Design,Synthesis, and Antimicrobial Evaluation of some Novel Pyridine,Coumarin, and Thiazole Derivatives

Treatment of 2‐cyano‐N′‐(1‐(pyridin‐2‐yl)ethylidene)acetohydrazide 1 with aromatic/heterocyclic aldehydes 2a–f gave arylidene derivatives 3a–f . Polysubstituted pyridine derivatives 4a,b were prepared either from reaction of arylidene 3a,b with malononitrile or from reaction of acetohydrazide 1 with arylidenemalononitrile 5a,b . Cyclocondensation of acetohydrazide 1 with salicylaldehyde derivatives and acetylacetone furnished pyrido‐coumarins 6,7 and 2‐pyridone‐3‐carbonitrile 8, respectively. In addition, pyrido‐thiazoles 13 and 15 were obtained through reaction of 2‐(1‐(pyridin‐2‐yl)ethylidene)hydrazinecarbothioamide 11 with hydrazonyl chlorides and α‐haloketones, respectively. The structures of synthesized compounds were elucidated with spectral and elemental data. The antimicrobial activity of the synthesized compounds was studied.     

Synthesis and Cytotoxicity Evaluation of Metal‐Chelator‐Bearing Flavone,Carbazole, Dibenzofuran,Xanthone, and Anthraquinone

2‐(Aryloxymethyl)‐5‐benzyloxy‐1‐methyl‐1H‐pyridin‐4‐ones 8a – 8g , 2‐(aryloxymethyl)‐5‐hydroxy‐4H‐pyran‐4‐ones 9a – 9g , and 2‐(aryloxymethyl)‐5‐hydroxy‐1‐methyl‐1H‐pyridin‐4‐ones 10a – 10g were prepared from the known 5‐benzyloxy‐2‐(hydroxymethyl)pyran‐4‐one ( 3 ) in a good overall yield. These compounds were evaluated in vitro against a three‐cell lines panel consisting of MCF7 (breast), NCI‐H460 (lung), and SF‐268 (CNS), and the active compounds passed on for evaluation in the full panel of 60 human tumor cell lines derived from nine cancer cell types. The results indicated that 5‐hydroxy derivatives are more favorable than their corresponding 5‐benzyloxy precursors ( 10a – 10g vs. 8a – 8g ), and 1‐methyl‐1H‐pyridin‐4‐ones are more favorable than their corresponding pyran‐4(1H)‐ones ( 10a – 10g vs. 9a – 9g ). Among these three types of compounds, 2‐(aryloxymethyl)‐5‐hydroxy‐1‐methyl‐1H‐pyridin‐4‐ones 10a – 10g were the most cytotoxic; they inhibited the growth of almost all the cancer cells tested. On the contrary, compound 8a (a mean GI₅₀=27.8 μM ), 8b (38.5), 8d (11.0), and 8e (30.5) are especially active against the growth of SK‐MEL‐5 (a melanoma cancer cell) with a GI₅₀ of <0.01, 5.65, 0.55, and 0.03 μM , respectively (cf. Table 2).     

Synthesis,Antioxidant, Antituomer Activities of Some New Thiazolopyrimidines,Pyrrolothiazolopyrimidines and Triazolopyrrolothiazolopyrimidines Derivatives

Reaction of 6‐amino‐2‐thiouracil 1 with ethyl bromoacetate yielded ethyl 2‐(7‐amino‐2,5‐dioxo‐3,5‐dihydro‐2H‐thiazolo[3,2‐a]pyrimidin‐6‐yl)acetate 2 . Reaction of 2 with sodium ethoxide afforded the pyrrolothiazolopyrimidine derivative 3 . Compound 2 reacted with hydrazine hydrate to give 7‐amino‐thiazolopyrimidine‐carbohydrazide 4 . The latter compound 4 reacted with carbon disulphide to form 7‐amino‐6‐(oxadiazolylmethyl) thiazolopyrimidine 5 . Compound 5 was heated in methanol to yield 9‐thioxotriazolopyrrolothiazolopyrimidine 6 . Also, the reaction of 3 with aromatic aldehydes afforded the diarylmethylenepyrrolothiazolopyrimidine derivatives 7a‐c . The latter compounds 7a‐c underwent cyclocondensation with hydroxylamine to give diaryldioxazolopyrrolothiazolopyrimidine derivatives 8a‐c . The new prepared compounds were subjected for antioxidant and antituomer studies, some of these compounds exhibited promising activity.     

Synthesis,molecular docking studies,and absorption,distribution, metabolism,and excretion prediction of novel sulfonamide derivatives as antibacterial agents

A series of novel sulfonamide‐amide derivatives were synthesized from 3‐(2,4 dichlorophenylamino)‐3‐oxopropane‐1‐sulfonylchloride and a variety of amines under solvent‐free conditions at room temperature. 3‐(2,4‐dichlorophenylamino)‐3‐oxopropane‐1 sulfonylchloride was synthesized in four steps starting from 2,4‐dichloroaniline and chloropropanoic acid in good yield and purity. The synthesized compounds were screened for their in vitro antibacterial activity against Escherichia coli (ATCC 25922) and Staphylococcus aureus (ATCC 29213). Molecular docking of sulfonamide derivatives into S. aureus tyrosyl‐tRNA synthetase (TyrRS)‐active site was also performed and among these, 5m and 5g tightly fit the active sites that might be inhibitors of TyrRS for further investigations. Also in the silico metabolism profile, drug‐like properties and absorption, distribution, metabolism, excretion and toxicity (ADMET) of the title compounds were calculated by the preADMET server.     

Synthesis,Crystal Structures,Optical Properties,and Photocurrent Response of Heteroacene Derivatives

Six 5,9,14,18‐tetrathiaheptacene derivatives ( 1 a – 1 f ) were synthesized by using a simple ether–ether exchange reaction and fully characterized. In contrast to the planar conformation usually observed in thiophene‐fused benzene systems, single‐crystal analysis indicates that 7,16‐dipropyl‐5,9,14,18‐tetrathiaheptacene ( 1 a ), 7,16‐diphenyl‐5,9,14,18‐tetrathiaheptacene ( 1 b ), and 7,16‐di(4′‐chlorophenyl)‐5,9,14,18‐tetrathiaheptacene ( 1 c ) adopt chair conformations. The as‐formed dihedral angle between anthracene and the terminal benzene units are 137.258, 137.855, and 134.912° for 1 a , 1 b , and 1 c , respectively, which is close to the theoretical optimization results (128° for 1 b ). Interestingly, the oxidized product of 7,16‐di(trifluoromethylphenyl)‐5,9,14,18‐tetrathiaheptacene ( 1 e ) has a saddle shape, which results in the formation of column‐shaped units in the single crystal. The substituents on the side phenyl group have less effect on their UV/Vis absorption spectra, but a distinct redshift that accounts for the intramolecular charge transfer can be observed in the emission spectra. The electrochemical measurements show that all compounds present two oxidation waves. The photoswitching behavior based on 1 a–1 f was further measured and the experimental results suggest that these heteroacene derivatives are promising semiconductor materials for organic electronics.     

Synthesis,crystal structure,electronic spectroscopy,electrochemistry and biological studies of carbohydrate containing ferrocene amides

A series of four new ferrocene–carbohydrate amides was prepared from pentose and hexose sugar derivatives. These include (5‐amino‐5‐deoxy‐1,2‐O‐isopropylidene‐α‐d ‐xylofuranose)‐1‐ferrocene carboxamide (2a), (5‐amino‐3‐O‐benzyl‐5‐deoxy‐1,2‐O‐isopropylidene‐α‐d ‐xylofuranose)‐1‐ferrocene carboxamide (2b), (methyl‐6‐amino‐6‐deoxy‐2,3‐O‐isopropylidene‐β‐d ‐ribofuranoside)‐1‐ferrocene carboxamide (2c) derived from furanose sugars and (6‐amino‐6‐deoxy‐1,2:3,4‐di‐O‐isopropylidene‐α‐d ‐galactopyranose)‐1‐ferrocene carboxamide (2d) derived from pyranose sugar. The compounds were characterized by spectroscopic means and the structure of amide derived from α‐d ‐xylofuranose (2a) was determined by X‐ray crystallography. The electronic and optical properties of the compounds were studied by means of cyclic voltammetry and absorption spectroscopy. The UV and electrochemical studies of these compounds, performed in aqueous solutions under physiological conditions (at pH 7.4), confirmed their stability. These results indicated that the compounds were suitable for conducting biological studies. The CD spectral analysis displays the effect of sugar substituents on the compounds. The cytotoxicity and antimicrobial activity of these conjugates were investigated on different cancer cell lines and microbes respectively. The degree of inhibition varied over a broad spectrum of Gram‐ positive and Gram‐negative bacteria. In addition, the compounds also exhibited antioxidant properties. Copyright © 2012 John Wiley & Sons, Ltd.     

Synthesis of Novel Pyridothienopyrimidines,Pyridothienopyrimidothiazines, Pyridothienopyrimidobenzthiazoles and Triazolopyridothienopyrimidines

The reaction of 3‐amino‐4,6‐dimethylthieno[2,3‐b]pyridine‐2‐carboxamide (1a) or its N‐aryl derivatives 1b‐d with carbon disulphide gave the pyridothienopyrimidines 2a‐d , whilst when the same reaction was carried out using N¹‐arylidene‐3‐amino‐4,6‐dimethylthieno[2,3‐b]pyridine‐2‐carbohydrazides (1e‐h) , pyridothienothiazine 3 was obtained. Also, refluxing of 1b‐d with acetic anhydride afforded oxazinone derivative 4 . Compounds 2a and 2b‐d were also obtained by the treatment of thiazine 3 with ammonium acetate or aromatic amines, respectively. When compound 2a was allowed to react with arylidene malononitriles or ethyl α‐cyanocinnamate, novel pyrido[3″,2″:4′,5′]thieno[3′,2′:4,5]pyrimido[2,1‐b][1,3] thiazines 5a‐c were obtained. Treatment of 2b‐d with bromine in acetic acid furnished the disulphide derivatives 6a‐c . U.V. irradiation of 2b‐d resulted in the formation of pyrido[3″,2″:4′,5′]thieno[3′,2′:4,5]pyrimido[2,1‐b]benzthiazoles 7a‐c . The reaction of 2a‐d with some halocarbonyl compounds afforded the corresponding S‐substituted thiopyrido thienopyrimidines 8a‐j . Compound 8b was readily cyclized into the corresponding thiazolo[3″,2″‐a]‐pyrido[3′,2′:4,5]thieno[3,2‐d]pyrimidine 9 upon treatment with conc. sulphuric acid. Heating of 2a,b with hydrazine hydrate in pyridine afforded the hydrazino derivatives 11a,b . Reaction of ester 8c with hydrazine hydrate in ethanol gave acethydrazide 10 . Compounds 10 and 11a,b were used as versatile synthons for other new pyridothienopyrimidines 12–15 as well as [1,2,4] triazolopyridothienopyrimidines 16–19.     

Synthesis and Antimicrobial Activity of Some Novel Hydrazide,Pyrazole, Triazine,Isoxazole, and Pyrimidine Derivatives

In continuation of our efforts to find a new class of antimicrobial agents, a series of pyrazole, 1,2,4‐triazine, isoxazole, pyrimidine, and other related products containing a hydrazide moiety were prepared via the reaction of 2‐cyano‐N‐((2‐methoxynaphthalen‐1‐yl)methylene) acetohydrazide ( 1 ) with appropriate chemical reagents. These compounds were evaluated for their antimicrobial activities, and also their minimum inhibitory concentration against most of test organisms was performed. Among the tested compounds 4 , 5 , 6 , and 16 displayed excellent antimicrobial activity. All the synthesized products were confirmed by elemental analysis, IR, ¹H‐NMR, ¹³C‐NMR, and mass spectral data.     

Synthesis and properties of a novel,liquid, trifunctional,cycloaliphatic epoxide

A novel cycloaliphatic triepoxide, 1,1‐bis(2′,3′‐epoxycyclohexyloxymethyl)‐3,4‐epoxycyclohexane ( II ), and its precursor, 1,1‐bis(2′‐cyclohexenyloxymethyl)‐3‐cyclohexene, were synthesized. Their chemical structures were confirmed with IR spectroscopy, elemental analysis, and ¹H NMR spectroscopy. II was easily cured with hexahydro‐4‐methylphthalic anhydride with 1,3,5‐triethylhexahydro‐s‐triazine as a curing accelerator. The physical properties of the cured product were examined with thermomechanical analysis, thermogravimetric analysis, and dynamic mechanical analysis. Compared with the commercial diepoxide ERL‐4221 under the same curing conditions, the cured product based on II showed a much higher glass‐transition temperature (198 °C), a higher crosslinking density (2.08 × 10^?3 mol/cm³), and a lower coefficient of thermal expansion [6.2 × 10⁵(/°C)]. II may become a promising candidate material for modern microelectronic packaging. © 2001 John Wiley & Sons, Inc. J Polym Sci Part A: Polym Chem 39: 2799–2804, 2001     

Curcumaromins A,B, and C,Three Novel Curcuminoids from Curcuma aromatica

Three novel curcuminoids, curcumaromins A–C ( 1 – 3 , resp.), along with a known compound, longiferone B ( 4 ) were isolated from Curcuma aromatica Salisb . The structures of the new compounds were elucidated as (1E,4Z,6E)‐5‐hydroxy‐7‐{4‐hydroxy‐3‐[(1R*,6R*)‐3‐methyl‐6‐(propan‐2‐yl)cyclohex‐2‐en‐1‐yl)phenyl}‐1‐(4‐hydroxyphenyl)hepta‐1,4,6‐trien‐3‐one ( 1 ), 2,3‐dihydro‐2‐(4‐hydroxyphenyl)‐6‐[(E)‐2‐(4‐hydroxyphenyl)ethenyl]‐5‐[(1R*,6R*)‐3‐methyl‐6‐(propan‐2‐yl)cyclohex‐2‐en‐1‐yl]‐4H‐pyran‐4‐one ( 2 ), and (1E,6E)‐1,7‐bis(4‐hydroxyphenyl)‐4‐[(1R*,6R*)‐3‐methyl‐6‐(propan‐2‐yl)cyclohex‐2‐en‐1‐yl]hepta‐1,6‐diene‐3,5‐dione ( 3 ) on the basis of spectroscopic analysis. Curcumaromins A–C ( 1 – 3 ) represented the first examples of menthane monoterpene‐coupled curcuminoids. The known compound, longiferone B ( 4 ), was the first daucane sesquiterpene isolated from the genus Curcuma.     

Synthesis of Peripherally Nitrated,Aminated, and Arylaminated Subporphyrins

2‐Nitro‐5,10,15‐tri(4‐tert‐butylphenyl)subporphyrin 2 was prepared by the nitration of 5,10,15‐tri(4‐tert‐ butylphenyl)subporphyrin 1a with five equivalents of Cu(NO₃)₂ ? 5 H₂O in a mixed EtOAc/Ac₂O solution and was reduced into 2‐amino‐5,10,15‐tri(4‐tert‐butylphenyl)subporphyrin 3 . Bromination of 5,10,15‐triphenylsubporphyrin 1b with 1.5 equivalents of N‐bromosuccinimide (NBS) gave 2‐bromo‐5,10,15‐triphenylsubporphyrin, which was converted into various 2‐arylamino‐5,10,15‐triphenylsubporphyrins ( 4a , 4b , 4c , 4d ) and 2‐benzamido‐5,10,15‐triphenylsubporphyrin 5 through Pd‐catalyzed cross‐coupling reactions. These molecules constitute the first examples of mono‐β‐substituted subporphyrins. These subporphyrins exhibit significantly perturbed optical and electrochemical properties, which reflect a large influence of the peripherally attached substituents on the electronic networks of subporphyrins.     

First Total Synthesis of Cytotoxic Diarylheptanoids,Galeon, and Pterocarine

The first total synthesis of cytotoxic diphenyl ether‐type diarylheptanoids, galeon and pterocarine, was described in which the Ullmann reaction was employed at the final step for the diaryl ether formation of key intermediate, 1‐(3‐bromo‐4‐benzyloxyphenyl)‐7‐(4‐hydroxy‐3‐methoxyphenyl)heptan‐3‐one, assembled by a series of cross‐aldol condensation from 3‐methoxy‐4‐benzyloxybenzaldehyde.     

Tetraalkoxyphenanthrene‐Fused Dehydroannulenes: Synthesis,Self‐Assembly,and Electronic,Optical, and Electrochemical Properties

Novel tetraalkoxyphenanthrene‐fused dehydro[12]‐, [18]‐, and [24]annulenes 1 – 3 were synthesized by using Cu‐mediated or Pd‐catalyzed oxidative macrocyclization reactions as key steps, and their electronic, optical, and electrochemical properties have been investigated in detail. X‐ray crystallographic analysis of a single crystal of 1 a demonstrated that the molecules were arranged longitudinally in a slipped π‐stacked fashion to form a 1D column. ¹H NMR and UV/Vis spectroscopic and cyclic voltammetric analysis in conjugation with nucleus‐independent chemical shift (NICS) calculations for 1 – 3 support that the annulation at the 9,10‐positions of phenanthrene to the dehydroannulene ring enhances the tropicity and decreases the HOMO–LUMO gaps of the molecules relative to the benzannulation and that 1 possesses an antiaromatic character. Self‐association behavior due to π–π stacking in CDCl₃ was observed for 1 and 2 and was quantified by concentration‐dependent ¹H NMR spectroscopic measurements. The self‐assembly of 1 and 2 into well‐defined 1D superstructures with high aspect ratios were obtained, and the morphology and crystallinity of these compounds were investigated by means of SEM and wide‐angle X‐ray diffraction (WAXD) measurements. Furthermore, it was shown that 1 b and 2 b display liquid‐crystalline phases by means of differential scanning calorimetry, polarizing optical microscopy, and variable‐temperature WAXD measurements.     

Design,Synthesis, Characterization,and Antimicrobial Activity of Biginelli Products of Indandione

A simple and efficient method has been developed for the synthesis of 4‐(substituted phenyl)‐3,4‐dihydro‐1H‐indeno [1,2‐d] pyrimidine‐2,5‐dione (5) and 4‐(substituted phenyl)‐2‐thioxo‐1,2,3,4‐tetrahydroindeno [1,2‐d] pyrimidine‐5‐one (6) , by a one‐pot three component cyclocondensation reaction of 1,3 dicarbonyl compound (Indandione) (1) , aromatic aldehyde (2) , and urea/thiourea (3/4) using catalytic amount of conc. HCl in refluxing ethanol. Representative samples were screened for their antimicrobial activity against gram‐negative bacteria, E coli and Paeruginosa and gram‐positive bacteria, S aureus, and C diphtheriae using disc diffusion method. The structures of the products were confirmed by IR, ¹H, ¹³C NMR, and elemental analysis.     

Open Chemistry,JupyterLab, REST,and quantum chemistry

Quantum chemistry must evolve if it wants to fully leverage the benefits of the internet age, where the worldwide web offers a vast tapestry of tools that enable users to communicate and interact with complex data at the speed and convenience of a button press. The Open Chemistry project has developed an open‐source framework that offers an end‐to‐end solution for producing, sharing, and visualizing quantum chemical data interactively on the web using an array of modern tools and approaches. These tools build on some of the best open‐source community projects such as Jupyter for interactive online notebooks, coupled with 3D accelerated visualization, state‐of‐the‐art computational chemistry codes including NWChem and Psi4, and emerging machine learning and data mining tools such as ChemML and ANI. They offer flexible formats to import and export data, along with approaches to compare computational and experimental data.     

Derivational,Structural, and Biological Studies of Some New Pyrazolyl,Isoxazolyl, Pyrimidinyl,Pyridazinyl, and Pyridopyridazinyl from 4‐Substituted Antipyrine

(1,5‐Dimethyl‐3‐oxo‐2‐phenyl‐2,3‐dihydro‐1H‐pyrazol‐4‐yl)carbono‐hydrazonoyl dicyanide was used as a key intermediate for the synthesis of novel pyrazole, isoxazole, pyrimidine, and pyridazine derivatives. The newly synthesized compounds were characterized by elemental analyses and spectral data (IR, ¹H‐NMR, ¹³C‐NMR, and mass spectra). The compounds were tested for their in vitro antibacterial activity against Gram‐positive bacteria as (Staphylococcus aureus and Bacillus subtilis ) and Gram‐negative bacteria (Pseudomonas aeruginosa and Escherichia coli ). The investigated compounds were tested against two strains of fungi Botrytis fabae and Fusarium oxysporum using diffusion agar technique. The biological results showed clearly that most of the synthesized compounds revealed mild to moderate activity against the used microorganisms.     

Targeting π‐Conjugated Multiple Donor–Acceptor Motifs Exemplified by Tetrathiafulvalene‐Linked Quinoxalines and Tetrabenz[bc,ef,hi,uv]ovalenes: Synthesis,Spectroscopic, Electrochemical,and Theoretical Characterization

An efficient synthetic approach to a symmetrically functionalized tetrathiafulvalene (TTF) derivative with two diamine moieties, 2‐[5,6‐diamino‐4,7‐bis(4‐pentylphenoxy)‐1,3‐benzodithiol‐2‐ylidene]‐4,7‐bis(4‐pentylphenoxy)‐1,3‐benzodithiole‐5,6‐diamine ( 2 ), is reported. The subsequent Schiff‐base reactions of 2 afford large π‐conjugated multiple donor–acceptor (D–A) arrays, for example, the triad 2‐[4,9‐bis(4‐pentylphenoxy)‐1,3‐dithiolo[4,5‐g]quinoxalin‐2‐ylidene]‐4,9‐bis(4‐pentylphenoxy)‐1,3‐dithiolo[4,5‐g]quinoxaline ( 8 ) and the corresponding tetrabenz[bc,ef,hi,uv]ovalene‐fused pentad 1 , in good yields and high purity. The novel redox‐active nanographene 1 is so far the largest known TTF‐functionalized polycyclic aromatic hydrocarbon (PAH) with a well‐resolved ¹H NMR spectrum. The electrochemically highly amphoteric pentad 1 and triad 8 exhibit various electronically excited charge‐transfer states in different oxidation states, thus leading to intense optical intramolecular charge‐transfer (ICT) absorbances over a wide spectral range. The chemical and electrochemical oxidations of 1 result in an unprecedented TTF^?+ radical cation dimerization, thereby leading to the formation of [ 1 ^?+]₂ at room temperature in solution due to the stabilizing effect, which arises from strong π–π interactions. Moreover, ICT fluorescence is observed with large solvent‐dependent Stokes shifts and quantum efficiencies of 0.05 for 1 and 0.035 for 8 in dichloromethane.     

Dithiolopyranthione Synthesis,Spectroscopy, and an Unusual Reactivity with DDQ

The bicyclic pyran thiolone tetrahydro‐3αH‐[1,3]dithiolo[4,5‐β]pyran‐2‐thione ( 3a ) engages in a highly unusual fragmentation in the presence of DDQ. The pyran thiolone, 3a , was synthesized by chlorination of 3,4‐dihydro‐2H‐pyran ( 1 ) followed by condensing with CS₂ and NaSH. Reaction of 3a with DDQ generates the isomerized pyran thiolone tetrahydro‐3αH‐[1,3]dithiolo[4,5‐β]pyran‐2‐thione ( 3b ) and 4‐benzyl‐5‐(3‐hydroxypropyl)‐1,3‐dithiole‐2‐thione ( 4 ) via a deep‐seated rearrangement. The identity of 3b was confirmed by single crystal X‐ray analysis: P2₁/c, a = 5.807(9) Å, b = 12.99(2) Å, c = 11.445(15), β = 113.23(6)°. Mechanistic experiments and computational insight is used to explain the likely sequence of events in the highly unusual formation of 4 . Collectively, these results establish fundamental reactivity patterns for further research in this area.     

Total Syntheses of Echitamine,Akuammiline, Rhazicine,and Pseudoakuammigine

Echitamine ( 1 ) and akuammiline ( 2 ) are representative members of a fascinating class of monoterpenoid indole alkaloids. We report the syntheses of 2 and its congener deacetylakuammiline ( 3 ). The azabicyclo[3.3.1]nonane motif was assembled through silver‐catalyzed internal alkyne cyclization, and one‐pot C?O bond cleavage/C?N bond formation furnished the pentacyclic scaffold. Compound 3 then served as a common intermediate for preparing a series of structurally diverse and synthetically challenging congeners including 1 . A position‐selective Polonovski–Potier reaction followed by formal N‐4 migration built the core of N‐demethylechitamine ( 4 ) and 1 . An alternative route featuring Meisenheimer rearrangement gave 4 as well. Oxidation of the alcohol within 3 gave rhazimal ( 5 ), which underwent tandem indolenine hydrolysis, hemiaminalization, and hemiketalization to form rhazicine ( 6 ). A sequence of N,O‐ketalization and reductive amination secured the chemoselectivity of N‐methylation, leading to pseudoakuammigine ( 7 ).     

Total Syntheses of Echitamine,Akuammiline, Rhazicine,and Pseudoakuammigine

Echitamine ( 1 ) and akuammiline ( 2 ) are representative members of a fascinating class of monoterpenoid indole alkaloids. We report the syntheses of 2 and its congener deacetylakuammiline ( 3 ). The azabicyclo[3.3.1]nonane motif was assembled through silver‐catalyzed internal alkyne cyclization, and one‐pot C?O bond cleavage/C?N bond formation furnished the pentacyclic scaffold. Compound 3 then served as a common intermediate for preparing a series of structurally diverse and synthetically challenging congeners including 1 . A position‐selective Polonovski–Potier reaction followed by formal N‐4 migration built the core of N‐demethylechitamine ( 4 ) and 1 . An alternative route featuring Meisenheimer rearrangement gave 4 as well. Oxidation of the alcohol within 3 gave rhazimal ( 5 ), which underwent tandem indolenine hydrolysis, hemiaminalization, and hemiketalization to form rhazicine ( 6 ). A sequence of N,O‐ketalization and reductive amination secured the chemoselectivity of N‐methylation, leading to pseudoakuammigine ( 7 ).