1192-88-7

Usage

Uses

Used in the Chemical Industry:
1-Cyclohexene-1-carboxaldehyde is used as a reactant/reagent for the chemoselective synthesis of aliphatic alcohols via NSS-ruthenium complex-catalyzed hydrogenation of α,β-unsaturated carbonyl compounds. This process allows for the creation of valuable intermediates and products in the chemical synthesis of various compounds.
Used in the Pharmaceutical Industry:
1-Cyclohexene-1-carboxaldehyde may be used in the synthesis of azomethine imines, which are important building blocks in the development of pharmaceutical compounds. These imines can be further modified and utilized in the creation of novel drugs with potential therapeutic applications.
Used in the Synthesis of Benzopyrans:
1-Cyclohexene-1-carboxaldehyde also participates in the synthesis of benzopyrans, a class of organic compounds with diverse biological activities. Benzopyrans have been found to possess various pharmacological properties, making them valuable in the development of new drugs and therapeutic agents.

Synthesis Reference(s)

Journal of the American Chemical Society, 105, p. 7175, 1983 DOI: 10.1021/ja00362a028Tetrahedron Letters, 19, p. 5, 1978 DOI: 10.1016/S0040-4039(01)88967-XChemical and Pharmaceutical Bulletin, 20, p. 309, 1972 DOI: 10.1248/cpb.20.309

InChI:InChI=1/C7H10O/c8-6-7-4-2-1-3-5-7/h4,6H,1-3,5H2

Upstream product

• 4394-85-8 4-morpholinecarboxaldehyde 
• 110-83-8 cyclohexene 
• 15839-23-3 2-(i-propoxymethylene)cyclohexanone 
• 4354-50-1 hexahydro-benzofuran-2,3-dione 
• 15839-65-3 2-(ethoxymethylidene)cyclohexanone 
• 92195-98-7 2-Anilinomethyl-1-cyclohexanol 
• 15839-24-4 2-isobutoxymethylene-cyclohexanone 
• 1193-63-1 Cyclohexanone-2-carbaldehyde 
• 36278-22-5 1-cyclohexenoyl chloride 
• 36929-66-5 1-oxaspiro<2,5>octane-2-carboxylic acid nitrile 
• 21849-30-9 2-benzenesulfinyl-1-oxa-spiro[2.5]octane 
• 34899-90-6 1-bromocyclohexanecarbaldehyde 
• 15839-18-6 2-methoxymethylenecyclohexanone 
• 23865-95-4 exo-7-Methoxynorcaran 

Downstream Products

• 104507-68-8 1-(1-cyclohexen-1-ylmethyl)-1-piperidine 
• 5005-72-1 1-(cyclohexylmethyl)piperidine 
• 56842-96-7 1-(cyclohex-1-enyl)but-3-yn-1-ol 
• 31171-59-2 N,N-dimethyl-1-cyclohexenylmethylamine 
• 93743-28-3 1-(cyclohexen-1-yl)-3-buten-1-ol 
• 6252-18-2 1-(1-methylethenyl)cyclohexene 
• 5471-56-7 2-cyclohex-1-enyl-1-methyl-ethylamine 
• 58371-29-2 2-(Cyclohex-1-enyl-hydroxy-methyl)-acrylic acid methyl ester 
• 41438-10-2 (2Z,4E)-5-Cyclohex-1-enyl-3-methyl-penta-2,4-dienoic acid 
• 68470-83-7 2-Benzenesulfonyl-1,2-di-cyclohex-1-enyl-ethanol 
• 5680-41-1 cis-1-(1-propenyl)cyclohexene 
• 4845-04-9 1-cyclohexene-1-methanol 
• 35811-99-5 1,2-Di-(1-cyclohexenyl)aethylenplycol 
• 68826-56-2 Acetic acid (1R,2R)-2-benzenesulfonyl-1,2-di-cyclohex-1-enyl-ethyl ester 

Relevant academic research and scientific papers

Electrochemically driven desaturation of carbonyl compounds

Electrochemical techniques have long been heralded for their innate sustainability as efficient methods to achieve redox reactions. Carbonyl desaturation, as a fundamental organic oxidation, is an oft-employed transformation to unlock adjacent reactivity through the formal removal of two hydrogen atoms. To date, the most reliable methods to achieve this seemingly trivial reaction rely on transition metals (Pd or Cu) or stoichiometric reagents based on I, Br, Se or S. Here we report an operationally simple pathway to access such structures from enol silanes and phosphates using electrons as the primary reagent. This electrochemically driven desaturation exhibits a broad scope across an array of carbonyl derivatives, is easily scalable (1–100 g) and can be predictably implemented into synthetic pathways using experimentally or computationally derived NMR shifts. Systematic comparisons to state-of-the-art techniques reveal that this method can uniquely desaturate a wide array of carbonyl groups. Mechanistic interrogation suggests a radical-based reaction pathway. [Figure not available: see fulltext.]

Synthesis of aldehydes by a one-carbon homologation of ketones and aldehydes via --α,β-unsaturated isocyanides

Ketones and aldehydes react via a Wittig-Horner-Emmons reaction using diethyl(isocyanomethyl)phosphonate to form α,β-unsaturated isocyanides (4), which are either hydrolyzed as such, under acid conditions, or hydrolyzed after oxidation to α,β-unsaturated isocyanates (6) to give aldehydes containing one additional carbon atom.The scope of the reaction is demonstrated by 20 examples.

2-(N'-alkylidenehydrazino)adenosines: Potent and selective coronary vasodilators

The reaction of aliphatic aldehydes and ketones with 2-hydrazinoadenosine under relatively mild conditions (at room temperature or in refluxing methanol) formed 2-(N'-alkylidenehydrazino)-adenosines, 5-22, in good yields. Two kinds of adenosine receptors regulate cardiac and coronary physiology. In supraventricular tissues an A1AR coupled to muscarinic K channels mediates the negative chronotropic, dromotropic, and inotropic actions of adenosine, and an inhibitory A1AR coupled to adenylate cyclase mediates the 'antiadrenergic' action of adenosine. One or more kinds of A2 receptors mediate coronary vasodilation. Bioassays employing a guinea pig heart Langendorff preparation showed that 5-22 weakly retard impulse conduction through the AV node (negative dromotropic effect), but several analogues were very active coronary vasodilators. The coronary vasoactivity of the (n- alkylidene- and of the (isoalkylidenehydrazino)adenosines paralleled the length of the alkyl chain, the EC50s of the most active n-pentylidene (8) and isopentylidene (18) congeners being 1 nM. The EC50s of the cyclohexylmethylene (9), cyclohexylethylidene (10), and cyclohex-3- enylmethylene (12), analogues were likewise 50s of the negative dromotropic effects of 8, 9, and 18 by 5-28-fold and the EC50s of coronary vasodilation of 22-90-fold. Catalytic reduction of 9 increased the hydrophobicity and changed the UV spectrum, suggesting reduction of the -CH=N- bond. The product darkened on exposure to air and so was not characterized further. A new method for preparing 2',3',5'-tri-O- acetyl-2,6-dichloropurine riboside, a precursor in the synthesis of 2- hydrazinoadenosine, consists of the addition of tert-butyl nitrite to a mixture of 2',3',5'-tri-O-acetyl-6-chloroguanosine and CuCl in CHCl3 saturated with Cl2.

Structure-activity relationships of xanthene carboxamides, novel CCR1 receptor antagonists

The structure-activity relationships of xanthene carboxamide derivatives on the CCR1 receptor binding affinity and the functional antagonist activity were described. Previously, we reported a quaternarized xanthen-9-carboxamide 1 as a potent human CCR1 receptor antagonist that was derived from a xanthen-9-carboxamide lead 2a. Further derivatization of 2a focusing on installing an additional substituent into the xanthene ring resulted in the identification of 2b-1 with IC50 values of 1.8 nM and 13 nM in the binding assay using human CCR1 receptors transfected CHO cells and in the functional assay using U937 cells expressing human CCR1 receptors, respectively.

Pd-Catalyzed Carbonylation of Vinyl Triflates to Afford α,β-Unsaturated Aldehydes, Esters, and Amides under Mild Conditions

An efficient and general protocol for the synthesis of α,β-unsaturated aldehydes, esters, and amides via carbonylation of vinyl triflates including derivatives of camphor, ketoisophorone, verbenone, and pulegone was developed. Crucial for these transformations is the use of a specific palladium catalyst containing a pyridyl-substituted dtbpx-type ligand. This procedure also allows for an easy access of dicarbonylated products from the corresponding ketones.

Ring Expansion, Ring Contraction, and Annulation Reactions of Allylic Phosphonates under Oxidative Cleavage Conditions

Oxidative cleavage of cycloalkenylalkylphosphonates 1 followed by treatment with base gives rise to homologated cycloalkenones 2 in good to excellent yields. Subjecting cycloalk-2-enylphosphonates 3 to identical conditions provides the one-carbon ring-contracted compounds 4 in excellent yields. Oxidative cleavage of γ,δ-unsaturated ketophosphonates 6 followed by treatment with base affords 2-cyclopenten-1-ones 7 in good overall yields. This method may offer a practical alternative to existing methods for effecting one-carbon ring expansion, ring contraction, and annulation reactions.

Dehydrogenative Synthesis of Linear α,β-Unsaturated Aldehydes with Oxygen at Room Temperature Enabled by tBuONO

Synthesis of linear α,β-unsaturated aldehydes via a room-temperature oxidative dehydrogenation has been realized by the cocatalysis of an organic nitrite and palladium with molecular oxygen as the sole clean oxidant. Linear α,β-unsaturated aldehydes could be efficiently prepared under aerobic catalytic conditions directly from the corresponding saturated linear aldehydes. Besides linear products, the aromatic analogy could also be smoothly achieved by the same standard method. The organic nitrite redox cocatalyst and alcohol solvent play a key role for realizing this method.

Efficient Access to All-Carbon Quaternary and Tertiary α-Functionalized Homoallyl-type Aldehydes from Ketones

β,γ-Unsaturated aldehydes with all-carbon quaternary or tertiary α-centers were rapidly assembled from ketones through a unique synthetic operation consisting of 1) C1 homologation, 2) Lewis acid mediated epoxide–aldehyde isomerization, and 3) electrophilic trapping. The synthetic equivalence of a vinyl oxirane and a β,γ-unsaturated aldehyde is the key concept of this previously undisclosed tactic. Mechanistic studies and labeling experiments suggest that an aldehyde enolate is a crucial intermediate. The homologating carbenoid formation plays a critical role in determining the chemoselectivity.

COMPOUNDS AND METHODS OF TREATING OCULAR DISORDERS

A method of treating an ocular disorder in a subject associated with increased all-trans-retinal in an ocular tissue includes administering to the subject a therapeutically effective amount of a primary amine compound of formula (I); and pharmaceutically acceptable salts thereof.

Two-Component Assembly of Thiochroman-4-ones and Tetrahydrothiopyran-4-ones Using a Rhodium-Catalyzed Alkyne Hydroacylation/Thio-Conjugate-Addition Sequence

β′-Thio-substituted-enones, assembled from the combination of β-tert-butylthio-substituted aldehydes and alkynes, using rhodium catalysis, are shown to smoothly undergo in situ intramolecular S-conjugate addition to deliver a range of S-heterocycles in a one-pot process. Aryl, alkenyl, and alkyl aldehydes can all be employed, to provide thiochroman-4-ones, hexahydro-4H-thiochromen-4-ones, and tetrahydrothiopyran-4-ones, respectively. A variety of in situ oxidations are also performed, allowing access to S,S-dioxide derivatives, as well as unsaturated variants.