Enediynes, enyne‐allenes, their reactions, and beyond

Kraka, Elfi

doi:10.1002/wcms.1174

Cited by 38 publications

(35 citation statements)

References 220 publications

(336 reference statements)

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“…This is in contrast, then, to the Bergman cycloaromatization of an enediyne, 30 which generates a diradical p -benzyne intermediate that is incapable of further closure owing to the instability of what would be a “Dewar benzyne” product. 31 The intramolecular HDDA is also in contrast with the Myers-Saito 32 and Schmittel 33 cycloaromatizations of enyne-allenes, which lead to α,3-didehydrotoluene and extracyclic fulvenoid diradical intermediates, respectively, 31e,34 and with the cycloaromatization of the enyne-cumulene neocarzinostatin chromophore, which leads to a 1,5-didehydroindene. 35 In none of these other cases are the radical centers able to react (intramolecularly) with one another to form a new bond (and ring): geometric constraints prevent such a closure.…”

Section: Resultsmentioning

confidence: 99%

Mechanism of the Intramolecular Hexadehydro-Diels–Alder Reaction

et al. 2015

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Theoretical analysis of the mechanism of the intramolecular hexadehydro-Diels–Alder (HDDA) reaction, validated against prior and newly measured kinetic data for a number of different tethered yne-diynes, indicates that the reaction proceeds in a highly asynchronous fashion. The rate-determining step is bond formation at the alkyne termini nearest the tether, which involves a transition-state structure exhibiting substantial diradical character. Whether the reaction then continues to close the remaining bond in a concerted fashion or in a stepwise fashion (i.e., with an intervening intermediate) depends on the substituents at the remaining terminal alkyne positions. Computational modeling of the HDDA reaction is complicated by the significant diradical character that arises along the reaction coordinate, which leads to instabilities in both restricted singlet Kohn-Sham density functional theory (DFT) and coupled-cluster theory based on a Hartree-Fock reference wave function. A consistent picture emerges, however, from comparison of broken-symmetry DFT calculations and second-order perturbation theory based on complete-active-space self-consistent-field (CASPT2) calculations.

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Section: Resultsmentioning

confidence: 99%

Mechanism of the Intramolecular Hexadehydro-Diels–Alder Reaction

et al. 2015

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“…The therapeutic applications of these enediyne antitumor antibiotics have also triggered a series of research efforts in connection with enediyne chemistry including quantum chemical theory, thermodynamics, and kinetics studies of the Bergman cyclization [14]. Based on these studies, the activation barrier of the Bergman cyclization is influenced by three dominant factors: (1) the proximity effect [15], stating that the critical distance between the two enediyne carbon atoms forming the new bond should be in the range of 3.31-3.20 Å for a spontaneous Bergman cyclization at physiological temperature; (2) molecular-strain differences [16,17], leading to a significant activation of some cyclic enediynes; (3) electronic effects [18], influencing the stability of the rearranged enediyne, the transition state, and the biradical that is produced.…”

Section: Introductionmentioning

confidence: 99%

Recent advances of the Bergman cyclization in polymer science

Chen

2015

Sci. China Chem.

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The Bergman cyclization has strongly impacted on a number of fields including pharmaceutics, synthetic chemistry, and material science. The diradical intermediates stemmed from enediynes can not only cause DNA cleavage under physiological conditions but also function as monomer or initiator participants in polymer science. The homo-polymerization of enediynes through the Bergman cyclization to fabricate conjugated polymers is a fascinating strategy due to the advantages of facial operation, high efficiency, tailored structure, and catalyst-free operation. Moreover, conjugated polymers generated through the Bergman cyclization show many remarkable properties, such as excellent thermal stability, good solubility, and processability, which enables these polymers to be further manufactured into carbon-rich materials. Recent times have seen extensive efforts devoted to the application of the Bergman cyclization in polymer science and materials chemistry. A variety of synthetic strategies have been developed to fabricate structurally unique materials via the Bergman cyclization, including the fabrication of rod-like polymers with polyester, dendrimers and chiral imide side chains, functionalization of carbon nanomaterials by surface-grafting conjugated polymers, formation of nanoparticles by intramolecular collapse of single polymer chains, and the construction of carbon nanomembranes with different morphologies. Future developments involving the Bergman cyclization in polymer science, probably by altering the reaction mechanism to precisely control the microstructure of polymeric products, are also proposed in this review article.

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“…19,20 Thus, we have also varied the size of the ortho substituents (-H, -CH 3 , and -TMS) on the phenyl ring and studied its impact on the conformation of anthracenyl groups and the cyclization reaction. 9-Anthracenylethynyl arenediyne derivatives 1-3, possessing ortho substituents of increasing steric demand -H (1), -CH 3 (2), and -TMS (3) were synthesized (Scheme 2). Compounds 1 and 2 were prepared starting from 9-bromoanthracene (5).…”

Section: Contents Lists Available At Sciencedirectmentioning

confidence: 99%

“…[1][2][3][4] Single crystals of molecules 1-3 were grown to determine the distance between alkyne groups and the preferred intramolecular orientation of anthracenyl moieties (Fig. 2).…”

Section: Contents Lists Available At Sciencedirectmentioning

confidence: 99%