl and nitrogen in DMA could be functionalized at both the ends simultaneously. Dialkyl amides due to low cost, ready availability and flexibility in reactivity, will continue to gain attention of synthetic chemists as a synthon, ligand, dehydrating agent and solvent. We appreciate all of the authors cited herein for their tremendous contributions that have developed this field. We hope that it is sufficiently impressive and thorough that it will increase the interest on organic chemistry and will initiate further developments in the applications of DMF/DMA beyond being just a polar solvent, because it can be used as substrates in several reactions such as formylation, amination, amidoalkylation, aminocarbonylation, amidation, and cyanation and it has been achieved under both metal-catalyzed and metal-free conditions. We believe this book chapter will make it easy for the synthetic chemists and invoke an idea about utility of dialkyl amides for some novel functional group transformations.



P.S thanks to UGC-RFSMS, New Delhi for the award of the fellowship for Ph.D.


Conflict of interest

The authors declare no conflict of interest.


  1. 1. Muzart J. N,N-dimethylformamide: Much more than a solvent. Tetrahedron. 2009;65:8313-8323. DOI: 10.1016/j.tet.2009.06.091
  2. 2. Dubey A, Upadhyay A, Kumar P. Pivaloyl chloride/DMF: A new reagent for conversion of alcohols to chlorides. Tetrahedron Letters. 2010;51:744-746. DOI: 10.1016/j.tetlet.2009.11.131
  3. 3. Liu Y, He G, Chen K, Jin Y, Li Y, Zhu H. DMF-catalyzed direct and regioselective C-H functionalization: Electrophilic/nucleophilic 4-halogenation of 3-oxypyrazoles. European Journal of Organic Chemistry. 2011;2011:5323-5330. DOI: 10.1002/ejoc.201100571
  4. 4. Rai A, Rai VK, Singh AK, Yadav LDS. [2 + 2] Annulation of aldimines with sulfonic acids: A novel one-pot cis-selective route to β-sultams. European Journal of Organic Chemistry. 2011;2011:4302-4306. DOI: 10.1002/ejoc.201100628
  5. 5. Gowda M, Pande S, Ramakrishna R, Prabhu K. Acylation of Grignard reagents mediated by N-methyl pyrrolidone: A remarkable selectivity for the synthesis of ketones. Organic & Biomolecular Chemistry. 2011;9:5365-5368. DOI: 10.1039/C1OB05780D
  6. 6. Liu X, Li C, Xu J, Lv J, Zhu M, Guo Y, et al. Surfactant-free synthesis and functionalization of highly fluorescent gold quantum dots. Journal of Physical Chemistry C. 2008;112:10778-10783. DOI: 10.1021/jp8028227
  7. 7. Kawasaki H, Yamamoto H, Fujimori H, Arakawa R, Inada M, Iwasaki Y. Surfactant-free solution synthesis of fluorescent platinum subnanoclusters. Chemical Communications. 2010;46:3759-3761. DOI: 10.1039/B925117K
  8. 8. Hyotanishi M, Isomura Y, Yamamoto H, Kawasaki H, Obora Y. Surfactant-free synthesis of palladium nanoclusters for their use in catalytic cross-coupling reactions. Chemical Communications. 2011;47:5750-5752. DOI: 10.1039/C1CC11487E
  9. 9. Yao W, Gong WJ, Li HX, Li FL, Gao J, Lang JP. Synthesis of DMF-protected Au NPs with different size distributions and their catalytic performance in the Ullmann homocoupling of aryl iodides. Dalton Transactions. 2014;43:15752-15759. DOI: 10.1039/C4DT01856G
  10. 10. Azuma R, Nakamichi S, Kimura J, Yano H, Kawasaki H, Suzuki T, et al. Solution synthesis of N,N-dimethylformamide-stabilized iron-oxide nanoparticles as an efficient and recyclable catalyst for alkene hydrosilylation. ChemCatChem. 2018;10:2378-2382. DOI: 10.1002/cctc.201800161
  11. 11. Shanab FA, Sherif SM, Mousa SAS. Dimethylformamide dimethyl acetal as a building block in heterocyclic synthesis. Journal of Heterocyclic Chemistry. 2009;46(5):801-827. DOI: 10.1002/jhet.69
  12. 12. Ding S, Jiao N. N,N-dimethylformamide: A multipurpose building block. Angewandte Chemie, International Edition. 2012;51:9226-9237. DOI: 10.1002/anie.201200859
  13. 13. Batra A, Singh P, Singh KN. Cross dehydrogenative coupling (CDC) reactions of N,N disubstituted formamides, benzaldehydes and cycloalkanes. European Journal of Organic Chemistry. 2016:4927-4947. DOI: 10.1002/ejoc.201600401
  14. 14. Bras JL, Muzart J. Recent uses of N,N-dimethylformamide and N,N-dimethylacetamide as reagents. Molecules. 2018;23:1939. DOI: 10.3390/molecules23081939
  15. 15. Heravi MM, Ghavidel M, Mohamadkhani L. Beyond a solvent: triple roles of dimethylformamide in organic chemistry. RSC Advances. 2018;8:27832-27862. DOI: 10.1039/C8RA04985H
  16. 16. Kodimuthali A, Mungara A, Prasunamba PL, Pal M. A simple synthesis of aminopyridines: Use of amides as amine source. Journal of the Brazilian Chemical Society. 2010;21:1439-1445. DOI: 10.1590/S0103-50532010000800005
  17. 17. Gu DW, Guo XX. Synthesis of N-arylcarboxamides by the efficient transamidation of DMF and derivatives with anilines. Tetrahedron. 2015;71:9117-9122. DOI: 10.1016/j.tet.2015.10.008
  18. 18. Chen C, Tan L, Zhou P. Approach for the synthesis of N-phenylamides from β-ketobutylanilides using dimethylformamide and dimethylacetamide as the acyl donors. Journal of Saudi Chemical Society. 2015;19:327-333
  19. 19. Mondal S, Samanta S, Santra S, Bagdi AK, Hajra A. N,N-dimethylformamide as a methylenating reagent: Synthesis of heterodiarylmethanes via copper-catalyzed coupling between imidazo[1,2-a]pyridines and indoles/N,N-dimethylaniline. Advanced Synthesis and Catalysis. 2016;358:3633-3641. DOI: 10.1002/adsc.201600674
  20. 20. Weng JQ, Xu WX, Dai XQ, Zhang JH, Liu XH. Alkylation reactions of benzothiazoles with N,N-dimethylamides catalyzed by the two-component system under visible light. Tetrahedron Letters. 2019;60:390-396. DOI: 10.1016/j.tetlet.2018.12.064
  21. 21. Iranpoor N, Firouzabadi H, Rizi ZT, Erfan S. WCl6/DMF as a new reagent system for the phosphine-free Pd(0)-catalyzed aminocarbonylation of aryl halides. RSC Advances. 2014;4:43178-43182. DOI: 10.1039/C4RA04673K
  22. 22. Venu B, Vishali B, Naresh G, Kumar VV, Sudhakar M, Kishore R, et al. C-H bond cyanation of arenes using N,N-dimethylformamide and NH4HCO3 as a CN source over a hydroxyapatite supported copper catalyst. Catalysis Science & Technology. 2016;6:8055-8062. DOI: 10.1039/C6CY01536K
  23. 23. Kim J, Choi J, Shin K, Chang S. Copper-mediated sequential cyanation of aryl C-B and arene C-H bonds using ammonium iodide and DMF. Journal of the American Chemical Society. 2012;134:2528-2531. DOI: 10.1021/ja211389g
  24. 24. Mata EG, Suarez AG. Regioselective acylation of benzodioxin derivatives employing AlCl3-DMSO or AlCl3-DMF reagent in the Friedel-Crafts reaction. Synthetic Communications. 1997;27:1291-1300. DOI: 10.1080/00397919708003368
  25. 25. Ahmed S, Boruah R. An efficient conversion for conjugated oximes into substituted pyridines under Vilsmeier conditions. Tetrahedron Letters. 1996;37:8231-8232. DOI: 10.1016/0040-4039(96)01909-0
  26. 26. Zhao MN, Hui RR, Ren ZH, Wang YY, Guan ZH. Ruthenium-catalyzed cyclization of ketoxime acetates with DMF for synthesis of symmetrical pyridines. Organic Letters. 2014;16:3082-3085. DOI: 10.1021/ol501183z
  27. 27. Weng Y, Zhou H, Sun C, Xie Y, Su W. Copper-catalyzed cyclization for access to 6H-chromeno[4,3-b]quinolin-6-ones employing DMF as the carbon source. The Journal of Organic Chemistry. 2017;82:9047-9053. DOI: 10.1021/acs.joc.7b01515
  28. 28. Bai B, Tang L, Huanga H, Deng GJ. Synthesis of 2,4-diarylsubstituted-pyridines through a Ru-catalyzed four component reaction. Organic & Biomolecular Chemistry. 2015;13:4404-4407. DOI: 10.1039/05c5ob00162e
  29. 29. Guo W, Liao J, Liu D, Li J, Ji F, Wu F, et al. A four-component reaction strategy for pyrimidine carboxamide synthesis. Angewandte Chemie. 2016;128:1-6. DOI: 10.1002/ange.201608433
  30. 30. Lv Y, Li Y, Xiong T, Pu W, Zhang H, Sun K, et al. Copper-catalyzed annulation of amidines for quinazoline synthesis. Chemical Communications. 2013;49:6439-6644. DOI: 10.1039/c3cc43129k
  31. 31. Zheng LY, Guo W, Fan XL. Metal-free, TBHP-mediated, [3+ +2+ +1]-type intermolecular cycloaddition reaction: Synthesis of pyrimidines from amidines, ketones, and DMF through C(sp3)C-H activation. Asian Journal of Organic Chemistry. 2017;6:837-840. DOI: 10.1002/ajoc.201700105
  32. 32. Rao DN, Rasheed SK, Das P. Palladium/silver synergistic catalysis in direct aerobic carbonylation of C(sp2)-H bonds using DMF as a carbon source: Synthesis of pyrido-fused quinazolinones and phenanthridinones. Organic Letters. 2016;18:3142-3145. DOI: 10.1021/acs.orglett.6b01292
  33. 33. Chen J, Feng JB, Natte K, Wu X. Palladium-catalyzed carbonylative cyclization of arenes by C-H bond activation with DMF as the carbonyl source. Chemistry - A European Journal. 2015;21:16370-16373. DOI: 10.1002/chem.201503314
  34. 34. Zhang Q, Song C, Huang H, Zhang K, Chang J. Cesium carbonate promoted cascade reaction involving DMF as a reactant for the synthesis of dihydropyrrolizino[3,2-b]indol-10ones. Organic Chemistry Frontiers. 2018;5:80-87. DOI: 10.1039/C7QO00771J
  35. 35. Wang JB, Li YL, Deng J. Metal-free activation of DMF by dioxygen: A cascade multiple-bond-formation reaction to synthesize 3-acylindoles from 2-alkenylanilines. Advanced Synthesis and Catalysis. 2017;359:3460. DOI: 10.1002/adsc.201700584
  36. 36. Gao X, Yu B, Mei Q, Yang Z, Zhao Y, Zhang H, et al. Atmospheric CO2 promoted synthesis of N-containing heterocycles over B(C6F5)3 catalyst. New Journal of Chemistry. 2016;40:8282-8287. DOI: 10.1039/C6NJ01721E
  37. 37. Rasal KB, Yadav GD. One-pot synthesis of benzimidazole using DMF as a multitasking reagent in presence CuFe2O4 as catalyst. Catalysis Today. 2018;309:51-60
  38. 38. Yoshida H, Ito Y, Ohshita J. Three-component coupling using arynes and DMF: Straightforward access to coumarins via ortho-quinone methides. Chemical Communications. 2011;47:8512-8514. DOI: 10.1039/c1cc11955a
  39. 39. Mori S, Shibuya M, Yamamoto Y. Ruthenium-catalyzed hydrocarbamoylative cyclization of 1,6-diynes with formamides. Chemistry Letters. 2017;46:2. DOI: 10.1246/cl.160961
  40. 40. Hosoi K, Nozaki K, Hiyama T. Carbon monoxide free aminocarbonylation of aryl and alkenyl iodides using DMF as an amide source. Organic Letters. 2002;4:2849-2851. DOI: 10.1021/ol026236k
  41. 41. Schnyder A, Beller M, Mehltretter G, Nsenda T, Studer M, Indolese AF. Synthesis of primary aromatic amides by aminocarbonylation of aryl halides using formamide as an ammonia synthon. The Journal of Organic Chemistry. 2001;66(12):4311-4315. DOI: 10.1021/jo015577t
  42. 42. Ju J, Jeong M, Moon J, Jung HM, Lee S. Aminocarbonylation of aryl halides using a nickel phosphite catalytic system. Organic Letters. 2007;9(22):4615-4618. DOI: 10.1021/ol702058e
  43. 43. He T, Li H, Li P, Wang L. Direct amidation of azoles with formamides via metal-free C-H activation in the presence of tert-butyl perbenzoate. Chemical Communications. 2011;47:8946-8948. DOI: 10.1039/C1CC13086B
  44. 44. Xu K, Hu Y, Zhang S, Zha Z, Wang Z. Direct amidation of alcohols with N-substituted formamides under transition-metal-free conditions. Chemistry - A European Journal. 2012;18:9793-9797. DOI: 10.1002/chem.201201203
  45. 45. Gao L, Tang H, Wang Z. Oxidative coupling of methylamine with an aminyl radical: Direct amidation catalyzed by I2/TBHP with HCl. Chemical Communications. 2014;50:4085-4088. DOI: 10.1039/c4cc00621f
  46. 46. Fan W, Shi D, Feng B. TBAI-catalyzed synthesis of α-ketoamides via sp3 C-H radical/radical cross-coupling and domino aerobic oxidation. Tetrahedron Letters. 2015;56:4638-4641. DOI: 10.1016/j.tetlet.2015.06.021
  47. 47. Mai WP, Wang HH, Li ZC, Yuan JW, Xiao YM, Yang LR, et al. nBu4NI-catalyzed direct synthesis of a-ketoamides from aryl methyl ketones with dialkylformamides in water using TBHP as oxidant. Chemical Communications. 2012;48:10117-10119. DOI: 10.1039/C2CC35279F
  48. 48. Bi X, Li J, Shi E, Wang H, Gao R, Xiao J. Ru-catalyzed direct amidation of carboxylic acids with N-substituted formamides. Tetrahedron. 2016;72:8210-8214. DOI: 10.1016/j.tet.2016.10.043
  49. 49. Bannwart L, Abele S, Tortoioli S. Metal-free amidation of acids with formamides and T3P. Synthesis. 2016;48(13):2069-2078. DOI: 10.1055/s-0035-1561427
  50. 50. Mete TB, Singh A, Bhat RG. Transition-metal-free synthesis of primary to tertiary carboxamides: A quick access to prodrug-pyrazinecarboxamide. Tetrahedron Letters. 2017;58:4709-4712
  51. 51. Ali W, Rout SK, Guin S, Modi A, Banerjee A, Pater BK. Copper-catalyzed cross dehydrogenative coupling of N,N-disubstituted formamides and phenols: A direct access to carbamates. Advanced Synthesis and Catalysis. 2015;357:515-522. DOI: 10.1002/adsc.201400659
  52. 52. Phan NTS, Nguyen TT, Vu PHL. A copper metal-organic framework as an efficient and recyclable catalyst for the oxidative cross-dehydrogenative coupling of phenols and formamides. ChemCatChem. 2013;5:3068-3077. DOI: 10.1002/cctc.201300400
  53. 53. Yuan YG, Guo SR, Xiang JN. Cu(OAc)2-catalyzed thiolation of acyl C-H bonds with thiols using TBHP as an oxidant. Synlett. 2013;24(4):443-448. DOI: 10.1055/s-0032-1318188
  54. 54. Singh P, Batra A, Singh P, Kaur A, Singh KN. Oxidative C-Se coupling of formamides and diselenides by using aqueous tert-butyl hydroperoxide: A convenient synthesis of selenocarbamates. European Journal of Organic Chemistry. 2013:7688-7692. DOI: 10.1002/ejoc.201301248
  55. 55. Kumar GS, Kumar RA, Kumar PS, Reddy NV, Kumar KV, Kantam ML, et al. Copper catalyzed oxidative coupling of amines with formamides: A new approach for the synthesis of unsymmetrical urea derivatives. Chemical Communications. 2013;49:6686-6688. DOI: 10.1039/C3CC42381F
  56. 56. Cho S, Kim J, Lee S, Chang S. Silver-mediated direct amination of benzoxazoles: Tuning the amino group source from formamides to parent amines. Angewandte Chemie International Edition. 2009;48:9127-9130. DOI: 10.1002/anie.200903957
  57. 57. Li Y, Xie Y, Zhang R, Jin K, Wang X, Duan C. Copper-catalyzed direct oxidative C-H amination of benzoxazoles with formamides or secondary amines under mild conditions. The Journal of Organic Chemistry. 2011;76:5444-5449. DOI: 10.1021/jo200447x
  58. 58. Wang J, Hou JT, Wen J, Zhang J, Yu XQ. Iron-catalyzed direct amination of azoles using formamides or amines as nitrogen sources in air. Chemical Communications. 2011;47:3652-3654. DOI: 10.1039/c0cc05811d
  59. 59. Chen X, Yang Q, Zhou Y, Deng Z, Mao X, Peng Y. Synthesis of 4-(dimethylamino) quinazoline via direct amination of quinazolin-4(3H)-one using N,N-dimethylformamide as a nitrogen source at room temperature. Synthesis. 2015;47(14):2055-2062. DOI: 10.1055/s-0034-1380550
  60. 60. Sharma A, Mehta VP, Eycken EVD. A convenient microwave-assisted desulfitative dimethylamination of the 2(1H)-pyrazinone scaffold using N,N-dimethylformamide. Tetrahedron. 2008;64:2605-2610. DOI: 10.1016/j.tet.2008.01.030
  61. 61. Ruijie Z, Hongting S, Bo R, Yan F, Hao W, Yehua S, et al. An efficient and green approach to synthesizing enamines by intermolecular hydroamination of activated alkynes. Chemical Research in Chinese Universities. 2015;31(2):212-217. DOI: 10.1007/s40242-015-4388-8
  62. 62. Zhang C, Yue Q, Xiao Z, Wang X, Zhang Q, Li D. Synthesis of O-aroyl-N,N-dimethylhydroxylamines through hypervalent iodine-mediated amination of carboxylic acids with N,N-dimethylformamide. Synthesis. 2017;49(18):4303-4308. DOI: 10.1055/s-0036-1588460
  63. 63. Wei E, Liu B, Lin S, Liang F. Multicomponent reaction of chalcones, malononitrile and DMF leading to γ-ketoamides. Organic & Biomolecular Chemistry. 2014;12:6389-6392. DOI: 10.1039/C4OB00971A
  64. 64. Bao XD, Rong X, Liu Z, Gu Y, Liang G, Xia Q. Potassium tert-butoxide-mediated metal-free synthesis of sulfonamides from sodium sulfinates and N,N-disubstituted formamides. Tetrahedron Letters. 2018;50:2853-2858. DOI: 10.1016/j.tetlet.2018.06.031
  65. 65. Yang C, Zhang F, Deng GJ, Gon H. Amination of aromatic halides and exploration of the reactivity sequence of aromatic halides. The Journal of Organic Chemistry. 2019;84(1):181-190. DOI: 10.1021/acs.joc.8b02588
  66. 66. Li Y, Guo F, Zha Z, Wang Z. Iron-catalyzed synthesis of 2-vinylquinolines via sp3 C-H functionalization and subsequent CN cleavage. Chemistry, An Asian Journal. 2013;8:534-537. DOI: 10.1002/asia.201201039
  67. 67. Lou SJ, Xu DQ, Shen DF, Wang YF, Liua YK, Xu ZY. Highly efficient vinylaromatics generation via iron-catalyzed sp3 C-H bond functionalization CDC reaction: A novel approach to preparing substituted benzo[α]phenazines. Chemical Communications. 2012;48:11993-11995. DOI: 10.1039/C2CC36708D
  68. 68. Liu J, Yi H, Zhang X, Liu C, Liu R, Zhang G, et al. Copper-catalysed oxidative Csp3-H methylenation to terminal olefins using DMF. Chemical Communications. 2014;50:7636-7638. DOI: 10.1039/C4CC02275K
  69. 69. Li YM, Lou SJ, Zhou QH, Zhu LW, Zhu LF, Li L. Iron-catalyzed α-methylenation of ketones with N,N-dimethylacetamide: An approach for α,β-unsaturated carbonyl compounds. European Journal of Organic Chemistry. 2015;2015:3044-3047. DOI: 10.1002/ejoc.201500189
  70. 70. Liu Y, Wang CL, Xia HM, Wang Z, Wang YF. Direct Csp3-H methylenation of 2-arylacetamides using DMF/Me2NH-BH3 as the methylene source. Organic & Biomolecular Chemistry. 2019;17:6153-6157. DOI: 10.1039/C9OB00875F
  71. 71. Pu F, Li Y, Song YH, Xiao J, Liu ZW, Wang C, et al. Copper-catalyzed coupling of indoles with dimethylformamide as a methylenating reagent. Advanced Synthesis and Catalysis. 2016;358:539-542. DOI: 10.1002/adsc.201500874
  72. 72. Li Y, Xue D, Lu W, Wang C, Liu ZT, Xiao J. DMF as carbon source: Rh-catalyzed α-methylation of ketones. Organic Letters. 2014;16:66-69. DOI: 10.1021/ol403040g
  73. 73. Tang RY, Xie YX, Xie YL, Xiang JN, Li JH. TBHP-mediated oxidative thiolation of an sp3 C-H bond adjacent to a nitrogen atom in an amide. Chemical Communications. 2011;47:12867-12869. DOI: 10.1039/c1cc15397h
  74. 74. Dai C, Meschini F, Narayanam JMR, Stephenson CRJ. Friedel-Crafts amidoalkylation via thermolysis and oxidative photocatalysis. The Journal of Organic Chemistry. 2012;77:4425-4431. DOI: 10.1021/jo300162c
  75. 75. Lao ZQ, Zhong WH, Lou QH, Li ZJ, Meng XB. KI-catalyzed imidation of sp3 C-H bond adjacent to amide nitrogen atom. Organic & Biomolecular Chemistry. 2012;10:7869. DOI: 10.1039/c2ob26430g
  76. 76. Deng X, Lei X, Nie G, Jia L, Li Y, Chen Y. Copper-catalyzed cross-dehydrogenative N2-coupling of NH-1,2,3-triazoles with N,N-dialkylamides: N-amidoalkylation of NH-1,2,3-triazoles. The Journal of Organic Chemistry. 2017;82:6163-6171. DOI: 10.1021/acs.joc.7b00752
  77. 77. Wang J, Li J, Huang J, Zhu Q. Transition metal-free amidoalkylation of benzothiazoles and amidoalkylarylation of activated alkenes with N,N-dialkylamides. The Journal of Organic Chemistry. 2016;81:3017-3022. DOI: 10.1021/acs.joc.6b00096
  78. 78. Ding S, Jiao N. Direct transformation of N,N-dimethylformamide to CN: Pd-catalyzed cyanation of heteroarenes via C-H functionalization. Journal of the American Chemical Society. 2011;133:12374-12377. DOI: 10.1021/ja204063z
  79. 79. Xiao J, Li Q, Chen T, Han LB. Copper-mediated selective aerobic oxidative C3-cyanation of indoles with DMF. Tetrahedron Letters. 2015;56:5937-5940. DOI: 10.1016/j.tetlet.2015.09.044
  80. 80. Zhang L, Lu P, Wang Y. Copper-mediated cyanation of indoles and electron-rich arenes using DMF as a single surrogate. Organic & Biomolecular Chemistry. 2015;13:8322. DOI: 10.1039/c5ob01244a
  81. 81. Pawara AB, Chang S. Catalytic cyanation of aryl iodides using DMF and ammonium bicarbonate as the combined source of cyanide: A dual role of copper catalysts. Chemical Communications. 2014;50:448. DOI: 10.1039/c3cc47926a
  82. 82. Ushijima S, Togo H. Metal-free one-pot conversion of electron-rich aromatics into aromatic nitriles. Synlett. 2010;7:1067-1070. DOI: 10.1055/s-0029-1219575
  83. 83. Ushijima S, Togo H. One-pot conversion of aromatic bromides and aromatics into aromatic nitriles. Synlett. 2010;10:1562-1566. DOI: 10.1055/s-0029-1219935
  84. 84. Ishii G, Moriyama K, Togo H. Transformation of aromatic bromides into aromatic nitriles via formations of Grignard reagents and their DMF adducts. Tetrahedron Letters. 2011;52:2404-2406. DOI: 10.1016/j.tetlet.2011.02.110
  85. 85. Wang Y, Wang F, Zhang C, Zhang J, Li M, Xu J. Transformylating amine with DMF to formamide over CeO2 catalyst. Chemical Communications. 2014;50:2438. DOI: 10.1039/c3cc48400a
  86. 86. Sonawane RB, Rasal NK, Jagtap SV. Nickel-(II)-catalyzed N-formylation and N-acylation of amines. Organic Letters. 2017;19:2078-2081. DOI: 10.1021/acs.orglett.7b00660
  87. 87. Journet M, Cai D, Dimichele LM, Larsen RD. Highly efficient synthesis of α,β-acetylenic aldehydes from terminal alkynes using DMF as the formylating reagent. Tetrahedron Letters. 1998;39:6427-6428. DOI: 10.1016/S0040-4039(98)01352-5
  88. 88. Yang D, Jeon HB. Convenient N-formylation of amines in dimethylformamide with methyl benzoate under microwave irradiation. Bulletin of the Korean Chemical Society. 2010;31(5):1424-1426. DOI: 10.5012/36 bkcs.2010.31.5.1424
  89. 89. Li J, Hua R. Stereodivergent ruthenium-catalyzed transfer semihydrogenation of diaryl alkynes. Chemistry - A European Journal. 2011;17:8462-8465. DOI: 10.1002/chem.201003662
  90. 90. Tam CM, To CT, Chan KS. Carbon-carbon σ-bond transfer hydrogenation with DMF catalyzed by cobalt porphyrins. Organometallics. 2016;35:2174-2177. DOI: 10.1021/acs.organomet.6b00434
  91. 91. Liu W, Chen C, Zhou P. Concise access to α-arylketothioamides by redox reaction between acetophenones, elemental sulfur and DMF. ChemistrySelect. 2017;2:5532. DOI: 10.1002/slct.201700866
  92. 92. Krishnakumar V, Chatterjee B, Gunanathan C. Ruthenium-catalyzed urea synthesis by N-H activation of amines. Inorganic Chemistry. 2017;56:7278-7284. DOI: 10.1021/acs.inorgchem.7b00962
  93. 93. Zeng W, Wang E, Qiu R, Sohail M, Wu S, Chen FX. Oxygen-atom insertion of NHC-copper complex: The source of oxygen from N,N-dimethylformamide. Journal of Organometallic Chemistry. 2013;743:4448. DOI: 10.1016/j.jorganchem.2013.06.017

Written By

Andivelu Ilangovan, Sakthivel Pandaram and Tamilselvan Duraisamy

Submitted: September 18th, 2019 Reviewed: December 23rd, 2019 Published: May 13th, 2020