A Modular Approach to Angularly Fused Polyquinanes via Ring-Rearrangement Metathesis: Synthetic Access to Cameroonanol Analogues and the Basic Core of Subergorgic Acid and Crinipellin

Kotha, Sambasivarao; Keesari, Ramakrishna Reddy

doi:10.1021/acs.joc.1c02258

Cited by 10 publications

(5 citation statements)

References 95 publications

(75 reference statements)

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“…The exo-DCPD-1-one 4 can serve as a key building block in the synthesis of several naturally occurring natural and unnatural compounds (Figure 4). [13][14][15] Therefore, exo-DCPD-1-one 4 occupies a unique place in organic synthesis.…”

Section: Discussionmentioning

confidence: 99%

“…The organic layer was washed with aqueous saturated NaHCO 3 solution (200-300 mL) twice. The [13][14][15] organic layer was concentrated to get crude compound and which was purified by column chromatography (2-4% EtOAc/PE as an eluent) to afford 4 (2%), 7 (50 g, 32%), and 8 (28%) as liquids.…”

Section: General Procedures For Seo 2 Oxidation: Synthesis Of Compoun...mentioning

confidence: 99%

“…[14] Whereas, 5/5-exo (exo-isomer) stereochemistry is favorable for the synthesis of polyquinanes and some fused cyclic molecules, and not favorable for the [2 + 2]-cycloaddition sequence. [14,15] Also, the exo-isomer undergoes ring-open metathesis polymerization (ROMP) at a faster rate as compared to the endo-isomer. [11] After establishing the structure of endo-DCPD 1 by Alder and Stein (1933), [16] many groups reported interesting studies to convert the endo-DCPD into its isomer, exo-DCPD 2.…”

Section: Introductionmentioning

confidence: 99%

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Synthetic Improvements and an Alternative Synthetic Approach to exo‐Dicyclopentadiene‐1‐one: A Useful Building Block for Cyclopentanoids

Kotha

Keesari

2023

Asian J Org Chem

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Here, we describe the synthetic improvements to the known compound exo‐dicyclopentadiene‐1‐one (exo‐DCPD‐1‐one). Also, an alternative and efficient synthetic approach to exo‐DCPD‐1‐one was developed in a non‐hazardous manner. All the synthesized compounds here are well‐characterized by NMR analysis. The structure and relative stereochemistry of some key intermediates were confirmed by single‐crystal X‐ray diffraction (XRD) studies. Overall, the synthetic studies described here are useful to prepare exo‐DCPD‐1‐one on a multi‐gram scale in a safe manner. The exo‐DCPD‐1‐one is found to be a useful building block to prepare a wide variety of cyclopentanoids.

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Section: Discussionmentioning

confidence: 99%

Section: General Procedures For Seo 2 Oxidation: Synthesis Of Compoun...mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Synthetic Improvements and an Alternative Synthetic Approach to exo‐Dicyclopentadiene‐1‐one: A Useful Building Block for Cyclopentanoids

Kotha

Keesari

2023

Asian J Org Chem

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“…Note : Experimental procedures for methylation, allylation, [22d] DIBALH reduction, Grignard reaction, Hydrogenation, DCC‐coupling, and the key starting materials are described in supporting information . Data of respective compounds are also well documented.…”

Section: Methodsmentioning

confidence: 99%

An Intramolecular Cycloetherification of Unactivated Olefinic Substrates Bearing endo‐Alcohol: Access to Diversely Alkylated Oxa‐Cage Derivatives Useful for Olefin‐Metathesis

Kotha

Keesari

2022

Chemistry An Asian Journal

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Herein, we report an efficient and rapid synthetic methodology to access diversely substituted oxa-cages from unactivated olefinic substrates derived from endo-norbornenes by employing Lewis acid-(BF 3 • OEt 2 ) or base (NaH)promoted intramolecular etherification. Although both BF 3 • OEt 2 and NaH are found to be efficient for this transformation, slightly better yields and less reaction times are achieved with NaH/DMF (0.25-1 h at 100 °C) as compared to BF 3 • OEt 2 /DCM (2-3 h at 0 °C to rt). The evolution of this intramolecular cyclization was studied by time-dependent NMR studies in CDCl 3 solvent. Further, these observations are supported by infrared (IR) spectral data. It is worth mentioning that the present methodology enables a new route to assemble highly fused oxa-cage systems by choosing suitably substituted oxa-cage compounds for the olefin-metathesis sequence. The highly fused oxa-cage systems may have potential applications in high-energy-density materials (HEDMs) and supramolecular chemistry.

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“…Seeking to combine the positive attributes of 2 (easy monomer synthesis) and 3 (desirable polymer properties), while eliminating the disadvantages noted above (e.g., the use of toxic oxidants or the need to purify away regioisomers at the monomer stage), we were attracted to the possibility of polymerizing dicyclopentadien-1-one (oxaDCPD; 4 m ). Ketone 4 m has long been known (in both endo and exo diastereomeric forms) as an intermediate in complex-molecule synthesis, − but its polymerization by ring-opening metathesis polymerization (ROMP) methods has not previously been described. − Compellingly, the one-step oxidation of DCPD ( 1 m ) to 4 m has been reported previously under photocatalytic conditions and is known to afford only a single regioisomer of the target compound, in good yield. − If this reaction could be adapted toward large-scale production, it could provide an attractive monomer synthesis that is both economically and environmentally sustainable. Moreover, if polymerization of 4 m were to proceed similarly to the previously known functionalized monomers 2 m and 3 m , this could afford a novel functionalized polydicyclopentadiene ( 4 p and/or 4 p,c ) that has a somewhat increased surface energy relative to the parent PDCPD (due to the polar ketone group), while also encoding a useful synthetic handle for further derivatization and avoiding the labile allylic alcohol (or allylic ester) functionality that limited the high-temperature performance and T g in polymer 2 p .…”

Section: Introductionmentioning

confidence: 99%

A Single-Atom Upgrade to Polydicyclopentadiene

et al. 2023

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Chemical cross-links within polymers increase mechanical strength and rigidity. Such cross-links can be either irreversible (e.g., those derived from carbon–carbon bonds) or reversible (e.g., those that depend on X–H···O hydrogen bonds). Here we describe a ketone-functionalized derivative of polydicyclopentadiene that establishes an unprecedented network of vinyl C–H···O hydrogen bonds within the polymer. The resulting thermoset displays a significantly increased glass transition temperature relative to the unfunctionalized polymer, together with enhancements to storage modulus, Young’s modulus, and compression strength.

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A Modular Approach to Angularly Fused Polyquinanes via Ring-Rearrangement Metathesis: Synthetic Access to Cameroonanol Analogues and the Basic Core of Subergorgic Acid and Crinipellin

Cited by 10 publications

References 95 publications

Synthetic Improvements and an Alternative Synthetic Approach to exo‐Dicyclopentadiene‐1‐one: A Useful Building Block for Cyclopentanoids

Synthetic Improvements and an Alternative Synthetic Approach to exo‐Dicyclopentadiene‐1‐one: A Useful Building Block for Cyclopentanoids

An Intramolecular Cycloetherification of Unactivated Olefinic Substrates Bearing endo‐Alcohol: Access to Diversely Alkylated Oxa‐Cage Derivatives Useful for Olefin‐Metathesis

A Single-Atom Upgrade to Polydicyclopentadiene

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