Category: 112-63-0

Alsowayigh, Marwah M.; Timco, Grigore A.; Borilovic, Ivana; Alanazi, Abdulaziz; Vitorica-yrezabal, Inigo J.; Whitehead, George F. S.; McNaughter, Paul D.; Tuna, Floriana; O’Brien, Paul; Winpenny, Richard E. P.; Lewis, David J.; Collison, David published the artcile< Heterometallic 3d-4f Complexes as Air-Stable Molecular Precursors in Low Temperature Syntheses of Stoichiometric Rare-Earth Orthoferrite Powders>, Application In Synthesis of 112-63-0, the main research area is heterometallic lanthanum gadolinium orthoferrite preparation crystal mol structure thermolysis.

Four 3d-4f heteropolymetallic complexes [Fe2Ln2((OCH2)3CR)2(O2CtBu)6(H2O)4] (where Ln = La (1 and 2) and Gd (3 and 4); and R = Me (1 and 3) and Et (2 and 4)) are synthesized and analyzed using elemental anal., Fourier transform IR spectroscopy (FT-IR), thermogravimetric anal. (TGA) and SQUID magnetometry. Crystal structures are obtained for both Me derivatives and show that the complexes are isostructural and adopt a defective dicubane topol. The four heavy metals are connected with two alkoxide bridges. These four precursors are used as single-source precursors to prepare rare-earth orthoferrite pervoskites of the form LnFeO3. Thermal decomposition in a ceramic boat in a tube furnace gives orthorhombic LnFeO3 powders using optimized temperatures and decomposition times: LaFeO3 formed at 650° over 30 min, whereas GdFeO3 formed at 750° over 18 h. These materials are structurally characterized using powder x-ray diffraction, Raman spectroscopy, SEM, energy-dispersive x-ray map spectroscopy, and SQUID magnetometry. EDX spectroscopy mapping reveals a homogeneous spatial distribution of elements for all four materials consistent with LnFeO3. Magnetic measurements on complexes 1-4 confirms the presence of weak antiferromagnetic coupling between the central Fe(III) ions of the clusters and negligible ferromagnetic interaction with peripheral Gd(III) ions in 3 and 4. Zero field cooled (ZFC) and field-cooled (FC) measurements of magnetization of LaFeO3 and GdFeO3 in the solid state suggests that both materials are ferromagnetic, and both materials show open magnetic hysteresis loops at 5 and 300 K, with Msat higher than previously reported for these as nanomaterials. We conclude that this is a new and facile low temperature route to these important magnetic materials that is potentially universal limited only by what metals can be programmed into the precursor complexes. Novel heterometallic 3d-4f complexes are reported, and their use as air stable mol. precursors for the synthesis of solid state rare earth orthoferrites (LnFeO3) is explored.

Inorganic Chemistry published new progress about Antiferromagnetic exchange. 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

Brunel, Jeremie; Ledoux, Isabelle; Zyss, Joseph; Blanchard-Desce, Mireille published the artcile< Propeller-shaped molecules with giant off-resonance optical nonlinearities>, Category: esters-buliding-blocks, the main research area is nonlinear optical triphenylbenzene crux preparation.

Propeller-shaped mols. based on a triphenylbenzene crux bearing three oligomeric phenylenevinylene branches were designed. Very large first-order hyperpolarizabilities (up to ‖β‖ = 800 10-30 esu) were obtained while maintaining wide transparency in the visible region by taking advantage and boosting of intramol. charge transfer between the center and the periphery.

Chemical Communications (Cambridge, United Kingdom) published new progress about Nonlinear optical materials. 112-63-0 belongs to class esters-buliding-blocks, and the molecular formula is C19H34O2, Category: esters-buliding-blocks.

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

Tietze, Ernst; Bayer, Otto published the artcile< Sulfonic acids of pyrene and their derivatives>, Application In Synthesis of 112-63-0, the main research area is .

Pyrene (I) in 6 parts C2Cl4, cooled to 0°, treated with the calculated quantity of ClSO3H in C2Cl4 at 0-5° and stirred 15-20 h. at 10-20°, decomposed with ice-H2O, the C2Cl4 removed by distillation in vacuo, the solution filtered hot and treated with a hot solution of the calculated quantity of Na2SO4, gives 90-2% of Na pyrene-3-sulfonate (II). II (61 g.) in 500 cc. AcOH and 17.5 g. of 80% HNO3, mixed and stirred 12 h. at 15-25°, give a NO2 compound, which is reduced by Fe in AcOH to an NH2 derivative (41 g.), yellow powder, whose aqueous solution shows an intense blue fluorescence; the solution is easily diazotized and couples with R salt to a dull-violet dye. Addition of 202 g. of I to 500 g. H2SO4 (66° Bé) at 0° during 1 h. and allowing the mixture to stand 2 days at 15° give 45 g. I and after addition of NaCl 130 g. III; II (61 g.), added during 30 min. to 400 g. H2SO4 (66°Bé.) at 5-10° and stirred 1 h., gives 42% of di-Na pyrene-3,8-disulfonate (III), yellow powder soluble in H2O with a violet fluorescence. Heating 15 g. III with 38 g. KOH and 115 g. H2O for 6 h. at 260° (internal temperature) and 40 atm. gives 6 g. 3,8-dihydroxypyrene, which is sensitive to the air and was characterized as the di-Ac derivative, m. 222-4°. The mother liquor from III, treated with CaCO3, gives 7 g. of Ca pyrene-3,5-disulfonate (IIIA), the aqueous solution of which shows a pale blue fluorescence; this acid differs from the 3,8-isomer in the much greater solubility of the Na and Ca salts. II (76 g.) in 550 g. H2SO4.H2O at 5-10°, stirred 1 day at 15° poured onto ice, the H2SO4 removed by CaCO3 and neutralized with K2CO3, gives 12-15 g. of di-K mono-Na pyrene-3,5,8-trisulfonate, thick yellow prisms, which shows a strong violet fluorescence in aqueous solution When 924 g. of II are quickly added to 2600 g. H2SO4.H2O at 15-20° and, after cooling, treated with 2400 g. of 65% oleum at 20° and the mixture is stirred for 15 h. at 20°, the H2SO4 removed with CaCO3, the filtrate concentrated to 101., neutralized and treated with 20% NaCl, there results 80% of tetra-Na pyrene-3,5,8,10-tetrasulfonate (IV), a yellow powder; IV can be precipitated directly by addition of NaCl but the yield is lower. IV also results in 70% yield by adding 202 g. I to a mixture of 1300 g. H2SO4.H2O and 300 g. Na2SO4 at 58°, stirring 15 min., cooling to 50-5° and adding 800 g. of 65% oleum during 20 min. NaClO3 and HCl give the known 3,5,8,10-tetrachloropyrene, thus establishing the structure of IV. Refluxing 488 g. IV with 280 g. com. NaOH in 1400 cc. H2O for 18 h., adding 400 cc. com. HCl and neutralizing with HCO2H give on addition of 10% NaCl 340 g. of tri-Na 3-hydroxypyrene-5,8,10-trisulfonate (V), with 1 mol H2O, yellow needles. Heating 61 g. of IV with 610 cc. 22% NH4OH for 18 h. at 200-10° gives 22% of the 3-NH2 analog of V, greenish yellow prisms; the slightly acid solution shows an intense green fluorescence; the NH2 group may be diazotized. 3-Chloropyrene (24 g.) in 130 g. H2SO4.H2O and 30 g. Na2SO4, treated at 50-60° with 80 g. of 65% oleum, gives 41 g. of tri-Na 3-chloropyrene-5,8,10-trisulfonate; the Cl in this salt could not be replaced by NH2 by heating with NH4OH in an autoclave. Addition of 732 g. IV to a melt of 720 g. com. NaOH in 450 cc. H2O at 130° and heating 30 min. at 155°, 20 min. at 165° and 5 min. at 170° give 90% of di-Na 3,5-dihydroxypyrene-8,10-disulfonate (VI), yellow, which shows a green fluorescence in H2O. VI (219 g.) and 2.2 l. 10% H2SO4, heated 12 h. at 140-50°, give 90% (crude) of 3,5-dihydroxypyrene (VII) which, crystallized from AcOH, m. 220° (decomposition) and darkens in the air; di-Ac derivative, m. 154-5°; di-Me ether, m. 177-8°. IV (61 g.) in 450 cc. H2O and 37.5 g. 33% NaOH with 7 g. Zn dust, boiled 7 h., give 29-30 g. of di-Na pyrene-3,5-disulfonate (VIII), which may be purified through IIIA. VIII (40.6 g.) and 110 g. NaOH in 300 cc. H2O, heated 8 h. at 210-20°, give 22 g. of Na 3-hydroxypyrene-5-sulfonate, yellow, the aqueous solution of which shows a strong bluish green fluorescence. Heating VIII with NaOH at 250-60° for 15 h. gives VII. VIII (40.6 g.) and HNO3-H2SO4 at 18° for 20 h. give a 3,5-di-NO2 derivative, which is very soluble in H2O and is reduced to a di-NH2 derivative (27 g.). IV (366 g.) and 360 g. NaOH in 1080 g. H2O, heated 12 h. at 240-50°, give 32% of 3,5,8,10-tetrahydroxypyrene (IX), m. 236-8°; the aqueous solution shows a blue fluorescence; the concentrated H2SO4 solution is yellow with a green fluorescence; IX does not couple with diazo solutions Oxidation of IX with CrO2 gives a black powder. Tetra-Me ether of IX, pale brown, m. 172-3°; it could not be nitrated. Some of these compounds are dyes and the behavior with fabrics is given.

Justus Liebigs Annalen der Chemie published new progress about Dyes. 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

Dolenc, Darko; Plesnicar, Bozo published the artcile< Abstraction of Iodine from Aromatic Iodides by Alkyl Radicals: Steric and Electronic Effects>, Application of C19H34O2, the main research area is steric electronic effect abstraction iodine aromatic iodides alkyl radical; crystallog aromatic iodide.

Abstraction of the iodine atom from aryl iodides by alkyl radicals takes place in some cases very efficiently despite the unfavorable difference in bond dissociation energies of C-I bonds in alkyl and aryl iodides. The abstraction is most efficient in iodobenzenes, ortho-substituted with bulky groups. The ease of abstraction can be explained by the release of steric strain during the elimination of the iodine atom. The rate of abstraction correlates fairly well with the strain energy, calculated by d. functional theory (DFT) and Hartree-Fock (HF) methods as a difference in the total energy of ortho and para isomers. However, besides the steric bulk, the presence of some other functional groups in an ortho substituent also influences the rate. The stabilization of the transition state, resembling a 9-I-2 iodanyl radical, by electron-withdrawing groups seems to explain a pos. sign of the Hammett ρ value in the radical abstraction of halogen atoms.

Journal of Organic Chemistry published new progress about Abstraction reaction (iodine). 112-63-0 belongs to class esters-buliding-blocks, and the molecular formula is C19H34O2, Application of C19H34O2.

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

Trowbridge, P. F.; Diehl, O. C. published the artcile< Halides and perhalides of pyridine>, SDS of cas: 112-63-0, the main research area is .

The range of formation with the periodides is great, C6H5N. HI.I to C5H5N.HI.I6, with the perbromides slight, and zero with the perchlorides. With the normal perhalides, increase in halogen lowers the melting point. With the normal halide, the hydrogen halide melts highest, the methyl halide lower, and the ethyl halide lowest. In the mixed perhalides, the power of displacement and the position of the halogen atoms in the molecule are points of great interest. Iodine in excess displaces bromine and chlorine completely, forming periodides from the normal bromides and chlorides. Bromine seems to displace iodine from the pyridine normal iodides and then combines with it to form a bromoiodide of a normal bromide. Bromine, on the other hand, displaces chlorine completely forming perbromides from the normal chlorides. Chlorine seems to displace both iodine and bromine at first to form normal chlorides, then it combines with the displaced halogen to form mixed perhalides, ICl, ICl3, BrCl, BrCl3, of the normal chlorides from C5H5N.HI and Cl2.

Journal of the American Chemical Society published new progress about Analysis (qual. test). 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

Nack, Tobias; Dinis de Oliveira, Thiago; Weber, Stefan; Schols, Dominique; Balzarini, Jan; Meier, Chris published the artcile< γ-Ketobenzyl-Modified Nucleoside Triphosphate Prodrugs as Potential Antivirals>, Recommanded Product: (9Z,12Z)-Methyl octadeca-9,12-dienoate, the main research area is antiviral nucleoside triphosphate prodrugs d4TTP HIV delivery.

The antiviral activity of nucleoside reverse transcriptase inhibitors is often hampered by insufficient phosphorylation. Nucleoside triphosphate analogs are presented, in which the γ-phosphate was covalently modified by a non-bioreversible, lipophilic 4-alkylketobenzyl moiety. Interestingly, primer extension assays using human immunodeficiency virus reverse transcriptase (HIV-RT) and three DNA-polymerases showed a high selectivity of these γ-modified nucleoside triphosphates to act as substrates for HIV-RT, while they proved to be nonsubstrates for DNA-polymerases α, β, and γ. In contrast to d4TTP, the γ-modified d4TTPs showed a high resistance toward dephosphorylation in cell extracts A series of acyloxybenzyl-prodrugs of these γ-ketobenzyl nucleoside triphosphates was prepared The aim was the intracellular delivery of a stable γ-modified nucleoside triphosphate to increase the selectivity of such compounds to act in infected vs. noninfected cells. Delivery of γ-ketobenzyl-d4TTPs was proven in T-lymphocyte cell extracts The prodrugs were potent inhibitors of HIV-1/2 in cultures of infected CEM/0 cells and more importantly in thymidine kinase-deficient CD4+ T-cells.

Journal of Medicinal Chemistry published new progress about Antiviral agents. 112-63-0 belongs to class esters-buliding-blocks, and the molecular formula is C19H34O2, Recommanded Product: (9Z,12Z)-Methyl octadeca-9,12-dienoate.

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

Wu, Jingjing; Zhang, Dongmei; Hu, Linlin; Zheng, Xiaowei; Chen, Caihong published the artcile< Paeoniflorin alleviates NG-nitro-L-arginine methyl ester (L-NAME)-induced gestational hypertension and upregulates silent information regulator 2 related enzyme 1 (SIRT1) to reduce H2O2-induced endothelial cell damage>, HPLC of Formula: 112-63-0, the main research area is gestational hypertension SIRT1 paeoniflorin endothelium cell injury; Paeoniflorin; SIRT1; pregnancy hypertension; vascular endothelial cell dysfunction.

Pregnancy-induced hypertension (PIH) is a leading cause of maternal mortality. Paeoniflorin has been reported to alleviate hypertension, thus relieving the injury of target organ. This study aimed to investigate the role of paeoniflorin in PIH development by regulating SIRT1 in rats. The mean arterial pressure (MAP), urine protein and histopathol. damage of placenta in gestational hypertension rats were, resp., detected by noninvasive tail-artery pressure measuring instrument, BCA method and H&E staining. The viability of human umbilical vein endothelial cells (HUVECs) treated with paeoniflorin or/and H2O2 was observed by CCK-8 assay. SIRT1 protein expression in HUVECs treated with paeoniflorin or/and H2O2 was analyzed by Western blot. Tunel assay, wound healing assay and tube formation assay were used to detect the apoptosis, migration and tube formation of HUVECs administrated with paeoniflorin or/and H2O2 or/and EX527 (SIRT1 inhibitor). As a result, MAP, urine protein and histopathol. damage of placenta were enhanced in PIH rats, which were then alleviated by paeoniflorin. Paeoniflorin decreased the levels of sFlt-1, PlGF and VEGF in serum and placental tissues of gestational hypertension rats as well as the inflammatory response and oxidative stress. In addition, paeoniflorin promoted the expressions of SIRT1 and NO/eNOS and inhibited the production of iNOS in gestational hypertension rats to improve vascular endothelial cell injury. However, SIRT1 inhibition could suppress the protective effects of paeoniflorin on endothelial dysfunction of H2O2-induced HUVECs. In conclusion, paeoniflorin could improve gestational hypertension development by upregulating SIRT1.

Bioengineered published new progress about Cell injury. 112-63-0 belongs to class esters-buliding-blocks, and the molecular formula is C19H34O2, HPLC of Formula: 112-63-0.

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

Ge, Yang; Yang, Haijun; Wang, Changyuan; Meng, Qiang; Li, Lei; Sun, Huijun; Zhen, Yuhong; Liu, Kexin; Li, Yanxia; Ma, Xiaodong published the artcile< Design and synthesis of phosphoryl-substituted diphenylpyrimidines (Pho-DPPYs) as potent Bruton's tyrosine kinase (BTK) inhibitors: Targeted treatment of B lymphoblastic leukemia cell lines>, Quality Control of 112-63-0, the main research area is preparation phosphoryl derivative diphenylpyrimidine Bruton’s kinase inhibitor leukemia; BTK; DPPY; Inhibitor; Leukemia; Phosphoryl.

A family of phosphoryl-substituted diphenylpyrimidine derivatives (Pho-DPPYs) were synthesized and biol. evaluated as potent BTK inhibitors in this study. Compound 7b was found to markedly inhibit BTK activity at concentrations of 0.82 nmol/L, as well as to suppress the proliferations of B-cell leukemia cell lines (Ramos and Raji) expressing high levels of BTK at concentrations of 3.17 μM and 6.69 μM. Moreover, flow cytometry anal. results further indicated that 7b promoted cell apoptosis to a substantial degree. In a word, compound 7b is a promising BTK inhibitor for the treatment of B-cell lymphoblastic leukemia.

Bioorganic & Medicinal Chemistry published new progress about Antitumor agents. 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

Huertas, Raul; William Allwood, J.; Hancock, Robert D.; Stewart, Derek published the artcile< Iron and zinc bioavailability in common bean (Phaseolus vulgaris) is dependent on chemical composition and cooking method>, Application of C19H34O2, the main research area is Phaseolus genotyoe iron zinc bioavailability cooking biofortification; Bioavailability; Common bean; Domestic processing; In vitro digestion; Iron; Phaseolus vulgaris; Zinc.

The influence of genotype and domestic processing on iron and zinc bioavailability in common bean germplasm was investigated using an in vitro digestion model. Raw beans exhibited diversity in iron content (50 to >90 mg kg-1) although zinc content was similar (30-40 mg kg-1). Following preparation by different household cooking methods < 5% of the iron in raw beans was recovered in the bioavailable fraction following in vitro digestion. However, up to 20% of zinc present in dry seeds was bioavailable. A high proportion of iron and zinc in raw beans (up to 40%) was lost by leaching into cooking water when beans were prepared by boiling. Although untargeted LC/MS revealed genotype-dependent differences in grain chem., correlations between mineral bioavailability and antinutritional phytates and polyphenols were mostly insignificant. Our data highlight the need to consider losses during domestic processing and the related physicochem. traits in biofortification programs. Food Chemistry published new progress about Aldaric acids Role: BSU (Biological Study, Unclassified), BIOL (Biological Study). 112-63-0 belongs to class esters-buliding-blocks, and the molecular formula is C19H34O2, Application of C19H34O2.

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

Nurhayati; Saputra, L.; Awaluddin, A.; Kurniawan, E. published the artcile< Converting waste cooking oil to biodiesel catalyzed by NaOH-impregnated CaO derived from cockle shell (Anadara granosa)>, Quality Control of 112-63-0, the main research area is sodium hydroxide calcium oxide biodeisel waste cooking oil transesterification.

Herein, we developed an efficient and easily separable Na/CaO catalyst derived from cockle shell (Anadara granosa) for biodiesel production from waste cooking oil. Impregnation with 3 wt % of NaOH could enhance the sp. surface area and catalytic performance (>89% biodiesel yield). The effects of calcination temperature, reaction time, and stirring speed were also carefully studied. The quality of biodiesel obtained using this method mainly fulfills the requirements for biodiesel standard (ASTM D 6751).

Kinetics and Catalysis published new progress about Adsorption. 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