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Development of high performance liquid chromatography methods with charged aerosol detection for the determination of lincomycin, spectinomycin and its impurities in pharmaceutical products
Accepted Manuscript Title: Development of high performance liquid chromatography methods with charged aerosol detection for the determination of lincomycin, spectinomycin and its impurities in pharmaceutical products Author: K. Stypulkowska A. Blazewicz A. Brudzikowska M. Warowna – Grzeskiewicz K. Sarna Z. Fijalek PII: DOI: Reference:
S0731-7085(15)00213-7 http://dx.doi.org/doi:10.1016/j.jpba.2015.03.036 PBA 10029
To appear in:
Journal of Pharmaceutical and Biomedical Analysis
Received date: Revised date: Accepted date:
16-1-2015 27-3-2015 29-3-2015
Please cite this article as: K. Stypulkowska, A. Blazewicz, A. Brudzikowska, M.W. Grzeskiewicz, K. Sarna, Z. Fijalek, Development of high performance liquid chromatography methods with charged aerosol detection for the determination of lincomycin, spectinomycin and its impurities in pharmaceutical products, Journal of Pharmaceutical and Biomedical Analysis (2015), http://dx.doi.org/10.1016/j.jpba.2015.03.036 This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
Simple and repeatable LC-CAD methods have been developed and tested.
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A parallel connection of HPLC system with MS and CAD was used.
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All peaks were identified by HPLC-MS/MS-TOF.
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Methods could be used as routine assay and purity test methods of pharmaceuticals.
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Development of high performance liquid chromatography methods
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with charged aerosol detection for the determination of
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lincomycin, spectinomycin and its impurities in pharmaceutical products
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12 K. Stypulkowskaa*, A. Blazewicza, A. Brudzikowskaa,b ,
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M. Warowna – Grzeskiewicza,c , K. Sarnaa, Z. Fijaleka,b a
National Medicines Institute, Pharmaceutical Chemistry Department, 30/34 Chelmska Str.,
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00-725 Warsaw, Poland
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b
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Medical University of Warsaw, Department of Bioanalysis and Drug Analysis,
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1 Banacha Str., 02-097 Warsaw, Poland
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Medical University of Warsaw, Department of Inorganic and Analytical Chemistry, 1 Banacha Str., 02-097 Warsaw, Poland
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Abstract
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Novel and simple liquid chromatography methods with charged aerosol detection (LC-
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CAD) for simultaneous quantitation of lincomycin and spectinomycin and its related
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substances have been developed and tested. This type of analysis is complicated due to the
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different chromatographic behavior of these two agents and the lack of chromophores in
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spectinomycin complex. CAD seems to be a promising alternative to overcome these
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difficulties. It shows a consistent inter-analyte response, independent of chemical structure of
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an analyte. It also enables the direct quantification of related substances for which no
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reference standards were available, with good accuracy and precision. Chromatographic
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separations were achieved using a C18 Hypersil® Gold column, with mobile phases consisting
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of water, acetonitrile and trifluoroacetic acid. All impurities were identified using time-of-
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flight mass spectrometry with electrospray ionization. The developed methods have been
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successfully used in the routine quality control analysis of pharmaceutical preparations.
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* Corresponding author, Tel.: +48 228412121, Fax: +48 223311563 e-mail address: [email protected] (K. Stypulkowska) Keywords: charged aerosol detector; spectinomycin; lincomycin; related substances.
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Spectinomycin produced by Streptomyces spectabilis belongs to aminoglycoside
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antibiotics and lincomycin produced by Streptomyces lincolnensis is a lincosamide antibiotic.
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Pharmaceuticals being a combination of these two antibiotics (in a 2:1 ratio) are widely used
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in veterinary medicine for the treatment of bacterial gastrointestinal and respiratory infections
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[11,22]. In human medicine, spectinomycin is used principally against Neisseria gonorrhoeae
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[[33]]. Due to their natural synthesis, both of them remain a mixture of similar compounds.
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Spectinomycin is the principal component of its complex. In solution, it undergoes a ring
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opening and closure of the hemiketal function. This results in an equilibrium mixture of four
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possible anomers, which may, or may not, co-elute in a chromatographic analysis. The
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chemical structures of both mentioned antibiotic and their related substances are presented in
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Fig. 1 and Fig. 2.
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Few chromatographic methods combined with electrochemical detection (ED) [[44]]
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and mass spectrometry (MS) [[55],[66]] have been reported in literature for the determination
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of lincomycin. The European Pharmacopoeia (Ph. Eur.) defines a HPLC-UV method for
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lincomycin assay and related substances test [[77]]. This method is rather simple to apply, it
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uses a very popular UV detector and a C8 column and produces repeatable results, so it may
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be used in a routine analysis successfully.
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For spectinomycin, the current Ph. Eur. monographs define a reversed phase HPLC-
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ED method after post-column derivatization [[88],[99]], whereas the United States
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Pharmacopoeia (US pharmacopoeia ) prescribes gas chromatography with flame ionization
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detection (GC-FID) [[1010],[1111]] for the assay determination, without defining the related
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substances test. Pharmacopoeial methods are hardly reproducible, so other methods have been
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developed. Some are performed using pre-column or post-column derivatization procedures
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[[1212],[1313],[1414]], which are typically cumbersome, difficult to reproduce and may
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result in introduction of non-controlled impurities. Therefore, non-derivatizing HPLC
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methods with ED [[1515],[1616],[1717]], MS [[1818],[1919]] and evaporative light scattering
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detection (ELSD) [[2020],[2121],[2222]] have been developed.
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As far as we are aware, there are only two chromatographic methods with pulsed
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amperometric detector (PAD) [[2323]] or MS [[2424]] describing the simultaneous
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determination of both compounds in pharmaceuticals in one run. This type of analysis is
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complicated due to the difference in the chromatographic behavior of these two agents.
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Corona Charged Aerosol Detection (CAD) seems to be a promising alternative to
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overcome the difficulties mentioned above. It shows consistent inter-analyte response,
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independent of chemical structures of an analyte, under identical mobile phase and CAD
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conditions.Its features have been described previously [[2525]] and An extensive overview of
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CAD’s applications has been reported by Almeling et al. [[2626]]. Also, its usefulness in the
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quantitative analysis of aminoglycosides has been reported [25,[2727],[2828],[2929]].
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This manuscript describes the development and validation of simple, repeatable and
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accurate HPLC-CAD methods to determine the assay of lincomycin and spectinomycin with
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its related substances in 18 minutes.
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2. Materials and methods
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2.1. Chemicals
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All reagents were LC grade: methanol (MeOH) and acetonitrile (ACN) (Rathburn
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Chemicals Ltd., Walkerburn, Scotland), trifluoroacetic acid (TFA) (AppliChem GmbH,
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Darmstadt, Denmark). Doubly distilled water additionally purified in the Nanopure
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DiamondTM UV Deionization System from Barnstead (a part of Thermo Scientific, Marietta,
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United States) was used throughout. Reference standards: Lincomycin hydrochloride CRS,
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Spectinomycini dihydrochloridum CRS and Spectinomycin hydrochloride for system
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suitability CRS containing impurities A, C, D, E, F and G were purchased from EDQM
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(Strasbourg, France).
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The methods were tested on two products: soluble powder containing lincomycin
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hydrochloride and spectinomycin sulphate at the concentration of 222 g + 444 g/1000g,
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respectively (Sample A), and solution for injection containing 50 mg/ml of lincomycin
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hydrochloride hydrate and 100 mg/ml of spectinomycin sulphate tetrahydrate (Sample B).
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The interesting fact is that both products had the same trade name, but one was a registered
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and commercially available pharmaceutical product. The other one was not registered in
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Poland (the illegal product), but it was provided from the legal Polish market.
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An LC UltiMate® 3000 system consisted of a pump, a degasser, an autosampler, a
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column heater and a pulse damper (DionexTM Softron GmbH, a part of Thermo Scientific,
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Germering, Germany) was used. LC system was coupled simultaneously to a CoronaTM ultra
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RSTM Charged Aerosol Detector (Thermo Scientific TM DionexTM) and a maXis 4G mass
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spectrometer (Bruker Daltonik GmbH, Bremen, Germany) by a 1/10 T-split. Nitrogen
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generator LCMS30-0 (Parker Donick Hunter, Cleveland, OH, USA) provided nitrogen gas to
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the both aerosol detectors. Additional nitrogen of high purity >99 % was introduced to the
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collision cell from a nitrogen cylinder. The CAD detection was performed using a medium
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filter and the 100 pA detection range. LC-CAD data were processed with ChromeleonTM 7
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and ChromeleonTM Validation ICH softwares (Thermo ScientificTM DionexTM).
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A time-of-flight mass spectrometer with electrospray ionization (ESI-MS-TOF) maXis
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4G from Bruker Daltonik was used for the peaks’ identification. The MS settings were: ESI
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in the positive ion mode, dry gas (nitrogen) flow rate 8.0 l/min, the dry heater 180°C, the
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capillary voltage 4500 V and end plate offset 500 V. MS data were recorded in the full scan
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mode (from 50 to 1000 m/z). MS data analysis was evaluated with Hystar 3.2., ESI Compass
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1.3 for micrOTOF/maXis and Data Analysis® Version 4.0 SP 4 softwares from Bruker
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Daltonik.
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The chromatographic separations by LC-CAD were performed on a C18 Hypersil®
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Gold analytical column (150 x 4.6 mm; 3 μm particle size, Thermo Scientific). The mobile
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phases consisted of a mixture of 0.3 % TFA and acetonitrile in a ratio 98:2 (v/v) for
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spectinomycin analysis and 80:20 (v/v) for lincomycin analysis, respectively. A flow rate was
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0.6 ml/min, a column temperature was set at 25oC. Samples were maintained at 8oC in
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autosampler and the injection volume was 10 µl in partial loop injection mode.
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2.3. Standard Solutions Preparation
The standards of the analyzed substances were accurately weighed into volumetric
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flasks and dissolved with water to produce stock solutions, which were successively diluted
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with water to obtain the required concentrations.
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2.4. Sample Preparation
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Samples were dissolved and diluted with water. For the assay determination samples
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were prepared and left for 24 h so that equilibrium between spectinomycin and its anomers
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was reached. For related substances tests, the solutions were prepared immediately before use
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[8].
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3. Results and Discussion
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3.1. LC methods development The hydrophilic nature of both compounds demanded the use of a rather highly
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aqueous mobile phase with addition of an ion-pair agent. Different water-MeOH and water-
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ACN mobile phases with addition of TFA or HFBA in isocratic and gradient elution modes
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were investigated. A Hypersil® Gold C18 column was used, because it was suitable for the
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analysis of other aminoglycosides previously [25,27]. The noise level when using HFBA was
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too high, so TFA was chosen for further investigations. Mixtures of water-ACN showed a
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more powerful separation. The effect of ACN content (0, 5, 10, 20, 40 %), TFA content (0.1,
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0.2, 0.3, 0.4 %), flow rate (0.5, 0.6, 0.7 ml/min) and column temperature (20, 25, 35ºC) on the
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peaks’ resolution were studied.
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For the spectinomycin analysis, the best mobile phase composition was 0.3 % TFA-
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ACN in a 98:2 (v/v) ratio, whereas for lincomycin assay a higher content of acetonitrile (20
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%) was demanded. To circumvent this problem, a one-step gradient was introduced in the 12
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minute after the spectinomycin analysis. With such gradient each compound was eluted on a
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defined plateau with a constant mobile phase composition, that is crucial for the usefulness of
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CAD’s universal response. What is more, depending on the type of the analyzed product, each
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analysis part may be used separately. The final elution program used is described in Table 1.
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After each run a four-minute step in the initial chromatographic conditions, for the system
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equilibration, was used.
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The other chromatographic parameters were as follow: a flow rate 0.6 ml/min, a
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temperature column set at 25oC, a sampler temperature set at 8oC and the injection volume 10
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µl. These conditions were optimal for the separation of ten related substances from the
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spectinomycin in 12 minutes and for the separation lincomycin from lincomycin B and other
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impurities in 6 minutes. The representative LC-CAD chromatogram obtained under these
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conditions is presented in Fig. 3. Also, different C18 columns were investigated. The best resolution was obtained with
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the initial Hypersil® Gold column, however, similar results were also obtained when using a
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TSKgel® ODS-100V column (150 x 4.6 mm; 3 μm, Tosoh Bioscience) and an Ascentis®
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Express C18 column (150 x 4.6 mm; 5 μm, Sigma-Aldrich).
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Spectinomycin and lincomycin were identified as the major peaks in standard
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solutions at 6.6 min and 15.3 min, respectively. The standards of (4R)-dihydrospectinomycin
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and lincomycin B were not available, so they were identified as the minor peaks in standard
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solutions and confirmed by LC-ESI-MS/MS-TOF at 8.6 min (4R)-dihydrospectinomycin) and
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14.0 min (lincomycin B). Other impurities of spectinomycin were identified by injecting the
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Spectinomycin for system suitability CRS solution (500 µg/ml) in the LC-MS full scan,
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positive ion mode. Chromatograms were obtained by plotting the total ion current (TIC) as a
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time function for [M+H]+ ions. For every peak MS and MS/MS spectra were recorded. The
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MS spectra showed ions that were consistent with the expected protonated molecular ions
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[M+H]+. However, for spectinomycin and impurities D and E the dominant ions were
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[M+H2O+H]+. Figure 4 presents typical MS and MS/MS spectra and fragmentation pathways
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of spectinomycin. The fragmentation scheme presented in this figure is also applicable to the
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related substances.
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During the LC-CAD analysis a peak at the retention time of 9.7 min was found. The
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LC-MS analysis identified its molecular ion mass as m/z [M+H]+ 305.2, which is 28 u less
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than m/z [M+H]+ =333.2 of spectinomycin. This corresponds to a loss of carbon monoxide
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from spectinomycin. Thus, the proposed molecular formula is C13H24N2O6.
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Degradation studies (see Section 3.3.7.1.) showed that during basic hydrolysis a big
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peak at 7.8 min has appeared. On the basis of LC-ESI-MS/MS-TOF analysis this peak was
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identified as the actinospectinoic acid (impurity B). The full peak assignment on the basis of
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LC-ESI-MS/MS-TOF results is presented in Table 2.
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The quantitative aspects of the proposed methods were examined according to the ICH
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guideline [[3030]]. Validation parameters were evaluated using standard solutions of
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spectinomycin dihydrochloride and lincomycin hydrochloride. Peak areas were evaluated in
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the whole validation, except the LOD and LOQ determination.
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3.3.1. Specificity
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The specificity of the proposed method was determined by comparing any interfering
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peaks from the blank injection and by checking peak purity of each peak via LC-ESI-MS-
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TOF. The LC-MS analysis demonstrated no co-elution of any peak of interest. Also, two
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peaks from the mobile phase at retention time of 3.5 and 3.8 min were observed, but no
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interferences with the other peaks occurred (Fig. 3).
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3.3.2. Linearity
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For both active substances the linearity was tested in two concentration ranges: the
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first one for the assay and the second one for the related substances quantitation. Six
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concentration levels were included. in the investigating ranges, in triplicate injections at each
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level.
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The obtained results were plotted as a linear and power function. The results are
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presented in Table 3. There were no differences in the investigated ranges in the coefficient of
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determination values (R2) between the linear and power functions. The linearity was found
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with very good R2 values, for both compounds, within a concentration range of one-order of
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magnitude. The obtained results confirmed that, although the CAD response is nonlinear at a
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range of four orders of magnitude, the signal is nearly linear in the smaller ranges
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[[3131],[3232]].
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3.3.3. Limits of detection and quantitation
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The detection limit (LOD) and quantitation limit (LOQ) were defined as a signal-to-
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noise ratio of 3:1 and 10:1, respectively. Peaks heights were evaluated for this validation
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parameter. For lincomycin the LOD and LOQ values were 0.3 µg/ml and 1.0 µg/ml,
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respectively. For spectinomycin the LOD and LOQ values were 0.5 µg/ml and 2.0 µg/ml,
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respectively.
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The LOD and LOQ values for lincomycin and spectinomycin are different, because
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the mobile phase composition is different. CAD is an aerosol-based detector and the intensity
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of the response depends on the composition of a mobile phase – the higher organic content is,
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the higher response is observed.
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3.3.4. Accuracy
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The accuracy of the methods was evaluated by injecting in triplicate standard solutions
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covering the linearity range. It was assessed by calculating the difference between the
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measured concentrations of standard solutions and their known concentrations, and expressed
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as percentage. The concentrations of the active substances in standard solutions were
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measured by putting the peak area into the calibration curve created during the linearity study.
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The accuracy results are shown in Table 4 at the α = 0.05 and they are satisfactory.
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3.3.5. Precision
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The precision of the methods was determined by intra-day precision (repeatability) and
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inter-day (intermediate) precision experiments. The relative standard deviations concern the 10
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calculated concentrations of spectinomycin and lincomycin. The repeatability was calculated
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on the basis of three consecutive injections at each concentration level. The inter-day
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precision was calculated on the basis of the results from two days in two weeks’ period. All
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data is summarized in Table 4.
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Also, the precision of the methods in sample analysis was evaluated using 6 solutions
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of Sample A at the test concentrations (see Section 3.4). Samples were tested due to
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determination of the percentage contents of spectinomycin dihydrochloride, lincomycin
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hydrochloride, (4R)-dihydrospectinomycin dihydrochloride and lincomycin B hydrochloride.
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The RSD values for the assay of spectinomycin and lincomycin were 0.3 % and 0.2 %,
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respectively. The RSD values for the content determination of (4R)-dihydrospectinomycin
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and lincomycin B were 0.8 % and 0.5 %, respectively.
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3.3.6. Robustness
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The methods’ robustness was evaluated during the method development. It was tested
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by the variation of the acetonitrile content (0 and 5 %), TFA content (0.2 and 0.4 %), column
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temperature (23 and 27 ºC) and flow rate (0.5 and 0.7 ml/min). The resolution (Rs) between
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the peaks was used as the robustness index. The method is robust for the column temperature
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± 2ºC and flow rate ± 0.1 ml/min. The acetonitrile and TFA content were demonstrated to be
249
critical parameters for the peaks resolution. Also, different C18 columns were investigated.
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Similar results were obtained when using TSKgel® ODS-100V column (150 x 4.6 mm; 3 μm,
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Tosoh Bioscience) and Ascentis® Express C18 column (150 x 4.6 mm; 5 μm, Sigma-Aldrich).
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3.3.7. Stability
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3.3.7.1. Stability of the methods
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The stability of the methods was investigated by conducting stress degradation studies
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under following conditions: heat (dry heat 80 ºC for 72 h), acidic hydrolysis (1M HCl, dry
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heat 80ºC for 2 h), basic hydrolysis (1M NaOH, dry heat 80 ºC for 2 h) and oxidation (H2O2
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3%, v/v, dry heat 80ºC for 0.5 h). The sample solutions at concentration of 500 µg/ml
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spectinomycin and 250 µg/ml lincomycin were analyzed. Then, peak’s purity was conducting
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by LC-ESI-MS-TOF. In all samples all peaks of interest had good peak purity.
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The stability studies showed that analyzed substances are sensitive to stress conditions.
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In heat conditions only small amount of both active substances decomposed, but during the
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both type of the hydrolysis and oxidation spectinomycin and lincomycin decomposed almost
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completely and a big amount of related compounds appeared.
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3.3.7.2. Stability of the solutions
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The stability of the standard and sample solutions was evaluated by repeated injections
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of the same samples during a period of 24 hours, one week and one month. Peak areas were
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compared. Lincomycin solutions were stable during the stability test. Spectinomycin solutions
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were unstable. After 24 hours, three other peaks appeared at the retention time of 5.6 min, 7.4
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dihydrospectinomycin anomers (retention time 5.6 min and 7.4 min) and impurity B
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(retention time 7.8 min.). After one month, the peak at retention time 7.8 min. increased
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significantly and the peak area of spectinomycin decreased slightly. Therefore, spectinomycin
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solutions for the related substances test were prepared immediately before use.
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min.
These
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3.4. Application to pharmaceutical preparations
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The developed and validated LC-CAD methods were tested on the commercially
277
available products. Peak areas were used for the calculations. The assay of spectinomycin was
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calculated according to Ph. Eur. Thus, the factor of 1.062 was applied for the calculation of
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spectinomycin
280
dihydrochloride [9]. The assay of the actives was determined in diluted samples (50 µg/ml of
sulphate
occurring
in
veterinary
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preparations
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lincomycin hydrochloride and 100 µg/ml of spectinomycin dihydrochloride after calculations)
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with a reference to standard solutions. The quantity of related substances was evaluated in
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samples at the concentration of 300 µg/ml of lincomycin hydrochloride and 500 µg/ml of
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spectinomycin dihydrochloride. Standard solutions at concentration 5 µg/ml of each active
285
substance were used.
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The assay of both actives was in agreement with the label. The content of
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spectinomycin impurities A, C, D, E and F (according to the Ph. Eur.) was less than LOQ (2
288
µg/ml). The quantity of other related substances and lincomycin B complied with
289
pharmacopoeial requirements, so both analyzed preparations were good quality products. All
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results are presented in Table 5.
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291 4. Conclusions
The elaborate LC-CAD methods provide a rapid, simple and robust analysis for
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lincomycin and lincomycin B, spectinomycin and its related substances, due to a simple
295
composition of the mobile phases and a relatively short analysis time. The proposed
296
methodology may be applied successfully for the routine analysis of samples that contain only
297
one active agent or a mixture of such agents. In this paper we have demonstrated a Corona®
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CAD to be an ideal detector for the analysis of different non-chromophore compounds
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without any derivatization. It enables the direct quantitation of related substances for which
300
no reference standards are available, with good accuracy and precision. Due to unique
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synergistic approach with MS and ELSD to the mobile phase composition (only volatile
302
components), the developed chromatographic conditions may be transferred directly from an
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LC-CAD analysis to an LC-MS or LC-ELSD analysis. However, unlike these detectors, CAD
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is more reproducible and robust. To the best of our knowledge, no analytical method has been
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proposed for the simultaneous quantitation of lincomycin and spectinomycin and its
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impurities in pharmaceuticals by LC-CAD so far.
307 Acknowledgements
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Authors thank Sigma-Aldrich Poland for providing an Ascentis® Express column for this
310
project.
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311 Figure Legends
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Fig. 1. Chemical structures of lincomycin and its related substances.
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Fig. 2. Chemical structures of spectinomycin and its related substances.
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Fig. 3. LC-CAD chromatogram acquired for a mixture of Spectinomycin dihydrochloride
319
CRS
µg/ml)
and
Lincomycin
hydrochloride
CRS
(250
µg/ml)
solutions.
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(500
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Fig. 4. MS and MS/MS spectra acquired for Spectinomycin dihydrochloride CRS solution
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(500 µg/ml) and ESI-MS2 fragmentation pathways of spectinomycin.
323 324
Referencesp 1
A. Hamdy, D. Kratze, L. Paxton, B. Roberts, Effect of a single injection of lincomycin, spectinomycin, and linco-spectin on early chick mortality caused by Escherichia coli and Staphyllococcus aureus, Avian Dis. 23 (1979) 164-173. 2 D. Jordan, C. Venning, Treatment of ovine dermatophilosis with long-acting oxytetracycline or a lincomycin-spectinomycin combination, Aust. Vet. J. 72 (1995) 234-236. 3 J. Sherrard, Gonorrhoea, Medicine 38 (2010) 245-248. 4 M. Chiu, H. Yang , C. Liu, J. Zen, Determination of lincomycin in urine and some foodstuffs by flow injection analysis coupled with liquid chromatography and electrochemical
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detection with a preanodized screen-printed carbon electrode, J. Chromatogr. B 877 (2009) 991-994. 5 D. Sin, Y. Wong, A. Ip, Quantitative analysis of lincomycin in animal tissues and bovine milk by liquid chromatography electrospray ionization tandem mass spectrometry, J. Pharm. Biomed. Anal. 34 (2004) 651–659. 6 M. Dousa, Z. Sikac , M. Halama, K. Lemr, HPLC determination of lincomycin in premixes and feedstuffs with solid-phase extraction on HLB OASIS and LC–MS/MS confirmation, J. Pharm. Biomed. Anal. 40 (2006) 981-986. 7 European Pharmacopoeia ver. 8.5, Monograph 01/2012:0583, Council of Europe, Strasbourg, France (2015). 8 European Pharmacopoeia ver. 8.5, Monograph 01/2008:1152, Council of Europe, Strasbourg, France (2015). 9 European Pharmacopoeia ver. 8.5, Monograph 01/2008:1658, Council of Europe, Strasbourg, France (2015). 10 USP 35, monograph: Spectinomycin dihydrochloride,4679, USA, 2012. 11
USP 35, monograph: Spectinomycin for injectable suspension,4680, USA, 2012. H. Yan, P. Xu, H. Huang, J. Qiu, Analysis of spectinomycin in fermentation broth by reversed-phase chromatography, Chem. Pap. 63 (2009) 635-640. 13 N. Haagsma, P. Scherpenisse, R.J. Simmonds, S.A. Wood, S.A Rees, High-performance liquid chromatographic determination of spectinomycin in swine, calf and chicken plasma using post-column derivatization, J. Chromatogr. B 672 (1995) 165-171. 14 A. Bergwerff, P. Scherpenisse, N. Haagsma, HPLC determination of residues of spectinomycin in various tissue types from husbandry animals, Analyst 123 (1998) 21392144. 15 D. Debremaeker, E. Adams, E. Nadal, B. van Hove, E. Roets, J. Hoogmartens, Analysis of spectinomycin by liquid chromatography with pulsed electrochemical detection, J. Chromatogr. A 953 (2002) 123-132. 16 L. Elrod, J.F. Brauer, S.L. Messner, Determination of spectinomycin dihydrochloride by liquid chromatography with electrochemical detection, Pharm. Res. 5 (1988) 664-667. 17 J.G. Phillips, C. Simmonds, Determination of spectinomycin using cation-exchange chromatography with pulsed amperometric detection, J. Chromatogr. A 675 (1994) 123-128. 18 M.C. Carson, D.N. Heller, Confirmation of spectinomycin in milk using ion-pair solidphase extraction and liquid chromatography–electrospray ion trap mass spectrometry, J. Chromatogr. B 718 (1998) 95-102. 19 H. Berrada, J.C. Moltó, J. Mañes, G. Font, Determination of aminoglycoside and macrolide antibiotics in meat by pressurized liquid extraction and LC-ESI-MS, J. Sep. Sci. 33 (2010) 522–529. 20 M.J Wang, Ch.Q Hu, Analysis of Spectinomycin by HPLC with Evaporative LightScattering Detection, Chromatographia 63, (2006) 255-260. 21 J. Wang , X. Hu, Y. Tu, K.Ni, Determination of spectinomycin hydrochloride and its related substances by HPLC–ELSD and HPLC–MSn, J. Chromatogr. B 834 (2006) 178-182.
Ac ce p
te
d
M
an
12
22
J. Zhou, L. Zhang, Y. Wang, Ch. Yan, HPLC-ELSD analysis of spectinomycin dihydrochloride and its impurities, J. Sep. Sci. 34 (2011) 1811-1819. 23 J. Szu´nyog, E. Adams, K. Liekens, E. Roets, J. Hoogmartens, Analysis of a formulation containing lincomycin and spectinomycin by liquid chromatography with pulsed electrochemical detection, J. Pharm. Biomed. Anal. 29 (2002) 213-220. 24 K. Vucicevic-Prcetic, R. Cservenak, N. Radulovic, Development and validation of liquid chromatography tandem mass spectrometry methods for the determination of gentamicin,
15
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te
d
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an
us
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lincomycin, and spectinomycin in the presence of their impurities in pharmaceutical formulations, J. Pharm. Biomed. Anal. 56 (2011) 736-742. 25 K. Stypulkowska, A. Blazewicz, Z. Fijalek, M. Warowna-Grzeskiewicz, K. Srebrzynska, Determination of neomycin and related substances in pharmaceutical preparations by reversed-phase high performance liquid chromatography with mass spectrometry and charged aerosol detection, J. Pharm. Biomed. Anal. 76 (2013) 207-214. 26 S. Almeling, D. Ilko, U. Holzgrabe, Charged aerosol detection in pharmaceutical analysis, J. Pharm. Biomed. Anal. 69 (2012) 50-63. 27 K. Stypulkowska, A. Blazewicz, Z. Fijalek, K. Sarna, Determination of Gentamicin Sulphate Composition and Related Substances in Pharmaceutical Preparations by LC with Charged Aerosol Detection, Chromatographia 72 (2010) 1225-1229. 28 U. Holzgrabe, C.J. Nap, N. Kunz, S. Almeling, Identification and control of impurities in streptomycin sulfate by high-performance liquid chromatography coupled with mass detection and corona charged aerosol detection, J. Pharm. Biomed. Anal. 56 (2011) 271279. 29 A. Joseph, S. Patel, A. Rustum, Development and validation of a RP-HPLC method for the estimation of netilmicin sulfate and its related substances using charged aerosol detection, J. Chromatogr. Sci. 48 (2010) 607-612. 30 International Conference on Harmonization (ICH), Topic Q2 (R1): Validation of Analytical Procedures: Text and Methodology, Geneva, 2005, www.emea.europa.eu/pdfs/human/ich/038195en.pdf 31 R.W. Dixon, D.S. Peterson, Development and testing of a new detector for liquid chromatography based on aerosol charging, Anal. Chem. 74 (2002) 2930-2937. 32 T. Vehovec, A. Obreza, Review of operating principle and applications of the charged aerosol detector, J. Chromatogr. A 1217 (2010) 1549-1556.
16
Page 16 of 26
cr
i
*Graphical Abstract
Intens.
+MS, 6.8 min.
351.18
us
x105
M an
1.0
333.18 0.0 100
150
ce pt
ed
Intens.
HPLC
250
300
350
5
6
400
450
7
8
500 m/z
(TIC)
1.0
1 : 10
Ac
T-split
MS
[x1 MS 04] 2.0
200
0.0
CAD [mAU] 10.0 5.0 0.0
1
2
3
4
9 Time [min]
CAD Page 17 of 26
cr
ip t
Table(s)
B (%, v/v)
0.0
98
2
12.0
98
2
12.1
80
18.0
80
18.1
98
2
us
A (%, v/v)
an
Time (min)
M
Table 1. Elution program used in the final chromatographic conditions.
20
Ac c
ep te
d
20
Page 18 of 26
cr
ip t
Table2
us
Table 2. Peak assignment of spectinomycin related substances in LC-CAD on the basis of LC-MS/MS results. Compound
Chemical formula
m/z [M+H]+
m/z [M+H2O+H]+
0.63
Impurity A
C8H18N2O4
207.14
n.a.*
0.66
Impurity F
C14H26N2O7
335.18
353.19
0.76
Impurity D
C14H26N2O8
351.18
369.19
C14H24N2O7
333.17
351.18
C14H26N2O7
335.18
n.a.
C13H22N2O7
337.16
M
Impurity E
319.15
1.00
Spectinomycin
C14H24N2O7
333.18
351.19
1.11
Dihydrospectinomycin anomer
C14H26N2O7
335.18
n.a.
1.20
Impurity B
C14H26N2O8
351.18
n.a.
1.31
4R-dihydrospectinomycin
C14H26N2O7
335.37
n.a.
1.45
Unknown impurity
C13H24N2O6
305.18
n.a.
1.61
Impurity C
C14H26N2O7
335.18
n.a.
Ac c
0.93
ep te
0.87
Spectinomycin anomer Dihydrospectinomycin anomer
d
0.80
an
RRT*
* RRT = relative retention time to retention time of spectinomycin, n.a. = not applicable
Page 19 of 26
cr
ip t
Table3
LOQ (μg/ml)
Range (μg/ml)
R2
Equation
R2
y = 0.0101x + 0.0007
0.9998
y = 0.0093x1.0287
0.9998
y = 0.0069x + 0.2116
0.9990
y = 0.0212x0.8148
0.9990
1 - 25
y = 0.0259x + 0.0268
0.9968
y = 0.0346x0.9366
0.9968
40 - 120
y = 0.0190x + 0.3152
0.9991
y = 0.0506x0.8216
0.9991
M
1.0
80 - 200
ep te
d
0.3
2.0
Ac c
Lincomycin
0.5
Power function (y = bxa)
Equation
2 - 45 Spectinomycin
Linear function (y = ax+b)
an
Compound
LOD (μg/ml)
us
Table 3. LOD, LOQ and regression data of spectinomycin and lincomycin determined by LC-CAD.
Page 20 of 26
cr
ip t
Table4
Spectinomycin 80 - 180
Lincomycin
1.65 ± 0.07 10.09 ± 0.09 25.07 ± 0.04 44.51 ± 0.44
84.2 103.2 102.5 101.1
79.81 ± 0.97 100.78 ± 1.72 123.14 ± 2.53 151.41 ± 1.63 180.73 ± 3.95 1.03 ± 0.00 2.51 ± 0.04 5.05 ± 0.06 10.19 ± 0.03
97.7 98.7 100.5 98.9 98.3 100.4 98.5 99.0 99.8
0.43 0.69 1.02 0.65 1.59 0.00 0.02 0.02 0.01
0.5 0.7 0.8 0.4 0.9 0.1 0.6 0.5 0.1
0.40 0.81 1.41 0.87 1.92 0.00 0.01 0.02 0.11
0.5 0.8 1.2 0.6 1.1 0.4 0.6 0.4 1.0
39.64 ± 0.41 51.63 ± 0.19 63.24 ± 0.17 84.12 ± 0.33 103.82 ± 0.54 122.51 ± 1.09
97.0 101.1 103.2 103.0 101.7 100.0
0.17 0.07 0.06 0.13 0.22 0.44
0.4 0.1 0.1 0.2 0.2 0.4
0.37 0.18 0.51 0.40 0.78 0.53
1.0 0.3 0.8 0.5 0.8 0.4
81.68 102.10 122.52 153.15 183.78 1.02 2.55 5.11 10.21
40 - 120
an
1.96 9.78 24.45 44.01
Ac c
1 - 10
Accuracy (%)
M
2 - 45
Inter-day precision (n=6) SD RSD (μg/ml) (%) 0.04 2.2 0.26 2.5 0.37 1.5 0.96 2.2
Concentration found mean ± t S x , p = 0.05 (μg/ml)
d
Range
Intra-day precision (n=3) SD RSD (μg/ml) (%) 0.03 1.8 0.04 0.3 0.02 0.9 0.18 0.1
Concentration added (μg/ml)
ep te
Compound
us
Table 4. Precision and accuracy data of spectinomycin and lincomycin determined by LC-CAD.
40.85 51.05 61.27 81.69 102.12 122.54
Page 21 of 26
cr
ip t
Table5
Table 5.
Linc. B
Spect.+ 4R-DHS
4RDHS
A (legal)
100.1
2.6
101.3
1.2
B (illegal)
103.3
0.3
100.9
0.6
Imp.A
Imp.C
Imp.D
an
Linc.+ Linc. B
< LOQ (~0.01) < LOQ (~0.01)
< LOQ (~0.01) < LOQ (~0.01)
Imp.E
0.1
0.2
< LOQ (~0.05)
0.2
Imp.F < LOQ (~0.01) < LOQ (~0.01)
Other
Sum of imp.
0.2
0.5
0.1
0.3
Ac c
ep te
d
M
Sample
us
Determination of active substances and impurities of spectinomycin in commercial samples by LC-CAD (%, m/m).
Page 22 of 26
N H
N H
O
R2
R1
R2
Lincomycin
CH3
C3H7
OH
Lincomycin B
CH3
C2H5
OH
Impurity A (α-amide epimer)
CH3
C3H7
Impurity C
H
C3H7
CH3
C3H7
S
Impurity D (7-epi-lincomycin)
H 3C N
H
N H
CH 3 OH H O
OH
O
N H
HO OH
OH S
Ac c
H 3C H 3C
H3C
ep te
HO O H
d
M
H3C
Compound
us
R1
CH3 OH H
an
HO O H
Impurity B (propylidene analogues)
cr
ip t
Figure1
H
CH3 OH H
H2N O
OH
"
H3C Impurity E (4-propyl hygric acid)
H3C
OH
S
Impurity F (methyl-1-thiolincosaminide)
Page 23 of 26
HO
R1
O O
H
O
Spectinomycin
CH3
OH R3 R2
R1
CH3
R4
R2
R3
R4
R2+R3=O
H
(4R-dihydrospectinomycin)
CH3
OH
H
H
Impurity C (4S-dihydrospectinomycin)
CH3
H
OH
H
Impurity D (dihydroxyspectinomycin)
CH3
H
OH
OH
Impurity E (N-desmethylspectinomycin)
H
R2+R3=O
H
Impurity G (tetrahydroxyspectinomycin)
CH3
R2+R3=O
OH
OH OH
HO H3C
Ac c
H3C
H N
ep te
d
M
HN
H
Compound
us
HN
OH H
an
CH3
cr
ip t
Figure2
OH
NH
Impurity A (Actinamine)
H3C
H N
CH3 OH H
COOH OH
HO H3C
O
O
H3C
H N
OH H
Impurity B (Actinospectinoic acid)
O
OH
H
H OH
NH
O
O OH
HO H3C
NH
CH3
Impurity F (Triol spectinomycin)
Page 24 of 26
Ac
ce pt
ed
M an
us
cr
i
Figure3
Page 25 of 26
i
Figure4
cr
Intens. +MS, 6.8min x105
us
351.177
1.0
100
150
M an
0.0
200
Intens. x105 +MS2 (351.177), 24eV
300
ed
1.2 m/z 207
350
400
450
500
m/z
C14H27N2O8 351.177
m/z 126
OH
1.0
ce pt
CH3NH
0.8
HO
O
O
0.6
CH3
OH O m/z 305
m/z 153
Ac
+ H2O
m/z 315
O
NHCH3
0.4
333.167
247.132 250
m/z 351 m/z 333
m/z 189
- H2O C14H25N2O7 333.167 - H2O C14H23N2O6 - CO 315.157 C13H24N2O6 305.157
0.2 - H2O C H N O C8H13N2O C8H17N2O3 8 19 2 4 207.135 153.103 189.125 100
150
200
250
300
350
m/z
Page 26 of 26
S0731-7085(15)00213-7 http://dx.doi.org/doi:10.1016/j.jpba.2015.03.036 PBA 10029
To appear in:
Journal of Pharmaceutical and Biomedical Analysis
Received date: Revised date: Accepted date:
16-1-2015 27-3-2015 29-3-2015
Please cite this article as: K. Stypulkowska, A. Blazewicz, A. Brudzikowska, M.W. Grzeskiewicz, K. Sarna, Z. Fijalek, Development of high performance liquid chromatography methods with charged aerosol detection for the determination of lincomycin, spectinomycin and its impurities in pharmaceutical products, Journal of Pharmaceutical and Biomedical Analysis (2015), http://dx.doi.org/10.1016/j.jpba.2015.03.036 This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
Simple and repeatable LC-CAD methods have been developed and tested.
2
A parallel connection of HPLC system with MS and CAD was used.
3
All peaks were identified by HPLC-MS/MS-TOF.
4
Methods could be used as routine assay and purity test methods of pharmaceuticals.
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1
5
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6 87
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9
1
Page 1 of 26
9
Development of high performance liquid chromatography methods
10
with charged aerosol detection for the determination of
11
lincomycin, spectinomycin and its impurities in pharmaceutical products
ip t
12 K. Stypulkowskaa*, A. Blazewicza, A. Brudzikowskaa,b ,
14
M. Warowna – Grzeskiewicza,c , K. Sarnaa, Z. Fijaleka,b a
National Medicines Institute, Pharmaceutical Chemistry Department, 30/34 Chelmska Str.,
16
00-725 Warsaw, Poland
17
b
18
Medical University of Warsaw, Department of Bioanalysis and Drug Analysis,
c
20
an
1 Banacha Str., 02-097 Warsaw, Poland
19
Medical University of Warsaw, Department of Inorganic and Analytical Chemistry, 1 Banacha Str., 02-097 Warsaw, Poland
M
21
Abstract
d
22 23
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15
cr
13
Novel and simple liquid chromatography methods with charged aerosol detection (LC-
25
CAD) for simultaneous quantitation of lincomycin and spectinomycin and its related
26
substances have been developed and tested. This type of analysis is complicated due to the
27
different chromatographic behavior of these two agents and the lack of chromophores in
28
spectinomycin complex. CAD seems to be a promising alternative to overcome these
29
difficulties. It shows a consistent inter-analyte response, independent of chemical structure of
30
an analyte. It also enables the direct quantification of related substances for which no
31
reference standards were available, with good accuracy and precision. Chromatographic
32
separations were achieved using a C18 Hypersil® Gold column, with mobile phases consisting
33
of water, acetonitrile and trifluoroacetic acid. All impurities were identified using time-of-
34
flight mass spectrometry with electrospray ionization. The developed methods have been
35
successfully used in the routine quality control analysis of pharmaceutical preparations.
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2
Page 2 of 26
36 37 38 39
* Corresponding author, Tel.: +48 228412121, Fax: +48 223311563 e-mail address: [email protected] (K. Stypulkowska) Keywords: charged aerosol detector; spectinomycin; lincomycin; related substances.
41
ip t
40 1. Introduction
Spectinomycin produced by Streptomyces spectabilis belongs to aminoglycoside
43
antibiotics and lincomycin produced by Streptomyces lincolnensis is a lincosamide antibiotic.
44
Pharmaceuticals being a combination of these two antibiotics (in a 2:1 ratio) are widely used
45
in veterinary medicine for the treatment of bacterial gastrointestinal and respiratory infections
46
[11,22]. In human medicine, spectinomycin is used principally against Neisseria gonorrhoeae
47
[[33]]. Due to their natural synthesis, both of them remain a mixture of similar compounds.
48
Spectinomycin is the principal component of its complex. In solution, it undergoes a ring
49
opening and closure of the hemiketal function. This results in an equilibrium mixture of four
50
possible anomers, which may, or may not, co-elute in a chromatographic analysis. The
51
chemical structures of both mentioned antibiotic and their related substances are presented in
52
Fig. 1 and Fig. 2.
us
an
M
d
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Ac ce p
53
cr
42
Few chromatographic methods combined with electrochemical detection (ED) [[44]]
54
and mass spectrometry (MS) [[55],[66]] have been reported in literature for the determination
55
of lincomycin. The European Pharmacopoeia (Ph. Eur.) defines a HPLC-UV method for
56
lincomycin assay and related substances test [[77]]. This method is rather simple to apply, it
57
uses a very popular UV detector and a C8 column and produces repeatable results, so it may
58
be used in a routine analysis successfully.
59
For spectinomycin, the current Ph. Eur. monographs define a reversed phase HPLC-
60
ED method after post-column derivatization [[88],[99]], whereas the United States
61
Pharmacopoeia (US pharmacopoeia ) prescribes gas chromatography with flame ionization
3
Page 3 of 26
detection (GC-FID) [[1010],[1111]] for the assay determination, without defining the related
63
substances test. Pharmacopoeial methods are hardly reproducible, so other methods have been
64
developed. Some are performed using pre-column or post-column derivatization procedures
65
[[1212],[1313],[1414]], which are typically cumbersome, difficult to reproduce and may
66
result in introduction of non-controlled impurities. Therefore, non-derivatizing HPLC
67
methods with ED [[1515],[1616],[1717]], MS [[1818],[1919]] and evaporative light scattering
68
detection (ELSD) [[2020],[2121],[2222]] have been developed.
cr
ip t
62
As far as we are aware, there are only two chromatographic methods with pulsed
70
amperometric detector (PAD) [[2323]] or MS [[2424]] describing the simultaneous
71
determination of both compounds in pharmaceuticals in one run. This type of analysis is
72
complicated due to the difference in the chromatographic behavior of these two agents.
M
an
us
69
Corona Charged Aerosol Detection (CAD) seems to be a promising alternative to
74
overcome the difficulties mentioned above. It shows consistent inter-analyte response,
75
independent of chemical structures of an analyte, under identical mobile phase and CAD
76
conditions.Its features have been described previously [[2525]] and An extensive overview of
77
CAD’s applications has been reported by Almeling et al. [[2626]]. Also, its usefulness in the
78
quantitative analysis of aminoglycosides has been reported [25,[2727],[2828],[2929]].
te
Ac ce p
79
d
73
This manuscript describes the development and validation of simple, repeatable and
80
accurate HPLC-CAD methods to determine the assay of lincomycin and spectinomycin with
81
its related substances in 18 minutes.
82 83
2. Materials and methods
84
2.1. Chemicals
85
All reagents were LC grade: methanol (MeOH) and acetonitrile (ACN) (Rathburn
86
Chemicals Ltd., Walkerburn, Scotland), trifluoroacetic acid (TFA) (AppliChem GmbH,
4
Page 4 of 26
Darmstadt, Denmark). Doubly distilled water additionally purified in the Nanopure
88
DiamondTM UV Deionization System from Barnstead (a part of Thermo Scientific, Marietta,
89
United States) was used throughout. Reference standards: Lincomycin hydrochloride CRS,
90
Spectinomycini dihydrochloridum CRS and Spectinomycin hydrochloride for system
91
suitability CRS containing impurities A, C, D, E, F and G were purchased from EDQM
92
(Strasbourg, France).
cr
ip t
87
The methods were tested on two products: soluble powder containing lincomycin
94
hydrochloride and spectinomycin sulphate at the concentration of 222 g + 444 g/1000g,
95
respectively (Sample A), and solution for injection containing 50 mg/ml of lincomycin
96
hydrochloride hydrate and 100 mg/ml of spectinomycin sulphate tetrahydrate (Sample B).
97
The interesting fact is that both products had the same trade name, but one was a registered
98
and commercially available pharmaceutical product. The other one was not registered in
99
Poland (the illegal product), but it was provided from the legal Polish market.
an
M
2.2. Equipment and conditions
d
100
us
93
An LC UltiMate® 3000 system consisted of a pump, a degasser, an autosampler, a
102
column heater and a pulse damper (DionexTM Softron GmbH, a part of Thermo Scientific,
103
Germering, Germany) was used. LC system was coupled simultaneously to a CoronaTM ultra
104
RSTM Charged Aerosol Detector (Thermo Scientific TM DionexTM) and a maXis 4G mass
105
spectrometer (Bruker Daltonik GmbH, Bremen, Germany) by a 1/10 T-split. Nitrogen
106
generator LCMS30-0 (Parker Donick Hunter, Cleveland, OH, USA) provided nitrogen gas to
107
the both aerosol detectors. Additional nitrogen of high purity >99 % was introduced to the
108
collision cell from a nitrogen cylinder. The CAD detection was performed using a medium
109
filter and the 100 pA detection range. LC-CAD data were processed with ChromeleonTM 7
110
and ChromeleonTM Validation ICH softwares (Thermo ScientificTM DionexTM).
Ac ce p
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5
Page 5 of 26
A time-of-flight mass spectrometer with electrospray ionization (ESI-MS-TOF) maXis
112
4G from Bruker Daltonik was used for the peaks’ identification. The MS settings were: ESI
113
in the positive ion mode, dry gas (nitrogen) flow rate 8.0 l/min, the dry heater 180°C, the
114
capillary voltage 4500 V and end plate offset 500 V. MS data were recorded in the full scan
115
mode (from 50 to 1000 m/z). MS data analysis was evaluated with Hystar 3.2., ESI Compass
116
1.3 for micrOTOF/maXis and Data Analysis® Version 4.0 SP 4 softwares from Bruker
117
Daltonik.
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111
The chromatographic separations by LC-CAD were performed on a C18 Hypersil®
119
Gold analytical column (150 x 4.6 mm; 3 μm particle size, Thermo Scientific). The mobile
120
phases consisted of a mixture of 0.3 % TFA and acetonitrile in a ratio 98:2 (v/v) for
121
spectinomycin analysis and 80:20 (v/v) for lincomycin analysis, respectively. A flow rate was
122
0.6 ml/min, a column temperature was set at 25oC. Samples were maintained at 8oC in
123
autosampler and the injection volume was 10 µl in partial loop injection mode.
d
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118
125
te
124
2.3. Standard Solutions Preparation
The standards of the analyzed substances were accurately weighed into volumetric
Ac ce p
126 127
flasks and dissolved with water to produce stock solutions, which were successively diluted
128
with water to obtain the required concentrations.
129
2.4. Sample Preparation
130
Samples were dissolved and diluted with water. For the assay determination samples
131
were prepared and left for 24 h so that equilibrium between spectinomycin and its anomers
132
was reached. For related substances tests, the solutions were prepared immediately before use
133
[8].
134
6
Page 6 of 26
135
3. Results and Discussion
136
3.1. LC methods development The hydrophilic nature of both compounds demanded the use of a rather highly
138
aqueous mobile phase with addition of an ion-pair agent. Different water-MeOH and water-
139
ACN mobile phases with addition of TFA or HFBA in isocratic and gradient elution modes
140
were investigated. A Hypersil® Gold C18 column was used, because it was suitable for the
141
analysis of other aminoglycosides previously [25,27]. The noise level when using HFBA was
142
too high, so TFA was chosen for further investigations. Mixtures of water-ACN showed a
143
more powerful separation. The effect of ACN content (0, 5, 10, 20, 40 %), TFA content (0.1,
144
0.2, 0.3, 0.4 %), flow rate (0.5, 0.6, 0.7 ml/min) and column temperature (20, 25, 35ºC) on the
145
peaks’ resolution were studied.
M
an
us
cr
ip t
137
For the spectinomycin analysis, the best mobile phase composition was 0.3 % TFA-
147
ACN in a 98:2 (v/v) ratio, whereas for lincomycin assay a higher content of acetonitrile (20
148
%) was demanded. To circumvent this problem, a one-step gradient was introduced in the 12
149
minute after the spectinomycin analysis. With such gradient each compound was eluted on a
150
defined plateau with a constant mobile phase composition, that is crucial for the usefulness of
151
CAD’s universal response. What is more, depending on the type of the analyzed product, each
152
analysis part may be used separately. The final elution program used is described in Table 1.
153
After each run a four-minute step in the initial chromatographic conditions, for the system
154
equilibration, was used.
te
Ac ce p
155
d
146
The other chromatographic parameters were as follow: a flow rate 0.6 ml/min, a
156
temperature column set at 25oC, a sampler temperature set at 8oC and the injection volume 10
157
µl. These conditions were optimal for the separation of ten related substances from the
158
spectinomycin in 12 minutes and for the separation lincomycin from lincomycin B and other
7
Page 7 of 26
159
impurities in 6 minutes. The representative LC-CAD chromatogram obtained under these
160
conditions is presented in Fig. 3. Also, different C18 columns were investigated. The best resolution was obtained with
162
the initial Hypersil® Gold column, however, similar results were also obtained when using a
163
TSKgel® ODS-100V column (150 x 4.6 mm; 3 μm, Tosoh Bioscience) and an Ascentis®
164
Express C18 column (150 x 4.6 mm; 5 μm, Sigma-Aldrich).
cr
165 3.2. Peaks assignment
us
166
ip t
161
Spectinomycin and lincomycin were identified as the major peaks in standard
168
solutions at 6.6 min and 15.3 min, respectively. The standards of (4R)-dihydrospectinomycin
169
and lincomycin B were not available, so they were identified as the minor peaks in standard
170
solutions and confirmed by LC-ESI-MS/MS-TOF at 8.6 min (4R)-dihydrospectinomycin) and
171
14.0 min (lincomycin B). Other impurities of spectinomycin were identified by injecting the
172
Spectinomycin for system suitability CRS solution (500 µg/ml) in the LC-MS full scan,
173
positive ion mode. Chromatograms were obtained by plotting the total ion current (TIC) as a
174
time function for [M+H]+ ions. For every peak MS and MS/MS spectra were recorded. The
175
MS spectra showed ions that were consistent with the expected protonated molecular ions
176
[M+H]+. However, for spectinomycin and impurities D and E the dominant ions were
177
[M+H2O+H]+. Figure 4 presents typical MS and MS/MS spectra and fragmentation pathways
178
of spectinomycin. The fragmentation scheme presented in this figure is also applicable to the
179
related substances.
Ac ce p
te
d
M
an
167
180
During the LC-CAD analysis a peak at the retention time of 9.7 min was found. The
181
LC-MS analysis identified its molecular ion mass as m/z [M+H]+ 305.2, which is 28 u less
182
than m/z [M+H]+ =333.2 of spectinomycin. This corresponds to a loss of carbon monoxide
183
from spectinomycin. Thus, the proposed molecular formula is C13H24N2O6.
8
Page 8 of 26
Degradation studies (see Section 3.3.7.1.) showed that during basic hydrolysis a big
185
peak at 7.8 min has appeared. On the basis of LC-ESI-MS/MS-TOF analysis this peak was
186
identified as the actinospectinoic acid (impurity B). The full peak assignment on the basis of
187
LC-ESI-MS/MS-TOF results is presented in Table 2.
ip t
184
188 3.3. Method validation
cr
189
The quantitative aspects of the proposed methods were examined according to the ICH
191
guideline [[3030]]. Validation parameters were evaluated using standard solutions of
192
spectinomycin dihydrochloride and lincomycin hydrochloride. Peak areas were evaluated in
193
the whole validation, except the LOD and LOQ determination.
194
3.3.1. Specificity
M
an
us
190
The specificity of the proposed method was determined by comparing any interfering
196
peaks from the blank injection and by checking peak purity of each peak via LC-ESI-MS-
197
TOF. The LC-MS analysis demonstrated no co-elution of any peak of interest. Also, two
198
peaks from the mobile phase at retention time of 3.5 and 3.8 min were observed, but no
199
interferences with the other peaks occurred (Fig. 3).
200
3.3.2. Linearity
te
Ac ce p
201
d
195
For both active substances the linearity was tested in two concentration ranges: the
202
first one for the assay and the second one for the related substances quantitation. Six
203
concentration levels were included. in the investigating ranges, in triplicate injections at each
204
level.
205
The obtained results were plotted as a linear and power function. The results are
206
presented in Table 3. There were no differences in the investigated ranges in the coefficient of
207
determination values (R2) between the linear and power functions. The linearity was found
9
Page 9 of 26
with very good R2 values, for both compounds, within a concentration range of one-order of
209
magnitude. The obtained results confirmed that, although the CAD response is nonlinear at a
210
range of four orders of magnitude, the signal is nearly linear in the smaller ranges
211
[[3131],[3232]].
212
3.3.3. Limits of detection and quantitation
ip t
208
The detection limit (LOD) and quantitation limit (LOQ) were defined as a signal-to-
214
noise ratio of 3:1 and 10:1, respectively. Peaks heights were evaluated for this validation
215
parameter. For lincomycin the LOD and LOQ values were 0.3 µg/ml and 1.0 µg/ml,
216
respectively. For spectinomycin the LOD and LOQ values were 0.5 µg/ml and 2.0 µg/ml,
217
respectively.
an
us
cr
213
The LOD and LOQ values for lincomycin and spectinomycin are different, because
219
the mobile phase composition is different. CAD is an aerosol-based detector and the intensity
220
of the response depends on the composition of a mobile phase – the higher organic content is,
221
the higher response is observed.
222
3.3.4. Accuracy
d
te
Ac ce p
223
M
218
The accuracy of the methods was evaluated by injecting in triplicate standard solutions
224
covering the linearity range. It was assessed by calculating the difference between the
225
measured concentrations of standard solutions and their known concentrations, and expressed
226
as percentage. The concentrations of the active substances in standard solutions were
227
measured by putting the peak area into the calibration curve created during the linearity study.
228
The accuracy results are shown in Table 4 at the α = 0.05 and they are satisfactory.
229
3.3.5. Precision
230
The precision of the methods was determined by intra-day precision (repeatability) and
231
inter-day (intermediate) precision experiments. The relative standard deviations concern the 10
Page 10 of 26
calculated concentrations of spectinomycin and lincomycin. The repeatability was calculated
233
on the basis of three consecutive injections at each concentration level. The inter-day
234
precision was calculated on the basis of the results from two days in two weeks’ period. All
235
data is summarized in Table 4.
ip t
232
Also, the precision of the methods in sample analysis was evaluated using 6 solutions
237
of Sample A at the test concentrations (see Section 3.4). Samples were tested due to
238
determination of the percentage contents of spectinomycin dihydrochloride, lincomycin
239
hydrochloride, (4R)-dihydrospectinomycin dihydrochloride and lincomycin B hydrochloride.
240
The RSD values for the assay of spectinomycin and lincomycin were 0.3 % and 0.2 %,
241
respectively. The RSD values for the content determination of (4R)-dihydrospectinomycin
242
and lincomycin B were 0.8 % and 0.5 %, respectively.
243
3.3.6. Robustness
M
an
us
cr
236
The methods’ robustness was evaluated during the method development. It was tested
245
by the variation of the acetonitrile content (0 and 5 %), TFA content (0.2 and 0.4 %), column
246
temperature (23 and 27 ºC) and flow rate (0.5 and 0.7 ml/min). The resolution (Rs) between
247
the peaks was used as the robustness index. The method is robust for the column temperature
248
± 2ºC and flow rate ± 0.1 ml/min. The acetonitrile and TFA content were demonstrated to be
249
critical parameters for the peaks resolution. Also, different C18 columns were investigated.
250
Similar results were obtained when using TSKgel® ODS-100V column (150 x 4.6 mm; 3 μm,
251
Tosoh Bioscience) and Ascentis® Express C18 column (150 x 4.6 mm; 5 μm, Sigma-Aldrich).
252
3.3.7. Stability
253
3.3.7.1. Stability of the methods
Ac ce p
te
d
244
254
The stability of the methods was investigated by conducting stress degradation studies
255
under following conditions: heat (dry heat 80 ºC for 72 h), acidic hydrolysis (1M HCl, dry
11
Page 11 of 26
heat 80ºC for 2 h), basic hydrolysis (1M NaOH, dry heat 80 ºC for 2 h) and oxidation (H2O2
257
3%, v/v, dry heat 80ºC for 0.5 h). The sample solutions at concentration of 500 µg/ml
258
spectinomycin and 250 µg/ml lincomycin were analyzed. Then, peak’s purity was conducting
259
by LC-ESI-MS-TOF. In all samples all peaks of interest had good peak purity.
ip t
256
The stability studies showed that analyzed substances are sensitive to stress conditions.
261
In heat conditions only small amount of both active substances decomposed, but during the
262
both type of the hydrolysis and oxidation spectinomycin and lincomycin decomposed almost
263
completely and a big amount of related compounds appeared.
264
3.3.7.2. Stability of the solutions
an
us
cr
260
The stability of the standard and sample solutions was evaluated by repeated injections
266
of the same samples during a period of 24 hours, one week and one month. Peak areas were
267
compared. Lincomycin solutions were stable during the stability test. Spectinomycin solutions
268
were unstable. After 24 hours, three other peaks appeared at the retention time of 5.6 min, 7.4
269
min
270
dihydrospectinomycin anomers (retention time 5.6 min and 7.4 min) and impurity B
271
(retention time 7.8 min.). After one month, the peak at retention time 7.8 min. increased
272
significantly and the peak area of spectinomycin decreased slightly. Therefore, spectinomycin
273
solutions for the related substances test were prepared immediately before use.
275
min.
These
d
7.8
peaks
te
and
were
identified
by
LC-ESI/MS/MS-TOF
as
Ac ce p
274
M
265
3.4. Application to pharmaceutical preparations
276
The developed and validated LC-CAD methods were tested on the commercially
277
available products. Peak areas were used for the calculations. The assay of spectinomycin was
278
calculated according to Ph. Eur. Thus, the factor of 1.062 was applied for the calculation of
279
spectinomycin
280
dihydrochloride [9]. The assay of the actives was determined in diluted samples (50 µg/ml of
sulphate
occurring
in
veterinary
12
preparations
from
spectinomycin
Page 12 of 26
lincomycin hydrochloride and 100 µg/ml of spectinomycin dihydrochloride after calculations)
282
with a reference to standard solutions. The quantity of related substances was evaluated in
283
samples at the concentration of 300 µg/ml of lincomycin hydrochloride and 500 µg/ml of
284
spectinomycin dihydrochloride. Standard solutions at concentration 5 µg/ml of each active
285
substance were used.
ip t
281
The assay of both actives was in agreement with the label. The content of
287
spectinomycin impurities A, C, D, E and F (according to the Ph. Eur.) was less than LOQ (2
288
µg/ml). The quantity of other related substances and lincomycin B complied with
289
pharmacopoeial requirements, so both analyzed preparations were good quality products. All
290
results are presented in Table 5.
an
us
cr
286
292
M
291 4. Conclusions
The elaborate LC-CAD methods provide a rapid, simple and robust analysis for
294
lincomycin and lincomycin B, spectinomycin and its related substances, due to a simple
295
composition of the mobile phases and a relatively short analysis time. The proposed
296
methodology may be applied successfully for the routine analysis of samples that contain only
297
one active agent or a mixture of such agents. In this paper we have demonstrated a Corona®
298
CAD to be an ideal detector for the analysis of different non-chromophore compounds
299
without any derivatization. It enables the direct quantitation of related substances for which
300
no reference standards are available, with good accuracy and precision. Due to unique
301
synergistic approach with MS and ELSD to the mobile phase composition (only volatile
302
components), the developed chromatographic conditions may be transferred directly from an
303
LC-CAD analysis to an LC-MS or LC-ELSD analysis. However, unlike these detectors, CAD
304
is more reproducible and robust. To the best of our knowledge, no analytical method has been
Ac ce p
te
d
293
13
Page 13 of 26
305
proposed for the simultaneous quantitation of lincomycin and spectinomycin and its
306
impurities in pharmaceuticals by LC-CAD so far.
307 Acknowledgements
309
Authors thank Sigma-Aldrich Poland for providing an Ascentis® Express column for this
310
project.
cr
ip t
308
311 Figure Legends
us
312 313
Fig. 1. Chemical structures of lincomycin and its related substances.
an
314
316
M
315
Fig. 2. Chemical structures of spectinomycin and its related substances.
d
317
Fig. 3. LC-CAD chromatogram acquired for a mixture of Spectinomycin dihydrochloride
319
CRS
µg/ml)
and
Lincomycin
hydrochloride
CRS
(250
µg/ml)
solutions.
Ac ce p
320
(500
te
318
321
Fig. 4. MS and MS/MS spectra acquired for Spectinomycin dihydrochloride CRS solution
322
(500 µg/ml) and ESI-MS2 fragmentation pathways of spectinomycin.
323 324
Referencesp 1
A. Hamdy, D. Kratze, L. Paxton, B. Roberts, Effect of a single injection of lincomycin, spectinomycin, and linco-spectin on early chick mortality caused by Escherichia coli and Staphyllococcus aureus, Avian Dis. 23 (1979) 164-173. 2 D. Jordan, C. Venning, Treatment of ovine dermatophilosis with long-acting oxytetracycline or a lincomycin-spectinomycin combination, Aust. Vet. J. 72 (1995) 234-236. 3 J. Sherrard, Gonorrhoea, Medicine 38 (2010) 245-248. 4 M. Chiu, H. Yang , C. Liu, J. Zen, Determination of lincomycin in urine and some foodstuffs by flow injection analysis coupled with liquid chromatography and electrochemical
14
Page 14 of 26
us
cr
ip t
detection with a preanodized screen-printed carbon electrode, J. Chromatogr. B 877 (2009) 991-994. 5 D. Sin, Y. Wong, A. Ip, Quantitative analysis of lincomycin in animal tissues and bovine milk by liquid chromatography electrospray ionization tandem mass spectrometry, J. Pharm. Biomed. Anal. 34 (2004) 651–659. 6 M. Dousa, Z. Sikac , M. Halama, K. Lemr, HPLC determination of lincomycin in premixes and feedstuffs with solid-phase extraction on HLB OASIS and LC–MS/MS confirmation, J. Pharm. Biomed. Anal. 40 (2006) 981-986. 7 European Pharmacopoeia ver. 8.5, Monograph 01/2012:0583, Council of Europe, Strasbourg, France (2015). 8 European Pharmacopoeia ver. 8.5, Monograph 01/2008:1152, Council of Europe, Strasbourg, France (2015). 9 European Pharmacopoeia ver. 8.5, Monograph 01/2008:1658, Council of Europe, Strasbourg, France (2015). 10 USP 35, monograph: Spectinomycin dihydrochloride,4679, USA, 2012. 11
USP 35, monograph: Spectinomycin for injectable suspension,4680, USA, 2012. H. Yan, P. Xu, H. Huang, J. Qiu, Analysis of spectinomycin in fermentation broth by reversed-phase chromatography, Chem. Pap. 63 (2009) 635-640. 13 N. Haagsma, P. Scherpenisse, R.J. Simmonds, S.A. Wood, S.A Rees, High-performance liquid chromatographic determination of spectinomycin in swine, calf and chicken plasma using post-column derivatization, J. Chromatogr. B 672 (1995) 165-171. 14 A. Bergwerff, P. Scherpenisse, N. Haagsma, HPLC determination of residues of spectinomycin in various tissue types from husbandry animals, Analyst 123 (1998) 21392144. 15 D. Debremaeker, E. Adams, E. Nadal, B. van Hove, E. Roets, J. Hoogmartens, Analysis of spectinomycin by liquid chromatography with pulsed electrochemical detection, J. Chromatogr. A 953 (2002) 123-132. 16 L. Elrod, J.F. Brauer, S.L. Messner, Determination of spectinomycin dihydrochloride by liquid chromatography with electrochemical detection, Pharm. Res. 5 (1988) 664-667. 17 J.G. Phillips, C. Simmonds, Determination of spectinomycin using cation-exchange chromatography with pulsed amperometric detection, J. Chromatogr. A 675 (1994) 123-128. 18 M.C. Carson, D.N. Heller, Confirmation of spectinomycin in milk using ion-pair solidphase extraction and liquid chromatography–electrospray ion trap mass spectrometry, J. Chromatogr. B 718 (1998) 95-102. 19 H. Berrada, J.C. Moltó, J. Mañes, G. Font, Determination of aminoglycoside and macrolide antibiotics in meat by pressurized liquid extraction and LC-ESI-MS, J. Sep. Sci. 33 (2010) 522–529. 20 M.J Wang, Ch.Q Hu, Analysis of Spectinomycin by HPLC with Evaporative LightScattering Detection, Chromatographia 63, (2006) 255-260. 21 J. Wang , X. Hu, Y. Tu, K.Ni, Determination of spectinomycin hydrochloride and its related substances by HPLC–ELSD and HPLC–MSn, J. Chromatogr. B 834 (2006) 178-182.
Ac ce p
te
d
M
an
12
22
J. Zhou, L. Zhang, Y. Wang, Ch. Yan, HPLC-ELSD analysis of spectinomycin dihydrochloride and its impurities, J. Sep. Sci. 34 (2011) 1811-1819. 23 J. Szu´nyog, E. Adams, K. Liekens, E. Roets, J. Hoogmartens, Analysis of a formulation containing lincomycin and spectinomycin by liquid chromatography with pulsed electrochemical detection, J. Pharm. Biomed. Anal. 29 (2002) 213-220. 24 K. Vucicevic-Prcetic, R. Cservenak, N. Radulovic, Development and validation of liquid chromatography tandem mass spectrometry methods for the determination of gentamicin,
15
Page 15 of 26
Ac ce p
te
d
M
an
us
cr
ip t
lincomycin, and spectinomycin in the presence of their impurities in pharmaceutical formulations, J. Pharm. Biomed. Anal. 56 (2011) 736-742. 25 K. Stypulkowska, A. Blazewicz, Z. Fijalek, M. Warowna-Grzeskiewicz, K. Srebrzynska, Determination of neomycin and related substances in pharmaceutical preparations by reversed-phase high performance liquid chromatography with mass spectrometry and charged aerosol detection, J. Pharm. Biomed. Anal. 76 (2013) 207-214. 26 S. Almeling, D. Ilko, U. Holzgrabe, Charged aerosol detection in pharmaceutical analysis, J. Pharm. Biomed. Anal. 69 (2012) 50-63. 27 K. Stypulkowska, A. Blazewicz, Z. Fijalek, K. Sarna, Determination of Gentamicin Sulphate Composition and Related Substances in Pharmaceutical Preparations by LC with Charged Aerosol Detection, Chromatographia 72 (2010) 1225-1229. 28 U. Holzgrabe, C.J. Nap, N. Kunz, S. Almeling, Identification and control of impurities in streptomycin sulfate by high-performance liquid chromatography coupled with mass detection and corona charged aerosol detection, J. Pharm. Biomed. Anal. 56 (2011) 271279. 29 A. Joseph, S. Patel, A. Rustum, Development and validation of a RP-HPLC method for the estimation of netilmicin sulfate and its related substances using charged aerosol detection, J. Chromatogr. Sci. 48 (2010) 607-612. 30 International Conference on Harmonization (ICH), Topic Q2 (R1): Validation of Analytical Procedures: Text and Methodology, Geneva, 2005, www.emea.europa.eu/pdfs/human/ich/038195en.pdf 31 R.W. Dixon, D.S. Peterson, Development and testing of a new detector for liquid chromatography based on aerosol charging, Anal. Chem. 74 (2002) 2930-2937. 32 T. Vehovec, A. Obreza, Review of operating principle and applications of the charged aerosol detector, J. Chromatogr. A 1217 (2010) 1549-1556.
16
Page 16 of 26
cr
i
*Graphical Abstract
Intens.
+MS, 6.8 min.
351.18
us
x105
M an
1.0
333.18 0.0 100
150
ce pt
ed
Intens.
HPLC
250
300
350
5
6
400
450
7
8
500 m/z
(TIC)
1.0
1 : 10
Ac
T-split
MS
[x1 MS 04] 2.0
200
0.0
CAD [mAU] 10.0 5.0 0.0
1
2
3
4
9 Time [min]
CAD Page 17 of 26
cr
ip t
Table(s)
B (%, v/v)
0.0
98
2
12.0
98
2
12.1
80
18.0
80
18.1
98
2
us
A (%, v/v)
an
Time (min)
M
Table 1. Elution program used in the final chromatographic conditions.
20
Ac c
ep te
d
20
Page 18 of 26
cr
ip t
Table2
us
Table 2. Peak assignment of spectinomycin related substances in LC-CAD on the basis of LC-MS/MS results. Compound
Chemical formula
m/z [M+H]+
m/z [M+H2O+H]+
0.63
Impurity A
C8H18N2O4
207.14
n.a.*
0.66
Impurity F
C14H26N2O7
335.18
353.19
0.76
Impurity D
C14H26N2O8
351.18
369.19
C14H24N2O7
333.17
351.18
C14H26N2O7
335.18
n.a.
C13H22N2O7
337.16
M
Impurity E
319.15
1.00
Spectinomycin
C14H24N2O7
333.18
351.19
1.11
Dihydrospectinomycin anomer
C14H26N2O7
335.18
n.a.
1.20
Impurity B
C14H26N2O8
351.18
n.a.
1.31
4R-dihydrospectinomycin
C14H26N2O7
335.37
n.a.
1.45
Unknown impurity
C13H24N2O6
305.18
n.a.
1.61
Impurity C
C14H26N2O7
335.18
n.a.
Ac c
0.93
ep te
0.87
Spectinomycin anomer Dihydrospectinomycin anomer
d
0.80
an
RRT*
* RRT = relative retention time to retention time of spectinomycin, n.a. = not applicable
Page 19 of 26
cr
ip t
Table3
LOQ (μg/ml)
Range (μg/ml)
R2
Equation
R2
y = 0.0101x + 0.0007
0.9998
y = 0.0093x1.0287
0.9998
y = 0.0069x + 0.2116
0.9990
y = 0.0212x0.8148
0.9990
1 - 25
y = 0.0259x + 0.0268
0.9968
y = 0.0346x0.9366
0.9968
40 - 120
y = 0.0190x + 0.3152
0.9991
y = 0.0506x0.8216
0.9991
M
1.0
80 - 200
ep te
d
0.3
2.0
Ac c
Lincomycin
0.5
Power function (y = bxa)
Equation
2 - 45 Spectinomycin
Linear function (y = ax+b)
an
Compound
LOD (μg/ml)
us
Table 3. LOD, LOQ and regression data of spectinomycin and lincomycin determined by LC-CAD.
Page 20 of 26
cr
ip t
Table4
Spectinomycin 80 - 180
Lincomycin
1.65 ± 0.07 10.09 ± 0.09 25.07 ± 0.04 44.51 ± 0.44
84.2 103.2 102.5 101.1
79.81 ± 0.97 100.78 ± 1.72 123.14 ± 2.53 151.41 ± 1.63 180.73 ± 3.95 1.03 ± 0.00 2.51 ± 0.04 5.05 ± 0.06 10.19 ± 0.03
97.7 98.7 100.5 98.9 98.3 100.4 98.5 99.0 99.8
0.43 0.69 1.02 0.65 1.59 0.00 0.02 0.02 0.01
0.5 0.7 0.8 0.4 0.9 0.1 0.6 0.5 0.1
0.40 0.81 1.41 0.87 1.92 0.00 0.01 0.02 0.11
0.5 0.8 1.2 0.6 1.1 0.4 0.6 0.4 1.0
39.64 ± 0.41 51.63 ± 0.19 63.24 ± 0.17 84.12 ± 0.33 103.82 ± 0.54 122.51 ± 1.09
97.0 101.1 103.2 103.0 101.7 100.0
0.17 0.07 0.06 0.13 0.22 0.44
0.4 0.1 0.1 0.2 0.2 0.4
0.37 0.18 0.51 0.40 0.78 0.53
1.0 0.3 0.8 0.5 0.8 0.4
81.68 102.10 122.52 153.15 183.78 1.02 2.55 5.11 10.21
40 - 120
an
1.96 9.78 24.45 44.01
Ac c
1 - 10
Accuracy (%)
M
2 - 45
Inter-day precision (n=6) SD RSD (μg/ml) (%) 0.04 2.2 0.26 2.5 0.37 1.5 0.96 2.2
Concentration found mean ± t S x , p = 0.05 (μg/ml)
d
Range
Intra-day precision (n=3) SD RSD (μg/ml) (%) 0.03 1.8 0.04 0.3 0.02 0.9 0.18 0.1
Concentration added (μg/ml)
ep te
Compound
us
Table 4. Precision and accuracy data of spectinomycin and lincomycin determined by LC-CAD.
40.85 51.05 61.27 81.69 102.12 122.54
Page 21 of 26
cr
ip t
Table5
Table 5.
Linc. B
Spect.+ 4R-DHS
4RDHS
A (legal)
100.1
2.6
101.3
1.2
B (illegal)
103.3
0.3
100.9
0.6
Imp.A
Imp.C
Imp.D
an
Linc.+ Linc. B
< LOQ (~0.01) < LOQ (~0.01)
< LOQ (~0.01) < LOQ (~0.01)
Imp.E
0.1
0.2
< LOQ (~0.05)
0.2
Imp.F < LOQ (~0.01) < LOQ (~0.01)
Other
Sum of imp.
0.2
0.5
0.1
0.3
Ac c
ep te
d
M
Sample
us
Determination of active substances and impurities of spectinomycin in commercial samples by LC-CAD (%, m/m).
Page 22 of 26
N H
N H
O
R2
R1
R2
Lincomycin
CH3
C3H7
OH
Lincomycin B
CH3
C2H5
OH
Impurity A (α-amide epimer)
CH3
C3H7
Impurity C
H
C3H7
CH3
C3H7
S
Impurity D (7-epi-lincomycin)
H 3C N
H
N H
CH 3 OH H O
OH
O
N H
HO OH
OH S
Ac c
H 3C H 3C
H3C
ep te
HO O H
d
M
H3C
Compound
us
R1
CH3 OH H
an
HO O H
Impurity B (propylidene analogues)
cr
ip t
Figure1
H
CH3 OH H
H2N O
OH
"
H3C Impurity E (4-propyl hygric acid)
H3C
OH
S
Impurity F (methyl-1-thiolincosaminide)
Page 23 of 26
HO
R1
O O
H
O
Spectinomycin
CH3
OH R3 R2
R1
CH3
R4
R2
R3
R4
R2+R3=O
H
(4R-dihydrospectinomycin)
CH3
OH
H
H
Impurity C (4S-dihydrospectinomycin)
CH3
H
OH
H
Impurity D (dihydroxyspectinomycin)
CH3
H
OH
OH
Impurity E (N-desmethylspectinomycin)
H
R2+R3=O
H
Impurity G (tetrahydroxyspectinomycin)
CH3
R2+R3=O
OH
OH OH
HO H3C
Ac c
H3C
H N
ep te
d
M
HN
H
Compound
us
HN
OH H
an
CH3
cr
ip t
Figure2
OH
NH
Impurity A (Actinamine)
H3C
H N
CH3 OH H
COOH OH
HO H3C
O
O
H3C
H N
OH H
Impurity B (Actinospectinoic acid)
O
OH
H
H OH
NH
O
O OH
HO H3C
NH
CH3
Impurity F (Triol spectinomycin)
Page 24 of 26
Ac
ce pt
ed
M an
us
cr
i
Figure3
Page 25 of 26
i
Figure4
cr
Intens. +MS, 6.8min x105
us
351.177
1.0
100
150
M an
0.0
200
Intens. x105 +MS2 (351.177), 24eV
300
ed
1.2 m/z 207
350
400
450
500
m/z
C14H27N2O8 351.177
m/z 126
OH
1.0
ce pt
CH3NH
0.8
HO
O
O
0.6
CH3
OH O m/z 305
m/z 153
Ac
+ H2O
m/z 315
O
NHCH3
0.4
333.167
247.132 250
m/z 351 m/z 333
m/z 189
- H2O C14H25N2O7 333.167 - H2O C14H23N2O6 - CO 315.157 C13H24N2O6 305.157
0.2 - H2O C H N O C8H13N2O C8H17N2O3 8 19 2 4 207.135 153.103 189.125 100
150
200
250
300
350
m/z
Page 26 of 26