Hindered ethers represent an underexplored area of chemical space due to the difficulty and inoperability associated with conventional reactions, despite the high-value of such structural motifs in a variety of societal applications 1-2. For example, such motifs are highly coveted in medicinal chemistry, as extensive substitution about the ether bond prevents unwanted metabolic processes that can lead to rapid in vivo degradation. Demonstrated herein is an exceptionally simple solution to this problem that leverages the power of electrochemical oxidation to liberate *
A nickel-catalyzed
electrochemical cross-coupling reaction of aryl
bromides with dialkyl phosphites, ethyl phenylphosphinate, and diphenylphosphine
oxide has been developed. This reaction utilizes a simple undivided
cell with inexpensive carbon electrodes to synthesize aryl phosphonates,
aryl phosphinates, and arylphosphine oxides at room temperature. This
protocol provides a mild and efficient route for the construction
of C–P bond in moderate to high yields with broad substrate
scope.
An efficient and practical electrochemical
method for selective
reduction of cyclic imides has been developed using a simple undivided
cell with carbon electrodes at room temperature. The reaction provides
a useful strategy for the rapid synthesis of hydroxylactams and lactams
in a controllable manner, which is tuned by electric current and reaction
time, and exhibits broad substrate scope and high functional group
tolerance even to reduction-sensitive moieties. Initial mechanistic
studies suggest that the approach heavily relies on the utilization
of amines (e.g., i-Pr2NH), which are able
to generate α-aminoalkyl radicals. This protocol provides an
efficient route for the cleavage of C–O bonds under mild conditions
with high chemoselectivity.
[reaction: see text] Tandem Pictet-Spengler-type cyclization and Smiles rearrangement have been discovered in the synthesis of pyrimidine-fused heterocycles. The reaction of 4-chloro-5-pyrrol-1-ylpyrimidine amino aldehyde with an amine under an acidic condition yielded the Pictet-Spengler-type cyclization product diazepine, which readily underwent Smiles rearrangement to give a novel pyrrolo[1,2-f]pteridine derivative.
Method development was completed for a strategy to access a novel pyrimidine-fused heterocyclic scaffold. The key step for this synthetic route entails an intramolecular inverse electron demand hetero-Diels-Alder reaction of imines or iminiums formed in situ from allylaminopyrimidinealdehydes 3 and anilines. The reactions provided exclusively cis-configuration products 6. Products 6 were readily precipitated in the reaction solution in good to excellent yields. Further transformations of the phenylthio group were demonstrated by an oxidation and subsequent nucleophilic substitution sequence. The synthetic strategy provides an efficient way to access libraries of the tetracyclic pyrimidine-fused heterocycles that can be explored for potential pharmaceutical or biological activities.
Method development for a heterocyclic library which entails novel scaffolds of benzodiazepines fused with various heterocycles, such as pyrimidines, indolines, and tetrahydroquinolines, was accomplished. The new synthetic strategy is based on an electrophilic cyclization reaction involving an iminium intermediate formed by the corresponding aminopyrimidine with a carbonyl compound to give the desired heterocycles in high yields. Subsequent replacement of the chloro group in the resulted structures with a nucleophile, such as boronic acids, amines, alcohols and thiols, led to a library of privileged compounds with up to eight accessible diversity points.
<p>Hindered ethers represent an underexplored area of chemical space due to the difficulty and inoperability associated with conventional reactions, despite the high-value of such structural motifs in a variety of societal applications. Demonstrated herein is an exceptionally simple solution to this problem that leverages the power of electrochemical oxidation to liberate high-energy carbocations from simple carboxylic acids. The controlled formation of these reactive intermediates takes place with low electrochemical potentials under non-acidic conditions to capture an alcohol donor thereby producing a range (>80) of ethers that would be extremely difficult to otherwise access. Simple nucleophiles can also intercept such cations, leading to hindered alcohols and even alkyl fluorides. This method has been field tested to solve the synthetic bottlenecks encountered on twelve real-world chemical scaffolds with documented societal impact, resulting in a dramatic reduction in step-count and labor required, accompanied with a higher yield (average step-count, time, and yield = 6.3, ca. 100 h, 19% vs. 1.5, 9.8 h, 43%). Finally, the use of molecular probes coupled to kinetic studies support the proposed mechanism and role of additives in the conditions employed.</p>
Electrochemical regioselective bromination of electron-rich aromatic rings using stoichiometric tetrabutylammonium bromide (
n
Bu4NBr) has been accomplished under mild conditions. This protocol provides an environmentally friendly and simple way for the construction of C–Br bond in moderate to high yields with wide functional group tolerance.
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