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Search for "alcohols" in Full Text gives 859 result(s) in Beilstein Journal of Organic Chemistry. Showing first 200.
Synthesis of diaryl phosphates using phytic acid as a phosphorus source
- Kazuya Asao,
- Seika Matsumoto,
- Haruka Mori,
- Riku Yoshimura,
- Takeshi Sasaki,
- Naoya Hirata,
- Yasuyuki Hayakawa and
- Shin-ichi Kawaguchi
Beilstein J. Org. Chem. 2026, 22, 213–223, doi:10.3762/bjoc.22.15
- products of phosphate diesters were obtained through the reactions of commercially available phytic acid and aromatic alcohols with 31P nuclear magnetic resonance yields up to 83%. We also isolated a portion of the reaction substrates with yields up to 60%. Next, we extracted phytic acid from rice bran
- chlorides and the corresponding alcohols, which generates large amounts of heat and hydrogen chloride gas [32][33]. Focusing on the upstream material, phosphoryl chlorides are obtained via the chlorination of white phosphorus and excess chlorine gas. Further upstream, white phosphorus is obtained from
- esterification with alcohols using sustainable biomass-derived phytic acid as a phosphorus source (Figure 2E). This approach can facilitate the development of environmentally friendly phosphate ester production as well as phosphorus recovery and recycling techniques. To date, the preparation of phosphate esters
Graphical Abstract
Scheme 1: Structure of phytic acid.
Figure 1: Structures of representative phosphate esters.
Figure 2: Synthetic methods for phosphorus compounds bypassing white phosphorus or phosphorus chloride.
Figure 3: Conditions for the syntheses of diaryl phosphates using phytic acid as a phosphorus source and scop...
Scheme 2: Phosphoric acid diesterification reaction conducted in a previous study.
Scheme 3: Scale-up reaction conducted for the time-course analysis of phosphate esterification. The reaction ...
Figure 4: Time-course analysis plots of the diphenylphosphate formation from phytic acid and 1a. The beginnin...
Figure 5: A possible reaction pathway for the formation of phosphate ester using phytic acid as the phosphoru...
Figure 6: 31P NMR spectrum of phytic acid extracted from rice bran.
Scheme 4: Esterification reaction conditions using the extracted phytic acid. The yield refers to the isolate...
Base-promoted deacylation of 2-acetyl-2,5-dihydrothiophenes and their oxygen-mediated hydroxylation
- Vladimir G. Ilkin,
- Margarita Likhacheva,
- Igor V. Trushkov,
- Tetyana V. Beryozkina,
- Vera S. Berseneva,
- Vladimir T. Abaev,
- Wim Dehaen and
- Vasiliy A. Bakulev
Beilstein J. Org. Chem. 2026, 22, 192–204, doi:10.3762/bjoc.22.13
- Oxidative transformations are an important area of modern organic synthesis [1], producing a broad range of valuable synthetic products for the industry. A variety of catalytic reactions were developed for the oxidative conversions of unsaturated compounds [2][3][4][5], alcohols [6][7], alkanes [8][9][10
Graphical Abstract
Scheme 1: Previous reports (A‒C) and our work (D, E).
Scheme 2: Oxidation of 2-acetyldihydrothiophenes 1. Conditions: dihydrothiophenes 1 (0.12–0.21 mmol, 1.0 equi...
Scheme 3: Deacylation of 2-acetyldihydrothiophenes 1. Conditions: dihydrothiophenes 1 (0.11–0.18 mmol, 1.0 eq...
Scheme 4: Synthesis of dihydrothiophenes 5. Conditions: dihydrothiophenes 4 (0.13–0.22 mmol, 1.0 equiv), sodi...
Scheme 5: Control experiments.
Figure 1: HRMS analysis of the crude product.
Figure 2: UV–vis spectra of the crude mixture (5.6 mg of the crude mixture was dissolved in 15 mL of methanol...
Scheme 6: Proposed mechanism.
Circumventing Mukaiyama oxidation: selective S–O bond formation via sulfenamide–alcohol coupling
- Guoling Huang,
- Huarui Zhu,
- Shuting Zhou,
- Wanlin Zheng,
- Fangpeng Liang,
- Zhibo Zhao,
- Yifei Chen and
- Xunbo Lu
Beilstein J. Org. Chem. 2026, 22, 158–166, doi:10.3762/bjoc.22.9
- /bjoc.22.9 Abstract A selective and efficient method for the synthesis of sulfinimidate esters via an NBS-promoted oxidative coupling of sulfenamides with alcohols has been developed. This operationally simple, metal-free protocol uses inexpensive and readily available reagents, operates under mild
- conditions, exhibits a broad substrate scope and high chemoselectivity, and clearly distinguishes itself from classical Mukaiyama-type oxidations. The reaction is readily scalable to gram quantities and is applicable to late-stage functionalization of complex alcohols, including bioactive molecules such as
- RU58841. Moreover, chiral alcohols such as ʟ-menthol are well tolerated, affording diastereomeric sulfinimidate esters that can undergo stereospecific Grignard substitutions to furnish enantioenriched sulfilimines with up to 93% ee. These results demonstrate the potential of sulfinimidate esters as
Graphical Abstract
Figure 1: Representative molecules containing a sulfilimine moiety.
Scheme 1: PIDA-mediated approach versus the present NBS-mediated approach to sulfinimidate esters.
Scheme 2: Substrate scope of sulfenamides derived from various thiophenols and thiols. Reaction conditions: s...
Scheme 3: Substrate scope of sulfenamides derived from various amides. Reaction conditions: sulfenamide 1 (0....
Scheme 4: Substrate scope of reactions between sulfenamides 1a and various alcohols. Reaction conditions: asu...
Scheme 5: Scale-up synthesis, late-stage derivatization, and substitution of diastereomeric sulfinimidate est...
Asymmetric Mannich reaction of aromatic imines with malonates in the presence of multifunctional catalysts
- Kadri Kriis,
- Harry Martõnov,
- Annette Miller,
- Mia Peterson,
- Ivar Järving and
- Tõnis Kanger
Beilstein J. Org. Chem. 2026, 22, 151–157, doi:10.3762/bjoc.22.8
- between the catalyst and the reagents. The chirality of the catalysts is derived from either amino acid or amino alcohols (including cinchona alkaloid derivatives). There are three exceptional structures: catalysts A-H and E-H, which are the hydrogen analogues of the corresponding iodine-containing
Graphical Abstract
Scheme 1: The catalytic Mannich reaction under study.
Figure 1: Screened catalysts.
Figure 2: Model for the interaction of the catalyst with the imine.
Figure 3: Substrate scope of the asymmetric Mannich reaction.
Advances in Zr-mediated radical transformations and applications to total synthesis
- Hiroshige Ogawa and
- Hugh Nakamura
Beilstein J. Org. Chem. 2026, 22, 71–87, doi:10.3762/bjoc.22.3
- iodide 10n failed to give the desired products. In substrate 10o containing both iodide and bromide, selective activation of the alkyl iodide was observed, affording the coupled product in 96% yield. Furthermore, the reaction proceeded smoothly in the presence of alcohols 10p–q and carboxylic acid 10r
- unsymmetrical epoxides (Scheme 5B). Both monosubstituted epoxides 23a–e and di- and trisubstituted epoxides 23f–h underwent ring opening with regioselectivity opposite to that observed in conventional systems, affording the corresponding alcohols. Moreover, the method was successfully applied to complex
- molecules such as allose (23i) and cholesterol (23k), delivering the desired alcohols in good yields with excellent regioselectivity. The proposed mechanism is shown in Scheme 5C. Homolytic cleavage of the C–O bond in the epoxide generates a strong Zr–O bond, while the resulting alkyl radical abstracts a
Graphical Abstract
Figure 1: Historical background of zirconium and its physical properties. Image depicted in the background of ...
Scheme 1: Zr-mediated radical cyclization.
Scheme 2: Ni/Zr-mediated one-pot ketone synthesis.
Scheme 3: Zirconocene-catalyzed alkylative dimerization of 2-methylene-1,3-dithiane.
Scheme 4: Zirconium complexes as a photoredox catalyst.
Scheme 5: Zr-catalyzed reductive ring opening of epoxides.
Scheme 6: Zr-catalyzed reductive ring opening of oxetanes. a10 mol % of Cp2Zr(OTf)2·THF was used. bPhCF3 was ...
Scheme 7: Zr-catalyzed halogen atom transfer of alkyl chlorides.
Scheme 8: Zr-catalyzed radical homo coupling of alkyl chlorides.
Scheme 9: Zr-catalyzed fluorine atom transfer.
Scheme 10: Zr-catalyzed C–O bond cleavage. aYield without the use of P(OEt)3.
Scheme 11: Application to the total synthesis of halichondrins.
Scheme 12: Zr-catalyzed C3 dimerization of 3-bromotryptophan derivatives. aCp2ZrCl2 was used.
Scheme 13: Mechanistic studies.
Scheme 14: Application to the total synthesis of cyctetryptomycins. A photo of compound 61b was taken by the a...
Synthesis and applications of alkenyl chlorides (vinyl chlorides): a review
- Daniel S. Müller
Beilstein J. Org. Chem. 2026, 22, 1–63, doi:10.3762/bjoc.22.1
- oxidation/halogenation reaction of allylic alcohols, as recently reported by Chisholm and co-workers (Scheme 36) [137]. Their approach involves oxidation of the allylic alcohol under Moffatt–Swern conditions, followed by halogenation of the resulting enone to generate a chloronium ion. Subsequent ring
- the possible presence of oligomeric or polymeric material in the isolated sample. Biswas reported that benzylic, allylic, and propargylic alcohols could be activated by the addition of 0.4 equivalents of iron(III) chloride (Scheme 44) [149]. Although 19 examples were disclosed, limited information is
- ]. Revisiting this transformation, we found that hydrated indium trichloride afforded superior results under otherwise comparable conditions (Scheme 46B) [153]. In addition, we demonstrated that free alcohols could be employed as precursors using stoichiometric amounts of FeCl3 (Scheme 46C) [153]. In both cases
Graphical Abstract
Figure 1: Representative alkenyl chloride motifs in natural products. References: Pinnaic acid [8], haterumalide ...
Figure 2: Representative alkenyl chloride motifs in pharmaceuticals and pesticides. References: clomifene [25], e...
Figure 3: Graphical overview of previously published reviews addressing the synthesis of alkenyl chlorides.
Figure 4: Classification of synthetic approaches to alkenyl chlorides.
Scheme 1: Early works by Friedel, Henry, and Favorsky.
Scheme 2: Product distribution obtained by H NMR integration of crude compound as observed by Kagan and co-wo...
Scheme 3: Side reactions observed for the reaction of 14 with PCl5.
Scheme 4: Only compounds 15 and 18 were observed in the presence of Hünig’s base.
Scheme 5: Efficient synthesis of dichloride 15 at low temperatures.
Scheme 6: Various syntheses of alkenyl chlorides on larger scale.
Scheme 7: Scope of the reaction of ketones with PCl5 in boiling cyclohexane.
Scheme 8: Side reactions occur when using excess amounts of PCl5.
Scheme 9: Formation of versatile β-chlorovinyl ketones.
Scheme 10: Mixture of PCl5 and PCl3 used for the synthesis of 49.
Scheme 11: Catechol–PCl3 reagents for the synthesis of alkenyl chlorides.
Scheme 12: (PhO)3P–halogen-based reagents for the synthesis of alkenyl halides.
Scheme 13: Preparation of alkenyl chlorides from alkenyl phosphates.
Scheme 14: Preparation of alkenyl chlorides by treatment of ketones with the Vilsmeier reagent.
Scheme 15: Preparation of electron-rich alkenyl chlorides by treatment of ketones with the Vilsmeier reagent.
Scheme 16: Cu-promoted synthesis of alkenyl chlorides from ketones and POCl3.
Figure 5: GC yield of 9 depending on time and reaction temperature.
Figure 6: Broken reaction flask after attempts to clean the polymerized residue.
Figure 7: GC yield of 9 depending on the amount of CuCl and time.
Scheme 17: Treatment of 4-chromanones with PCl3.
Scheme 18: Synthesis of alkenyl chlorides from the reaction of ketones with acyl chlorides.
Scheme 19: ZnCl2-promoted alkenyl chloride synthesis.
Scheme 20: Regeneration of acid chlorides by triphosgene.
Scheme 21: Alkenyl chlorides from ketones and triphosgene.
Scheme 22: Various substitution reactions.
Scheme 23: Vinylic Finkelstein reactions reported by Evano and co-workers.
Scheme 24: Challenge of selective monohydrochlorination of alkynes.
Scheme 25: Sterically encumbered internal alkynes furnish the hydrochlorination products in high yield.
Scheme 26: Recent work by Kropp with HCl absorbed on alumina.
Scheme 27: High selectivities for monhydrochlorination with nitromethane/acetic acid as solvent.
Figure 8: Functionalized alkynes which typically afford the monhydrochlorinated products.
Scheme 28: Related chorosulfonylation and chloroamination reactions.
Scheme 29: Reaction of organometallic reagents with chlorine electrophiles.
Scheme 30: Elimination reactions of dichlorides to furnish alkenyl chlorides.
Scheme 31: Elimination reactions of allyl chloride 182 to furnish alkenyl chloride 183.
Scheme 32: Detailed studies by Schlosser on the elimination of dichloro compounds.
Scheme 33: Stereoselective variation caused by change of solvent.
Scheme 34: Elimination of gem-dichloride 189 to afford alkene 190.
Scheme 35: Oxidation of enones to dichlorides and in situ elimination thereof.
Scheme 36: Oxidation of allylic alcohols to dichlorides and in situ elimination thereof.
Scheme 37: Chlorination of styrenes with SOCl2 and elimination thereof.
Scheme 38: Chlorination of styrenes with SOCl2 and elimination thereof.
Scheme 39: Fluorine–chlorine exchange followed by elimination.
Scheme 40: Intercepting cations with alkynes and trapping of the alkenyl cation intermediate with chloride.
Scheme 41: Investigations by Mayr and co-workers.
Scheme 42: In situ activation of benzyl alcohol 230 with BCl3.
Scheme 43: In situ activation of benzylic alcohols with TiCl4.
Scheme 44: In situ activation of benzylic alcohols with FeCl3.
Scheme 45: In situ activation of benzylic alcohols with FeCl3.
Scheme 46: In situ activation of aliphatic chlorides and alcohols with ZnCl2, InCl3, and FeCl3.
Scheme 47: In situ generation of benzylic cations and trapping thereof with alkynes.
Scheme 48: Intramolecular trapping reactions affording alkenyl halides.
Scheme 49: Intramolecular trapping reactions affording alkenyl chlorides.
Scheme 50: Intramolecular trapping reactions of oxonium and iminium ions affording alkenyl chlorides.
Scheme 51: Palladium and nickel-catalyzed coupling reactions to afford alkenyl chlorides.
Scheme 52: Rhodium-catalyzed couplings of 1,2-trans-dichloroethene with arylboronic esters.
Scheme 53: First report on monoselective coupling reactions for 1,1-dichloroalkenes.
Scheme 54: Negishi’s and Barluenga’s contributions.
Scheme 55: First mechanistic investigation by Johnson and co-workers.
Scheme 56: First successful cross-metathesis with choroalkene 260.
Scheme 57: Subsequent studies by Johnson.
Scheme 58: Hoveyda and Schrock’s work on stereoretentive cross-metathesis with molybdenum-based catalysts.
Scheme 59: Related work with (Z)-dichloroethene.
Scheme 60: Further ligand refinement and traceless protection of functional groups with HBpin.
Scheme 61: Alkenyl chloride synthesis by Wittig reaction.
Scheme 62: Alkenyl chloride synthesis by Julia olefination.
Scheme 63: Alkenyl chloride synthesis by reaction of ketones with Mg/TiCl4 mixture.
Scheme 64: Frequently used allylic substitution reactions which lead to alkenyl chlorides.
Scheme 65: Enantioselective allylic substitutions.
Scheme 66: Synthesis of alkenyl chlorides bearing an electron-withdrawing group.
Scheme 67: Synthesis of α-nitroalkenyl chlorides from aldehydes.
Scheme 68: Synthesis of alkenyl chlorides via elimination of an in situ generated geminal dihalide.
Scheme 69: Carbenoid approach reported by Pace.
Scheme 70: Carbenoid approach reported by Pace.
Scheme 71: Ring opening of cyclopropenes in the presence of MgCl2.
Scheme 72: Electrophilic chlorination of alkenyl MIDA boronates to Z- or E-alkenyl chlorides.
Scheme 73: Hydroalumination and hydroboration of alkynyl chlorides.
Scheme 74: Carbolithiation of chloroalkynes.
Scheme 75: Chlorination of enamine 420.
Scheme 76: Alkyne synthesis by elimination of alkenyl chlorides.
Scheme 77: Reductive lithiation of akenyl chlorides.
Scheme 78: Reactions of alkenyl chlorides with organolithium reagents.
Scheme 79: Reactions of alkenyl chlorides with organolithium reagents.
Scheme 80: Addition–elimination reaction of alkenyl chloride 9 with organolithium reagents.
Scheme 81: C–H insertions of lithiumcarbenoids.
Scheme 82: Pd-catalyzed coupling reactions with alkenyl chlorides as coupling partner.
Scheme 83: Ni-catalyzed coupling of alkenylcopper reagent with alkenyl chloride 183.
Scheme 84: Ni-catalyzed coupling of heterocycle 472 with alkenyl chloride 473.
Scheme 85: Synthesis of α-chloroketones by oxidation of alkenyl chlorides.
Scheme 86: Tetrahalogenoferrate(III)-promoted oxidation of alkenyl chlorides.
Scheme 87: Chlorine–deuterium exchange promoted by a palladium catalyst.
Scheme 88: Reaction of alkenyl chlorides with thiols in the presence of AIBN (azobisisobutyronitrile).
Scheme 89: Chloroalkene annulation.
Competitive cyclization of ethyl trifluoroacetoacetate and methyl ketones with 1,3-diamino-2-propanol into hydrogenated oxazolo- and pyrimido-condensed pyridones
- Svetlana O. Kushch,
- Marina V. Goryaeva,
- Yanina V. Burgart,
- Marina A. Ezhikova,
- Mikhail I. Kodess,
- Pavel A. Slepukhin,
- Alexandrina S. Volobueva,
- Vladimir V. Zarubaev and
- Victor I. Saloutin
Beilstein J. Org. Chem. 2025, 21, 2716–2729, doi:10.3762/bjoc.21.209
- hetero- and carbocycles. To date, we have proposed new protocols for the synthesis of 2-pyridones [20], imidazo[1,2-a]pyridones and pyrido[1,2-a]pyrimidinones [21][22][23][24], pyrido[2,1-b]oxazinones and oxazolo[3,2-a]pyridones [25] using ammonia, 1,2- and 1,3-diamines or 1,2- and 1,3-amino alcohols
- octahydrocyclopenta[b]oxazolo[3,2-a]pyridin-5-ones in the reactions of 3-oxo ester 1 and cycloketones with amino alcohols [26]. However, these attempts turned out to be unsuccessful because of the increased occurrence of side processes (56%); however, an increase in the proportion of the cis,trans
Graphical Abstract
Figure 1: Structures of bioactive molecules with trifluoromethylpyridine and piperidine frameworks.
Scheme 1: The reaction of ethyl trifluoroacetoacetate (1), acetone (2a) and 1,3- diaminopropan-2-ol (3).
Scheme 2: Three-component reaction of ethyl trifluoroacetoacetate (1), alkyl methyl ketones 2b,c and 1,3-diam...
Scheme 3: Three-component reaction of ethyl trifluoroacetoacetate (1), acetophenone (2d) and 1,3-diaminopropa...
Scheme 4: The proposed mechanism of three-component cyclization of 3-oxo ester 1, methyl ketones 2a–d and 1,3...
Figure 2: ORTEP view of compounds 4асc (a, CCDC: 2479553), 4аct (b, CCDC: 2479554), 4аtt (c, CCDC: 2479555), ...
Figure 3: ORTEP view of compound 5ctc (a, CCDC: 2479558), 5ctt (b, CCDC: 2479559) showing with the thermal el...
Figure 4: The fragments of the 1H NMR spectra (400 MHz, DMSO-d6) of diastereomers 4acc (a), 4аct (b), 4аtt (c...
Figure 5: Fragments of 1H NMR spectra (400 MHz, DMSO-d6) of hexahydrooxazolo[3,2-a]pyridin-5-ones 5ctc (a) an...
Mechanistic insights into hydroxy(tosyloxy)iodobenzene-mediated ditosyloxylation of chalcones: a DFT study
- Jai Parkash,
- Sangeeta Saini,
- Vaishali Saini,
- Omkar Bains and
- Raj Kamal
Beilstein J. Org. Chem. 2025, 21, 2703–2715, doi:10.3762/bjoc.21.208
- -substituents; α,β-unsaturated carbonyl compounds; Introduction Hypervalent iodine compounds exhibit a range of bonding patterns which making these compounds powerful reagents or catalysts for a number of organic transformations [1][2][3][4] – oxidation of alcohols [5], epoxidation of alkenes [6], oxidative
- . The reactivity characteristics of these compounds are similar to transition metal reagents, as a result these hypervalent compounds can be used as an alternative. For example, iodobenzene diacetate (PhI(OAc)2), can be used to selectively oxidize alcohols to aldehydes or ketones over toxic chromium(VI
Graphical Abstract
Scheme 1: Structure of reactant (chalcone, compound A), geminal product (compound B), vicinal product (compou...
Scheme 2: Reaction mechanism of ditosyloxylation of chalcones with X = -OCH3 , -SCH3 followed by 1,2-aryl mig...
Scheme 3: Reaction mechanism of ditosyloxylation of chalcones with X = -Cl, -NO2 leading to the formation of ...
Figure 1: Relative Gibbs free energy profile for HTIB-mediated ditosyloxylation of chalcone with X = -SCH3 in...
Figure 2: Relative Gibbs free energy profile for HTIB-mediated ditosyloxylation of chalcone with X = -Cl invo...
Figure 3: Relative Gibbs free energy profile for HTIB-mediated ditosyloxylation of chalcone with X = -NO2 inv...
Scheme 4: Reaction mechanism of ditosyloxylation of chalcones with X = -OCH3, -SCH3, -Cl, -NO2 leading to the...
Figure 4: Relative Gibbs free energy profile for HTIB-mediated ditosyloxylation of chalcone with X = -OCH3 le...
Figure 5: Relative Gibbs free energy profile for HTIB-mediated ditosyloxylation of chalcone with X = -SCH3 le...
Figure 6: Relative Gibbs free energy profile for HTIB-mediated ditosyloxylation of chalcone with X = -Cl lead...
Figure 7: Relative Gibbs free energy profile for HTIB-mediated ditosyloxylation of chalcone with X = -NO2 lea...
Tandem hydrothiocyanation/cyclization of CF3-iminopropargyl alcohols with NaSCN in the presence of AcOH
- Ruslan S. Shulgin,
- Ol’ga G. Volostnykh,
- Anton V. Stepanov,
- Igor’ A. Ushakov,
- Alexander V. Vashchenko and
- Olesya A. Shemyakina
Beilstein J. Org. Chem. 2025, 21, 2694–2702, doi:10.3762/bjoc.21.207
- trifluoromethylated isothiazolium thiocyanates and 4-thiocyanato-2,5-dihydrofurans is presented through hydrothiocyanation/cyclization of CF3-iminopropargyl alcohols using NaSCN in AcOH/MeCN. The formation of the two products can be explained by different directions of cyclization of the primary adducts of thiocyanic
- acid at the triple bond – vinyl thiocyanates. This protocol features simple operating, readily prepared starting materials and occurs under relatively mild conditions. Keywords: CF3-alkynyl imines; hydrothiocyanation; isothiazolium thiocyanates; propargyl alcohols; sodium thiocyanate; Introduction
- light of the above examples and as part of our ongoing research into the chemistry of functionalized propargyl alcohols [25][26], we decided to use CF3-substituted iminopropargyl alcohols as a starting material for hydrothiocyanation reactions, since the alkynyl imine fragment can undergo a series of
Graphical Abstract
Scheme 1: Examples of hydrothiocyanation/cyclization of alkynes.
Figure 1: 1H and 19F NMR monitoring of 1a/NaSCN/AcOH (a, b) and 1g/NaSCN/AcOH (c, d) reaction mixtures in MeC...
Scheme 2: Plausible reaction mechanism.
Scheme 3: Oxidation of isothiazolium thiocyanate 2a.
Synthesis of new tetra- and pentacyclic, methylenedioxy- and ethylenedioxy-substituted derivatives of the dibenzo[c,f][1,2]thiazepine ring system
- Gábor Berecz,
- András Dancsó,
- Mária Tóthné Lauritz,
- Loránd Kiss,
- Gyula Simig and
- Balázs Volk
Beilstein J. Org. Chem. 2025, 21, 2645–2656, doi:10.3762/bjoc.21.205
- substitution reactions of benzo-1,3-dioxoles and benzo-1,4-dioxanes [20]. Reduction of ketones 6 and 7 with NaBH4 gave alcohols 16 and 17, which were chlorinated with SOCl2 to result in compounds 18 and 19. Treatment of the latter with the appropriate amines gave amino derivatives 20a, 20c–e, and 21a, 21c–p
- (22), an atypical antidepressant drug on the market [21][22][23][24][25], by hydrolysis of esters 20a and 21a (Scheme 3). Treatment of chloro derivative 19 with various alcohols afforded ethers 23, while its reaction with 2-(morpholin-4-yl)ethanethiol resulted in thioether 24 (Scheme 4). The structure
Graphical Abstract
Figure 1: Reported ring systems incorporating the dibenzo[c,f][1,2]thiazepine (1) skeleton.
Figure 2: Drugs exhibiting a 1,3-benzodioxole or 1,4-benzodioxane structural unit marketed or in development.
Scheme 1: Synthesis of tetracyclic key intermediates 6 and 7. Conditions: i) 1,3-benzodioxol-5-amine (n = 1)/...
Scheme 2: Synthesis of tetracyclic compounds 20 and 21. Conditions: i) NaBH4, DMF, EtOH, rt, 4.5 h/23 h, 95%/...
Figure 3: X-ray structures of compounds 20e and 21g.
Scheme 3: Synthesis of tianeptine analogues 20b and 21b. Conditions: 20b: NaOH, EtOH/H2O, rt, 25 h, 80%; 21b:...
Scheme 4: Synthesis of tetracyclic ethers 23 and thioether 24. Conditions: i) ROH, MeCN, rt, 2–3 h, 38–84%; i...
Figure 4: X-ray structure of compound 23a.
Scheme 5: Synthesis of pentacyclic compounds 25–27. Conditions: i) Py·HCl, 180 °C, 27 h, 51%; ii) Br(CH2)2Br,...
Figure 5: X-ray structures of compounds 25, 26, and 27.
Scheme 6: Synthesis of tetracyclic compounds 38. Conditions: i) NaBH4, DMF/EtOH, rt, 3 h, 89%; ii) SOCl2, DCM...
Scheme 7: Synthesis of tetracyclic compounds 45 and 46. Conditions: i) 2,3-dihydro-1,4-benzodioxin-5-amine, P...
Scheme 8: Synthesis of tetracyclic compounds 54. Conditions: i) methyl anthranilate, pyridine, 0–5 °C, 4 h, r...
Visible-light-driven NHC and organophotoredox dual catalysis for the synthesis of carbonyl compounds
- Vasudevan Dhayalan
Beilstein J. Org. Chem. 2025, 21, 2584–2603, doi:10.3762/bjoc.21.200
- –C, C–HA bond-forming reactions [36][37]. These chiral NHC catalysts, used to access enantiopure alcohol/amine derivatives, particularly 2° and 3° alcohols/amines, are significant structural motifs in numerous drugs and natural products and have found widespread synthetic applications in medicinal
Graphical Abstract
Scheme 1: NHC-catalyzed umpolung strategy for the metal-free synthesis of amide via dual catalysis.
Scheme 2: Visible-light promoted cooperative NHC/photoredox catalyzed ring-opening of aryl cyclopropanes.
Scheme 3: NHC-catalyzed benzylic C–H acylation by dual catalysis.
Scheme 4: NHC/photoredox-catalyzed three-component coupling reaction for the preparation of γ-aryloxy ketones....
Scheme 5: NHC-catalyzed silyl radical generation from silylboronate via dual catalysis.
Scheme 6: NHC-catalyzed C–H acylation of arenes and heteroarenes through photocatalysis.
Scheme 7: NHC-catalyzed iminoacylation of alkenes via photoredox dual organocatalysis.
Scheme 8: NHC/photoredox catalyzed direct synthesis of β-arylketoesters.
Scheme 9: Visible-light-driven NHC/photoredox catalyzed borylacylation of alkenes.
Scheme 10: NHC-catalyzed oxidative functionalization of cinnamaldehyde.
Scheme 11: NHC/photocatalyzed oxidative Smiles rearrangement.
Scheme 12: NHC-catalyzed synthesis of cyclohexanones through photocatalyzed annulation.
Scheme 13: Dual organocatalyzed meta-selective acylation of electron-rich arenes and heteroarenes using blue L...
Scheme 14: Asymmetric synthesis of fused pyrrolidinones via organophotoredox/N‑heterocyclic carbene dual catal...
Ex-situ generation of gaseous nitriles in two-chamber glassware for facile haloacetimidate synthesis
- Nikolai B. Akselvoll,
- Jonas T. Larsen and
- Christian M. Pedersen
Beilstein J. Org. Chem. 2025, 21, 2465–2469, doi:10.3762/bjoc.21.188
- the trifluoroacetimidate. We therefore decided to use the two-chamber method for the synthesis of a few non-carbohydrate acetimidates 8–11 (Figure 3). Hence a series of aryl alcohols with different substituents on the aromatic ring were synthesized and isolated in generally good yields. One exception
- was the p-methoxy derivative 11 which, as expected, was more reactive and hence more difficult to purify due to decomposition on silica gel. The p-methoxybenzyl trifluoroacetimidate (9) has been shown to be an effective regent for the acid-catalyzed benzylation of alcohols [12][30]. Conclusion In
Graphical Abstract
Figure 1: Examples of methods for the synthesis of trifluoroacetonitrile and our set-up using a two-chamber r...
Scheme 1: Reactions in chambers A and B. Chamber A: generation of the haloacetonitrile by dehydration of the ...
Figure 2: Glycosyl haloacetimidates synthesized using the two-chamber method.
Figure 3: Synthesis of arylmethylene fluoroacetimidates using the two-chamber method.
Transformation of the cyclohexane ring to the cyclopentane fragment of biologically active compounds
- Natalya Akhmetdinova,
- Ilgiz Biktagirov and
- Liliya Kh. Faizullina
Beilstein J. Org. Chem. 2025, 21, 2416–2446, doi:10.3762/bjoc.21.185
- 30% and a selectivity of 70% at −100 °C (Scheme 21). 2.3 Wolff rearrangement The Wolff rearrangement is the transformation of α-diazoketones into acids or their derivatives through heating, catalysis, or UV irradiation in the presence of water, alcohols, ammonia, amines, etc. The Wolff rearrangement
- contraction is demonstrated by the example of converting organoborane intermediates into alcohols, amines, and E-alkenes (Scheme 32). 4 Meinwald rearrangements of epoxides The rearrangements of oxiranes annelated to cyclohexane occupy an important place in the synthesis of cyclopentanes due to the
Graphical Abstract
Scheme 1: Ozonolysis–cyclization sequence in the synthesis of echinopine A (3).
Scheme 2: Ozonolysis–cyclization sequence in the synthesis of taiwaniaquinoids 7–12.
Figure 1: Iridoid skeleton.
Scheme 3: Ozonolysis–cyclization sequence in the synthesis of compounds 17a,b, 18 and 19 with iridoid topolog...
Scheme 4: Oxidation–aldol condensation sequence in the synthesis of compounds 21 and 23 with iridoid topology....
Scheme 5: Oxidation–aldol condensation sequence in the synthesis of compounds 29 and 30 with iridoid topology....
Scheme 6: Method for ring contraction in the absence of a double bond in a six-membered ring of triterpenoids....
Scheme 7: Oxidation–Dieckmann cyclization sequence in the synthesis of a new nortriterpenoid 39.
Scheme 8: Oxidation–Dieckmann cyclization sequence in the synthesis of 18,19-di-nor-cholesterol (40).
Scheme 9: Oxidation–cyclization sequence in the synthesis of 3-ethyl-substituted betulinic acid derivatives 49...
Scheme 10: Benzilic acid-type rearrangement in the synthesis of 4β-acetoxyprobotryane-9β,15α-diol (52).
Scheme 11: Benzilic acid-type rearrangement in the synthesis of (−)-taiwaniaquinone H (11).
Scheme 12: Benzilic acid-type rearrangement in the synthesis of dactylicapnosines A (63) and B (64).
Scheme 13: Aza-benzilic acid-type rearrangement in the synthesis of (+)-stephadiamine (71).
Scheme 14: α-Ketol rearrangement in the synthesis of saffloneoside (73).
Scheme 15: Conversion of (−)-preaustinoid A (80) to (−)-preaustinoid B (81) via α-ketol rearrangement.
Scheme 16: α-Ketol rearrangement in the synthesis of 2,8-oxymethano-bridged diquinane 90.
Scheme 17: Oxidative ring contraction during the synthesis of (+)-cuparene (91) and (+)-tochuinylacetate (92).
Scheme 18: Semipinacol rearrangement in the synthesis of diterpenoids 97–100.
Scheme 19: Co-catalyzed homoallyl-type rearrangement in the syntheses of meroterpenes 106–109.
Scheme 20: Ring contraction reaction promoted by TTN·3H2O and HTIB in the synthesis of indanes.
Scheme 21: Rearrangement involving a hypervalent iodine compound in the synthesis of derivative 120.
Scheme 22: Wolff rearrangement in the synthesis of taiwaniaquinones A (7), F (8), taiwaniaquinols B (10), D (1...
Scheme 23: Wolff rearrangement in the synthesis of cheloviolene C (128), seconorrisolide B (129), and seconorr...
Scheme 24: Wolff rearrangement in the synthesis of (−)-pavidolide B (134).
Scheme 25: Wolff rearrangement in the synthesis of presilphiperfolan-8-ol (141).
Scheme 26: Photochemical rearrangement in the synthesis of cyclopentane derivatives 147a,b.
Scheme 27: Synthesis of cyclopentane derivatives 147a and 151.
Scheme 28: Photochemical rearrangement in the synthesis of cyclopentane derivative 153.
Scheme 29: Photochemical rearrangement in the synthesis of tricyclic ketones 155, 156.
Scheme 30: Photochemical rearrangement in the synthesis of cis/trans salts 160.
Figure 2: Scope of the photoinduced carboborative ring contraction of steroids. Reaction conditions: steroid ...
Scheme 31: Photoinduced carboborative ring contraction in the synthesis of artalbic acid (180).
Scheme 32: Synthetic versatility of the photoinduced carboborative ring contraction.
Scheme 33: Methods of disclosure of epoxide 189.
Scheme 34: Methods of disclosure of epoxide 190.
Scheme 35: Rearrangement of α,β-epoxy ketone 197.
Scheme 36: Acid-induced rearrangement in the synthesis of perhydrindane ketones 202 and 205.
Scheme 37: Rearrangement of epoxyketone 208 in the synthesis of huperzine Q (206).
Scheme 38: Rearrangement of epoxide 212 under the action of Grignard reagent.
Scheme 39: Semipinacol rearrangement of epoxide 220 in the synthesis of (−)-citrinadin A (217) and (+)-citrina...
Scheme 40: Semipinacol rearrangement of epoxide 225 in the synthesis of hamigeran G (223).
Scheme 41: Semipinacol rearrangement of epoxide 231 in the synthesis of (−)-spirochensilide A (228).
Scheme 42: Wagner–Meerwein rearrangement in the synthesis of compound 234 with iridoid topology.
Scheme 43: Wagner–Meerwein rearrangement in the synthesis of compound 238 with iridoid topology.
Scheme 44: Wagner–Meerwein rearrangement in the synthesis of compound 241 with iridoid topology.
Scheme 45: Wagner–Meerwein rearrangement in the synthesis of lupane derivatives 245, 246, 248, and 249.
Scheme 46: Wagner–Meerwein rearrangement in the synthesis of weisaconitine D (252) and cardiopetaline (255).
Scheme 47: Wagner–Meerwein rearrangement in the synthesis of cardiopetaline (255).
Enantioselective radical chemistry: a bright future ahead
- Anna C. Renner,
- Sagar S. Thorat,
- Hariharaputhiran Subramanian and
- Mukund P. Sibi
Beilstein J. Org. Chem. 2025, 21, 2283–2296, doi:10.3762/bjoc.21.174
- preparation of chiral β-aminoalcohols [63]. Chiral copper(I) complexes convert imidate radicals, formed transiently through energy-transfer catalysis, to oxazolines. The transformation includes a regioselective and enantioselective HAT process. Upon blue LED irradiation, oxime imidates (derived from alcohols
Graphical Abstract
Figure 1: Methods of radical generation (A) and general types of radical reactions (B).
Figure 2: Chiral catalysis in enantioselective radical chemistry [13-37].
Scheme 1: Diastereo- and enantioselective additions of nucleophilic radicals to N-enoyloxazolidinone and pyrr...
Scheme 2: Organocatalyzed formal [3 + 2] cycloadditions affording substituted pyrrolidines.
Scheme 3: Synthesis of a hexacyclic compound via an organocatalyzed enantioselective polyene cyclization.
Scheme 4: Nickel-catalyzed asymmetric cross-coupling reactions.
Scheme 5: Chiral cobalt–porphyrin metalloradical-catalyzed radical cyclization reactions.
Scheme 6: Enantioselective radical chaperone catalysis.
Scheme 7: Enantioselective radical addition by decatungstate/iminium catalysis.
Scheme 8: An ene-reductase-catalyzed photoenzymatic enantioselective radical cyclization/enantioselective HAT...
Scheme 9: Photoenzymatic oxidative C(sp3)–C(sp3) coupling reactions between organoboron compounds and amino a...
Scheme 10: Electrochemical α-alkenylation reactions of 2-acylimidazoles catalyzed by a chiral-at-rhodium Lewis...
Scheme 11: Regio- and enantioselective electrochemical reactions of silyl polyenolates catalyzed by a chiral n...
Pathway economy in cyclization of 1,n-enynes
- Hezhen Han,
- Wenjie Mao,
- Bin Lin,
- Maosheng Cheng,
- Lu Yang and
- Yongxiang Liu
Beilstein J. Org. Chem. 2025, 21, 2260–2282, doi:10.3762/bjoc.21.173
- metal-free methodology delivered synthetically versatile iodinated homoallylic alcohols bearing piperidine motifs and pyrrolidine-fused cyclopropanes. Importantly, the reaction was carried out with high operational simplicity and environmental compatibility under mild reaction conditions. In 2024, Chan
- intermediate 150. Subsequent aromatization and ring expansion afforded benzene derivatives 151 (Scheme 31, path a). Conversely, E-configured substrates underwent gold-catalyzed alkyne activation, triggering terminal alkene 5-exo-dig cyclization to form carbocationic intermediate 152. Alcohols nucleophilically
Graphical Abstract
Scheme 1: Economical synthesis and pathway economy.
Scheme 2: Au(I)-catalyzed cascade cyclization paths of 1,5-enynes.
Scheme 3: Au(I)-catalyzed cyclization paths of 1,7-enynes.
Scheme 4: I2/TBHP-mediated radical cycloisomerization paths of 1,n-enyne.
Scheme 5: Au(I)-catalyzed cycloisomerization paths of 3-allyloxy-1,6-diynes.
Scheme 6: Pd(II)-catalyzed cycloisomerization paths of 2-alkynylbenzoate-cyclohexadienone.
Scheme 7: Stereoselective cyclization of 1,5-enynes.
Scheme 8: Substituent-controlled cycloisomerization of propargyl vinyl ethers.
Scheme 9: Au(I)-catalyzed pathway-controlled domino cyclization of 1,2-diphenylethynes.
Scheme 10: Au(I)-catalyzed tandem cyclo-isomerization of tryptamine-N-ethynylpropiolamide.
Scheme 11: Au(I)-catalyzed tunable cyclization of 1,6-cyclohexenylalkyne.
Scheme 12: Substituent-controlled 7-exo- and 8-endo-dig-selective cyclization of 2-propargylaminobiphenyl deri...
Scheme 13: BiCl3-catalyzed cycloisomerization of tryptamine-ynamide derivatives.
Scheme 14: Au(I)-mediated substituent-controlled cycloisomerization of 1,6-enynes.
Scheme 15: Ligand-controlled regioselective cyclization of 1,6-enynes.
Scheme 16: Ligand-dependent cycloisomerization of 1,7-enyne esters.
Scheme 17: Ligand-controlled cycloisomerization of 1,5-enynes.
Scheme 18: Ligand-controlled cyclization strategy of alkynylamide tethered alkylidenecyclopropanes.
Scheme 19: Ag(I)-mediated pathway-controlled cycloisomerization of tryptamine-ynamides.
Scheme 20: Gold-catalyzed cycloisomerization of indoles with alkynes.
Scheme 21: Catalyst-dependent cycloisomerization of dienol silyl ethers.
Scheme 22: Cycloisomerization of aromatic enynes governed by catalyst.
Scheme 23: Catalyst-dependent 1,2-migration in cyclization of 1-(indol-2-yl)-3-alkyn-1-ols.
Scheme 24: Gold-catalyzed cycloisomerization of N-propargyl-N-vinyl sulfonamides.
Scheme 25: Gold(I)-mediated enantioselective cycloisomerizations of ortho-(alkynyl)styrenes.
Scheme 26: Catalyst-controlled intramolecular cyclization of 1,7-enynes.
Scheme 27: Brønsted acid-catalyzed cycloisomerizations of tryptamine ynamides.
Scheme 28: Catalyst-controlled cyclization of indolyl homopropargyl amides.
Scheme 29: Angle strain-dominated 6-endo-trig cyclization of propargyl vinyl ethers.
Scheme 30: Angle strain-controlled cycloisomerization of alkyn-tethered indoles.
Scheme 31: Geometrical isomeration-dependent cycloisomerization of 1,3-dien-5-ynes.
Scheme 32: Temperature-controlled cyclization of 1,7-enynes.
Scheme 33: Cycloisomerizations of n-(o-ethynylaryl)acrylamides through temperature modulation.
Scheme 34: Temperature-controlled boracyclization of biphenyl-embedded 1,3,5-trien-7-ynes.
A m-quaterphenyl probe for absolute configurational assignments of primary and secondary amines
- Yuka Takeuchi,
- Mutsumi Kobayashi,
- Yuuka Gotoh,
- Mari Ikeda,
- Yoichi Habata,
- Tomohiko Shirai and
- Shunsuke Kuwahara
Beilstein J. Org. Chem. 2025, 21, 2211–2219, doi:10.3762/bjoc.21.168
- Shibazono, Narashino, Chiba 275-0023, Japan Research Center for Materials with Integrated Properties, Toho University, 2-2-1 Miyama, Funabashi, Chiba 274-8510, Japan 10.3762/bjoc.21.168 Abstract We report a method for determining the absolute configurations of chiral amino alcohols, amino acid esters, and
- , empirical approaches based on 1H NMR anisotropy method have gained attention as alternative strategies for stereochemical assignment of chiral molecules. Among these, the modified Mosher method, which utilizes the ring current effects of aryl substituents, has been extensively applied to chiral alcohols [2
- for determining the absolute configurations of chiral alcohols [8][9][10][11][12][13][14], primary amines [14][15][16][17][18][19][20][21][22][23][24][25][26][27][28][29][30][31][32], secondary amines [33][34][35], carboxylic acids [36][37][38], sulfoxides [39], and cyanohydrins [40]. We have reported
Graphical Abstract
Scheme 1: Coupling reaction of 1 and chiral primary and secondary amines. The central biphenyl moiety rotates...
Figure 1: CD and UV spectra of (a) tertiary amines (S)-2a–e and (b) quaternary ammonium salts (S)-2f,g and (R...
Figure 2: Schematic representation of the preferred conformation of (S)-2a.
Figure 3: Four major conformers of (S)-3a based on B3LYP/6-31G* level.
Figure 4: Four major conformers of (S)-3f based on B3LYP/6-31G* level.
Figure 5: The distribution of conformers of (S)-3a–h against dihedral angles ϕ (C6–C1–C1'–C6') calculated by ...
Figure 6: Crystal structure of (S)-2b. Four conformers exist in the unit cell. Hydrogen atoms are omitted for...
Figure 7: The relationship between the ACD values and excess of P conformer. Excess of P conformer (%) = ([P]...
Electrochemical cyclization of alkynes to construct five-membered nitrogen-heterocyclic rings
- Lifen Peng,
- Ting Wang,
- Zhiwen Yuan,
- Bin Li,
- Zilong Tang,
- Xirong Liu,
- Hui Li,
- Guofang Jiang,
- Chunling Zeng,
- Henry N. C. Wong and
- Xiao-Shui Peng
Beilstein J. Org. Chem. 2025, 21, 2173–2201, doi:10.3762/bjoc.21.166
- alkynes, amines and azides, respectively. Imidazopyridines could be obtained by electrochemical [3 + 2] cyclization of heteroarylamines. The electrochemical oxidative [3 + 2] cycloaddition of secondary propargyl alcohols was a simple and efficient access towards 1,2,3-triazoles. In this review
Graphical Abstract
Figure 1: Natural products and functional molecules possessing five-membered rings.
Scheme 1: Electrochemical intramolecular coupling of ureas to form indoles.
Scheme 2: Electrochemical dehydrogenative annulation of alkynes with anilines.
Scheme 3: Electrochemical annulations of o-arylalkynylanilines.
Scheme 4: Electrochemical cyclization of 2-ethynylanilines.
Scheme 5: Electrochemical selenocyclization of diselenides and 2-ethynylanilines.
Scheme 6: Electrochemical cascade approach towards 3-selenylindoles.
Scheme 7: Electrochemical C–H indolization.
Scheme 8: Electrochemical annulation of benzamides and terminal alkynes.
Scheme 9: Electrochemical synthesis of isoindolinone by 5-exo-dig aza-cyclization.
Scheme 10: Electrochemical reductive cascade annulation of o-alkynylbenzamide.
Scheme 11: Electrochemical intramolecular 1,2-amino oxygenation of alkyne.
Scheme 12: Electrochemical multicomponent reaction of nitrile, (thio)xanthene, terminal alkyne and water.
Scheme 13: Electrochemical aminotrifluoromethylation/cyclization of alkynes.
Scheme 14: Electrochemical cyclization of o-nitrophenylacetylene.
Scheme 15: Electrochemical annulation of alkynyl enaminones.
Scheme 16: Electrochemical annulation of alkyne and enamide.
Scheme 17: Electrochemical tandem Michael addition/azidation/cyclization.
Scheme 18: Electrochemical [3 + 2] cyclization of heteroarylamines.
Scheme 19: Electrochemical CuAAC to access 1,2,3-triazole.
C2 to C6 biobased carbonyl platforms for fine chemistry
- Jingjing Jiang,
- Muhammad Noman Haider Tariq,
- Florence Popowycz,
- Yanlong Gu and
- Yves Queneau
Beilstein J. Org. Chem. 2025, 21, 2103–2172, doi:10.3762/bjoc.21.165
- ][80][81]. Keto acetals have been observed as by-products, such as in the work reported by Gupta investigating the acid-catalyzed reactions of DHA with various alcohols (Scheme 17) [82]. Colbran and colleagues reported the conversion of DHA to dihydroxyacetone phosphate in four steps in 27% overall
- rapidly under mild conditions. The catalyst 1 oxidizes the vicinal diols to the corresponding hydroxy ketones faster than other alcohols. Primary alcohols and 1,5-diols are oxidized to yield secondary alcohols and cyclic lactones, respectively (Scheme 30). A high chemo- and regioselectivity was observed
- toward useful biobased functional compounds or intermediates with applications in fuels, polymer chemistry and fine organic synthesis (CH activation, Piancatelli rearrangement, etc.). Conversion of furfural to alcohols, aldehydes and ketones: One of the most important transformations of furfural is its
Graphical Abstract
Figure 1: C2–C6 biobased carbonyl building blocks.
Scheme 1: Proposed (2 + 2) route to glycolaldehyde and glycolic acid from erythritol by Cu/AC catalyst (AC = ...
Scheme 2: Reductive amination of GCA.
Scheme 3: N-Formylation of secondary amines by reaction with GCA.
Scheme 4: Synthesis and conversion of hydroxy acetals to cyclic acetals.
Scheme 5: Synthesis of 3-(indol-3-yl)-2,3-dihydrofurans via three-component reaction of glycolaldehyde, indol...
Scheme 6: BiCl3-catalyzed synthesis of benzo[a]carbazoles from 2-arylindoles and α-bromoacetaldehyde ethylene...
Scheme 7: Cu/NCNSs-based conversion of glycerol to glycolic acid and other short biobased acids.
Scheme 8: E. coli-based biotransformation of C1 source molecules (CH4, CO2 and CO) towards C2 glycolic acid.
Scheme 9: N-Formylation of amines with C2 (a) or C3 (b) biomass-based feedstocks.
Scheme 10: Methods for the formation of propanoic acid (PA) from lactic acid (LA).
Scheme 11: Co-polymerization of biobased lactic acid and glycolic acid via a bicatalytic process.
Scheme 12: Oxidation of α-hydroxy acids by tetrachloroaurate(III) in acetic acid–sodium acetate buffer medium.
Figure 2: Selective catalytic pathways for the conversion of lactic acid (LA).
Scheme 13: Synthesis of 1,3-PDO via cross-aldol reaction between formaldehyde and acetaldehyde to 3-hydroxypro...
Scheme 14: Hydrothermal conversion of 1,3-dihydroxy-2-propane and 2,3-dihydroxypropanal to methylglyoxal.
Scheme 15: FLS-catalyzed formose reaction to synthesize GA and DHA.
Scheme 16: GCA and DHA oxidation products of glycerol and isomerization of GCA to DHA under flow conditions us...
Scheme 17: Acid-catalyzed reactions of DHA with alcohols.
Scheme 18: Synthesis of dihydroxyacetone phosphate from dihydroxyacetone.
Scheme 19: Bifunctional acid–base catalyst DHA conversion into lactic acid via pyruvaldehyde or fructose forma...
Scheme 20: Catalytic one-pot synthesis of GA and co-synthesis of formamides and formates from DHA.
Scheme 21: (a) Synthesis of furan derivatives and (b) synthesis of thiophene derivative by cascade [3 + 2] ann...
Scheme 22: Brønsted acidic ionic liquid catalyzed synthesis of benzo[a]carbazole from renewable acetol and 2-p...
Scheme 23: Asymmetric hydrogenation of α-hydroxy ketones to 1,2-diols.
Scheme 24: Synthesis of novel 6-(substituted benzylidene)-2-methylthiazolo [2,3-b]oxazol-5(6H)-one from 1-hydr...
Scheme 25: ʟ-Proline-catalyzed synthesis of anti-diols from hydroxyacetone and aldehydes.
Scheme 26: C–C-bond-formation reactions of a biomass-based feedstock aromatic aldehyde (C5) and hydroxyacetone...
Scheme 27: Ethanol upgrading to C4 bulk chemicals via the thiamine (VB1)-catalyzed acetoin condensation.
Scheme 28: One-pot sequential chemoenzymatic synthesis of 2-aminobutane-1,4-diol and 1,2,4-butanetriol via 1,4...
Scheme 29: Synthesis of 1,4-dihydroxybutan-2-one by microbial transformation.
Scheme 30: Conversion of polyols by [neocuproine)Pd(OAc)]2(OTf)2] to α-hydroxy ketones.
Scheme 31: Chemoselective oxidation of alcohols with chiral palladium-based catalyst 2.
Scheme 32: Electrochemical transformation of furfural to 5-hydroxy-2(5H)-furanone (HFO).
Scheme 33: Selective hydrodeoxygenation of HFO and oxidation to γ-butyrolactone (GBL).
Scheme 34: Photosensitized oxygenation of furan towards HFO via ozonide intermediates.
Scheme 35: Conversion of furfural to HFO and MAN by using mesoporous carbon nitride (SGCN) as photocatalyst.
Scheme 36: Synthesis of HFO from furan derivatives.
Scheme 37: Photooxidation of furfural to 5-hydroxy-2(5H)-furanone (HFO).
Scheme 38: Synthesis of Friedel–Crafts indole adduct from HFO.
Scheme 39: Conversion of HFO to α,γ-substituted chiral γ-lactones.
Scheme 40: Tautomeric transformation of HFO to formylacrylic acid.
Scheme 41: Hydrolysis of HFO to succinic acid in aqueous solution.
Scheme 42: Substitution and condensation reactions of 5-hydroxy-2(5H)-furanone (HFO).
Scheme 43: (a) Conversion of HFO towards valuable C4 chemicals and (b) anodic oxidation of 5-hydroxy-2(5H)-fur...
Figure 3: Conversion of HFO towards other natural and synthetic substances.
Scheme 44: Conversion of furfural to maleic anhydride (reaction a: VOx/Al2O3; reaction b: VPO).
Scheme 45: Conversion of furfural into succinic acid.
Scheme 46: Electro‑, photo‑, and biocatalysis for one-pot selective conversions of furfural into C4 chemicals.
Scheme 47: Production route of furfural from hemicellulose.
Scheme 48: Mechanism for xylose dehydration to furfural through a choline xyloside intermediate.
Scheme 49: Conversion of furfural to furfuryl alcohol and its derivatives.
Scheme 50: Conversion of furfural to furfuryl alcohol and 3-(2-furyl)acrolein.
Scheme 51: The aerobic oxidative condensation of biomass-derived furfural and linear alcohols.
Scheme 52: The single-step synthesis of 2-pentanone from furfural.
Scheme 53: Electrocatalytic coupling reaction of furfural and levulinic acid.
Scheme 54: Conversion of furfural to m-xylylenediamine.
Scheme 55: Conversion of furfural to tetrahydrofuran-derived amines.
Scheme 56: Formation of trans-4,5-diamino-cyclopent-2-enones from furfural.
Scheme 57: Production of pyrrole and proline from furfural.
Scheme 58: Synthesis of 1‑(trifluoromethyl)-8-oxabicyclo[3.2.1]oct-3-en-2-ones from furfural.
Scheme 59: Conversion of furfural to furfural-derived diacids.
Scheme 60: A telescope protocol derived from furfural and glycerol.
Scheme 61: A tandem cyclization of furfural and 5,5-dimethyl-1,3-cyclohexanedione.
Scheme 62: A Ugi four-component reaction to construct furfural-based polyamides.
Scheme 63: One-pot synthesis of γ-acyloxy-Cy7 from furfural.
Scheme 64: Dimerization–Piancatelli sequence toward humins precursors from furfural.
Scheme 65: Conversion of furfural to CPN.
Scheme 66: Synthesis of jet fuels range cycloalkanes from CPN and lignin-derived vanillin.
Scheme 67: Solar-energy-driven synthesis of high-density biofuels from CPN.
Scheme 68: Reductive amination of CPN to cyclopentylamine.
Scheme 69: Asymmetric hydrogenation of C=O bonds of exocyclic α,β-unsaturated cyclopentanones.
Scheme 70: Preparation of levulinic acid via the C5 route (route a) or C6 route (routes b1 and b2).
Scheme 71: Mechanism of the rehydration of HMF to levulinic acid and formic acid.
Scheme 72: Important levulinic acid-derived chemicals.
Scheme 73: Direct conversion of levulinic acid to pentanoic acid.
Scheme 74: Catalytic aerobic oxidation of levulinic acid to citramalic acid.
Scheme 75: Conversion of levulinic acid to 1,4-pentanediol (a) see ref. [236]; b) see ref. [237]; c) see ref. [238]; d) see r...
Scheme 76: Selective production of 2-butanol through hydrogenolysis of levulinic acid.
Scheme 77: General reaction pathways proposed for the formation of 5MPs from levulinic acid.
Scheme 78: Selective reductive amination of levulinic acid to N-substituted pyrroles.
Scheme 79: Reductive amination of levulinic acid to chiral pyrrolidinone.
Scheme 80: Reductive amination of levulinic acid to non-natural chiral γ-amino acid.
Scheme 81: Nitrogen-containing chemicals derived from levulinic acid.
Scheme 82: Preparation of GVL from levulinic acid by dehydration and hydrogenation.
Scheme 83: Ruthenium-catalyzed levulinic acid to chiral γ-valerolactone.
Scheme 84: Catalytic asymmetric hydrogenation of levulinic acid to chiral GVL.
Scheme 85: Three steps synthesis of ε-caprolactam from GVL.
Scheme 86: Multistep synthesis of nylon 6,6 from GVL.
Scheme 87: Preparation of MeGVL by α-alkylation of GVL.
Scheme 88: Ring-opening polymerization of five-membered lactones.
Scheme 89: Synthesis of GVL-based ionic liquids.
Scheme 90: Preparation of butene isomers from GVL under Lewis acid conditions.
Scheme 91: Construction of C5–C12 fuels from GVL over nano-HZSM-5 catalysts.
Scheme 92: Preparation of alkyl valerate from GVL via ring opening/reduction/esterification sequence.
Scheme 93: Construction of 4-acyloxypentanoic acids from GVL.
Scheme 94: Synthesis of 1,4-pentanediol (PDO) from GVL.
Scheme 95: Construction of novel cyclic hemiketal platforms via self-Claisen condensation of GVL.
Scheme 96: Copper-catalyzed lactamization of GVL.
Figure 4: Main scaffolds obtained from HMF.
Scheme 97: Biginelli reactions towards HMF-containing dihydropyrimidinones.
Scheme 98: Hantzsch dihydropyridine synthesis involving HMF.
Scheme 99: The Kabachnik–Fields reaction involving HMF.
Scheme 100: Construction of oxazolidinone from HMF.
Scheme 101: Construction of rhodamine-furan hybrids from HMF.
Scheme 102: A Groebke–Blackburn–Bienaymé reaction involving HMF.
Scheme 103: HMF-containing benzodiazepines by [4 + 2 + 1] cycloadditions.
Scheme 104: Synthesis of fluorinated analogues of α-aryl ketones.
Scheme 105: Synthesis of HMF derived disubstituted γ-butyrolactone.
Scheme 106: Functionalized aromatics from furfural and HMF.
Scheme 107: Diels–Alder adducts from HMF or furfural with N-methylmaleimide.
Scheme 108: Pathway of the one-pot conversion of HMF into phthalic anhydride.
Scheme 109: Photocatalyzed preparation of humins (L-H) from HMF mixed with spoiled HMF residues (LMW-H) and fur...
Scheme 110: Asymmetric dipolar cycloadditions on HMF.
Scheme 111: Dipolar cycloadditions of HMF based nitrones to 3,4- and 3,5-substituted isoxazolidines.
Scheme 112: Production of δ-lactone-fused cyclopenten-2-ones from HMF.
Scheme 113: Aza-Piancatelli access to aza-spirocycles from HMF-derived intermediates.
Scheme 114: Cross-condensation of furfural, acetone and HMF into C13, C14 and C15 products.
Scheme 115: Base-catalyzed aldol condensation/dehydration sequences from HMF.
Scheme 116: Condensation of HMF and active methylene nitrile.
Scheme 117: MBH reactions involving HMF.
Scheme 118: Synthesis of HMF-derived ionic liquids.
Scheme 119: Reductive amination/enzymatic acylation sequence towards HMF-based surfactants.
Scheme 120: The formation of 5-chloromethylfurfural (CMF).
Scheme 121: Conversion of CMF to HMF, levulinic acid, and alkyl levulinates.
Scheme 122: Conversion of CMF to CMFCC and FDCC.
Scheme 123: Conversion of CMF to BHMF.
Scheme 124: Conversion of CMF to DMF.
Scheme 125: CMF chlorine atom substitutions toward HMF ethers and esters.
Scheme 126: Introduction of carbon nucleophiles in CMF.
Scheme 127: NHC-catalyzed remote enantioselective Mannich-type reactions of CMF.
Scheme 128: Conversion of CMF to promising biomass-derived dyes.
Scheme 129: Radical transformation of CMF with styrenes.
Scheme 130: Synthesis of natural herbicide δ-aminolevulinic acid from CMF.
Scheme 131: Four step synthesis of the drug ranitidine from CMF.
Scheme 132: Pd/CO2 cooperative catalysis for the production of HHD and HXD.
Scheme 133: Different ruthenium (Ru) catalysts for the ring-opening of 5-HMF to HHD.
Scheme 134: Proposed pathways for preparing HXD from HMF.
Scheme 135: MCP formation and uses.
Scheme 136: Cu(I)-catalyzed highly selective oxidation of HHD to 2,5-dioxohexanal.
Scheme 137: Synthesis of N‑substituted 3‑hydroxypyridinium salts from 2,5-dioxohexanal.
Scheme 138: Ru catalyzed hydrogenations of HHD to 1,2,5-hexanetriol (a) see ref. [396]; b) see ref. [397]).
Scheme 139: Aviation fuel range quadricyclanes produced by HXD.
Scheme 140: Synthesis of HDGK from HXD and glycerol as a chain extender.
Scheme 141: Synthesis of serinol pyrrole from HXD and serinol.
Scheme 142: Synthesis of pyrroles from HXD and nitroarenes.
Scheme 143: Two-step production of PX from cellulose via HXD.
Scheme 144: Preparation of HCPN from HMF via hydrogenation and ring rearrangement.
Scheme 145: Suggested pathways from HMF to HCPN.
Scheme 146: α-Alkylation of HCPN with ethylene gas.
Scheme 147: Synthesis of 3-(hydroxymethyl)cyclopentylamine from HMF via reductive amination of HCPN.
Scheme 148: Production of LGO and Cyrene® from biomass.
Scheme 149: Synthesis of HBO from LGO and other applications.
Scheme 150: Construction of m-Cyrene® homopolymer.
Scheme 151: Conversion of Cyrene® to THFDM and 1,6-hexanediol.
Scheme 152: RAFT co-polymerization of LGO and butadienes.
Scheme 153: Polycondensation of HO-LGOL and diols with dimethyl adipate.
Scheme 154: Self-condensation of Cyrene® and Claisen–Schmidt reactions.
Scheme 155: Synthesis of 5-amino-2-(hydroxymethyl)tetrahydropyran from Cyrene®.
Enantioselective desymmetrization strategy of prochiral 1,3-diols in natural product synthesis
- Lihua Wei,
- Rui Yang,
- Zhifeng Shi and
- Zhiqiang Ma
Beilstein J. Org. Chem. 2025, 21, 1932–1963, doi:10.3762/bjoc.21.151
- synthesis of complex molecules which are spatially crowded. Among various types of substrates for enantioselective desymmetrization, symmetrical diols, especially prochiral 1,3-diols, are often prioritized for testing, because the two primary alcohols of the products (one of them is functionalized in an
Graphical Abstract
Scheme 1: General mechanism of a lipase-catalyzed esterification.
Scheme 2: Shishido’s synthesis of (−)-xanthorrhizol (4) and (+)-heliannuol D (8).
Scheme 3: Shishido’s synthesis of a) (−)-heliannuol A (15) and b) heliannuol G (20) and heliannuol H (21).
Scheme 4: Deska’s synthesis of hyperione A (30) and ent-hyperione B (31).
Scheme 5: Huang’s synthesis of (+)-brazilin (37).
Scheme 6: Shishido’s synthesis of (−)-heliannuol D (42) and (+)-heliannuol A (43).
Scheme 7: Chênevert’s synthesis of (S)-α-tocotrienol (49).
Scheme 8: Kita’s synthesis of monoester 53.
Scheme 9: Kita’s synthesis of fredericamycin A (60).
Scheme 10: Takabe’s synthesis of (E)-3,7-dimethyl-2-octene-1,8-diol (64).
Scheme 11: Takabe’s synthesis of (18S)-variabilin (70).
Scheme 12: Kawasaki’s synthesis of (S)-Rosaphen (74) and (R)-Rosaphen (75).
Scheme 13: Tokuyama’s synthesis of a) (−)-petrosin (84) and b) (+)-petrosin (86).
Scheme 14: Fukuyama’s synthesis of leustroducsin B (96).
Scheme 15: Nanda’s synthesis of a) fragment 100, b) fragment 106 and c) (−)-rasfonin (109).
Scheme 16: Davies’ synthesis of (+)-pilocarpine (115) and (+)-isopilocarpine (116).
Scheme 17: Ōmura’s synthesis of salinosporamide A (125).
Scheme 18: Kang’s synthesis of ʟ-cladinose (124) and its derivative.
Scheme 19: Kang’s preparation of fragment 139.
Scheme 20: Kang’s synthesis of azithromycin (149).
Scheme 21: Kang’s synthesis of (−)-dysiherbaine (156).
Scheme 22: Kang’s synthesis of (−)-kaitocephalin (166).
Scheme 23: Kang’s synthesis of laidlomycin (180).
Scheme 24: Snyder’s synthesis of arboridinine (190).
Scheme 25: Ma’s synthesis of (+)-alstrostine G (203).
Scheme 26: Trost’s synthesis of (−)-18-epi-peloruside A (215).
Scheme 27: Lindel’s synthesis of (–)-dihydroraputindole (223).
Scheme 28: Iwata’s synthesis of a) (−)-talaromycin B (232) and b) (+)-talaromycin A (235).
Scheme 29: Cook’s synthesis of a) (−)-vincamajinine (240) and b) (−)-11-methoxy-17-epivincamajine (245).
Scheme 30: Cook’s synthesis of (+)-dehydrovoachalotine (249) and voachalotine (250).
Scheme 31: Cook’s synthesis of a) (−)-12-methoxy-Nb-methylvoachalotine (257) and b) (+)-polyneuridine, macusin...
Scheme 32: Trauner’s synthesis of stephadiamine (273).
Scheme 33: Garg’s synthesis of (–)-ψ-akuammigine (285).
Scheme 34: Ding’s synthesis of (+)-18-benzoyldavisinol (293) and (+)-davisinol (294).
Chiral phosphoric acid-catalyzed asymmetric synthesis of helically chiral, planarly chiral and inherently chiral molecules
- Wei Liu and
- Xiaoyu Yang
Beilstein J. Org. Chem. 2025, 21, 1864–1889, doi:10.3762/bjoc.21.145
- synthesis of planarly chiral macrocycles via CPA-catalyzed coupling of carboxylic acids with alcohols via ynamide mediation. Kinetic resolution of substituted amido[2.2]paracyclophanes via CPA-catalyzed asymmetric electrophilic amination. Enantioselective synthesis of inherently chiral calix[4]arenes via
Graphical Abstract
Figure 1: General structure of CPAs and selected CPAs with various chiral scaffolds.
Figure 2: Representative elements of molecular chirality.
Scheme 1: CPA-catalyzed asymmetric synthesis of azahelicenes via Fischer indole synthesis.
Scheme 2: CPA-catalyzed asymmetric synthesis of azahelicenes via sequential Povarov reaction and oxidative ar...
Scheme 3: CPA-catalyzed asymmetric synthesis of azahelicenes via sequential Povarov reaction involving 3-viny...
Scheme 4: CPA-catalyzed asymmetric synthesis of heterohelicenes via sequential Povarov reaction involving 2-v...
Scheme 5: Diverse enantioselective synthesis of hetero[7]helicenes via a CPA-catalyzed double annulation stra...
Scheme 6: CPA-catalyzed asymmetric synthesis of indolohelicenoids through enantioselective cycloaddition and ...
Scheme 7: Kinetic resolution of helical polycyclic phenols via CPA-catalyzed enantioselective aminative dearo...
Scheme 8: Kinetic resolution of azahelicenes via CPA-catalyzed transfer hydrogenation.
Scheme 9: Asymmetric synthesis of planarly chiral macrocycles via CPA-catalyzed electrophilic aromatic aminat...
Scheme 10: Enantioselective synthesis of planarly chiral macrocycles via CPA-catalyzed macrocyclization.
Scheme 11: (Dynamic) kinetic resolution of planarly chiral paracyclophanes via CPA-catalyzed asymmetric reduct...
Scheme 12: Kinetic resolution of macrocyclic paracyclophanes through CPA/Bi-catalyzed asymmetric allylation.
Scheme 13: Enantioselective synthesis of planarly chiral macrocycles via CPA-catalyzed coupling of carboxylic ...
Scheme 14: Kinetic resolution of substituted amido[2.2]paracyclophanes via CPA-catalyzed asymmetric electrophi...
Scheme 15: Enantioselective synthesis of inherently chiral calix[4]arenes via sequential CPA-catalyzed Povarov...
Scheme 16: Asymmetric synthesis of inherently chiral calix[4]arenes via CPA-catalyzed aminative desymmetrizati...
Scheme 17: Asymmetric synthesis of chiral heterocalix[4]arenes via CPA-catalyzed intramolecular SNAr reaction.
Scheme 18: Enantioselective synthesis of inherently chiral DDDs via CPA-catalyzed cyclocondensation.
Scheme 19: Asymmetric synthesis of saddle-shaped inherently chiral 9,10-dihydrotribenzoazocines via CPA-cataly...
Scheme 20: Enantioselective synthesis of inherently chiral saddle-shaped dibenzo[b,f][1,5]diazocines via CPA-c...
Scheme 21: Enantioselective synthesis of inherent chiral 7-membered tribenzocycloheptene oximes via CPA-cataly...
Photoswitches beyond azobenzene: a beginner’s guide
- Michela Marcon,
- Christoph Haag and
- Burkhard König
Beilstein J. Org. Chem. 2025, 21, 1808–1853, doi:10.3762/bjoc.21.143
Graphical Abstract
Figure 1: Energy diagram of a two-state photoswitch. Figure 1 was redrawn from [2].
Figure 2: Example of the absorption spectra of the isomers of a photoswitch with most efficient irradiation w...
Scheme 1: Photoswitch classes described in this review.
Figure 3: Azoheteroarenes.
Scheme 2: E–Z Isomerisation (top) and mechanisms of thermal Z–E isomerisation (bottom).
Scheme 3: Rotation mechanism favoured by the electron displacement in push–pull systems. Selected examples of...
Figure 4: A) T-shaped and twisted Z-isomers determine the thermal stability and the Z–E-PSS (selected example...
Figure 5: Effect of di-ortho-substitution on thermal half-life and PSS.
Figure 6: Selected thermal lifetimes of azoindoles in different solvents and concentrations. aConcentration o...
Figure 7: Aryliminopyrazoles: N-pyrazoles (top) and N-phenyl (bottom).
Scheme 4: Synthesis of symmetrical heteroarenes through oxidation (A), reduction (B), and the Bayer–Mills rea...
Scheme 5: Synthesis of diazonium salt (A); different strategies of azo-coupling: with a nucleophilic ring (B)...
Scheme 6: Synthesis of arylazothiazoles 25 (A) and heteroaryltriazoles 28 (B).
Scheme 7: Synthesis of heteroarylimines 31a,b [36-38].
Figure 8: Push–pull non-ionic azo dye developed by Velasco and co-workers [45].
Scheme 8: Azopyridine reported by Herges and co-workers [46].
Scheme 9: Photoinduced phase transitioning azobispyrazoles [47].
Figure 9: Diazocines.
Scheme 10: Isomers, conformers and enantiomers of diazocine.
Scheme 11: Partial overlap of the ππ* band with electron-donating substituents and effect on the PSS. Scheme 11 was ada...
Figure 10: Main properties of diazocines with different bridges. aMeasured in n-hexane [56]. bMeasured in THF. cMe...
Scheme 12: Synthesis of symmetric diazocines.
Scheme 13: Synthesis of asymmetric diazocines.
Scheme 14: Synthesis of O- and S-heterodiazocines.
Scheme 15: Synthesis of N-heterodiazocines.
Scheme 16: Puromycin diazocine photoswitch [60].
Figure 11: Indigoids.
Figure 12: The main representatives of the indigoid photoswitch class.
Scheme 17: Deactivation process that prevents Z-isomerisation of indigo.
Figure 13: Stable Z-indigo derivative synthesised by Wyman and Zenhäusern [67].
Figure 14: Selected examples of indigos with aliphatic and aromatic substituents [68]. Dashed box: proposed π–π in...
Scheme 18: Resonance structures of indigo and thioindigo involving the phenyl ring.
Scheme 19: Possible deactivation mechanism for 4,4'-dihydroxythioindigo [76].
Scheme 20: Effect of different heteroaryl rings on the stability and the photophysical properties of hemiindig...
Figure 15: Thermal half-lives of red-shifted hemithioindigos in toluene [79]. aMeasured in toluene-d8.
Scheme 21: Structures of pyrrole [81] and imidazole hemithioindigo [64].
Figure 16: Examples of fully substituted double bond hemithioindigo (left), oxidised hemithioindigos (centre),...
Scheme 22: Structure of iminothioindoxyl 72 (top) and acylated phenyliminoindolinone photoswitch 73 (bottom). ...
Scheme 23: (top) Transition states of iminothioindoxyl 72. The planar transition state is associated with a lo...
Scheme 24: Baeyer–Drewsen synthesis of indigo (top) and N-functionalisation strategies (bottom).
Scheme 25: Synthesis of hemiindigo.
Scheme 26: Synthesis of hemithioindigo and iminothioindoxyl.
Scheme 27: Synthesis of double-bond-substituted hemithioindigos.
Scheme 28: Synthesis of phenyliminoindolinone.
Scheme 29: Hemithioindigo molecular motor [85].
Figure 17: Arylhydrazones.
Scheme 30: Switching of arylhydrazones. Note: The definitions of stator and rotor are arbitrary.
Scheme 31: Photo- and acidochromism of pyridine-based phenylhydrazones.
Scheme 32: A) E–Z thermal inversion of a thermally stable push–pull hydrazone [109]. B) Rotation mechanism favoured...
Scheme 33: Effect of planarisation on the half-life.
Scheme 34: The longest thermally stable hydrazone switches reported so far (left). Modulation of thermal half-...
Figure 18: Dependency of t1/2 on concentration and hypothesised aggregation-induced isomerisation.
Figure 19: Structure–property relationship of acylhydrazones.
Scheme 35: Synthesis of arylhydrazones.
Scheme 36: Synthesis of acylhydrazones.
Scheme 37: Photoswitchable fluorophore by Aprahamian et al. [115].
Scheme 38: The four-state photoswitch synthesised by the Cigáň group [116].
Figure 20: Diarylethenes.
Scheme 39: Isomerisation and oxidation pathway of E-stilbene to phenanthrene.
Scheme 40: Strategies adapted to avoid E–Z isomerisation and oxidation.
Scheme 41: Molecular orbitals and mechanism of electrocyclisation for a 6π system.
Figure 21: Aromatic stabilisation energy correlated with the thermal stability of the diarylethenes [127,129].
Figure 22: Half-lives of diarylethenes with increasing electron-withdrawing groups [128,129].
Scheme 42: Photochemical degradation pathway promoted by electron-donating groups [130].
Figure 23: The diarylethenes studied by Hanazawa et al. [134]. Increased rigidity leads to bathochromic shift.
Scheme 43: The dithienylethene synthesised by Nakatani's group [135].
Scheme 44: Synthesis of perfluoroalkylated diarylethenes.
Scheme 45: Synthesis of 139 and 142 via McMurry coupling.
Scheme 46: Synthesis of symmetrical derivatives 145 via Suzuki–Miyaura coupling.
Scheme 47: Synthesis of acyclic 148, malonic anhydride 149, and maleimide derivatives 154.
Figure 24: Gramicidin S (top left) and two of the modified diarylethene derivatives: first generation (bottom ...
Scheme 48: Pyridoxal 5'-phosphate and its reaction with an amino acid (top). The analogous dithienylethene der...
Figure 25: Fulgides.
Scheme 49: The three isomers of fulgides.
Scheme 50: Thermal and photochemical side products of unsubstituted fulgide [150].
Figure 26: Maximum absorption λc of the closed isomer compared with the nature of the aromatic ring and the su...
Scheme 51: Possible rearrangement of the excited state of 5-dimethylaminoindolylfulgide [153].
Figure 27: Quantum yields of ring closure (ΦE→C) and E–Z isomerisation (ΦE→Z) correlated with the increasing s...
Scheme 52: Active (Eα) and inactive (Eβ) conformers (left) and the bicyclic sterically blocked fulgide 169 (ri...
Scheme 53: Quantum yield of ring-opening (ΦC→E) and E–Z isomerisation (ΦE→Z) for different substitution patter...
Scheme 54: Stobbe condensation pathway for the synthesis of fulgides 179, fulgimides 181 and fulgenates 178.
Scheme 55: Alternative synthesis of fulgides through Pd-catalysed carbonylation.
Scheme 56: Optimised synthesis of fulgimides [166].
Scheme 57: Photoswitchable FRET with a fulgimide photoswitch [167].
Scheme 58: Three-state fulgimide strategy by Slanina's group.
Figure 28: Spiropyrans.
Scheme 59: Photochemical (left) and thermal (right) ring-opening mechanisms for an exemplary spiropyran with a...
Figure 29: Eight possible isomers of the open merocyanine according to the E/Z configurations of the bonds hig...
Scheme 60: pH-Controlled photoisomerisation between the closed spiropyran 191-SP and the open E-merocyanine 19...
Scheme 61: Behaviour of spiropyran in water buffer according to Andréasson and co-workers [180]. 192-SP in an aqueo...
Scheme 62: (left box) Proposed mechanism of basic hydrolysis of MC [184]. (right box) Introduction of electron-dona...
Scheme 63: Photochemical interconversion of naphthopyran 194 (top) and spirooxazine 195 (bottom) photoswitches...
Scheme 64: Synthesis of spiropyrans and spirooxazines 198 and the dicondensation by-product 199.
Scheme 65: Alternative synthesis of spiropyrans and spirooxazines with indolenylium salt 200.
Scheme 66: Synthesis of 4’-substituted spiropyrans 203 by condensation of an acylated methylene indoline 201 w...
Scheme 67: Synthesis of spironaphthopyrans 210 by acid-catalysed condensation of naphthols and diarylpropargyl...
Scheme 68: Photoswitchable surface wettability [194].
Figure 30: Some guiding principles for the choice of the most suitable photoswitch. Note that this guide is ve...
Synthesis of chiral cyclohexane-linked bisimidazolines
- Changmeng Xi,
- Qingshan Sun and
- Jiaxi Xu
Beilstein J. Org. Chem. 2025, 21, 1786–1790, doi:10.3762/bjoc.21.140
- alcohols and utilized in different metal-catalyzed asymmetric organic reactions [1][2][3][4][5][6][7][8][9]. In comparison with bisoxazoline ligands, relatively less attention has been paid to bisimidazoline ligands [10][11][12][13][14][15]. Some well investigated bisimidazoline ligands are pyridine-linked
- vicinal amino alcohols as starting materials in their synthesis. However, it is difficult to tune the electronic effects of cHBOX ligands. Chiral cyclohexane-1,2-linked bisimidazolines possess similar structural features as cHBOX ligands and their electronic effect can be tuned by the introduction of
Graphical Abstract
Figure 1: Bisoxazoline and bisimidazoline ligands.
Scheme 1: Synthesis of chiral cyclohexane-linked bisimidazoline ligands.
Scheme 2: Attempted synthesis of chiral cyclohexane-linked bisimidazoline 5h.
Scheme 3: Proposed reaction mechanism.
Preparation of a furfural-derived enantioenriched vinyloxazoline building block and exploring its reactivity
- Madara Darzina,
- Anna Lielpetere and
- Aigars Jirgensons
Beilstein J. Org. Chem. 2025, 21, 1737–1741, doi:10.3762/bjoc.21.136
- amino alcohols derived from furfural and ʟ- or ᴅ-valinol were subjected to Torii-type ester electrosynthesis to obtain the corresponding unsaturated esters. These served as key intermediates to prepare (S)- and (R)-enantioenriched unsaturated amides by N-Alloc deprotection which induced concomitant
- trans-isomer of amide 5. Results and Discussion The protected furfuryl amino alcohols S-2d and R-2d were prepared by reductive amination of furfural (1) with ʟ- and ᴅ-valinol followed by N-protection with Alloc-Cl (Scheme 2). The amino alcohols S-2d and R-2d were then subjected to electrochemical
- competent substrate for the aza-Diels–Alder reaction in with TsNCO to give oxazolo[3,2-c]pyrimidine derivative 7 as a single diastereomer. Proposed approach for the preparation of vinyloxazoline 6. Synthesis of furfuryl amino alcohols S-2d and R-2d and their electrochemical oxidation to esters S-3d and R-3d
Graphical Abstract
Scheme 1: Proposed approach for the preparation of vinyloxazoline 6.
Scheme 2: Synthesis of furfuryl amino alcohols S-2d and R-2d and their electrochemical oxidation to esters S-...
Scheme 3: Cleavage of the N-Alloc group leading to a mixture of isomers cis-S-5 and trans-S-5.
Scheme 4: Cleavage of the N-Alloc group with PdCl2(S-BINAP) leading to trans-S-5 and trans-R-5.
Scheme 5: Cyclization of amides trans-S-5 and trans-R-5 to oxazolines S-6 and R-6.
Scheme 6: aza-Diels–Alder reaction of vinyloxazoline S-6 with TsNCO.
Scheme 7: The proposed mechanism of product 7 formation.
Continuous-flow-enabled intensification in nitration processes: a review of technological developments and practical applications over the past decade
- Feng Zhou,
- Chuansong Duanmu,
- Yanxing Li,
- Jin Li,
- Haiqing Xu,
- Pan Wang and
- Kai Zhu
Beilstein J. Org. Chem. 2025, 21, 1678–1699, doi:10.3762/bjoc.21.132
- classifications necessitate tailored nitrating reagent selections, giving rise to fundamentally distinct mechanistic pathways. This reactivity is exemplified by the comparative kinetic profiles: N-nitration of amines and O-nitration of alcohols – facilitated by accessible lone electron pairs – exhibit markedly
Graphical Abstract
Figure 1: Three key dimensions of a complete nitration process.
Figure 2: A typical continuous-flow nitration reaction system.
Figure 3: Corrosion characteristics of common wetted materials used in continuous-flow nitration system. Note...
Figure 4: Analysis of the literature on continuous-flow nitration reaction over the past decade.
Scheme 1: Model reaction for the homogeneous nitration by nitric acid/mixed acid.
Figure 5: Safety assessment criteria for nitration reactions. Notes: apressure-independent; bno hazards arisi...
Figure 6: Guide for the investigation of continuous-flow nitration processes.
General method for the synthesis of enaminones via photocatalysis
- Paula Pérez-Ramos,
- Raquel G. Soengas and
- Humberto Rodríguez-Solla
Beilstein J. Org. Chem. 2025, 21, 1535–1543, doi:10.3762/bjoc.21.116
- presence of amines and CuI as catalyst, as reported by Zhang and co-workers (Scheme 1B) [32]. On the other hand, Li et al. disclosed a silver-catalyzed amination of propargyl alcohols to afford enaminones (Scheme 1C) [33]. Although these new methods provide a wide variety of enaminones, there are
Graphical Abstract
Figure 1: Examples of compounds with medicinal effects containing an enaminone structural moiety.
Scheme 1: Synthesis of enaminones.
Scheme 2: Substrate scope.
Scheme 3: Scale-up synthesis of enaminone 9a.
Scheme 4: Mechanistic studies.
Scheme 5: Proposed mechanism.
