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In some applications, this compound(3685-23-2)Reference of cis-4-Aminocyclohexane carboxylic acid is unique.If you want to know more details about this compound, you can contact with the author or consult more relevant literature.

Zhang, Liyuan; Yu, Runzhong; Yu, Yingbo published the article 《Analysis of metabolites and metabolic mechanism in Bt transgenic and non-transgenic maize》. Keywords: metabolite metabolic mechanism Bt transgenic maize.They researched the compound: cis-4-Aminocyclohexane carboxylic acid( cas:3685-23-2 ).Reference of cis-4-Aminocyclohexane carboxylic acid. Aromatic heterocyclic compounds can be divided into two categories: single heterocyclic and fused heterocyclic. In addition, there is a lot of other information about this compound (cas:3685-23-2) here.

The gas chromatog.-mass spectrometry was used to isolate and identify metabolites of non-transgenic and Bacillus thuringiensis transgenic maize. The non-targeted metabolomics technique was used to anal. the metabolic pathway and mechanism of two kinds of maize. The methanol was used as extractant and the N,O-bis(trimethylsilyl) trifluoroacetamide was used as derivatization reagent. 38 kinds of metabolites were isolated and identified from non-transgenic maize, and 61 kinds of metabolites were isolated and identified in Bacillus thuringiensis transgenic maize. The specific metabolites between non-transgenic and Bacillus thuringiensis transgenic maize were analyzed. The metabolic pathway of specific metabolites was analyzed by KEGG annotation. The metabolic mechanism of non-transgenic maize and Bacillus thuringiensis transgenic maize was explored. The result indicated there were more metabolites involved in metabolic pathways in Bacillus thuringiensis transgenic maize than in non-transgenic maize, and tricarboxylic acid cycle and energy metabolism pathways of Bacillus thuringiensis transgenic maize are found to be higher than that of non-transgenic maize. The metabolic pathway of Bacillus thuringiensis transgenic maize conforms to the biol. activity law.

In some applications, this compound(3685-23-2)Reference of cis-4-Aminocyclohexane carboxylic acid is unique.If you want to know more details about this compound, you can contact with the author or consult more relevant literature.

Reference:
Synthesis and Crystal Structure of a Chiral C3-Symmetric Oxygen Tripodal Ligand and Its Applications to Asymmetric Catalysis,
Chiral lanthanide(III) complexes of sulphur–nitrogen–oxygen ligand derived from aminothiourea and sodium D-camphor-β-sulfonate

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The reaction of an aromatic heterocycle with a proton is called a protonation. One of articles about this theory is 《Practical synthesis of thieno[3,2-b]pyrrole》. Authors are Matteson, Donald S.; Snyder, H. S..The article about the compound:3-Methyl-1H-pyrrolecas:616-43-3,SMILESS:CC1=CNC=C1).Electric Literature of C5H7N. Through the article, more information about this compound (cas:616-43-3) is conveyed.

cf. C.A. 51, 16422a. KCNS(200 g.) in 250 ml. MeOH at -75° (Dry Ice-Me2CO bath) stirred with dropwise addition of 159.6 g. Br in 125 ml. MeOH at -75° and the mixture kept below -60°, the thiocyanogen solution cooled to -75° and treated rapidly with 67.1 g. redistilled pyrrole in 250 ml. MeOH at -75° and the mixture stirred (with cooling bath removed) until the temperature rose to -25°, poured onto 2 kg. crushed ice and stirred with 300 g. NaCl, filtered through a 5-6-in. Buchner funnel and the ice and solids washed freely with H2O, the crude 3-thiocyanopyrrole (I) dried in vacuo and clarified in 100 ml. CH2Cl2 and 500 ml. methylcyclohexane (MgSO4 and Darco) at 40°, the colorless solution chilled and seeded, kept 17 hrs. at 0°, and chilled to -20° gave 62 g. I, m. 40-4°, infrared spectrum identical with that of I prepared from Cu(CNS)2 and pyrrole. I stains the skin deep red and may cause burning or itching sensations. The use of rubber gloves is mandatory and contacted areas should be washed immediately with soap and H2O and treated with 3% H2O2. Pyrrole (0.71 g.) in 75 ml. MeOH stirred at 0-5° (N atm.) with portionwise addition of 0.2 mole Cu(CNS)2 [on basis of (NCS)2 analysis] in a few min. and stirring continued 50 min. at 0-5°, the mixture filtered and the CuCNS washed with 50 ml. MeOH, the filtrate and washings poured onto 300 g. crushed ice and 100 g. NaCl added, the mixture filtered and the solids extracted with 225 ml. methylcyclohexane, the solution treated with Darco and cooled, seeded, and kept 17 hrs. at 0° gave 5.83 g. I, m. 41.5-43° (methylcyclohexane). As a route to 3-(alkylthio)pyrroles, attempts to isolate 3-mercaptopyrrole (II), 3-RSC4H4N (R = H) (IIa), were made but abandoned when a more promising way was found. Mg (1.87 g.) in 125 ml. MeOH (N atm.) at -20° kept 1 hr. with 6.2 g. I and the mixture poured into 500 ml. H2O, 200 ml. Et2O, and sufficient solid CO2 to dissolve the precipitated Mg(OH)2, the aqueous phase extracted with Et2O and the dried Et2O solutions evaporated in vacuo, the residue sublimed at 75°/0.1 mm. and the product (6.8 g.) recrystallized from PhMe, resublimed, recrystallized from dilute MeOH, and resublimed at 55-65°/0.1 mm. gave S-3-pyrrolyl O-Me thioimidocarbonate, II [R = C(:NH)OMe], m. 77-80°. I(6.21 g.) and 8.5 g. MeI in 50 ml. MeOH at -20° (N atm.) stirred with dropwise addition in 10 min. of 7.9 g. 85% KOH in 20 ml. H2O and 20 ml. MeOH and stirring continued 1.5 hrs. without cooling, the excess alkali neutralized with solid CO2 and the mixture poured into 500 ml. H2O containing 100 g. NaCl, the mixture extracted 3 times with 50 ml. CH2Cl2 and the dried solution (K2CO3) evaporated in vacuo, the residue distilled, and the product (5.1 g.) redistilled gave II (R = Me) (IIb), b12-13 88-9°. The excellent (90%) yield of IIb showed that the extremely unstable anion of IIa exists long enough to displace halide ions from a moderately active alkyl halide. I (62.1 g.) and 83.5 g. BrCH2CO2H in 500 ml. MeOH at -50° stirred rapidly with addition of 123 g. 85% KOH in 500 ml. 50% dilute MeOH in 10 min. and stirring continued 2 hrs. without cooling, the mixture brought to pH 8 with solid CO2 and the solvent evaporated in vacuo (warm H2O bath to avoid bumping), the solid residue taken up in 500 ml. CH2Cl2 and the mixture stirred with controlled addition of 375 ml. ice-cold 4N HCl, the aqueous phase extracted twice with 250 ml. CH2Cl2 and the combined dried CH2Cl2 solutions treated with Darco and filtered, the filtrate saturated with excess dry NH3, and filtered gave 78 g. II (R = CH2CO2NH4) (IIc), m. 127-33°, purified by treatment of IIc with N HCl and extraction with CH2Cl2, dehydration over MgSO4, and crystallization by treatment with anhydrous NH3 to give IIc, m. 125-33°; Ca salt-2H2O, m. 112-20° (decomposition). IIc in MeOH refluxed 20 hrs. with ZnCl2 and the product purified by extraction followed by distillation in a sublimation apparatus at 80°/0.1 mm. gave the liquid ester II (R = CH2CO2Me). BrCH2CH(OEt)2 failed to react with I under the above conditions and active alkyl halides such as PhCOCH2Br, BrCH2CO2Et, and ClCH2COCO2H appeared to be attacked by OH- more rapidly than was I and also failed to give sulfides. IIc (17.42 g.) and 250 ml. CH2Cl2 shaken with 30 ml. ice-cold 6N HCl and the aqueous phase extracted twice with 250 ml. CH2Cl2, the combined CH2Cl2 extracts dried (MgSO4) and treated with Darco, filtered and the filtrates combined with the 150 ml. CH2Cl2 washings of the Mg2SO4, the CH2Cl2 solution added dropwise in 50 min. to the most vigorously agitated region of 400 g. well-stirred polyphosphoric acid at 120-3° with free vaporization of the CH2Cl2, the mixture cooled below 100° and added slowly with stirring to 1200 ml. H2O and 750 ml. EtOAc, the stirring continued 30 min. and the aqueous layer extracted with 250 ml. EtOAc, the aqueous layer saturated with 300 g. NaCl and extracted twice with 250 ml. EtOAc, the emulsion layer neutralized with Na2CO3 and warmed on a steam bath prior to a 3-fold extraction with 100 ml. portions of EtOAc, the combined EtOAc solutions washed with aqueous NaHCO3 and dried over MgSO4, evaporated in vacuo, and the residue sublimed twice at 120°/0.1 mm. gave 5.0 g. product, m. 183-8.5°, purified by sublimation twice, recrystallization twice from aqueous HCONMe2 and sublimation twice, treatment with Darco, and recrystallization from MeOH to give 2H,3H-thieno[3,2-b]pyrrol-3-one (III), m. 187-90°, λ 330, 303 (min.), 279, 236 (min.) mμ (ε 7400, 3900, 16,000, 500, 95% alc.), ν 3140, 1635 cm.-1 (Nujol). III (0.28 g.) in 35 ml. 95% alc. refluxed 1 hr. with 2.5 g. Raney Ni (W6) and the solution filtered, the residue washed with alc. and the alc. solutions evaporated in vacuo, the residue sublimed, and the product (0.06 g.) recrystallized from H2O gave 23 mg. 2-acetylpyrrole, m. 89-91°, identical with that prepared from C4H4NMgBr and AcCl. III (1.39 g.) and 1.5 g. NaBH4 in 50 ml. MeOH refluxed 16 hrs. under N and the mixture poured into 200 ml. 15% aqueous NaCl, extracted 3 times with 50 ml. CH2Cl2 and the dried extract evaporated, the residue sublimed at 6070°/0.1 mm., and the 0.76 g. product recrystallized from Et2O-C5H12 at -70° and resublimed 3 times gave thieno[3,2-b]pyrrole, m. 25-8°, λ 260, 233 (min.) mμ (ε 11,800, 4900, 95% alc.), infrared spectrum and that of a less pure sample synthesized from thiophene (cf. Snyder, et al., C.A. 51, 13846b) given.

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Reference:
Synthesis and Crystal Structure of a Chiral C3-Symmetric Oxygen Tripodal Ligand and Its Applications to Asymmetric Catalysis,
Chiral lanthanide(III) complexes of sulphur–nitrogen–oxygen ligand derived from aminothiourea and sodium D-camphor-β-sulfonate

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Computed Properties of C7H13NO2. So far, in addition to halogen atoms, other non-metallic atoms can become part of the aromatic heterocycle, and the target ring system is still aromatic. Compound: cis-4-Aminocyclohexane carboxylic acid, is researched, Molecular C7H13NO2, CAS is 3685-23-2, about Synthesis of di- and tripeptides containing 4-aminocyclohexanecarboxylic acid.

Amino acid derivatives were coupled to cis- and trans-4-aminocyclohexanecarboxylic acid with diethylphosphoryl cyanide as coupling reagent. Treatment of trans-I (R = Me3CO2C, R1 = OH) with diethylphosphoryl cyanide, followed by condensation with L-valine Me ester gave trans I (R = Me3CO2C, R1 = Val-OMe) (II). Deprotection and coupling of II with N-tert-butoxycarbonyl-L-alanine gave trans-I (R = Me3CO2C-Ala-, R1 = Val-OMe). Similar transformations were effected with cis-I (R = Me3CO2C, R1 = OH). Other coupling procedures investigated were the carbodiimide, p-nitrophenyl active ester, and sym. anhydride methods, which were less satisfactory for coupling to cyclohexane amino acids.

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Reference:
Synthesis and Crystal Structure of a Chiral C3-Symmetric Oxygen Tripodal Ligand and Its Applications to Asymmetric Catalysis,
Chiral lanthanide(III) complexes of sulphur–nitrogen–oxygen ligand derived from aminothiourea and sodium D-camphor-β-sulfonate

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Application of 3685-23-2. Aromatic heterocyclic compounds can also be classified according to the number of heteroatoms contained in the heterocycle: single heteroatom, two heteroatoms, three heteroatoms and four heteroatoms. Compound: cis-4-Aminocyclohexane carboxylic acid, is researched, Molecular C7H13NO2, CAS is 3685-23-2, about Synthesis of di- and tripeptides containing 4-aminocyclohexanecarboxylic acid. Author is Chen, Wen-Yih; Olsen, Richard K..

Amino acid derivatives were coupled to cis- and trans-4-aminocyclohexanecarboxylic acid with diethylphosphoryl cyanide as coupling reagent. Treatment of trans-I (R = Me3CO2C, R1 = OH) with diethylphosphoryl cyanide, followed by condensation with L-valine Me ester gave trans I (R = Me3CO2C, R1 = Val-OMe) (II). Deprotection and coupling of II with N-tert-butoxycarbonyl-L-alanine gave trans-I (R = Me3CO2C-Ala-, R1 = Val-OMe). Similar transformations were effected with cis-I (R = Me3CO2C, R1 = OH). Other coupling procedures investigated were the carbodiimide, p-nitrophenyl active ester, and sym. anhydride methods, which were less satisfactory for coupling to cyclohexane amino acids.

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Reference:
Synthesis and Crystal Structure of a Chiral C3-Symmetric Oxygen Tripodal Ligand and Its Applications to Asymmetric Catalysis,
Chiral lanthanide(III) complexes of sulphur–nitrogen–oxygen ligand derived from aminothiourea and sodium D-camphor-β-sulfonate

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The preparation of ester heterocycles mostly uses heteroatoms as nucleophilic sites, which are achieved by intramolecular substitution or addition reactions. Compound: cis-4-Aminocyclohexane carboxylic acid( cas:3685-23-2 ) is researched.Synthetic Route of C7H13NO2.Litvin, E. F.; Freidlin, L. Kh.; Oparina, G. K.; Gurskii, R. N.; Istratova, R. V.; Gosteva, L. I. published the article 《Hydrogenation of 4-aminobenzoic acid on catalysts of the platinum group》 about this compound( cas:3685-23-2 ) in Zhurnal Organicheskoi Khimii. Keywords: kinetics hydrogenation aminobenzoic acid; benzoic acid amino hydrogenation; catalyst hydrogenation aminobenzoic acid. Let’s learn more about this compound (cas:3685-23-2).

The rate of 4-H2NC6H4-CO2H hydrogenation to cis-4-aminocyclohexanecarboxylic acid and isomerization of the latter to the trans acid at 90-170° and 80 atm increased in the order of catalysts Pd ∼ Pt < Ru ≪ Rh and was higher with metal on C than with metal black; these reaction rates decreased in the order of solvents H2O > dioxane > EtOH > Me2SO > cyclohexylamine, and with Ru/C and Rh/C, decreased in the order of mineral acids H2SO4 > H3PO4 > HCl. At 90° the product stereochem. was determined by the reduction mechanism, and not by the rate of the secondary isomerization; the cis-trans ratio decreased in the order Ru > Rh > Pt > Pd.

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Reference:
Synthesis and Crystal Structure of a Chiral C3-Symmetric Oxygen Tripodal Ligand and Its Applications to Asymmetric Catalysis,
Chiral lanthanide(III) complexes of sulphur–nitrogen–oxygen ligand derived from aminothiourea and sodium D-camphor-β-sulfonate

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Related Products of 56413-95-7. The mechanism of aromatic electrophilic substitution of aromatic heterocycles is consistent with that of benzene. Compound: 5,6-Dichloropyrazine-2,3-dicarbonitrile, is researched, Molecular C6Cl2N4, CAS is 56413-95-7, about Synthesis and studies on photodynamic activity of new water-soluble azaphthalocyanines. Author is Zimcik, Petr; Miletin, Miroslav; Ponec, Jan; Kostka, Miroslav; Fiedler, Zdenek.

Aza analogs of phthalocyanines (AzaPc’s) bearing four long chains with carboxy groups at the end and four “”bulky”” diethylamino groups on periphery were synthesized and characterized. Their sodium salts are very soluble in water. The first studies on photodynamic activity of this tetrapyrazinoporphyrazines (a type of AzaPc) are presented. The dye-sensitized photooxidation of 1,3-diphenylisobenzofurane via 1O2 was studied in pyridine. Their photodynamic activity in vitro was not detected due to the aggregation behavior of these compounds in water.

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Reference:
Synthesis and Crystal Structure of a Chiral C3-Symmetric Oxygen Tripodal Ligand and Its Applications to Asymmetric Catalysis,
Chiral lanthanide(III) complexes of sulphur–nitrogen–oxygen ligand derived from aminothiourea and sodium D-camphor-β-sulfonate

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Most of the compounds have physiologically active properties, and their biological properties are often attributed to the heteroatoms contained in their molecules, and most of these heteroatoms also appear in cyclic structures. A Journal, IUCrData called 2-Sulfanylidene-1,3-dithiolo[4,5-b]pyrazine-5,6-dicarbonitrile, Author is Tomura, Masaaki, which mentions a compound: 56413-95-7, SMILESS is N#CC1=NC(Cl)=C(Cl)N=C1C#N, Molecular C6Cl2N4, HPLC of Formula: 56413-95-7.

In the title compound, C7N4S3, the mol. entity consisting of a 1,3-dithiole-2-thione with a fused pyrazine ring is planar, with an r.m.s. deviation of 0.042 (3) Å from the least-squares plane. In the crystal, mols. are linked via short intermol. S···N contacts [3.251 (4) and 3.308 (3) Å] between the S atom of the thiocarbonyl group and N atoms of the cyano groups.

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Reference:
Synthesis and Crystal Structure of a Chiral C3-Symmetric Oxygen Tripodal Ligand and Its Applications to Asymmetric Catalysis,
Chiral lanthanide(III) complexes of sulphur–nitrogen–oxygen ligand derived from aminothiourea and sodium D-camphor-β-sulfonate

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Name: 3-Methyl-1H-pyrrole. The reaction of aromatic heterocyclic molecules with protons is called protonation. Aromatic heterocycles are more basic than benzene due to the participation of heteroatoms. Compound: 3-Methyl-1H-pyrrole, is researched, Molecular C5H7N, CAS is 616-43-3, about Immunochemical Detection of Protein Modification Derived from Metabolic Activation of 8-Epidiosbulbin E Acetate. Author is Zhou, Shenzhi; Zhang, Na; Hu, Zixia; Lin, Dongju; Li, Weiwei; Peng, Ying; Zheng, Jiang.

Furanoid 8-epidiosbulbin E acetate (EEA) is one of the most abundant diterpenoid lactones in herbal medicine Dioscorea bulbifera L. (DB). Our early work proved that EEA could be metabolized to EEA-derived cis-enedial (EDE), a reactive intermediate, which is required for the hepatotoxicity observed in exptl. animals exposed to EEA. Also, we found that EDE could modify hepatic protein by reaction with thiol groups and/or primary amines of protein. The present study was inclined to develop polyclonal antibodies to detect protein modified by EDE. An immunogen was prepared by reaction of EDE with keyhole limpet hemocyanin (KLH), and polyclonal antibodies were raised in rabbits immunized with the immunogen. Antisera collected from the immunized rabbits demonstrated high titers evaluated by enzyme-linked immunosorbent assays (ELISAs). Immunoblot anal. showed that the polyclonal antibodies recognized EDE-modified bovine serum albumin (BSA) in a hapten load-dependent manner but did not cross-react with native BSA. Competitive inhibition experiments elicited high selectivity of the antibodies toward EDE-modified BSA. The antibodies allowed us to detect and enrich EDE-modified protein in liver homogenates obtained from EEA-treated mice. The developed immunoprecipitation technique, along with mass spectrometry, enabled us to succeed in identifying multiple hepatic proteins of animals given EEA. We have successfully developed polyclonal antibodies with the ability to recognize EDE-derived protein adducts, which is a unique tool for us to define the mechanisms of toxic action of EEA.

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Reference:
Synthesis and Crystal Structure of a Chiral C3-Symmetric Oxygen Tripodal Ligand and Its Applications to Asymmetric Catalysis,
Chiral lanthanide(III) complexes of sulphur–nitrogen–oxygen ligand derived from aminothiourea and sodium D-camphor-β-sulfonate

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The chemical properties of alicyclic heterocycles are similar to those of the corresponding chain compounds. Compound: 5,6-Dichloropyrazine-2,3-dicarbonitrile, is researched, Molecular C6Cl2N4, CAS is 56413-95-7, about Azaphthalocyanines: Red Fluorescent Probes for Cations, the main research direction is azaphthalocyanine red fluorescent indicator cation.Quality Control of 5,6-Dichloropyrazine-2,3-dicarbonitrile.

Chelation of sodium and potassium cations by aza[15]crown-5 switches on strong red fluorescence in azaphthalocyanines. This is due to an inhibition of ultrafast intramol. charge transfer by coordination of the cations to the donor center. Sodium cations fit well into a cavity of the recognition moiety, while potassium forms supramol. assemblies of azaphthalocyanines with 1:2 stoichiometry.

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Reference:
Synthesis and Crystal Structure of a Chiral C3-Symmetric Oxygen Tripodal Ligand and Its Applications to Asymmetric Catalysis,
Chiral lanthanide(III) complexes of sulphur–nitrogen–oxygen ligand derived from aminothiourea and sodium D-camphor-β-sulfonate

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Safety of cis-4-Aminocyclohexane carboxylic acid. So far, in addition to halogen atoms, other non-metallic atoms can become part of the aromatic heterocycle, and the target ring system is still aromatic. Compound: cis-4-Aminocyclohexane carboxylic acid, is researched, Molecular C7H13NO2, CAS is 3685-23-2, about Characterization of an inhibitory receptor in rat hippocampus. A microiontophoretic study using conformationally restricted amino acid analogs.

The inhibitory potencies of GABA [56-12-2], β-alanine [107-95-9], and glycine [56-40-6] in rat hippocampal pyramidal cells were determined and compared with those of substituted aminocyclopentane and aminocyclohexane carboxylic acids (ACPC and ACHC resp.). The order of effectiveness of the small aliphatic amino acids was GABA > β-alanine > glycine. GABA-induced inhibition was inhibited by iontophoresis of bicuculline or picrotoxin but not strychnine-HCl. The inhibitory abilities of the substituted ACPC and ACHC derivatives was a direct function of the separation of NH2 and CO2H groups in both series of cyclic amino acids. The most potent inhibition was observed when the spatial separation was similar to that of the extended GABA mol. (4.74 Å). Inhibition by (±)-cis-3-aminocyclopentanecarboxylic acid was blocked by simultaneous application of bicuculline or picrotoxin, but not by strychnine-HCl. The physiol. active conformation of GABA is probably the fully extended mol. and one dimension of the postsynaptic receptor site is probably within the range 4.2-4.8 Å.

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Reference:
Synthesis and Crystal Structure of a Chiral C3-Symmetric Oxygen Tripodal Ligand and Its Applications to Asymmetric Catalysis,
Chiral lanthanide(III) complexes of sulphur–nitrogen–oxygen ligand derived from aminothiourea and sodium D-camphor-β-sulfonate