Category: 112-63-0

Lakouraj, Moslem M.; Ghodrati, Keivan published the artcile< Carboxy pyridinium bromide perbromide reagents. Part I. Selective oxidation of thiols and sulfides>, Electric Literature of 112-63-0, the main research area is thiol selective oxidation pyridinium hydrobromide perbromide oxidant; sulfide selective oxidation pyridinium hydrobromide perbromide oxidant; disulfide preparation; sulfoxide preparation.

Efficient and convenient oxidation of aliphatic and aromatic thiols to disulfides and of sulfides to sulfoxides with pyridinium hydrobromide perbromide (PHBP), nicotinic acid hydrobromide perbromide (NAHBP), and 2,6-dicarboxy pyridinium hydrobromide perbromide (DCPHBP) in a solvent or under solvent free conditions and at ambient temperature is introduced.

Phosphorus, Sulfur and Silicon and the Related Elements published new progress about Disulfides Role: SPN (Synthetic Preparation), PREP (Preparation). 112-63-0 belongs to class esters-buliding-blocks, and the molecular formula is C19H34O2, Electric Literature of 112-63-0.

Referemce:
Ester – Wikipedia,
Ester – an overview | ScienceDirect Topics

Fregeau-Proulx, Lilianne; Lacouture, Aurelie; Berthiaume, Line; Weidmann, Cindy; Harvey, Mario; Gonthier, Kevin; Pelletier, Jean-Francois; Neveu, Bertrand; Jobin, Cynthia; Bastien, Dominic; Bergeron, Alain; Fradet, Yves; Lacombe, Louis; Laverdiere, Isabelle; Atallah, Chantal; Pouliot, Frederic; Audet-Walsh, Etienne published the artcile< Multiple metabolic pathways fuel the truncated tricarboxylic acid cycle of the prostate to sustain constant citrate production and secretion>, Quality Control of 112-63-0, the main research area is citrate anticancer agent tricarboxylic acid cycle secretion prostate cancer; Androgen; Fertility; Organoids; Prostate cancer; TCA cycle.

The prostate is metabolically unique: it produces high levels of citrate for secretion via a truncated tricarboxylic acid (TCA) cycle to maintain male fertility. In prostate cancer (PCa), this phenotype is reprogrammed, making it an interesting therapeutic target. However, how the truncated prostate TCA cycle works is still not completely understood.We optimized targeted metabolomics in mouse and human organoid models in ex vivo primary culture. We then used stable isotope tracer analyses to identify the pathways that fuel citrate synthesis.First, mouse and human organoids were shown to recapitulate the unique citrate-secretory program of the prostate, thus representing a novel model that reproduces this unusual metabolic profile. Using stable isotope tracer anal., several key nutrients were shown to allow the completion of the prostate TCA cycle, revealing a much more complex metabolic profile than originally anticipated. Indeed, along with the known pathway of aspartate replenishing oxaloacetate, glutamine was shown to fuel citrate synthesis through both glutaminolysis and reductive carboxylation in a GLS1-dependent manner. In human organoids, aspartate entered the TCA cycle at the malate entry point, upstream of oxaloacetate. Our results demonstrate that the citrate-secretory phenotype of prostate organoids is supported by the known aspartate-oxaloacetate-citrate pathway, but also by at least three addnl. pathways: glutaminolysis, reductive carboxylation, and aspartate-malate conversion.Our results add a significant new dimension to the prostate citrate-secretory phenotype, with at least four distinct pathways being involved in citrate synthesis. Better understanding this distinctive citrate metabolic program will have applications in both male fertility as well as in the development of novel targeted anti-metabolic therapies for PCa.

Molecular Metabolism published new progress about Androgen receptors Role: BSU (Biological Study, Unclassified), BIOL (Biological Study). 112-63-0 belongs to class esters-buliding-blocks, and the molecular formula is C19H34O2, Quality Control of 112-63-0.

Referemce:
Ester – Wikipedia,
Ester – an overview | ScienceDirect Topics

Zeng, Tengchao; He, Guiping; Li, Xinxiang; Wang, Chaoxia published the artcile< Synthesis of reactive self-adhesive branched polyurethane dispersant for textile pigment printing>, Application In Synthesis of 112-63-0, the main research area is cotton fabric printing polyurethane dispersant.

A series of reactive branched polyurethane dispersants (BPUs) were successfully synthesized based on epoxy as reactive group and nitrogen-containing heterocycles as anchoring group. The branched polyurethane was adopted an ”A2 + B3” approach with diisocyanate prepolymer and trimethylolpropane. The structure, mol. weight, and thermodn. property of BPUs were characterized. The pigment dispersions were prepared with BPUs as the dispersant by ball milling, and then the characteristic parameters such as pigment particle size, viscosity, stability, color properties, and fastness were evaluated. Excellent dispersing performances were observed that the particle size of five dispersions were below 200 nm, with the viscosity as low as 6-9 mPa·s. It is worth noting that the pigment dispersion prepared by BPU exhibited excellent stability and self-adhesive performance. These dispersions were printed on cotton fabrics without adhesives, their water washing fastness was approx. grade 4. And the dry rubbing and wet rubbing fastnesses were 3 and 2-3, resp.

Journal of Applied Polymer Science published new progress about Cotton textiles. 112-63-0 belongs to class esters-buliding-blocks, and the molecular formula is C19H34O2, Application In Synthesis of 112-63-0.

Referemce:
Ester – Wikipedia,
Ester – an overview | ScienceDirect Topics

Lu, Xianghong; Chen, Qianxia; Lu, Jiaqi; Xu, Haoliang; Ji, Jianbing published the artcile< Investigation of reinforced braided hollow fiber membrane containing silver-based butanediol for methyl linolenate separation:Better penetration rate, higher stability>, SDS of cas: 112-63-0, the main research area is hollow fiber composite membrane silver butanediol methyl linolenate separation.

Supported liquid membranes show great potential in the efficient separation of Me linolenate from its analogs, but there still remain some critical challenges to further this technol. towards larger application because of the slow transmembrane transport and poor stability of liquid membrane. Herein, 1,2-butanediol (1,2-BDO) with good solubility for AgBF4 substitutes for ionic liquid as membrane solvent, and fabric reinforced hollow fiber composite membrane (PR-HFM) with higher mech. strength and interfacial area replaces plate membrane as base support. A new supported liquid membrane has been prepared by coating the 1,2-BDO solution dissolving AgBF4 on the surface of PR-HFM and embedding the solution into the micro-pores of PR-HFM by repeated pull with vacuum and push with N2. The as-prepared liquid membranes exhibit good separation performance and stability. It can be safely and steadily used to treat the feed with fatty acid Me esters (FAMEs) concentration < 150 mg/mL at the velocity of less than 0.22 m/s. Within 24 h continuous operation, Me linolenate (C18-3) can pass steadily through the liquid membrane at the mean permeability > 3.13 x 10-7 m/s, the C18-3 product with the purity > 82%, and the selectivity of C18-3 over C18-2 (SC18-3/C18-2) > 6.63 can be obtained steadily.

Journal of Membrane Science published new progress about Coating materials. 112-63-0 belongs to class esters-buliding-blocks, and the molecular formula is C19H34O2, SDS of cas: 112-63-0.

Referemce:
Ester – Wikipedia,
Ester – an overview | ScienceDirect Topics

Kang, Inhan; Kang, Jungwon published the artcile< Direct growth of CuO particles on carbon papers for high-performance rechargeable Li-O2 batteries>, Quality Control of 112-63-0, the main research area is lithium oxygen battery carbon paper copper oxide particle growth.

Lithium-oxygen (Li-O2) batteries are considered as a promising high-energy storage system. However, they suffer from overpotential and low energy efficiency. This study showed that CuO growth on carbon using facile synthesis (simple dipping and heating process) reduces overpotential, thus increasing the energy efficiency. We confirmed the structure of CuO on carbon using X-ray diffraction pattern, XPS, field-emission SEM, and field-emission transmission electron microscopy. The cathode of CuO on carbon shows an average overpotential reduction of ~6% charge/discharge during 10 cycles in nonaqueous Li-O2 batteries. The possible reason for the reduced charge overpotential of the cathode of CuO on carbon is attributed to the formed Li2O2 of smaller particle size during discharging compared to pristine carbon.

Journal of Nanoscience and Nanotechnology published new progress about Air. 112-63-0 belongs to class esters-buliding-blocks, and the molecular formula is C19H34O2, Quality Control of 112-63-0.

Referemce:
Ester – Wikipedia,
Ester – an overview | ScienceDirect Topics

Sonsona, Isaac G.; Vicenzi, Andrea; Guidotti, Marco; Bisag, Giorgiana Denisa; Fochi, Mariafrancesca; Herrera, Raquel P.; Bernardi, Luca published the artcile< Investigation of Squaramide Catalysts in the Aldol Reaction En Route to Funapide>, COA of Formula: C19H34O2, the main research area is funapide squaramide catalyst aldol enantioselective organocatalysis.

Funapide (I) is a 3,3′-spirocyclic oxindole with promising analgesic activity. A reported pilot-plant scale synthesis of this chiral compound involves an asym. aldol reaction, catalyzed by a common bifunctional thiourea structure. In this work, we show that the swapping of the thiourea unit of the catalyst for a tailored squaramide group provides an equally active, but rewardingly more selective, catalyst for this aldol reaction (from 70.5 to 85% ee). The reaction was studied first on a model oxindole compound Then, the set of optimal conditions was applied to the target funapide intermediate. The applicability of these conditions seems limited to oxindoles bearing the 3-substituent of funapide. Exemplifying the characteristics of target-focused methodol. development, this study highlights how a wide-range screening of catalysts and reaction conditions can provide non-negligible improvements in an industrially viable asym. transformation.

European Journal of Organic Chemistry published new progress about Aldol addition catalysts, stereoselective. 112-63-0 belongs to class esters-buliding-blocks, and the molecular formula is C19H34O2, COA of Formula: C19H34O2.

Referemce:
Ester – Wikipedia,
Ester – an overview | ScienceDirect Topics

Samath, Sheik A.; Jeyasubramanian, Kadarkaraithangam; Thambidurai, Subramanian; Kamardeen, Sickandar; Ramalingam, Sutharavalli K. published the artcile< Substitutions of coordinated salicylaldehyde and its Schiff bases>, Reference of 112-63-0, the main research area is cobalt salicylaldehyde Schiff brominating agent reaction; copper salicylaldehyde Schiff brominating agent reaction; salicylaldehyde Schiff cobalt copper brominating agent; bromination cobalt copper salicylaldehyde Schiff; cyano substitution cobalt copper salicylaldehyde Schiff; succinimido substitution cobalt copper salicylaldehyde Schiff.

Several bis/tris-salicylaldehyde, salicylaldimine and salicylethylenediimine chelates of Co(III), Cr(III), Co(II), Ni(II) and Cu(II) readily react with various brominating agents and undergo α-bromo/cyano/succinimido substitution, with or without accompanying Br substitution of the aryl ring. The selectivity of these reactions on the metal-coordinated salicylaldehyde derivatives allows the preparation in 5-80% yield of hitherto unreported specific α-bromo products. Data are presented for several reactions with Co and Cu complexes. The substituted organic compounds could be isolated by demetalation of the chelate products.

Transition Metal Chemistry (Dordrecht, Netherlands) published new progress about Bromination. 112-63-0 belongs to class esters-buliding-blocks, and the molecular formula is C19H34O2, Reference of 112-63-0.

Referemce:
Ester – Wikipedia,
Ester – an overview | ScienceDirect Topics

Chen, Xun; Kuang, Sufang; He, Yi; Li, Hongyu; Yi, Chen; Li, Yiming; Wang, Chao; Chen, Guanhui; Chen, Shangwu; Yu, Dongsheng published the artcile< The Differential Metabolic Response of Oral Squamous Cell Carcinoma Cells and Normal Oral Epithelial Cells to Cisplatin Exposure>, Name: (9Z,12Z)-Methyl octadeca-9,12-dienoate, the main research area is cisplatin anticancer agent drug metabolism oral squamous cell carcinoma; cisplatin exposure; metabolic response; metabolomics; normal oral epithelial cells; oral squamous cell carcinoma cells.

Metabolic reprogramming is one of the hallmarks of a tumor. It not only promotes the development and progression of tumor but also contributes to the resistance of tumor cells to chemotherapeutics. The difference in the metabolism between drug-resistant and sensitive tumor cells indicates that drug-resistant tumor cells have experienced metabolic adaptation. The metabolic response induced by chemotherapy is dynamic, but the early metabolic response of tumor cells to anticancer drugs and the effect of an initial response on the development of drug resistance have not been well studied. Early metabolic intervention may prevent or slow down the development of drug resistance. The differential metabolic responses of normal cells and tumor cells to drugs are unclear. The specific metabolites or metabolic pathways of tumor cells to chemotherapeutic drugs can be used as the target of metabolic intervention in tumor therapy. In this study, we used comparative metabolomics to analyze the differential metabolic responses of oral cancer cells and normal oral epithelial cells to short-term cisplatin exposure, and to identify the marker metabolites of early response in oral cancer cells. Oral cancer cells showed a dynamic metabolic response to cisplatin. Seven and five metabolites were identified as specific response markers to cisplatin exposure in oral cancer cell SCC-9 and normal oral epithelial cell HOEC, resp. Glyoxylate and dicarboxylate metabolism and fructose, malate, serine, alanine, sorbose and glutamate were considered as specific enriched metabolic pathways and biomarkers of SCC-9 cells in response to cisplatin, resp. The existence of differential metabolic responses lays a foundation for tumor chemotherapy combined with metabolic intervention.

Metabolites published new progress about Antitumor agents. 112-63-0 belongs to class esters-buliding-blocks, and the molecular formula is C19H34O2, Name: (9Z,12Z)-Methyl octadeca-9,12-dienoate.

Referemce:
Ester – Wikipedia,
Ester – an overview | ScienceDirect Topics

Li, Dan; Zhu, Changyan; Zhang, Min; Wang, Ying; Kang, Ziye; Liu, Yulong; Liu, Jun; Liu, Jia; Xie, Haiming published the artcile< 1,2-dimethyl-3-propylimidazolium iodide as a multiple-functional redox mediator for Li-O2 batteries: In situ generation of a ""self-defensed"" SEI layer on Li anode>, Related Products of 112-63-0, the main research area is dimethyl propylimidazolium iodide redox mediator lithium oxygen battery anode.

How to develop a homogeneous redox mediator (RM) towards both ORR and OER and how to prevent the shuttle effect are two main issues for Li-O2 batteries thus far. Here, we firstly report 1,2-dimethyl-3-propylimidazolium iodide (DMPII), which serves multiple functions as a RM for discharge capacity promotion, a RM for charge potential reduction, and a Li anode protector for shuttling suppression by in situ generating a “”self-defensed”” SEI layer. Benefiting from these advantages, a cell with DMPII displays a stable cyclability with a low terminal charge potential of ∼3.6 V till the cell death, a considerable rate performance, and a good reversibility associated with Li2O2 formation and degradation Based on the exptl. and d. functional theory (DFT) calculation results, a working mechanism for a cell operation is also proposed. These results represent a promising progress in the development of multiple-functional RM for Li-O2 batteries. Moreover, we expect that this work gives an insight into the in situ protection of Li metal anode for board applications (e.g., Li-S batteries, all-solid-state Li-ion batteries, etc.).

Chemical Engineering Journal (Amsterdam, Netherlands) published new progress about Adsorption. 112-63-0 belongs to class esters-buliding-blocks, and the molecular formula is C19H34O2, Related Products of 112-63-0.

Referemce:
Ester – Wikipedia,
Ester – an overview | ScienceDirect Topics

Shandura, M. P.; Poronik, Ye. M.; Kovtun, Yu. P. published the artcile< New heterocyclic analogues of rhodamines>, Reference of 112-63-0, the main research area is rhodamine heterocyclic analog synthesis fluorescent property; fluorescent quantum yield hetarylpyronine.

Double formylation of 9-methylpyronine yielded the corresponding 9-diformylmethinexanthene which was heterocyclized to furnish 9-hetarylpyronines. The chem. and spectral behavior of the rhodamine analogs thus obtained was studied.

Dyes and Pigments published new progress about Fluorescence. 112-63-0 belongs to class esters-buliding-blocks, and the molecular formula is C19H34O2, Reference of 112-63-0.

Referemce:
Ester – Wikipedia,
Ester – an overview | ScienceDirect Topics