759-36-4

Usage

Chemical Properties

clear colorless liquid

Uses

Diethyl Isopropylmalonate can be used to treat CCR2-mediated disease.

General Description

Diethyl isopropylmalonate reacts with chalcone by Michael addition, under high pressure and fluoride catalyst, to form compounds having quarternary C atoms.

InChI:InChI=1/C10H18O4/c1-5-13-9(11)8(7(3)4)10(12)14-6-2/h7-8H,5-6H2,1-4H3

Upstream product

• 693-03-8 n-butyl magnesium bromide 
• 6802-75-1 diethyl isopropylidenemalonate 
• 60-29-7 diethyl ether 
• 2033-24-1 cycl-isopropylidene malonate 
• 917-64-6 methyl magnesium iodide 
• 1462-12-0 diethyl ethylidenemalonate 
• 3431-67-2 di-n-butylcadmium 
• 75-29-6 isopropyl chloride 
• 996-82-7 sodium diethylmalonate 
• 75-30-9 2-iodo-propane 
• 105-53-3 diethyl malonate 
• 141-52-6 sodium ethanolate 
• 89984-56-5 methyl manganese chloride 
• 62485-87-4 butyl-iodo-manganese 

Downstream Products

• 19110-07-7 5-isopropyl-1-phenylbarbituric acid 
• 41692-47-1 ethyl 3-methylhexanoate 
• 117-47-5 diethyl (1-methylbutyl)malonate 
• 108-64-5 Ethyl isovalerate 
• 2049-66-3 ethyl-isopropyl-malonic acid diethyl ester 
• 7391-69-7 5-isopropylbarbituric acid 
• 2612-27-3 2-isopropylpropan-1,3-diol 
• 63791-85-5 2-Ethyl-3-methylbutansaeure-ethylester 
• 38214-19-6 bromo-isopropyl-malonic acid diethyl ester 
• 59726-39-5 ethyl 2-carbethoxy-α-isopropyl pent-4-enoate 
• 55000-99-2 benzyl-isopropyl-malonic acid diethyl ester 
• 100135-00-0 4-isopropyl-1-phenyl-3,5-pyrazolidinedione 
• 139416-19-6 isopropyl-malonic acid bis-methylamide 
• 54639-26-8 5-isopropyl-1-methyl-3-phenyl-barbituric acid 

Relevant academic research and scientific papers

First total synthesis of a novel amide alkaloid derived from Aconitum taipeicum and its anticancer activity

A concise total synthesis of a naturally occurring 3-isopropyl-tetrahydropyrrolo[1, 2-a]pyrimidine-2, 4(1H, 3H)-dione (ITPD) isolated from Aconitum taipeicum with a three-step approach was depicted in this study for the first time. Two key intermediates, diethyl isopropylmalonate (2) and pyrrolidin-2-amine (3), being synthsesised separately from initial diethyl malonate (4) and 3, 4-dihydro-2H-pyrrol-5-amine (5), were utilised to obtain the compound entitled ITPD. ITPD showed a promising anticancer activity in vitro on SMMC-7721 cell lines. Flow cytometry and cell cycle analysis revealed that ITPD could induce apoptosis and cell cycle arrest in S phase. The occurrence of apoptosis possibly attributed to the mechanism that ITPD could mediate the mitochondrial pathway through activating caspase-3/9 and increasing the ratio of Bax/Bcl-2 to finally trigger cell apoptosis and DNA damage. Collectively, the possibility to produce sufficient quantity of synthetic ITPD provided the base for further bio-evaluation in vivo and in vitro. The bioactive assay suggested that it may be a potential candidate for further chemical optimisation and use in cancer therapy.

Regiospecific S-aminoalkylation of 5-substituted 6-hydroxy-2-thiouracil derivatives in the synthesis of structural analogs of isothiobarbamine

Regiospecific S-monoaminoalkylation of 5-substituted derivatives of 6-hydroxy-2-thiouracil with free N,N-dialkyl-N-(2-chloroethyl)amines in anhydrous PriOH was described for the first time. In compliance with the rules and regulations of green chemistry, this approach was used to synthesize a number of structural analogs of isothiobarbamine in high yield and purity, which are potential synthetic actoprotectors of immediate action.

Silylene-Bridged Tetranuclear Palladium Cluster as a Catalyst for Hydrogenation of Alkenes and Alkynes

A planar tetranuclear palladium cluster was obtained from the reaction of a cyclotetrasilane with [Pd(CNtBu)2]3. Single-crystal X-ray diffraction analysis and DFT calculations revealed that the tetranuclear framework of the cluster was supported effectively by the bridging organosilylene ligand. Although [Pd(CNtBu)2]3 as well as mononuclear palladium bis(silyl) complex, cis-Pd(SiMePh2)2(CNtBu)2, do not act as the effective catalyst, the planar tetranuclear palladium cluster acts as an efficient catalyst for the hydrogenation of alkenes and alkynes including sterically hindered tri- and tetra-substituted alkenes.

Nuclearity expansion in Pd clusters triggered by the migration of a phenyl group in cyclooligosilanes

Heptanuclear palladium clusters with six palladium atoms in a planar arrangement were obtained from the reaction of [Pd(CNtBu)2]3with Ph-substituted cyclotetrasilane or cyclopentasilaneviathe migration of a phenyl group. The molecular structures of these clusters as well as those of two possible intermediates were determined by single-crystal X-ray diffraction analyses.

Preparation of mono-substituted malonic acid half oxyesters (SMAHOs)

The use of mono-substituted malonic acid half oxyesters (SMAHOs) has been hampered by the sporadic references describing their preparation. An evaluation of different approaches has been achieved, allowing to define the best strategies to introduce diversity on both the malonic position and the ester function. A classical alkylation step of a malonate by an alkyl halide followed by a monosaponification gave access to reagents bearing different substituents at the malonic position, including functionalized derivatives. On the other hand, the development of a monoesterification step of a substituted malonic acid derivative proved to be the best entry for diversity at the ester function, rather than the use of an intermediate Meldrum acid. Both these transformations are characterized by their simplicity and efficiency, allowing a straightforward access to SMAHOs from cheap starting materials.

Synthesis of Cyclopentenones through Rhodium-Catalyzed C-H Annulation of Acrylic Acids with Formaldehyde and Malonates

An efficient rhodium-catalyzed protocol for the synthesis of cyclopentenones based on a three-component reaction of acrylic acids, formaldehyde, and malonates via vinylic C-H activation is reported. Exploratory studies showed that 5-alkylation of as-prepared cyclopentenones could be realized smoothly by the treatment of a variety of alkyl halides with a Na2CO3/MeOH solution. Excess formaldehyde and malonate led to a multicomponent reaction that afforded the multisubstituted cyclopentenones through a Michael addition.

General access to C-centered radicals: Combining a bioinspired photocatalyst with boronic acids in aqueous media

Carbon-centered radicals are indispensable building blocks for modern synthetic chemistry. In recent years, visible light photoredox catalysis has become a promising avenue to access C-centered radicals from a broad array of latent functional groups, including boronic acids. Herein, we present an aqueous protocol wherein water features a starring role to help transform aliphatic, aromatic, and heteroaromatic boronic acids to C-centered radicals with a bioinspired flavin photocatalyst. These radicals are used to deliver a diverse pool of alkylated products, including three pharmaceutically relevant compounds, via open-shell conjugate addition to disparate Michael acceptors. The mechanism of the reaction is investigated by computational studies, deuterium labeling, radical-trapping experiments, and spectroscopic analysis.

Gem-Dialkyl Effect in Diphosphine Ligands: Synthesis, Coordination Behavior, and Application in Pd-Catalyzed Hydroformylation

A series of palladium complexes with C3-bridged bidentate bis(diphenylphosphino)propane ligands with substituents of varying steric bulk at the central carbon have been synthesized. The size of the gem-dialkyl substituents affects the C-C-C bond angles within the ligands and consequently the P-M-P ligand bite angles. A combination of solid-state X-ray diffraction (XRD) and density functional theory (DFT) studies has shown that an increase in substituent size results in a distortion of the 6-membered metal-ligand chair conformation toward a boat conformation, to avoid bond angle strain. The influence of the gem-dialkyl effect on the catalytic performance of the complexes in palladium-catalyzed hydroformylation of 1-octene has been investigated. While hydroformylation activity to nonanal decreases with increasing size of the gem-dialkyl substituents, a change in chemoselectivity toward nonanol via reductive hydroformylation is observed.

Dehydroxymethylation of alcohols enabled by cerium photocatalysis

Dehydroxymethylation, the direct conversion of alcohol feedstocks as alkyl synthons containing one less carbon atom, is an unconventional and underexplored strategy to exploit the ubiquity and robustness of alcohol materials. Under mild and redox-neutral reaction conditions, utilizing inexpensive cerium catalyst, the photocatalytic dehydroxymethylation platform has been furnished. Enabled by ligand-to-metal charge transfer catalysis, an alcohol functionality has been reliably transferred into nucleophilic radicals with the loss of one molecule of formaldehyde. Intriguingly, we found that the dehydroxymethylation process can be significantly promoted by the cerium catalyst, and the stabilization effect of the fragmented radicals also plays a significant role. This operationally simple protocol has enabled the direct utilization of primary alcohols as unconventional alkyl nucleophiles for radical-mediated 1,4-conjugate additions with Michael acceptors. A broad range of alcohols, from simple ethanol to complex nucleosides and steroids, have been successfully applied to this fragment coupling transformation. Furthermore, the modularity of this catalytic system has been demonstrated in diversified radical-mediated transformations including hydrogenation, amination, alkenylation, and oxidation.

Dehydroxymethylation of Alcohols Enabled by Cerium Photocatalysis

Dehydroxymethylation, the direct conversion of alcohol feedstocks as alkyl synthons containing one less carbon atom, is an unconventional and underexplored strategy to exploit the ubiquity and robustness of alcohol materials. Under mild and redox-neutral reaction conditions, utilizing inexpensive cerium catalyst, the photocatalytic dehydroxymethylation platform has been furnished. Enabled by ligand-to-metal charge transfer catalysis, an alcohol functionality has been reliably transferred into nucleophilic radicals with the loss of one molecule of formaldehyde. Intriguingly, we found that the dehydroxymethylation process can be significantly promoted by the cerium catalyst, and the stabilization effect of the fragmented radicals also plays a significant role. This operationally simple protocol has enabled the direct utilization of primary alcohols as unconventional alkyl nucleophiles for radical-mediated 1,4-conjugate additions with Michael acceptors. A broad range of alcohols, from simple ethanol to complex nucleosides and steroids, have been successfully applied to this fragment coupling transformation. Furthermore, the modularity of this catalytic system has been demonstrated in diversified radical-mediated transformations including hydrogenation, amination, alkenylation, and oxidation.