19740-90-0

Basic information

• Product Name: (1R,8S)-rel-9-Oxabicyclo[6.1.0]non-4-ene
• Synonyms: (1R,8S)-rel-9-Oxabicyclo[6.1.0]non-4-ene;1,2-Epoxy-cis-cyclooct-5-ene;5,6-Epoxy-cis-cyclooctene;5,6-Epoxycyclooctene
• CAS NO: 19740-90-0
• Molecular Formula: C₈H₁₂O
• Molecular Weight: 124.18
• Mol File: 19740-90-0.mol

Chemical Properties

• Boiling Point: 178 ºC
• Flash Point: 54 ºC
• Appearance: /
• Density: 0.993
• Vapor Pressure: 1.36mmHg at 25°C
• Refractive Index: 1.49
• CAS DataBase Reference: (1R,8S)-rel-9-Oxabicyclo[6.1.0]non-4-ene(CAS DataBase Reference)
• NIST Chemistry Reference: (1R,8S)-rel-9-Oxabicyclo[6.1.0]non-4-ene(19740-90-0)
• EPA Substance Registry System: (1R,8S)-rel-9-Oxabicyclo[6.1.0]non-4-ene(19740-90-0)

Safety Data

• Hazardous Substances Data: 19740-90-0(Hazardous Substances Data)

Usage

Uses

Used in Fragrance and Flavor Industry:
(1R,8S)-rel-9-Oxabicyclo[6.1.0]non-4-ene is used as a fragrance and flavoring agent for its citrus-like odor and is commonly found in essential oils such as eucalyptus, citronella, and mint.
Used in Pharmaceutical Synthesis:
(1R,8S)-rel-9-Oxabicyclo[6.1.0]non-4-ene is used as a precursor in the synthesis of pharmaceuticals and other organic compounds.
Used in Natural Pesticides and Antibacterial Agents:
(1R,8S)-rel-9-Oxabicyclo[6.1.0]non-4-ene is used as an active ingredient in the development of natural pesticides and antibacterial agents due to its antimicrobial and insecticidal properties.

InChI:InChI=1/C8H12O/c1-2-4-6-8-7(9-8)5-3-1/h1-2,7-8H,3-6H2/b2-1-/t7-,8+

Upstream product

• 1552-12-1 1,5-cis,cis-cyclooctadiene 
• 931-88-4 1,2-cyclooctene 
• 5259-72-3 cyclo-octa-1,5-diene 
• 93953-49-2 trans-8-iodo-cyclooct-4-en-1-yl acetate 
• 108909-88-2 Trans-2-fluorocyclooct-5-en-1-ol 

Downstream Products

• 286-62-4 Cyclooctene oxide 
• 29417-19-4 trans-trans-2,5-di-iodo-9-oxabicyclo<4.2.1>nonane 
• 10299-46-4 endo,endo-2,6-diiodo-9-oxa-bicyclo[3.3.1]nonane 
• 51097-60-0 (Z)-oct-4-enedial 
• 4277-34-3 (Z)-cyclooct-4-enol 
• 108909-88-2 Trans-2-fluorocyclooct-5-en-1-ol 
• 123836-24-8 (+/-)-trans-8-phenyl-4-cycloocten-1-ol 
• 112348-22-8 (Z)-8-(benzylamino)cyclooct-4-enol 
• 1191889-58-3 (1S,8S)-8-(4-chlorophenylthio)cyclooct-4-en-1-ol 
• 1354323-64-0 (Z)-cyclooct-4-en-1-yl (4-nitrophenyl) carbonate 
• 637-90-1 (E)-9-oxabicyclo[6.1.0]non-4-ene 
• 353461-15-1 tert-butyl (1R*,6R*)-2-oxo-9-azabicyclo[4.2.1]nonane-9-carboxylate 
• 90741-53-0 t-butyl-1-(9-azabicyclo<4.2.1>-non-2-ene-2-yl)ethanone carbamate 
• 64314-16-5 (+)-anatoxin-a hydrochloride 

Relevant articles and documents

MONOACYLGLYCEROL LIPASE MODULATORS

Fused and bridged compounds of Formula (I), and pharmaceutically acceptable salts, isotopes, N-oxides, solvates, and stereoisomers thereof, pharmaceutical compositions containing them, methods of making them, and methods of using them including methods for treating disease states, disorders, and conditions associated with MGL modulation, such as those associated with pain, psychiatric disorders, neurological disorders (including, but not limited to major depressive disorder, treatment resistant depression, anxious depression, autism spectrum disorders, Asperger syndrome, bipolar disorder), cancers and eye conditions: (I) wherein R1a, R1b, R2, and R3, are defined herein.

Monoacylglycerol Lipase Modulators

Bridged compounds of Formula (I) and Formula (II), pharmaceutical compositions containing them, methods of making them, and methods of using them including methods for treating disease states, disorders, and conditions associated with MGL modulation, such as those associated with pain, psychiatric disorders, neurological disorders (including, but not limited to major depressive disorder, treatment resistant depression, anxious depression, bipolar disorder), cancers and eye conditions. wherein R2, R3 R4, R5 and R6 are defined herein.

A Bioorthogonal Click Chemistry Toolbox for Targeted Synthesis of Branched and Well-Defined Protein–Protein Conjugates

Bioorthogonal chemistry holds great potential to generate difficult-to-access protein–protein conjugate architectures. Current applications are hampered by challenging protein expression systems, slow conjugation chemistry, use of undesirable catalysts, or often do not result in quantitative product formation. Here we present a highly efficient technology for protein functionalization with commonly used bioorthogonal motifs for Diels–Alder cycloaddition with inverse electron demand (DAinv). With the aim of precisely generating branched protein chimeras, we systematically assessed the reactivity, stability and side product formation of various bioorthogonal chemistries directly at the protein level. We demonstrate the efficiency and versatility of our conjugation platform using different functional proteins and the therapeutic antibody trastuzumab. This technology enables fast and routine access to tailored and hitherto inaccessible protein chimeras useful for a variety of scientific disciplines. We expect our work to substantially enhance antibody applications such as immunodetection and protein toxin-based targeted cancer therapies.

Aerobic oxidation of the C-H bond under ambient conditions using highly dispersed Co over highly porous N-doped carbon

Highly dispersed Co sites in highly porous N-doped carbon (Co-NC) were synthesized by high-temperature pyrolysis of Zn/Co bimetallic zeolitic imidazolate framework-8 (CoxZn100-x-ZIF). Wide characterization indicated that the pyrolysis atmosphere and temperature play crucial roles in the metal dispersion and pore structure of the resulting materials. A hydrogen treatment at elevated temperatures is found to favour the Zn volatilization and restrict the pore shrinkage of the ZIF precursor, thus yielding efficient catalysts with highly dispersed Co, a high surface area (1090 m2 g-1) and pore volume (0.89 cm3 g-1). When used as a catalyst for aerobic oxidation of ethylbenzene (EB), Co1Zn99-ZIF-800-H2 contributes to 98.9% EB conversion and 93.1% ketone selectivity under mild conditions (60 °C, 1 atm O2), which is 41.3 times more active in comparison to the ZIF-67-derived Co catalyst. Co-NC is stable and could be reused four times without obvious deactivation. This catalyst displays good chemoselectivity to the corresponding ketones when using a broad scope of hydrocarbon compounds.

Synthesis of functionalized carbon microspheres and their catalyst activity in C—O and C—N bond formation reactions

Disclosed herein is a simple process for functionalization/grafting of carbon microspheres obtained from bagasse with various active functional groups onto it and use of the same as catalyst for various organic reactions, having very high selectivity and conversion rate.

Photocatalytic Aerobic Phosphatation of Alkenes

A catalytic regime for the direct phosphatation of simple, non-polarized alkenes has been devised that is based on using ordinary, non-activated phosphoric acid diesters as the phosphate source and O2 as the terminal oxidant. The title method enables the direct and highly economic construction of a diverse range of allylic phosphate esters. From a conceptual viewpoint, the aerobic phosphatation is entirely complementary to traditional methods for phosphate ester formation, which predominantly rely on the use of prefunctionalized or preactivated reactants, such as alcohols and phosphoryl halides. The title transformation is enabled by the interplay of a photoredox and a selenium π-acid catalyst and involves a sequence of single-electron-transfer processes.

Identification of in situ flower volatiles from kiwifruit (Actinidia chinensis var. deliciosa) cultivars and their male pollenisers in a New Zealand orchard

In situ flower volatiles from six kiwifruit cultivars (Actinidia chinensis var. deliciosa); ‘Hayward’, ‘Chieftain’, ‘M56’, ‘Zes007’ (Green11), ‘M36’, and ‘M43’ were collected by dynamic headspace sampling. Forty-five compounds were detected in the headspace of the flowers, with straight chain hydrocarbons and terpenes accounting for >98% of the volatiles emitted quantitatively across the six cultivars. Of these hydrocarbons, (3Z,6Z,9Z)-heptadecatriene is reported for the first time from a floral source while (8Z)-hexadecene and (9Z)-nonadecene are reported for the first time from kiwifruit flowers. All three hydrocarbons were verified by synthesis. Quantitative comparison of the six honey bee perceived compounds from the headspace of the cultivars showed that the males ‘M36’ and ‘M43’ closely matched the female cultivar Green11 that they are used to pollinate. Males ‘M56’ and ‘Chieftain’ were not as closely matched to the female cultivar ‘Hayward’ that they are used to pollinate. The male ‘M56’ in particular differed significantly from the female ‘Hayward’ in four of the six honey bee perceived compounds.

New multiblock copolymers of norbornene and 5-hydroxycyclooctene

Cross-metathesis of 5-hydroxycyclooctene and norbornene homopolymers affords the multiblock copolymer possessing a broad range in the degree of blockiness (from 0.03 to 1).

Novel Super-Resolution Imaging Compositions and Methods Using Same

The invention provides compositions that may be used for imaging intracellular structures. The invention further provides methods of imaging intracellular structures. In certain embodiments, the compositions of the invention include trans-cyclooctene-containing ceramide lipids and tetrazine-containing rhodamine-related dyes.

Co(ii) complexes loaded into metal-organic frameworks as efficient heterogeneous catalysts for aerobic epoxidation of olefins

A series of efficient cobalt(ii)-anchored Cr-MOF (Cr-MIL-101-NH2) catalysts, such as Co(ii)@Cr-MIL-101-Sal, Co(ii)@Cr-MIL-101-P2I and Co(ii)@Cr-MIL-101-P3I, have been successfully synthesized by one-pot modification of the terminal amino group with salicylaldehyde, pyridine-2-aldehyde or pyridine-3-aldehyde and anchoring of Co(ii) ions into the mesoporous Cr-MOF supports. The Co(ii)@Cr-MIL-101-P2I catalyst exhibited high catalytic performance for epoxidation of olefins with air as an oxidant due to the nitrogen atom in the pyridine ring as a strong electron-withdrawing substituent, high dispersion of Co(ii) species and high surface area for sufficient contact between the substrate and active sites. The strong coordination interaction between the Co(ii) ions and chelating groups in the Co(ii)@Cr-MIL-101-P2I catalyst guaranteed the excellent recycling performance. Furthermore, the synthesized Co(ii)@Cr-MIL-101-P2I catalyst realized its general applicability towards various olefins, such as cyclic olefins, tri-substituted olefins, aliphatic olefins and aromatic olefins.