Carbon-13 chemical shifts of some cholinergic neural transmission agents

Carbon-13 chemical shifts have been obtained in the pulse Fourier transform mode on the following cholinergic neural transmission agents: acetylcholine, β-methyl acetylcholine, carbamoyl choline, choline, tetramethylammonium, scopolamine, atropine, methyl atropine, tropine, tropic acid, nicotine, dimethyl phenylpiperazinium, arecoline, oxotremorine and pilocarpine. The effects of structural variations, asymmetric centers and steric interactions on the ¹³C shielding are considered. The observed chemical shifts do not appear to correlate simply with potencies in the cholinergic nervous system.     

Methods of assessment of atropine and scopolamine levels in transdermal permeation

Three methods of atropine and scopolamine determination in transdermal permeation have been developed. Radiometric determination seems to be an excellent, quick and extremely sensitive method, which ought to be preferred when working with biological systems. The radioreceptor analysis is of group specificity. It can be used to advantage in monitoring atropine plasma concentrations exceeding 1.5 ng cm^–3 and scopolamine concentrations above 50 pg cm^–3. GC/MS provides adequate specificity and sensitivity for the determination of therapeutic levels of atropine and scopolamine in blood. The sensitivity of this method is approximately 1–2 ng cm^–3.     

Flow-injection post chemiluminescence determination of atropine sulfate

A new post chemiluminescence (PCL) reaction was observed when atropine sulfate was injected into the reaction mixture after the finish of CL reaction of Ce(IV) and sodium sulfite. The possible mechanism for the PCL reaction was discussed via the investigation of the CL kinetic characteristics, the CL spectra, the UV absorption spectra and the fluorescence spectra of some related substances. The flow injection PCL method for the determination of atropine sulfate was established. The relative standard deviation (R.S.D.) was 2.8% (n = 11, c = 5.0 × 10⁻⁶ g mL⁻¹). The PCL intensity responded linearly to the concentration of atropine sulfate in the range 1.0 × 10⁻⁶ to 5.0 × 10⁻⁵ g mL⁻¹ with a linear correlation of 0.9947. The detection limit was 4 × 10⁻⁷ g mL⁻¹ atropine sulfate. The method had been applied to the determination of atropine sulfate in the tablets and the results were consistent with the method of Chinese pharmacopoeia.     

Simultaneous Determination of Pethidine and Atropine in Rabbit Plasma by LC�CMS�CMS and Its Application to a Pharmacokinetic Study after Intramuscular Administration

A sensitive and selective liquid chromatography?Ctandem mass spectrometry method for the determination of pethidine and atropine in rabbit plasma was developed and validated. The analytes and internal standard (IS) are extracted from plasma by liquid?Cliquid extraction using ethyl acetate, and separated on a Zorbax SB-Aq column (2.1 × 150 mm, 3.5 ??m) using acetonitrile?C0.1% formic acid as mobile phase with gradient elution. Electrospray ionization source was applied and operated in positive ion mode, and multiple reaction monitoring mode was used for quantification using target fragment ions m/z 247.8 ?? 219.7 for pethidine, m/z 289.9 ?? 123.8 for atropine and m/z 295.0 ?? 266.8 for IS, respectively. The assay is linear over the range of 5?C1,000 ng mL^?1 for pethidine and atropine, with a lower limit of quantification of 3 ng mL^?1 for pethidine and 5 ng mL^?1 for atropine. Intra-day and inter-day precision are less than 11% and the accuracy are in the range of 90.4?C106.3%. Furthermore, the newly developed method is successfully used for the determination of pethidine and atropine in rabbit plasma for pharmacokinetic study.     

Simultaneous determination of two active ingredients in Flos daturae by capillary electrophoresis with electrochemiluminescence detection

The coupling of Ru(bpy)₃²⁺ based electrochemiluminescence (ECL) detection with capillary electrophoresis (CE) was developed for the simultaneous determination of the two major active ingredients (atropine and scopolamine) in Flos daturae. Parameters related to the separation and detection were discussed and optimized. It was proved that 20 mM phosphate buffer at pH 8.48 could achieve the most favorable resolution, and the high sensitivity of detection was obtained by maintaining the detection potential at 1.2 V. Under the optimized conditions: ECL detection at 1.2 V, 20 mM phosphate buffer at pH 8.48, 5 mM Ru(bpy)₃²⁺ and 50 mM phosphate buffer at pH 7.48 in the detection reservoir, detection limits of 5 × 10⁻⁸ mol/l for atropine and 1 × 10⁻⁶ mol/l for scopolamine were obtained. Relative standard derivations of the ECL intensity and the migration time were 5.16 and 0.71% for atropine and 5.07 and 1.22% for scopolamine, respectively. Developed method was successfully applied to determine the amounts of both alkaloids in Flos daturae. A baseline separation for atropine and scopolamine was achieved within 11 min.     

Pulse radiolysis investigations on the reactions of primary radiolytic species of water with atropine

On pulse radiolysis of N₂O saturated aqueous solutions of atropine, an optical absorption band (_max at 320 nm,e=2.81·10³ dm³·mol^–1·cm^–1) was observed, which is assigned to the product of reaction of OH radicals with the solute. This absorption decayed following second order kinetics with a rate constant of 4.5·10⁸ dm³·mol^–1·s^–1. The rate constant for the reaction of OH radicals with atropine as estimated by following the build-up kinetics is 2.7·10⁹ dm³·mol^–1·s^–1. The H atoms also reacted with this compound to produce a transient absorption band behaving similarly to the one observed in the case of reaction with OH radicals. The transient species formed in both cases is assigned to a radical derived by H atom abstraction by H/OH radicals from the parent compound. This radical was unreactive towards 2-mercaptoethanol. e _aq ^– was found to react with atropine forming a transient band with _max at 310 nm (=3.55·10³ dm³·mol^–1). Its decay was also second order with a rate constant of 1.64·10⁹ dm³·mol^–1·s^–1. The bimolecular rate constant for the reaction of e _aq ^– with atropine as estimated from the decay of e _aq ^– absorption at 720 nm is 3.9·10⁹ dm³·mol^–1·s^–1. Specific one-electron oxidizing and reducing agents (such as Cl ₂ ^– , Tl²⁺, SO ₄ ^– and (CH₃)₂COH, CO ₂ ^– , respectively) failed to oxidize or reduce this compound in aqoues solutions. The radical anion of atropine formed by its reaction with e _aq ^– was found to reduce thionine and methyl viologen with bimolecular rate constant of 3.8·10⁹ and 3.2·10⁹ dm³·mol^–1·s^–1, respectively.     

Construction and analytical applications of liquid-membrane electrodes for atropine and novatropine

Liquid-membrane electrodes sensitive to atropinium and novatropinium cations are described. The atropinium electrode exhibits rapid and near-Nernstian response in the 10^-2–3 × 10^-5 M range over the pH range 2–8.5; the novatropinium electrode shows near-Nernstian response in the 10^-2–3 × 10^-6 M range at pH 2–10. Other alkaloids interfere. Direct potentiometry and potentiometric titrations are used to determine atropine and novatropine in pharmaceutical preparations with satisfactory results.     

Development of CE-C4D Method for Determination Tropane Alkaloids

A fast method for the determination of tropane alkaloids, using a portable CE instrument with a capacitively coupled contactless conductivity detector (CE-C⁴D) was developed and validated for determination of atropine and scopolamine in seeds from Solanaceae family plants. Separation was obtained within 5 min, using an optimized background electrolyte consisting of 0.5 M acetic acid with 0.25% (w/v) β-CD. The limit of detection and quantification was 0.5 µg/mL and 1.5 µg/mL, respectively, for both atropine and scopolamine. The developed method was validated with the following parameters—precision (CV): 1.07–2.08%, accuracy of the assay (recovery, RE): 101.0–102.7% and matrix effect (ME): 92.99–94.23%. Moreover, the optimized CE-C⁴D method was applied to the analysis of plant extracts and pharmaceuticals, proving its applicability and accuracy.     

Enantioseparation of five racemic N-alkyl drugs by reverse phase HPLC using sulfobutylether-β-cyclodextrin as a chiral mobile phase additive

Analytical enantioseparations of five N-alkyl drugs, fluoxetine hydrochloride, labetalol, venlafaxine hydrochloride, trans-paroxol, and atropine sulfate, were investigated by reverse phase high-performance liquid chromatography with sulfobutylether-β-cyclodextrin as chiral mobile phase additive. Effects of various factors such as composition of mobile phase, concentration of cyclodextrins, and column temperature on retention and enantioselectivity were studied. Apparent formation constant between methanol, acetonitrile, and sulfobutylether-β-cyclodextrin were determined to be 2.90 × 10⁻³ and 1.00 × 10⁻⁴ L mmol⁻¹ under 25°C using UV-spectrophotometry. Van't Hoff plots were used to investigate thermodynamic parameters for enantiomers–stationary phase interaction and formation of inclusion complex. Two retention models were employed individually for evaluation of inclusion complexation between five racemates and sulfobutylether-β-cyclodextrin. The second model with complex adsorption was more accord with the retention behavior of fluoxetine hydrochloride, labetalol, and venlafaxine hydrochloride enantiomers, while the first model was more consistent with the retention behaviors of trans-paroxol and atropine sulfate. In the selected mobile phase, stoichiometric ratio for both of inclusion complex was found to be 1:1.     

LC–MS for Identification and Elucidation of the Structure of In-Vivo and In-Vitro Metabolites of Atropine

In-vivo and in-vitro metabolism of atropine has been investigated by use of a highly specific and sensitive LC–MS ⁿ method. Feces, urine, and plasma samples were collected separately after ingestion of 25 mg kg⁻¹ atropine by healthy rats. Rat feces and urine samples were cleaned by liquid–liquid extraction and by solid-phase extraction (on C₁₈ cartridges), respectively. Methanol was added to rat plasma samples to precipitate plasma proteins. Atropine was incubated, in vitro, with homogenized liver and with intestinal flora from rats. The metabolites in the incubation solution were extracted with ethyl acetate. These pretreated samples were then analyzed by reversed-phase high-performance liquid chromatography on a C₁₈ column with methanol–ammonium acetate (2 mm, adjusted to pH 3.5 with formic acid), 70:30 (v/v), as mobile phase. Detection was by on-line MS ⁿ . Identification and elucidation of the structure of the metabolites were achieved by comparing molecular mass (ΔM), retention-times, and full-scan MS ⁿ spectra with those of the parent drug. Ten new metabolites (aponoratropine, apoatropine, hydroxymethoxyatropine, trihydroxyatropine, dimethoxyatropine, dihydroxymethoxyatropine, hydroxydimethoxyatropine, trihydroxymethoxyatropine, dihydroxydimethoxyatropine, and tropic acid) were identified in rat urine after ingestion of atropine. Nine metabolites (nortropine, tropine, aponoratropine, apoatropine, noratropine, hydroxyatropine, hydroxyatropine N-oxide, hydroxymethoxyatropine, and tropic acid) and the parent drug were detected in rat feces. Five metabolites (nortropine, tropine, tropic acid, apoatropine, and hydroxyatropine) and the parent drug were detected in rat plasma. Only two metabolites (apoatropine and noratropine) were detected in the homogenized liver incubation mixture. The hydrolyzed metabolites (tropine and tropic acid) and dehydrated metabolite apoatropine were found in the rat intestinal flora incubation mixture.     

Simultaneous determination of atropine,scopolamine, and anisodamine in Flos daturae by capillary electrophoresis using a capillary coated by graphene oxide

A novel CE method was developed for the separation and determination of three main tropane alkaloids in Flos daturae with a capillary coated by graphene oxide (GO). The GO‐coated capillary was characterized by SEM, energy dispersive X‐ray spectroscopy, and Raman spectroscopy, and the results indicated that the inner surface of the capillary was partially coated by GO. A phosphate solution (40 mM, pH7.0) containing 20% v/v methanol and 30% v/v acetonitrile was used as the running buffer for the analysis of the atropine, scopolamine, and anisodamine. The linear ranges of atropine, scopolamine, and anisodamine was 0.5–200 μg/mL with satisfactory correlation coefficients (R²) > 0.9987, and this novel method provided an efficient separation for three tropane alkaloids as well as a good reproducibility and stability. Finally, the method was successfully applied for the determination of these three tropane alkaloids in plant extracts.     

Substituent effects on 13C?13C coupling constants and chemical shifts in 13C labelled polycyclic aromatic hydroxy compounds

The effects of an hydroxy substituent on ¹³C? ¹³C coupling constants and ¹³C chemical shifts have been measured in 1-hydroxynaphthalene-2-¹³C and 1-hydroxypyrene-1-¹³C. The changes observed in the ¹³C? ¹³C couplings show the effect of a substituent attached directly to the labelled carbon or to a carbon ortho to this. In both situations the effect is a decrease in the numerical magnitude of most of the long range ¹³C? ¹³C coupling constants.     

Unterscheidung symmetrisch substituierter Kohlenstoffringe durch 13C,13C-Spin-Spin-Kopplung. Vergleich von herkömmlicher und INADEQUATE-13C-NMR-Spektroskopie

Distinction of Symmetrically Substituted Carbocyclic Compounds by ¹³C, ¹³C Spin-Spin Coupling. Comparison of Conventional and INADEQUATE¹³C-NMR Spectroscopy ¹³C,¹³C spin-spin couplings allow an easy distinction of symmetrically substituted carbocyclic compounds. On the basis of the number and ratio of ¹³C,¹³C satellite pairs, for instance head to head and head to tail products of photodimerisations can be distinguished. The informations derived from a conventional and an INADEQUATE ¹³C-NMR spectrum are compared.     

The development of nuclear microprobe techniques for the spatial determination of13C and13C/12C ratios

Sensitive and selective nuclear reaction methods have been sought for the nuclear microprobe measurement of the spatial distributions of¹³C and¹³C/¹²C ratios. The¹³C(α, n)¹⁶O reaction, with neutron detection, is the most selective for¹³C, and has a sensitivity of ca. 100 ppm. The reactions¹³C(d, p)¹⁴C and¹²C(d, p)¹³C, with proton detection, are the most sensitive for the simultaneous measurement of¹³C and¹²C, with detection limits of 30 and 2 ppm respectively. Less sensitive alternative reaction pairs are;¹³C(³He, p)¹⁵N and¹²C(³He, p)¹⁴N;¹³C(d, nγ)¹⁴N and¹²C(d, pγ)¹³C;¹³C(³He, pγ)¹⁵N and¹²C(³He, pγ)¹⁴N. The conditions governing their use, particularly light element interferences, are detailed.     

13C?13C spin coupling constants in tetrahydronaphthylene,hexahydrobenzanthracene and benzo[a]pyrene derivatives

The ¹³C? ¹³C spin coupling constants have been determined in substituted [1-¹³C]tetrahydronaphthylenes, [5-¹³C]hexahydrobenzanthracenes and [5-¹³C]benzanthracene. In addition, the ¹³C? ¹³C spin coupling constants for 7-hydroxy[7-¹³C]benzopyrene, trans-7,8-dihydro[7-¹³C]benzopyrene-7,8-diol and trans-7,8-dihydro[10-¹³C]benzopyrene-7,8-diol are reported, together with the one-bond carbon-carbon coupling constants between C-4 and C-5 in selected 4,5-disubstituted benzopyrenes. Values for the directly bonded coupling constants and long-range coupling constants are similar to those reported previously for other aromatic and aliphatic systems. Substituent effects on carbon-carbon coupling are compared for similarly substituted cyclic and acyclic systems.     

Gas-phase 13C chemical shifts in the zero-pressure limit: refinements to the absolute shielding scale for 13C

¹³C chemical shifts have been measured relative to ¹³CO in the zero-pressure limit for over twenty molecules for which theoretical calculations of ¹³C nuclear shielding have recently been reported. Rovibrational averaging effects on the spin-rotation constant in ¹³C¹⁶O have been used to find σ_e(¹³C in ¹³C¹⁶O) = 3.0 ± 1.2 ppm and σ₀(¹³C in ¹³C¹⁶O) = 1.0 ± 1.2 ppm. With the latter, the σ₀ values for the ¹³C nuclei in this work have been determined absolutely and compared with calculated values. Agreement is generally good in most cases except where low-lying n → π transitions contribute significantly to the paramagnetic shielding.     

13C-NMR studies of polyfluorinated hydrocarbons,carboxylic acid derivatives,alcohols and ethers

δ¹³C values and coupling constants (¹J(¹³C¹H), ¹J(¹³C¹³C), ⁿJ(¹⁹F¹³C) are reported for 19 polyfluorinated organic compounds. It is shown that the shielding of carbon depends upon the number of fluorine atoms in α -position. If the R_F-group is linked to a π -system hyperconjugative $\text{and}$ η-π interaction accounts for the δ¹³C data. The values ¹J(¹³C¹H) and ¹J(¹³C¹³C) are in qualitative agreement with changes of the s-character of the respective bonds.     

Highly sensitive determination of atropine using cobalt oxide nanostructures: Influence of functional groups on the signal sensitivity

This study describes sensitive determination of atropine using glassy carbon electrodes (GCE) modified with Co₃O₄ nanostructures. The as-synthesised nanostructures were grown using cysteine (CYS), glutathione (GSH) and histidine (HYS) as effective templates under hydrothermal action. The obtained morphologies revealed interesting structural features, including both cavity-based and flower-shaped structures. The as-synthesised morphologies were noted to actively participate in electro-catalysis of atropine (AT) drug where GSH-assisted structures exhibited the best signal response in terms of current density and over-potential value. The study also discusses the influence of functional groups on the signal sensitivity of atropine electro-oxidation. The functionalisation was carried with the amino acids originally used as effective templates for the growth of Co₃O₄ nanostructures. The highest increment was obtained when GSH was used as the surface functionalising agent. The GSH-functionalised Co₃O₄-modified electrode was utilised for the electro-chemical sensing of AT in a concentration range of 0.01–0.46 μM. The developed sensor exhibited excellent working linearity (R² = 0.999) and signal sensitivity up to 0.001 μM of AT. The noted high sensitivity of the sensor is associated with the synergy of superb surface architectures and favourable interaction facilitating the electron transfer kinetics for the electro-catalytic oxidation of AT. Significantly, the developed sensor demonstrated excellent working capability when used for AT detection in human urine samples with strong anti-interference potential against common co-existing species, such as glucose, fructose, cysteine, uric acid, dopamine and ascorbic acid.     

Chemical effect of13N formed in butyric-d7 acid irradiated in a pile

A distinct phase effect was observed on the formation of¹³NH₃, H¹³NO_x and [¹³N]-amide in pile-irradiated butyric-d₇ acid, although the magnitude of the effect was rather smaller than that in deuterated trifluoroacetic, acetic and propionic acids previously reported. In frozen butyric-d₇ acid, most of¹³N was found in the forms such as¹³NH₃ (54.8±0.7%), H¹³NO_x (26.8±0.6%). and [¹³N]amide (15.9±1.8%). The yields of HC¹³N and [¹³N]aminobutyric acid were only 0.6±0.3 and 1.2±0.3% even in the liquid, respectively. The scavenger effect of acetic anhydride-d₆ on the formation of¹³NH₃, H¹³NO_x and [¹³N]amide was examined. In liquid and frozen carboxylic acids, the yields of¹³NH₃ and H¹³NO_x were proportional and inversely proportional to the number of hydrogen atoms in a target molecule in the region of the number of hydrogen from unity to eight.     

Structural Revision and Elucidation of the Biosynthesis of Hypodoratoxide by 13C,13C COSY NMR Spectroscopy

Feeding of (2,3,4,5,6‐¹³C₅)mevalonolactone to the fungus Hypomyces odoratus resulted in a completely labeled sesquiterpene ether. The connectivity of the carbon atoms was easily deduced from a ¹³C,¹³C COSY spectrum, revealing a structure that was different from the previously reported structure of hypodoratoxide, even though the reported ¹³C NMR data matched. A structural revision of hypodoratoxide is thus presented. Its absolute configuration was tentatively assigned from its co‐metabolite cis‐dihydroagarofuran. Its biosynthesis was investigated by feeding of (3‐¹³C)‐ and (4,6‐¹³C₂)mevalonolactone, which gave insights into the complex rearrangement of the carbon skeleton during terpene cyclization by analysis of the ¹³C,¹³C couplings.