Microwave-assisted organic synthesis of nucleoside ProTide analogues

Bordoni, C; Cima, Cecilia Maria; Azzali, Elisa; Costantino, Gabriele; Brancale, Andrea

doi:10.1039/c9ra01754b

Cited by 12 publications

(5 citation statements)

References 16 publications

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“…The MI has tremendous applications in various chemistry research areas such as, heterogeneous catalytic reactions [46], solid state chemistry [47], different heterocyclic organic synthesis involving O, N, and S [48], nitrogen containing heterocycles [49], heterocyclic synthetic reactions [50], solvent free heterocyclic synthesis processes [51], colloidal inorganic nanocrystal synthesis [52], bioactive six membered heterocycles synthesis [53], five membered nitrogen heterocycles synthesis [54], Knoevenagel condensation [55], indoles synthesis [56], triazoloquinazolinones and benzimidazoquinazolinones synthesis [57], extraction of volatile compounds [58], oxazoles and diastereoselective oxazolines [59], synthesis of quinazolines and quinazolinones [60], polymer synthesis [61], ferrocenyl chalcone synthesis [62], arylidene acetophenones synthesis [63], photo oxidation of sulfoxides [64], potential biological compounds [65], organic nanoparticle synthesis [66], synthesis of amino-quinazoline derivatives [67], coumarin-purine derivatives [68], various ring opening polymerisation reactions [69], nucleoside protide analogues synthesis [70], organic trans-formations and synthesis [71], benzannulation reactions [72], heterocyclic phosphonate synthesis [73], azha heterocycle synthesis [74], one pot three component pyrazole synthesis [75], heterocyclic hydrazone synthesis [73], degradation reactions [76], heterogeneous catalysis [77,78], 1,2,3 triazolobenzodiazepinones synthesis [79], silica material synthesis…”

Section: How Are the Reactants Heated By Microwaves?mentioning

confidence: 99%

“…Catalysts 2023, 13, x FOR PEER REVIEW 4 of 21 oxidation of sulfoxides [64], potential biological compounds [65], organic nanoparticle synthesis [66], synthesis of amino-quinazoline derivatives [67], coumarin-purine derivatives [68], various ring opening polymerisation reactions [69], nucleoside protide analogues synthesis [70], organic transformations and synthesis [71], benzannulation reactions [72], heterocyclic phosphonate synthesis [73], azha heterocycle synthesis [74], one pot three component pyrazole synthesis [75], heterocyclic hydrazone synthesis [73], degradation reactions [76], heterogeneous catalysis [77,78], 1,2,3 triazolobenzodiazepinones synthesis [79], silica material synthesis [80], 2-aryl and 2,5-diarylthiophene derivatives preparation [81], decarboxylation of malonic acid derivatives [82], Pd-carbon catalysed reactions [83], and carbon supported-Co catalytic reactions [84].…”

Section: Preparation Of Chromenesmentioning

confidence: 99%

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A Concise Review of Multicomponent Reactions Using Novel Heterogeneous Catalysts under Microwave Irradiation

Damera¹,

Pagadala

Rana

et al. 2023

Catalysts

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Multi-component reactions for the construction of heterocycles have been fascinated by microwave energy as an alternative technique of heating, owing to the advantages over traditional reflux methods. The heterogeneous catalysts contribute significantly towards recycling, harmless, easy filtration, catalyst preparation, more life span, abundance, and product yields. With novel and creative uses in organic and peptide synthesis, polymer chemistry, material sciences, nanotechnology, and biological processes, the usage of microwave energy has rapidly increased during the past 20 years. This article covers multicomponent reactions involving construction of chromenes, pyridines, pyrroles, triazoles, pyrazoles, tetrazoles, trans and cis julolidines using heterogeneous catalysts under microwave. It provides an overview of contemporary microwave-assisted heterogeneous catalytic reactions. Microwave chemistry is now an established technology with several advantages regarding reaction rate and production yield, improving energy savings as confirmed by many applications. Due to the widespread curiosity in medicinal chemistry, the heterogeneously catalysed construction of heterocycles under microwave irradiation is explored to reduce time and energy. By considering various aspects of economy, eco-friendly, and user-friendly factors, this review focuses on recent advances in the multi-component construction of heterocycles using heterogeneous catalysts under microwave irradiation. This review also discusses the benefits and limitations of reaction conditions and yields from the literature reports for the past five years.

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Section: How Are the Reactants Heated By Microwaves?mentioning

confidence: 99%

Section: Preparation Of Chromenesmentioning

confidence: 99%

A Concise Review of Multicomponent Reactions Using Novel Heterogeneous Catalysts under Microwave Irradiation

Damera¹,

Pagadala

Rana

et al. 2023

Catalysts

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show abstract

“…It can be used under solvent-free conditions in a one-pot process and activated by microwave or ultrasound irradiation. 5 Microwave-assisted organic synthesis has been widely used in organic chemistry for the last 40 years to solve problems such as low yields, long reaction times, formation of byproducts, and efficient synthesis of libraries of compounds. 6 In 2014, Bamoniri and co-workers developed a green heterogeneous solid acid based on BF 3 embedded in silica nanoparticles for preparing formazan dyes under solvent-free conditions.…”

Section: Table 1 Catalyst Screening For Halogenation Of...mentioning

confidence: 99%

BF3@K10: An Efficient Heterogeneous Montmorillonite Catalyst for the Halogenation of N-Heterocycles

Lazrek,

El Mansouri,

Lachhab

et al. 2023

Synlett

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Halogenated N-heterocycles are an essential structural building-block in medicinal chemistry. Herein, we describe an economical and efficient protocol for regioselective halogenation of several N-heterocycles (pyrimidines, pyrazole, 2-aminopyridine, theophylline and imidazo[1,2-a]pyridine) using BF3 doped montmorillonite (BF3@K10). The new catalyst was characterized by FTIR, 11B NMR, XRD, SEM and EDS spectroscopy. The developed strategy provides easy and fast access to iodo-, bromo-, and chloro- N-heterocycles under mild conditions. The developed strategy is used to synthesized nine new halogenated derivatives of pyrimidines. This reaction under conventional heating or microwave conditions is simple, general, affording good to excellent yields of products, in the presence of BF3@K10 as an eco-friendly, inexpensive, and efficient catalyst, this reaction is simple and affording good to excellent yields of products under conventional heating or microwave conditions. This protocol is clearly superior to conventional route offering short reaction times, high yields, and easy workup..

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“…In recent years, the importance of phosphate prodrugs with asymmetric centers has increased, which calls for efficient synthesis of ProTide‐type prodrugs such as tenofovir alafenamide ( 154 ). There are many reports of diastereoselective synthesis of ProTide‐type phosphate prodrugs by examining the Lewis acids and catalysts used for coupling with nucleosides [85–87] . In addition to tenofovir alafenamide ( 154 ), sofosbuvir, a top drug against hepatitis C virus (HCV), and remdesivir, which is expected to be a therapeutic agent against COVID‐19, a global threat as of 2020, are also useful ProTide‐type phosphate prodrugs, [88,89] and the development of more innovative methods to synthesize ProTide‐type phosphate prodrugs is desired.…”

Section: Nrtis That Target Hiv‐1mentioning

confidence: 99%

“…Lamivudine 83is phosphorylated by deoxycytidine kinase in cells to lamivudine-monophosphate (87). Lamivudine-monophosphate (87) is phosphorylated to lamivudine-diphosphate (86) by dCMP kinase, and lamivudine-diphosphate (88) is phosphorylated by NDP kinase and metabolized to the active species lamivudine-triphosphate (89; Scheme 22).…”

Section: Inhibition Mechanism Of Lamivudinementioning

confidence: 99%

Structure, Synthesis and Inhibition Mechanism of Nucleoside Analogues as HIV‐1 Reverse Transcriptase Inhibitors (NRTIs)

et al. 2021

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Acquired immunodeficiency syndrome (AIDS) is caused by infection with the human immunodeficiency virus (HIV). Although treatments against HIV infection are available, AIDS remains a serious disease that causes many deaths annually. Although a variety of anti‐HIV drugs have been synthesized and marketed to treat HIV‐infected patients, nucleoside analogue reverse transcriptase inhibitors (NRTIs), which mimic nucleosides, are used extensively and remain a subject of interest to medicinal chemists. However, HIV has acquired drug resistance against NRTIs, and thus the struggle to find novel therapies continues. In this review, we trace the trajectory of NRTIs, focusing on the synthesis, mechanisms of action and applications of NRTIs that have been developed.

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Microwave-assisted organic synthesis of nucleoside ProTide analogues

Abstract: A microwave enhanced synthesis of prodrug nucleotide (ProTide) analogues is presented.

Cited by 12 publications

References 16 publications

A Concise Review of Multicomponent Reactions Using Novel Heterogeneous Catalysts under Microwave Irradiation

A Concise Review of Multicomponent Reactions Using Novel Heterogeneous Catalysts under Microwave Irradiation

BF3@K10: An Efficient Heterogeneous Montmorillonite Catalyst for the Halogenation of N-Heterocycles

Structure, Synthesis and Inhibition Mechanism of Nucleoside Analogues as HIV‐1 Reverse Transcriptase Inhibitors (NRTIs)

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