Pot economy and one-pot synthesis

I2-Catalyzed Cascade Annulation/Cross-Dehydrogenative Coupling: Excellent Platform to Access 3-Sulfenyl Pyrazolo[1,5-a]pyrimidines with Potent Antibacterial Activity against Pseudomonas aeruginosa and Staphylococcus aureus

The increasing resistance of bacteria to antibiotics has become a serious threat to existing options for treating bacterial infections. We have developed a synthetic methodology for 3-sulfenyl pyrazolo[1,5-a]pyrimidines with potent antibacterial activity. This iodine-catalyzed strategy has been developed by employing amino pyrazoles, enaminones/chalcones, and thiophenols through intermolecular cyclization and subsequent cross-dehydrogenative sulfenylation. This highly regioselective and practicable protocol has been utilized to synthesize structurally diverse 3-sulfenyl pyrazolo[1,5-a]pyrimidines with wide functionalities. This strategy is also extendable toward the synthesis of bis(pyrazolo[1,5-a]pyrimidin-3-yl)sulfanes from amino pyrazole, enaminones/chalcone, and KSCN and the synthesis of 3-sulfenyl pyrazolo[1,5-a]pyrimidine from direct acetophenone. Mechanistic investigation disclosed a radical pathway for C-H sulfenylation and the involvement of 3-iodo pyrazolo[1,5-a]pyrimidine as the active intermediate. The biological investigation disclosed the potent antibacterial activity of sulfenyl pyrazolo[1,5-a]pyrimidines against Pseudomonas aeruginosa and Staphylococcus aureus, whereas pyrazolo[1,5-a]pyrimidine and sulfinyl pyrazolo[1,5-a]pyrimidine have no such antibacterial activity. Sulfenyl pyrazolo[1,5-a]pyrimidines mechanistically inhibited bacterial growth by the accumulation of ROS as well as induction in lipid peroxidation. Subsequently, such circumstances changed the membrane potential and facilitated the interaction with membrane-associated proteins, leading to a loss in membrane integrity and damage to bacterial cell membranes. Moreover, these derivatives potentiated the antibacterial efficacy of the commercial antibiotic ciprofloxacin against the selected bacterial strains and can be considered an alternative therapy against these bacterial infections.

Development of Chiral Bisphosphine Ligands with a Terminal Olefin Enables Asymmetric Orthogonal Auto-Tandem Catalysis

Auto-tandem catalysis (ATC) leverages the multiple roles of the catalyst, facilitating the direct synthesis of complex molecules from simple starting materials in a highly efficient and step-economical manner. However, in conventional ATC, employing a single catalyst imposes significant limitations on the variety of catalyzed reactions. Herein, we present a novel catalysis strategy termed "orthogonal auto-tandem catalysis (OATC)", which provides the unique opportunity to develop more efficient chemical transformations that cannot be achieved with existing catalytic modes. An unprecedented tandem annulation process involving four different catalytic cycles via asymmetric OATC is demonstrated. The enantio-determining step is a previously unrealized Pd(0)-catalyzed asymmetric allylic lactonization. The key to the whole success lies in the development of a new class of chiral bisphosphine ligands with a terminal olefin (TOPhos) that addressed not only the racemization issue of allylic ester products in classic π-allylmetal chemistry, but also the inherent compatibility challenges in transition-metal/organo dual catalytic system. Density functional theory (DFT) calculations unveil the vital role of the terminal olefin in TOPhos, enabling the differentiation of competitive enantioselective pathways.

Studies on the Reactions of Lactone Intermediates Derived from Levulinic Acid: Telescoped Routes to Higher Levulinate Ester Biofuels

The development of efficient strategies for the synthesis of levulinate esters is of significant current interest due to their potential as biofuels and fuel additives. Herein, we report a novel strategy to access levulinate esters derived from higher alcohols directly from levulinic acid through the in situ generation of lactone intermediates employing commercial heterogeneous catalysts, such as Amberlyst-15. This strategy employs a telescoped approach in which the lactonization/ring-opening reactions are combined into an operationally simple one-pot procedure. This strategy is advantageous as it employs a readily available and inexpensive catalyst and proceeds in short reaction times to produce excellent yields of higher levulinate esters with high selectivity. Furthermore, the Amberlyst-15 catalyst is fully recyclable and can be reused without loss of activity or selectivity.

Enhancing Multi-Enzyme Cascade Activity in Metal-Organic Frameworks via Controlled Enzyme Encapsulation

To position multi-enzymes in a core-shell structure, the conventional layer-by-layer approach is often used. However, this method is time-consuming and complex, requiring multiple steps and the isolation of intermediates at each stage. To address this challenge, a sequential strategy is introduced for the controlled encapsulation of multi-enzymes within metal-organic frameworks (MOFs), achieving a core-shell structure without the need for intermediate isolation. Synchrotron Terahertz-Far-Infrared (THz-Far-IR) spectroscopy is employed to monitor this encapsulation process. The results revealed that the first enzyme is co-precipitated within the MOFs, followed by biomineralization upon the addition of a second enzyme, achieving distinct enzyme positioning. This approach is applicable to both two-enzyme and three-enzyme cascade systems. The results demonstrate that multi-enzyme cascade activity is significantly enhanced compared to conventional one-pot and layer-by-layer approaches, owing to optimal spatial arrangement, increased surface area, and improved enzyme conformation. Furthermore, the encapsulated enzymes exhibit strong resistance to high temperatures, proteolysis, and organic solvents, along with excellent reusability, making this method highly promising for industrial biocatalytic applications.

Harnessing Deep Eutectic Solvents for Regioselective Polar Additions to α, β Unsaturated Ketones and Aldehydes

Advancing the use of air-sensitive polar organometallic Grignard and organolithium reagents under more environmentally benign conditions, here we report the addition of these reagents to α,β-unsaturated ketones and aldehydes using the deep eutectic solvent (DES) choline chloride (ChCl): glycerol (Gly) (1 : 2), under air. Reactions occur at room temperature within seconds with excellent regioselective control. Furthering understanding of how these C-C bond forming processes take place in these reaction media, we have explored the surface concentration of the organic substrate (chalcone) in DES using interfacial tension and neutron reflectivity measurements, finding that chalcone is concentrated at the DES-hydrocarbon interface compared to the bulk concentration, although the interfacial chalcone concentration is still relatively low in this system. The influence of aggregation of the organometallic reagent in the organic solvent employed has also been evaluated, revealing the importance of achieving a balance between activation (via de-aggregation) and stability (to avoid its decomposition in the DES). This DES approach has been successfully extended to double additions to α,β-unsaturated esters and for one pot sequential 1,4 and 1,2 additions to ketones, providing a new entry point to a range of tertiary-alcohols, minimising the use of organic solvents and avoiding intermediate time-consuming purification steps.

Photocatalytic Strecker-Type Reaction for the Synthesis of Primary α-Aminonitriles

A practical photoinduced direct N-O cleavage of oxime ethers via a single electron transfer (SET) process was developed, enabling controlled generation of N-H imines via iminyl radical intermediates. By employing this strategy, an efficient Strecker-type reaction was established to construct a variety of primary α-aminonitriles using TMSCN as a cyanide source. This protocol showed exceptional tolerance to various functional groups, delivering the corresponding products in good yields. Mechanistic investigations indicate the involvement of iminyl radicals and a radical/polar crossover sequence.

Universal Reagent for Mild and Stereospecific Nucleophilic Substitution of Alcohols with Amines

A user-friendly reagent for mild and general activation of alcohols towards bimolecular nucleophilic substitution (SN2) leveraging diverse nucleophiles, including primary and secondary amines is reported herein. The new ion-paired reagent discovery was based upon the putative zwitterionic betaine intermediate of the Mitsunobu reaction and enabled the one-step conversion of enantioenriched alcohols to valuable chiral C-X bonds (where X=N, C, S, O or halide). The described activating reagent has also been applied to a one-step methylation reaction using methanol and to an intermolecular amination/intramolecular cyclization sequence that generates heterocycles, such as tetrahydroisoquinolines. This work provides the first evidence by X-ray crystallography of a protonated betaine as intermediate in the Mitsunobu reaction.

Asymmetric Synthesis of Noradamantane Scaffolds via Diphenylprolinol Silyl Ether-Mediated Domino Michael/Epimerization/Michael (or Aldol)/1,2-Addition Reactions

Topologically unique chiral noradamantanes are synthesized using a diphenylprolinol silyl ether-mediated domino Michael/epimerization/Michael/1,2-addition or Michael/epimerization/aldol/1,2-addition reaction with excellent enantioselectivity in a single reaction vessel. Three carbon-carbon bonds are formed, and six chiral centers, including one all-carbon quaternary center, are generated, five of which are fully controlled. These functionalized noradamantanes are 3D, cage-like molecules that can serve as valuable chiral building blocks for drug design.

Visible Light-Mediated Selective Synthesis of β-Amino Sulfide Scaffolds via Dual Role of N-Iodosuccinimide

The synthesis of β-amino sulfides is significant in organic chemistry. However, challenges such as achieving regioselectivity and the limited availability of starting materials remain unresolved. In this study, we present a visible light-mediated method for the selective synthesis of β-amino sulfide scaffolds. Remarkably, two distinct types of β-amino sulfides were selectively synthesized through the dual role of N-iodosuccinimide, which functions as either a reactant or an activator in the construction of the target scaffolds.

Total Syntheses of (+)-Aigialospirol and (+)-7',8'-Dihydroaigialospirol by a One-Pot Stepwise Approach

(+)-Aigialospirol and (+)-7',8'-dihydroaigialospirol are known to be spiroketal polyketide-type natural products isolated from mangrove-derived fungus Aigialus parvus BCC 5311. These polyketides are structurally characterized by fusing resorcylic acid lactone and spiroketal moieties containing six asymmetric carbon centers. In this paper, we describe concise and stereoselective syntheses of these natural products based on biosynthesis-inspired transformation in nine steps. The total syntheses are highlighted by a one-pot stepwise synthesis involving (i) stereoselective lactone ring formation from a chiral epoxide, (ii) reduction of alkyne, (iii) global deprotection, and (iv) spiroketal formation, which are performed in the final step of the total synthesis.

Ruthenium-Catalyzed Transfer Hydrogenation of Alkynes: Access to Alkanes and (E)- or (Z)-Alkenes in Tandem with Pd/Cu Sonogashira Cross-Coupling

A complete reduction of alkynes using a combination of [RuCl2(p-cymene)]2, DTBM-SEGPHOS, and a paraformaldehyde/water system as the hydrogen source was developed, affording alkanes in 52-99% yields. In addition, the preparation of alkenes from terminal alkynes and aryl iodides by a tandem process of Pd/Cu-catalyzed Sonogashira reaction followed by Ru-catalyzed transfer hydrogenation is reported, affording alkenes in 38-99% yields. This multicatalysis proceeds via three consecutive reactions and can be extended further, as shown by adding an iodine-catalyzed cis-trans alkene isomerization step.

Cascade Synthesis in Water: Michael Addition/Hemiketalization/Retro-Claisen Fragmentation Catalyzed by CatAnionic Vesicular Nanoreactor from Dithiocarbamate

N,N-didodecylammonium N,N-didodecyldithiocarbamate (AmDTC-C12C12) underwent self-assembly to form a CatAnionic vesicular nanoreactor in water. AmDTC-C12C12 can be readily prepared by condensation between N,N-didodecylamine and carbon disulfide. Previously, the cascade Michael addition/hemiketalization/retro-Claisen fragmentation was reported, but it required petroleum-based organic solvents as reaction media. Herein, the application of AmDTC-C12C12 in aqueous cascade synthesis is investigated. Initially, we explored the catalytic activity of AmDTC-C12C12 (10 mol %) in the synthesis of 4H-chromene through a double-cascade Michael addition/hemiketalization. The reaction occurred in water at room temperature using 2-hydroxy-trans-β-nitrostyrene as Michael acceptor and acetylacetone as Michael donor, yielding 2-chromanol intermediates. Subsequent acidic dehydration of 2-chromanols produced 4H-chromenes with moderate yields (34-60 %) and phenyl acetates of γ-nitro ketone as co-products (13-31 %), deriving from retro-Claisen fragmentation. Surprisingly, using Michael donors with aromatic moieties on the 1,3-dicarbonyls resulted in spontaneous triple-cascade Michael addition/hemiketalization/retro-Claisen fragmentation in water without the need for acidic dehydration. The γ-nitro ketones were obtained as sole products, with no detection of 4H-chromenes, in moderate to high yields (24-84 %) for symmetrical 1,3-dicarbonyl containing two aromatic groups. Unsymmetrical 1,3-dicarbonyl bearing aromatic/aliphatic or aromatic/aromatic groups afforded γ-nitro ketones in favorable yields (73-97 %).

Gold Nanoparticles Functionalized With 5-Amino-2-Mercaptobenzimidazole: A Promising Antimicrobial Strategy Against Carbapenem-Resistant Gram-Negative Bacteria

Introduction

Carbapenem-resistant gram-negative bacteria (CR-GNB) pose a significant threat to public health and require immediate attention. The development of novel antibacterial agents against CR-GNB has become an urgent priority, and nanomaterials offer promising solutions due to their unique properties. This study introduces 5-amino-2-mercaptobenzimidazole (5-A-2MBI) functionalized gold nanoparticles (5-A-2MBI_Au NPs) and evaluates their antibacterial activity against CR-GNB.

Methods

The 5-A-2MBI_Au NPs was synthesized using a one-pot method. Its biocompatibility, bactericidal properties, and mechanisms of action were systematically characterized through in vivo and in vitro toxicity tests, antimicrobial susceptibility testing, live/dead staining, membrane permeability and reactive oxygen species (ROS) generation assays, as well as transcriptomic analysis.

Results

The results of this study demonstrate that 5-A-2MBI_Au NPs exhibit excellent antibacterial efficacy against carbapenem-resistant gram-negative bacteria with various resistance mechanisms, with a minimum inhibitory concentration (MIC) of 2 μg/mL. In vivo experiments further confirmed that 5-A-2MBI_Au NPs not only possess effective bactericidal activity but also exhibit satisfactory biocompatibility. Mechanistic studies revealed that 5-A-2MBI_Au NPs enhance bacterial membrane permeability, increase the generation of reactive oxygen species, and disrupt intracellular oxidative stress and succinate synthesis, thereby conferring potent antibacterial activity. This study results demonstrate that 5-A-2MBI_Au NPs exhibit notable antibacterial efficacy against CR-GNB, with a minimum inhibitory concentration of 2 μg/mL. The antibacterial mechanism involves enhanced membrane permeability, increased reactive oxygen species production, and interference with intracellular oxidative stress and succinate synthesis. These mechanisms collectively contribute to the potent antibacterial activity of 5-A-2MBI_Au NPs against CR-GNB.

Discussion

5-A-2MBI_Au NPs are a novel and highly effective antibacterial agent prepared through a simple process using benzimidazole and HAuCl4•3H2O. They efficiently eradicate the most challenging multidrug-resistant GNB both in vitro and in vivo while demonstrating excellent biocompatibility. This highlights their potential as a promising antibacterial agent to combat multidrug-resistant GNB.

Dual relay Rh-/Pd-catalysis enables β-C(sp3)-H arylation of α-substituted amines

A dual relay catalytic protocol, built on reversible dehydrogenation of amines by Rh catalysis and C-H functionalisation of transient imines by Pd catalysis, is reported to enable regioselective arylation of amines at their unactivated β-C(sp3)-H bond. Notably, the new strategy is applicable to secondary anilines and N-PMP-protected primary aliphatic amines of intermediate steric demands, which is in contrast to the existing strategies that involve either free-amine-directed C-H activation for highly sterically hindered secondary aliphatic amines or steric-controlled migrative cross-coupling for unhindered N-Boc protected secondary aliphatic amines. Regioselectivity of the reaction is imposed by the electronic effects of transient imine intermediates rather than by the steric effects between specific starting materials and catalysts, thereby opening the uncharted scope of amines. In a broader sense, this study demonstrates new opportunities in dual relay catalysis involving hydrogen borrowing chemistry, previously explored in the functionalisation of alcohols, to execute otherwise challenging transformations for amines, commonly present in natural products, pharmaceuticals, biologically active molecules, and functional materials.

High-yielding total synthesis of embelin, rapanone, and irisoquin A, D, F

Simple and sustainable three- and four-step sequences of di-OH-protection/mono-OMe-deprotection/OrgRC and di-OH-protection/mono-OMe-deprotection/OrgRC/OMe-deprotection protocols were developed to construct biologically active natural products of irisoquin, irisoquin A, irisoquin D, irisoquin F, sorgoleone-364, embelin, rapanone, 5-O-methylembelin, 5-O-methylrapanone and their analogues from the commercially available 2,5-dihydroxy-1,4-benzoquinone, aliphatic aldehydes and Hantzsch ester (1,4-DHP) in very good to excellent yields by using organocatalytic reductive coupling (OrgRC) as key reaction. Many of these natural compounds exhibited a broad spectrum of biological activities including antioxidant, anti-inflammatory, anticonvulsant, anxiolytic, analgesic, anthelmintic, antitumor, antibacterial, and antifertility properties. At the same time, simple and readily available 2,5-dihydroxy-1,4-benzoquinone was transformed into a functionally rich library of 2,5-dihydroxy-3,6-dialkyl-1,4-benzoquinones in very good yields by using sequential OrgRC followed by deprotection reactions and resulting natural/unnatural products would be excellent targets for investigation to show their biological activities compared to known natural products. Further, we tried to synthesize another mero-sesquiterpenoid of (+)-cyclospongiaquinone-1 from a chiral bicyclic aldehyde and hydroxy-1,4-benzoquinone by using OrgRC followed by etherification reactions, but we ended up with the synthesis of their ring-open analogues in good yields. The high-yielding gram-scale chemoselective synthesis of natural products irisoquin and demethylated-irisoquin demonstrated the potential to conduct these processes on larger scales.

One-Pot Cobalt- or Copper-Catalyzed Asymmetric Ring-Opening Hydrosilylation/Hydroboration of Arylidenecyclopropanes

An operationally convenient cobalt-catalyzed one-pot one-step hydrosilylation/hydroboration reaction of arylidenecyclopropanes is developed to access racemic 1,4-borylsilylalkanes. In addition, the corresponding asymmetric reaction is developed with a chiral copper catalyst to prepare 1,4-borylsilylalkanes with high enantioselectivity by a one-pot two-step procedure. Mechanistic studies reveal that this difunctionalization process begins with metal-hydride-catalyzed ring-opening hydrosilylation of arylidenecyclopropanes to generate homoallylsilane intermediates, followed by regio- or enantioselective metal-hydride-catalyzed hydroboration of homoallylsilanes to produce skipped borylsilylalkanes. Selective transformations of C-B and Si-H bonds in skipped borylsilylalkane products are also demonstrated.

One-Pot, Telescoped Aryl Nitrile Synthesis from Benzylic Silyl Ethers

A one-pot, telescoped transformation of silyl ethers into cyanides that proceeds via silyl-ether oxidation mediated by nitroxyl-radical catalyst 1 and [bis(trifluoroacetoxy)iodo]benzene followed by an imine formation-oxidation sequence using iodine and aqueous ammonia is reported. This transformation is effective for the site-selective transformation of benzylic and allylic silyl ethers in the presence of other silyl ethers. Using an O-protected oxime and a catalytic amount of triflic acid instead of iodine/aqueous ammonia is also effective for cyanation.

Conversion of aromatic methyl ketones to esters and carboxylic acids using o-phthalaldehyde as an oxidant

Herein we describe a two-step conversion of aromatic methyl ketones to esters and carboxylic acids employing o-phthalaldehyde as an oxidant. In the first step, o-phthalaldehyde oxidizes the methyl group to 1-indanone, which acts as a leaving group in a subsequent regioselective retro-Claisen condensation to form esters and carboxylic acids. The mild oxidation conditions ensure the method is applicable to a broad range of substrates. Additionally, the two-step method is operationally simple and scalable, and can also be performed in a single pot.

One-Pot Domino Catalysis to Construct Alkyl/Aryl Pyrroles Initiated by Pd-TMM Annulation of Unactivated Imines

Herein, a one-pot domino catalyzed three-component process is described, which is initiated by a palladium/zinc cooperatively catalyzed cycloaddition between trimethylenemethane (TMM) and unactivated alkyl/aryl imines, followed by one-pot isomerization and Zn(OTf)2-catalyzed DDQ oxidation, furnishing valuable substituted pyrroles. We disclose that the palladium/zinc cooperative catalysis affords a dual-Zn(OTf)2-stabilized azapalladacycle, wherein the Pd-N bond is polarized by Zn(OTf)2, facilitating a unique outer-sphere allylic amination. Moreover, subsequent DDQ dehydrogenation can be feasibly promoted by zinc catalysis.

Switch of Five Contiguous Chiral Centers in the Synthesis of Both Enantiomers of Hajos-Parrish Ketone Analogs via Diphenylprolinol Silyl Ether-Mediated Domino Reaction

Both enantiomers of functionalized Hajos-Parrish ketone (HPK) analogs were prepared with excellent diastereoselectivities and enantioselectivities using the same chiral catalyst under two slightly different conditions. In condition A, dioxane was used as the solvent with 3 equivalents of water. In condition B, acetonitrile was used as the solvent with 30 equivalents of water, followed by epimerization with a base in a one-pot. The reaction consisted of a domino reaction including a diphenylprolinol silyl ether-mediated asymmetric Michael reaction and an intramolecular Henry reaction. In the Michael reaction, depending on the solvent and water amounts, syn- and anti-isomers were selectively synthesized with excellent enantioselectivity, in which the absolute configuration at C5 (indanone numbering) was opposite. The subsequent Henry reaction was diastereoselective, in which the C5 substituent controlled the three chiral centers in a highly diastereoselective manner. The final base treatment in condition B caused epimerization, changing the configuration at C6. Switching more than two chiral centers with high enantioselectivity is extremely difficult using the same chiral catalyst; the present reaction is a very rare enantiodivergent reaction that switches five continuous chiral centers with high enantioselectivity.

Organocatalytic Asymmetric Construction of 2,6-Diazabicyclo-[2.2.2]octanes by Harnessing the Potential of an 3-Oxindolium Ion Intermediate

Due to its structural complexity and intrinsic sensitivity of bridged aminal junction, 2,6-diazabicyclo[2.2.2]octane (2,6-DABCO) has remained a highly desirable target in synthetic chemistry. However, the asymmetric access to this unit is still insufficient and hampered by the need for meticulously created functionalities for intricate double aza-cyclizations. Herein, we have developed a novel enantio- and diastereoselective protocol to access polycyclic chiral 2,6-DABCOs under metal-free conditions. This domino process involves the amine-catalyzed [4+2] annulation between glutaraldehyde and 2-arylindol-3-ones, followed by an acid-mediated Pictet-Spengler reaction/intramolecular aza-cyclization cascade sequence with tryptamine by trapping of in situ generated 3-oxindolium ion intermediate for the first time. Overall, 2,6-DABCOs fused with medicinally relevant scaffolds were isolated with good yield and excellent stereoselectivity by constructing five new bonds and four stereocenters in a one-pot operation.

Combining Photochemical Oxyfunctionalization and Enzymatic Catalysis for the Synthesis of Chiral Pyrrolidines and Azepanes

Chiral heterocyclic alcohols and amines are frequently used building blocks in the synthesis of fine chemicals and pharmaceuticals. Herein, we report a one-pot photoenzymatic synthesis route for N-Boc-3-amino/hydroxy-pyrrolidine and N-Boc-4-amino/hydroxy-azepane with up to 90% conversions and >99% enantiomeric excess. The transformation combines a photochemical oxyfunctionalization favored for distal C-H positions with a stereoselective enzymatic transamination or carbonyl reduction step. Our study demonstrates a mild and operationally simple asymmetric synthesis workflow from easily available starting materials.

Multicomponent reactions (MCRs) yielding medicinally relevant rings: a recent update and chemical space analysis of the scaffolds

In this review we have compiled multicomponent reactions (MCRs) that produce cyclic structures. We have covered articles reported since 2019 to showcase the recent advances in this area. In contrast to other available reviews on this topic, we focus specifically on MCRs with strong prospects in medicinal chemistry. Consequently, the reactions operating in a single-pot and yielding novel rings or new substitution patterns under mild conditions are highlighted. Moreover, MCRs that do not require special reagents or catalysts and yield diverse products from commercially available building blocks are reviewed. The synthetic schemes, substrate scope, and other key aspects such as regio- and stereoselectivity are discussed for each MCR. Using cheminformatic tools, we have also attempted to characterize the chemical space of the scaffolds obtained from these MCRs. We show that the MCR scaffolds are novel, more complex, and globular in shape compared to the approved drugs and clinical candidates. Thus, our review represents a step towards identifying and characterizing the novel ring space that can be accessed efficiently through MCRs in a short timeframe.

Recent Advances in Nanocatalyzed One-Pot Sustainable Synthesis of Bioactive N, N-Heterocycles with Anticancer Activities: An Outlook of Medicinal Chemistry

N-heterocycles represent a predominant and unique class of organic chemistry. They have received a lot of attention due to their important chemical, biomedical, and industrial uses. Food and Drug Administration (FDA) approved about 75% of drugs containing N-based heterocycles, which are currently available in the market. N-Heterocyclic compounds exist as the backbone of numerous natural products and act as crucial intermediates for the construction of pharmaceuticals, veterinary items, and agrochemicals frequently. Among N-based heterocyclic compounds, bioactive N,N-heterocycles constitute a broad spectrum of applications in modern drug discovery and development processes. Cefozopran (antibiotic), omeprazole (antiulcer), enviradine (antiviral), liarozole (anticancer), etc., are important drugs containing N,N-heterocycles. The synthesis of N,N-heterocyclic compounds under sustainable conditions is one of the most active fields because of their significant physiological and biological properties as well as synthetic utility. Current research is demanding the development of greener, cheaper, and milder protocols for the synthesis of N,N-heterocyclic compounds to save mother nature by avoiding toxic metal catalysts, extensive application of energy, and the excessive use of hazardous materials. Nanocatalysts play a profound role in sustainable synthesis because of their larger surface area, tiny size, and minimum energy; they are eco-friendly and safe, and they provide higher yields with selectivity in comparison to conventional catalysts. It is increasingly demanding research to design and synthesize novel bioactive compounds that may help to combat cancer since the major causes of death worldwide are due to cancer. Hence, the important uses of nanocatalysts for the one-pot synthesis of biologically potent N,N-heterocycles with anticancer activities have been presented in this review.

An improved ultrasound-assisted synthesis of phenytoin suitable for undergraduate education

A convenient and efficient method for undergraduate student experiments involves the one-pot synthesis of phenytoin from benzoin. This method utilized ultrasonic irradiation in the presence of basic catalyst at room temperature and atmospheric pressure, resulting in shortened reaction times, good yields, and excellent reproducibility. By employing a low-cost ultrasonic cleaner for ultrasonic irradiation in student experiments, the need for expensive equipment investment during the teaching process can be minimized. Consequently, this approach is suitable for widespread promotion and application in undergraduate education.

A Sonochemical and Mechanochemical One-Pot Multicomponent/Click Coupling Strategy for the Sustainable Synthesis of Bis-Heterocyclic Drug Scaffolds

Bis-heterocycles were synthesized via a consecutive one-pot process by a Groebke-Blackburn-Bienaymé reaction (GBB-3CR) followed by Copper-catalyzed Alkyne-Azide Cycloaddition (CuAAC) assisted by alternative sustainable energies (ASE) such as ultrasonic and mechanical. These efficient and convergent strategies allowed the in situ generation of complex azides functionalized with imidazo[1,2-a]pyridines (IMPs), which was used as a synthetic platform. The target molecules contain two privileged scaffolds in medicinal chemistry: IMPs and the heterocyclic bioisostere of trans-amide bond, the 1,4-disubstituted 1H-1,2,3-triazoles (1,4-DS-1,2,3-Ts).

Green Synthesis of Urethane-Linked Tamarind Seed Xyloglucan: Thermal Stability, Antibacterial Properties, and DFT Study

This study presents a feasible, one-pot synthesis approach for the preparation of a composite biopolymer material derived from tamarind seed xyloglucan (XG) by utilizing isocyanate chemistry. Through a facile reaction process, urethane bonds are formed in XG, resulting in the formation of a crosslinked network. FTIR spectra confirm the successful urethane link formation in XG via the OH-NCO reaction, and CHN analysis provides insights into the elemental composition. The synthesized XG-urethane composite (U-XG) exhibits enhanced thermal stability compared to native XG, with an enhanced degradation temperature (T5%) of 276°C (XG marked T5% at a lower temperature of 163°C). The optimized geometric structure, hydrogen bond types, and hydrogen bond strength of the synthesized U-XG are computationally studied by density functional theory (DFT) at the B3LYP/6-31G(d,p) level. This study also investigates the antibacterial efficacy of both XG and U-XG against a panel of pathogenic bacteria, including gram-positive bacteria such as S. aureus and S. epidermidis, as well as gram-negative E. coli. The U-XG demonstrates superior antibacterial activity against S. epidermidis compared to pristine XG. This research showcases the feasibility of a one-pot synthesis approach for preparing urethane-linked XG with enhanced thermal properties and superior antibacterial activity, offering promising prospects for biomedical and antimicrobial applications.

Potassium Persulfate Promoted the One-Pot and Selective Se-Functionalization of Pyrazoles under Acidic Conditions

Our research presents selective direct selenylation at the C-4 pyrazole ring using K2S2O8 as an oxidant under simple and mild conditions. This elegant synthesis involves the one-pot method under acidic conditions, thus minimizing reaction steps and waste generation. This innovative method allowed us to create a library of 4-selanylpyrazoles in good to excellent yields. Furthermore, with slight changes in the protocol, we describe the synthesis of the unprecedented 4,5-bis-selanylpyrazole. The selectivity of the new insertion of organoselenium into the pyrazole core was demonstrated by several 1H and 77Se NMR experiments.

A practical, biomimetic, one-pot synthesis of firefly luciferin

The bioluminescence reaction of firefly luciferase with D-luciferin has become an indispensable imaging technique in modern biology and life science experiments, but the high cost of D-luciferin is limiting its further application. Here, we report a practical, one-pot synthesis of D-luciferin from p-benzoquinone (p-BQ), L-cysteine methyl ester and D-cysteine, with an overall yield of 46%. Our route, which is six steps in length and proceeds via 2-cyano-6-hydroxybenzothiazole, is inspired by the mechanistic study of our previously reported biomimetic, non-enzymatic, one-pot formation of L-luciferin from p-BQ and L-cysteine. Advantages of our route include its high yield, low cost, use of only inexpensive, commercially available reagents, without requiring strictly anhydrous and oxygen-free conditions, and elevated temperatures.

Isochroman-3,4-dione and Tandem Aerobic Oxidation of 4-Bromoisochroman-3-one in the Highly Regio- and Diastereoselective Diels-Alder Reaction for the Construction of Bridged Polycyclic Lactones

Herein we report two processes facilitated by diisopropylethylamine (DIPEA) for the synthesis of novel bridged polycyclic molecule analogues to natural products. The use of 4-bromoisochroman-3-one initiated an autoxidation reaction, followed by a Diels-Alder cycloaddition in the presence of electron-deficient dienophiles. Mechanistic studies revealed isochromane-3,4-dione as a key intermediate, which undergoes in situ dienolization/dearomatization followed by a [4 + 2] cycloaddition. Subsequently, the synthesis and direct application of isochromane-3,4-diones in the Diels-Alder reaction enabled the development of an alternative method with an enhanced efficiency and improved atom economy. In addition to chalcones, other enones and common electron-poor alkenes, bearing ester, nitro and cyano electron-withdrawing groups (including both terminal, cis acyclic and cyclic alkenes), were successfully reacted. The mechanism was also investigated, and a subsequent reductive ring opening was successfully carried out.

Oxidative coupling of N-nitrosoanilines with substituted allyl alcohols under rhodium (III) catalysis

Rhodium(III) catalysis has been used for C-H activation of N-nitrosoanilines with substituted allyl alcohols. This method provides an efficient synthesis of the functional N-nitroso ortho β-aryl aldehydes and ketones with low catalyst loading, high functional group tolerance, and superior reactivity of allyl alcohols toward N-nitrosoanilines. We demonstrated that reaction also proceeds through the one-pot synthesis of N-nitrosoaniline, followed by subsequent, C-H activation. The protocol was also feasible with acyrlaldehyde and methyl vinyl ketone which furnished the same oxidative N-nitroso coupling product.

A Novel Pot-Economy Approach to the Synthesis of Triantennary GalNAc-Oligonucleotide

N-Acetylgalactosamine (GalNAc) is an efficient and multifunctional delivery tool in the development and synthesis of chemically modified oligonucleotide therapeutics (conjugates). Such therapeutics demonstrate improved potency in vivo due to the selective and efficient delivery to hepatocytes in the liver via receptor-mediated endocytosis, which is what drives the high interest in this molecule. The ways to synthesize such structures are relatively new and have not been optimized in terms of the yields and stages both in lab and large-scale synthesis. Another significant criterion, especially in large-scale synthesis, is to match ecological norms and perform the synthesis in accordance with the Green Chemistry approach, i.e., to control and minimize the amounts of reagents and resources consumed and the waste generated. Here, we provide a robust and resource effective pot-economy method for the synthesis of triantennary GalNAc and GalNAc phosphoramidite/CPG optimized for laboratory scales.

Recent advances in the total synthesis of alkaloids using chiral secondary amine organocatalysts

Since the early 21st century, organocatalytic reactions have undergone significant advancements. Notably, numerous asymmetric reactions utilizing chiral secondary amine catalysts have been developed and applied in the total synthesis of natural products. In this review, we provide an overview of alkaloid syntheses reported since 2017, categorized by scaffold, with a focus on key steps involving asymmetric reactions catalyzed by secondary amine organocatalysts.

Robust Organocatalytic Three-Component Approach to 1,3-Diarylallylidene Pyrazolones via Consecutive Double Condensation Reactions

A robust pyrrolidine-BzOH salt-catalyzed one-pot three-component reaction involving 4-unsubstituted pyrazolones, aryl/heteroarylaldehydes, and aryl methyl ketones is reported for the first time. This catalytic process fortifies an efficient method, allowing for the practical synthesis of a wide array of synthetically useful 1,3-diarylallylidene pyrazolones in good to high yields exclusively in their single geometrical isomer forms. Furthermore, this catalyst facilitates a sequential double condensation reaction under thermal conditions, thereby enabling two consecutive C═C bonds through displacement of aryl groups. Moreover, this organocatalytic technique achieves a 100% carbon atom economy, marking a significant step forward toward efficient and sustainable synthesis.

Glycerol as Reaction Medium for Sonogashira Couplings: A Green Approach for the Synthesis of New Triarylamine-Based Materials with Potential Application in Optoelectronics

This study focuses on the design, eco-friendly synthesis, and characterization of several novel three-legged triphenylamine derivatives. By performing Sonogashira couplings of functionalized aryl iodides with tris(4-ethynylphenyl)amine in glycerol, a readily available bio-derived solvent, we achieved the synthesis of target products in short times and high yields, up to 94 %, with consistently lower E-factors and reduced costs compared to standard conditions using toluene as the reaction medium. The target molecules possess a D-(π-A)₃ or D-(π-D)₃ structure, where an electron-donating core connects to three electron-donating (D) or electron-accepting (A) peripheral aromatic subunits through an acetylene spacer. Their main optical and electronic properties have been determined experimentally and by DFT simulations and suggest a possible implementation in energy conversion technologies such as luminescent solar concentrators (LSCs) and perovskite solar cells (PSCs).

Molybdenum-Mediated Reductive ortho-Alkylation of Nitroarenes with Alcohols

A molybdenum-mediated reductive ortho-alkylation of nitroarenes with alcohols for the synthesis of ortho-alkylated anilines has been developed. Using Mo(CO)6 as both the reductant and the catalyst, a range of ortho-alkyl-substituted anilines were prepared from nitroarenes and alcohols. Preliminary mechanistic studies indicate that nitroarenes were reduced by Mo(CO)6 to aniline in the presence of H2O, while an oxidized Mo species catalyzed the alkylation portion of this reaction.

IPr*F - Highly Hindered, Fluorinated N-Heterocyclic Carbenes

The introduction of fluorine atom has attracted considerable interest in molecular design owing to the high electronegativity and the resulting polarization of carbon-fluorine bonds. Simultaneously, sterically-hindered N-heterocyclic carbenes (NHCs) have received major interest due to high stabilization of the reactive metal centers, which has paved the way for the synthesis of stable and reactive organometallic compounds with broad applications in main group chemistry, inorganic synthesis and transition-metal-catalysis. Herein, we report the first class of sterically-hindered, fluorinated N-heterocyclic carbenes. These ligands feature variable fluorine substitution at the N-aromatic wingtip, permitting to rationally vary steric and electronic characteristics of the carbene center imparted by the fluorine atom. An efficient, one-pot synthesis of fluorinated IPr*F ligands is presented, enabling broad access of academic and industrial researchers to the fluorinated ligands. The evaluation of steric, electron-donating and π-accepting properties as well as coordination chemistry to Au(I), Rh(I) and Se is presented. Considering the unique properties of carbon-fluorine bonds, we anticipate that this novel class of fluorinated carbene ligands will find widespread application in stabilizing reactive metal centers.

Transition-metal-free iterative two-fold reductive coupling and 1,3-borotropic shift to form 1,4-skipped dienes

We report herein a transition-metal-free two-fold reductive coupling between prenal (allyl) tosylhydrazone and boronic acids/1,3-borotropic shift cascade to furnish 1,4-skipped dienes. In this work, a single batch operation produces (E,E)-1,4-skipped dienes by undergoing a second reductive coupling of the transient boronic acid, which developed in situ following the first reductive allylation and a cascade 1,3-boron migration. Remarkably, the protocol is compatible with various aryl- and alkyl-substituted boronic acids, is scalable and has demonstrated on 61 substrates with yields up to 98%.

Advances in the self-organized total synthesis of natural products

Natural product total synthesis has trailblazed in the era of multistep synthesis. The strategic application of existing synthetic methodologies and the stepwise construction that revolves around newly developed, tailored key steps, are two basic tactics in the principle of classic retrosynthetic analysis. However, a new synthetic model, termed self-organized total synthesis, has emerged in recent years, enabling the rapid creation of specific natural products by a one-pot reaction. Distinct from conventional analysis associated with certain bond disconnections, the design of self-organized total synthesis focuses on seeking a series of self-organized reaction sequences which can be integrated compatibly under a uniform condition, therefore allowing the entire sequence to proceed in one pot, and most importantly, starting from commercially available feedstocks or biomass materials. Whilst dauntingly challenging, this synthetic strategy is more consistent with the biogenetic pathway of natural products compared with conventional counterparts, and will hopefully provide the shortest synthesis for such natural products. Through this rational analysis, one-pot total synthesis is no longer in the way of serendipity but can be precisely designed and manipulated. In this review, we account for the definition, delimitation, and categorization of self-organized total synthesis and then elucidate a comprehensive understanding of this synthetic strategy based on our intensive explorations. We also highlight the contributions of other research groups in this growing field and anticipate that it will give rise to advancing new methodologies, as well as new concepts within organic synthesis.

One-pot synthesis and pharmacological evaluation of new quinoline/pyrimido-diazepines as pulmonary antifibrotic agents

Aim: Pulmonary fibrosis is a life threating disease which requires an immediate treatment and due to the limited medications, this study focused on synthesizing a series of quinoline-based pyrimidodiazepines 4a-f as a novel antifibrotic hit.Materials & methods: The target compounds were synthesized via a one-pot reaction then investigated in a rat model of lung fibrosis induced by bleomycin (BLM).Results: Results revealed significant attenuation of the tested pro-inflammatory cytokines, fibrotic genes and apoptotic markers; however, Bcl-2 was upregulated, indicating a protective effect against fibrosis. Moreover, the molecular docking studies highlighted promising interactions between compounds 4b and 4c and specific amino acids within the protein pockets of caspase-3 (ARG341 and THR177), malondialdehyde (LYS195, LYS118 and ARG188) and TNF-α (SER99 and NME102).Conclusion: Compounds 4b and 4c emerge as promising candidates for further preclinical investigation as pulmonary antifibrotic agents.

One-pot, microwave (MW)-assisted production of furfural from almond-, oil-, and wine-derived co-products through biorefinery-based approaches

This work outlines the first microwave (MW)-assisted protocol for the production of biofuel precursor furfural (FF) from the raw agricultural waste almond hull (AH), olive stone (OS), and the winemaking-derived grape stalk (GS), grape marc (GM) and exhausted grape marc (EGM) through a one-pot synthesis process. To enhance the overall yield, a catalytic process was firstly developed from xylose, major constituent of hemicellulose present in lignocellulosic biomass. This method afforded FF with 100 % selectivity, yielding over 85 % in isolated product when using H2SO4, as opposed to a 37 % yield with AlCl3·6H2O, at 150 °C in only 10 min. For both catalysts, the developed methodology was further validated, proving adaptable and efficient in producing the targeted FF from the aforementioned lignocellulosic raw materials. More specifically, the employment of AlCl3·6H2O resulted in the highest selectivity (up to 89 % from GM) and FF yield (42 % and 39 % molar from OS and AH, respectively), maintaining notable selectivity for the latter (61 and 48 % from AH and OS). At this regard, and considering the environmental factor of sustainability, it is important to point out the role of AlCl3·6H2O in contrast to H2SO4, thus mitigating detrimental substances. This study provides an important management of agricultural waste through sustainable practises for the development of potential bio-based chemicals, aligning with Green Chemistry and process intensification principles.

An insight into sustainable and green chemistry approaches for the synthesis of quinoline derivatives as anticancer agents

Quinolones, a key class of heterocyclics, are gaining popularity among organic and medicinal chemists due to their promising properties. Quinoline, with its broad spectrum of action, plays a primordial role in chemotherapy for cancer. Drugs include lenvatinib and its structural derivatives carbozantinib and bosutinib, and tipifarnib are the popular anticancer agents. Owing to the importance of quinoline, there are several classical methods for the synthesis such as, such as Gould-Jacobs, Conrad-Limpach, Camps cyclization, Skraup, Doebnervon Miller, Combes, Friedlander, Pfitzinger, and Niementowski synthesis. These methods are well-commended for developing an infinite variety of quinoline analogues. However, these procedures are associated with several drawbacks such as long reaction times, use of hazardous chemicals or stoichiometric proportions, difficulty of working up conditions, high temperatures, organic solvents, and the presence of numerous steps, all of which have an impact on the environment and the economy. As a result, researchers are working hard to develop green quinoline compounds in the hopes of making groundbreaking discoveries in the realm of cancer. In this review, we have highlighted significant research on quinoline-based compounds and their structure-activity relationship (SAR). Furthermore, because of the significant economic and environmental health and safety (EHS) concerns, more research is being dedicated to the green synthesis of quinolone derivatives. The current review offers recent advances in quinoline derivatives as anticancer agents for green synthesis using microwave, ultrasound, and one-pot synthesis. We believe that our findings will provide useful insight and inspire more green research on this framework to produce powerful and selective quinoline derivatives.

Seven-membered N-heterocycles as approved drugs and promising leads in medicinal chemistry as well as the metal-free domino access to their scaffolds

Azepanes or azepines are structural motifs of many drugs, drug candidates and evaluated lead compounds. Even though compounds having N-heterocyclic 7-membered rings are often found in nature (e.g. alkaloids), the natural compounds of this group are rather rare as approved therapeutics. Thus, recently studied and approved azepane or azepine-congeners predominantly consist of semi-synthetically or synthetically-obtained scaffolds. In this review a comparison of approved drugs and recently investigated leads was proposed taking into regard their structural aspects (stereochemistry), biological activities, pharmacokinetic properties and confirmed molecular targets. The 7-membered N-heterocycles reveal a wide range of biological activities, not only against CNS diseases, but also as e.g. antibacterial, anticancer, antiviral, antiparasitic and against allergy agents. As most of the approved or investigated potential drugs or lead structures, belonging to 7-membered N-heterocycles, are synthetic scaffolds, this report also reveals different and efficient metal-free cascade approaches useful to synthesize both simple azepane or azepine-containing congeners and those of oligocyclic structures. Stereochemistry of azepane/azepine fused systems, in view of biological data and binding with the targets, is discussed. Apart from the approved drugs, we compare advances in SAR studies of 7-membered N-heterocycles (mainly from 2018 to 2023), whereas the related synthetic part concerning various domino strategies is focused on the last ten years.

Catalytic enantioselective synthesis of 2-pyrazolines via one-pot condensation/6π-electrocyclization: 3,5-bis(pentafluorosulfanyl)-phenylthioureas as powerful hydrogen bond donors

A new conjugate-base-stabilized carboxylic acid (CBSCA) containing a 3,5-bis(pentafluorosulfanyl)phenylthiourea functionality catalyses challenging one-pot condensations/6π-electrocyclizations of hydrazines and α,β-unsaturated ketones under mild conditions. Structurally diverse N-aryl 2-pyrazolines are obtained in good yields and enantioselectivities. The superior performance of 3,5-bis(SF5)phenylthioureas over the widely used 3,5-bis(CF3)phenylthioureas is further demonstrated in the Michael addition of dimethyl malonate to nitrostyrene, using a new Takemoto-type catalyst.

A Merger of Relay Catalysis with Dynamic Kinetic Resolution Enables Enantioselective β-C(sp3)-H Arylation of Alcohols

The conceptual merger of relay catalysis with dynamic kinetic resolution strategy is reported to enable regio- and enantioselective C(sp3)-H bond arylation of aliphatic alcohols, forming enantioenriched β-aryl alcohols typically with >90 : 10 enantiomeric ratios (up to 98 : 2 er) and 36-74 % yields. The starting materials bearing neighbouring stereogenic centres can be converted to either diastereomer of the β-aryl alcohol products, with >85 : 15 diastereomeric ratios determined by the catalysts. The reactions occur under mild conditions, ensuring broad compatibility, and involve readily available aryl bromides, an inorganic base, and commercial Ru- and Pd-complexes. Mechanistic experiments support the envisioned mechanism of the transformation occurring through a network of regio- and stereoselective processes operated by a coherent Ru/Pd-dual catalytic system.

Asymmetric Synthesis of α-Arylcyclohexenones Catalyzed by Diphenylprolinol Silyl Ether

A general methodology for the asymmetric synthesis of α-arylcyclohexeneones from arylacetones and α,β-unsaturated aldehydes catalyzed by diphenylprolinol silyl ether followed by p-TSA-mediated cyclization is developed. A variety of arylacetones and α,β-unsaturated aldehydes were successfully converted to α-arylcyclohexeneones in 34-67% yield, 10:1-100:0 dr, and 81-99% ee. The scalability of this methodology by a gram-scale synthesis and their utility by converting the product to the corresponding epoxide, alcohol, and diol are demonstrated.

Polycyclic Pyrazolidines by Tandem Diazomalonate Dipolar Cycloadditions and CpRu-Catalyzed Carbene Additions

Thanks to the ability of diazo derivatives to react either as 1,3-dipoles and as carbenes after dinitrogen extrusion, combinations of oxa or aza benzonorbornadienes and diazomalonates afford polycyclic pyrazolidines via a three-step sequence of (i) a highly diastereoselective [3+2]-cycloaddition, (ii) a CpRu-catalyzed carbene addition, and (iii) a second dipolar cycloaddition. Of importance, step (II) represents a unique access to novel bench-stable N,N-cyclic azomethine imines, which behave as effective 1,3-dipoles in combination with electron-poor dipolarophiles. Each step proceeds efficiently and the 3-step process can be performed in one-pot to yield a polycyclic pyrazolidine in excellent overall yield (90 %).

Synthesis of Simplified 2-Desmethyl Sanctolide A Analogs

A one-pot, sequential phosphate tether-mediated method for the synthesis of simplified 2-desmethyl sanctolide A analogs is reported. Western side-chain diversification was achieved using a pot-efficient, sequential cross metathesis (CM)/ring-closing metathesis (RCM)/H2/dephosphorylation procedure. Further diversification was achieved by Me3Al-mediated amide formation, Yamaguchi esterification, and RCM macrocyclization to access five C11/C12 Z-configured, 2-des-methyl sanctolide A analogs with improved stability.

Heteropolyaromatic Covalent Organic Frameworks via One-Pot Multicomponent Reactions

Multicomponent reactions (MCRs) offer a platform to create different chemical structures and linkages for highly stable covalent organic frameworks (COFs). As an illustrative example, the multicomponent Povarov reaction generates 2,4-phenylquinoline from aldehydes and amines in the presence of electron-rich alkenes. In this study, we introduce a new domino reaction to generate unprecedented 2,3-phenylquinoline COFs in the presence of epoxystyrene. This work thus presents, for the first time, structural isomeric COFs produced by multicomponent domino and Povarov reactions. Furthermore, 2,3-phenylquinolines can undergo a Scholl reaction to form extended aromatic linkages. With this approach, we synthesize two thermally and chemically stable MCR-COFs and two heteropolyaromatic COFs using both domino and in situ domino and Scholl reactions. The structure and properties of these COFs are compared with the corresponding 2,4-phenylquinoline-linked COF and imine-COF, and their activity toward benzene and cyclohexane sorption and separation is investigated. The position of the pendant phenyl groups within the COF pore plays a crucial role in facilitating the industrially important sorption and separation of benzene over cyclohexane. This study opens a new avenue to construct heteropolyaromatic COFs via MCR reactions.

A Domino Dearomative ipso-Annulation/Desymmetrization Approach: Stereoselective Access to Tricyclic Alkaloid Skeletons

Herein, we reveal an unprecedented domino annulation of N-benzyl-acrylamides with 1,3-dicarbonyls for the assembly of fused tricyclic alkaloid frameworks incorporating a spirocycle via an alkylation/dearomative ipso-annulation/Michael addition (desymmetrization) sequence. This conversion involves three carbon-carbon bond formations, generating four chiral carbons, including three quaternary carbon centers, in a single diastereomer in one pot under identical reaction conditions. The synthetic potential of this atom-economic method is illustrated by modifications of the functional groups present in the products obtained.