RU2771851C1 - Express method for determining ceftriaxone in blood plasma and mixed saliva of covid-19 patients - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention relates to medicine, namely analytical chemistry, ionometry, and can be used to determine ceftriaxone in mixed saliva and blood plasma. Precipitation, removal of proteins and shaped elements, construction and determination of antibiotic concentrations according to the calibration schedule of EMF, mV, are carried out. 2 ml of biological fluid is placed in a 25 ml container, the pH is adjusted to 7-8, a selective electrode with a membrane based on an electro-active component in the form of an ion associate of ceftriaxone and octadecylamine is lowered into the solution, as well as the comparison electrode. Within one minute, the content of ceftriaxone in the test medium is determined.

EFFECT: method provides the possibility of reducing the time for determining ceftriaxone, increasing the detection interval of ceftriaxone and optimizing the metrological characteristics of the method (increasing accuracy, reducing the error in determining results) by ionometric quantitative determination of the content of the cephalosporin antibiotic ceftriaxone using a ceftriaxone-selective electrode in mixed saliva and blood plasma of the patient for one minute.

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Description

The invention relates to the field of analytical chemistry, more precisely to ionometry, a method for the quantitative determination of one of the cephalosporin antibiotics ceftriaxone (Ceftr) in the oral fluid (ORF) and in the whole blood of patients with covid. The invention can also be used in medicine for toxic and technical analysis of drugs, in biosystems (blood serum, saliva, etc.), as well as for pharmacokinetic studies in order to regulate the administration of optimal antibiotic doses in the treatment of various infectious diseases.

Antibiotics are used in medicine, veterinary medicine, food industry for canning, for processing food products during their transportation. In this regard, it is required to control the content of Ceftr in dosage forms, in biological fluids of the human and animal body, food, wastewater from pharmaceutical enterprises and other objects.

Analogues

From the prior art, various methods for the quantitative determination of antibiotics are known: microbiological, spectrophotometric, fluorimetric, chemiluminescent, various variants of chromatographic methods, incl. high performance liquid chromatography (HPLC), chromatomass spectrometry, stripping voltammetry, electroanalytical determination with modified electrodes.

To determine β-lactam antibiotics, spectroscopic methods are used based on the use of certain properties of antibiotics: intrinsic absorption, color reactions, the appearance or disappearance of characteristic bands in the UV, visible or IR regions of the spectrum under the influence of various reagents.

A known spectrophotometric method for the determination of antibiotics of the penicillin group - ampicillin, amoxicillin, cloxacillin, sulbenicillin, carbenicillin, ticarcillin in finished dosage forms (Amin A.S. Pyrocatechol violet in pharmaceutical analysis. Part I. A spectrophotometric method for the determination of some pMactam antibiotics in pure and in pharmaceutical dosage forms // Farmaco. - 2001. - V. 56, No. 3. - P. 211-218), based on measuring the absorption (λ=323-346 nm) of the reaction product of penicillins with a solution of 1,2,4-triazole, containing chloride of mercury (II). This method is applicable mainly for the determination of a substance in dosage forms that form its basis.

Known spectrophotometric and spectrofluorimetric methods for the determination of 4 penicillins (amoxicillin, bacampicillin, piperacillin and sultamicillin) and 10 cephalosporin antibiotics in pharmaceutical preparations, which are based on the oxidation of antibiotics with cerium (IV) in ODM H ₂ SO ₄ at 100°C. The methods include the operation of measuring the decrease in light absorption of cerium (IV) at λ=317 nm or the fluorescence intensity of the formed cerium (III) at excitation and emission wavelengths of 256 and 356 nm.

Belal S. Use of cerium (IV) in the spectrophotometric and spectrofluorimetric determinations of penicillins and cephalosporins in their pharmaceutical preparations // Spectrosc Lett, 2000. - Vol. 33. - No. 6. - P. 931-948).

A known spectrophotometric method for the determination of ampicillin, amoxicillin and carbenicillin using the phenolic reagent Folina-Ciocalteu (Ahmad A.S., Rahman N., Islam F. Spectrophotometric determination of ampicillin, amoxicillin and carbenicillin using the phenolic reagent Folina-Ciocalteu // Zhurn. analyt. Chemistry, 2004. - T. 12. - No. 2. - S. 138-142). A mixture of penicillins to be determined with a reagent at pH 2.25 is heated in a thermostatically controlled water bath at 95±2°C and the resulting blue color of the resulting heteropoly compounds is measured spectrophotometrically at λ=750 nm for ampicillin and carbenicillin and at λ=770 nm for amoxicillin.

A known method for the determination of sodium salts of cefotaxime and cefadroxil monohydrate in two constituent mixtures by the method of derivative spectrophotometry (Morelli B. Derivative spectrophotometry in the analysis of mixtures of cefotaxime sodium and cefadroxil monohydrate // J Pharm and Biomed Anal., 2003. - Vol. 32. - No. 2. - P. 257-267). The method consists in taking the absorption spectra of antibiotics and evaluating the first and second derivatives of the absorption spectra. Sensitivity limits from 0.28 to 0.51 mg/ml.

Potentiometric sensors based on ionic associates of cefuroxime with tetraalkylammonium cations have been developed. The sensors provide a wide range of determined antibiotics content 1⋅10 ^-4 -1⋅10 ^-2 M; the limit of detection of antibiotics is 8⋅10 ^-6 M. (O.I. Kulapina, M.S. Mikhailova, E.G. Kulapina Ionometric determination of cefuroxime and cefuroxime axetil in biological and medicinal media // Proceedings of the Saratov University. Ser. Chemistry, Ecology, 2013, vol. 15, issue 3, pp. 40-45).

Sensors for the determination of cefuroxime and cefuroxime axetil allow you to determine in biological media (oral fluid) to adjust and optimize the course of treatment, as well as to determine the main substance in drugs. There is also a method for the determination of cefazolin in biological media using ion-selective electrodes (O.I. Kulapina, V.V. Baraguzina, N.V. Skoblikova. Determination of cefazolin in biological media using ion-selective electrodes // Chemical Pharmaceutical Journal. 2008. T 42, No. 8. P. 41-44). The ratio of components in the ion associate, solubility, and thermal stability up to 70 degrees were estimated. It is shown that the dependence of the EMF on the concentration of cefazolin is in the range of 1⋅10 ^-1 -1⋅10 ^-5 mol; the slope of the electrode functions is 56±2 mV/pC. To _sat .to some inorganic ions (CI ^- , Br ^- , HCO ₃ ^- , HPO ₄ ^2- , SO ₄ ^2- ) allows the use of these electrodes for the determination of cefazolin in biological fluids.

Criticism of analogues

However, pharmacokinetic studies conducted on biological media require the determination of low concentrations of antibiotics Cmin<10 µg/ml, and therefore, a more sensitive and rapid method is needed for these purposes.

Known methods are intended for the determination of antibiotics in medicinal media and, due to insufficient sensitivity and duration, cannot be used to analyze biological media for the content of antibiotics.

However, commonly used excipients in pharmaceutical compositions (eg, sugar) affect the result of the determination, therefore, such excipients must be removed from the analyzed materials before the determination of penicillins in capsules and tablets. The method is proposed for the determination of antibiotics in model solutions. This method is also characterized by the duration of the process, it requires a heating operation, which adversely affects the state of the antibiotic and, consequently, the metrological parameters of the determination method. In the latest analogues, there is no acidity range at which the developed electrodes should function. The range of determined concentrations varies in two orders of magnitude. Selectivity to antibiotics of the beta-cypholosparin series has not been studied.

Prototype

The closest to the proposed technical solution is the determination of ceftriaxone in the blood and tissues by ion-exchange chromatography (V.V. Khasanov, E.G. Sokolovich, K.A. Dychko // Chemical Pharmaceutical Journal. Volume 40. No. 2, 2006), which is chosen as a prototype.

The prototype is as follows.

The determination procedure includes a preliminary solid phase extraction on a concentrating cartridge from a small volume of blood (200 μl) followed by reversed-phase HPLC with ion-pair modification. The separation mechanism is complex, involving electrostatic interactions of ceftriaxone anions with a positively charged amino group. The detection limit for ceftriaxone was 0.4 µg/ml in blood plasma and 0.03 mg/l in saliva (Table 1.). The working solution is stable when stored in the dark at 4°C for 10 hours.

Liver, lung blood samples were taken from healthy Kpbic (Vistar, Maccoft body 250-280 g) at various times after intramuscular administration of ceftriaxone at a dose of 25 mg/kg of body weight. The tissue sample was weighed, frozen in liquid nitrogen, then filled with physiological saline, thoroughly homogenized, and centrifuged for 5 min. at 6000 min ^-1 . The supernatant was taken and mixed with acetonitrile in a ratio of 1:3, filtered through a 0.45 μm membrane, and injected into the column. Blood samples were mixed with acetonitrile (1:3), thoroughly mixed and centrifuged, the supernatant was further processed as described above. Prepared samples were loaded onto the column using a constant volume sample injection loop of 100 or 500 µl. The calibration plot was found to be linear over the range of 10-400 ng ceftriaxone in the column with a correlation coefficient of 0.999.

Criticism of the prototype

Since ceftriaxone is a highly polar compound, it is difficult to extract from biological fluids. Sample preparation usually involves deprotenization with ethanol, acetonitrile, or methanol, and the ceftriaxone solution is unstable in alcohol, so analysis must be performed within 2 hours. With an increase in the concentration of counterions, as well as alkalization of the medium, damage to the column filler is possible.

Thus, the use of the prototype for the determination of ceftriaxone is very lengthy, requires expensive equipment, multi-stage sample preparation, the range of determined concentrations is narrow (Table 1).

Purpose of the invention

The aim of the invention is to develop an express method for the ionometric determination of ceftriaxone to regulate the administration of optimal antibiotic doses in the treatment of various infectious diseases, including patients with covid, as well as in the study of pharmacokinetics.

The objective of the invention is to create an express, affordable, inexpensive quantitative method for the determination of a cephalosporin antibiotic, in particular ceftriaxone, with a ceftriaxone-selective electrode (Ceftr-SE) in biological media, incl. oral fluid, blood plasma, etc.

The essence of the invention

An express method for the quantitative determination of ceftriaxone is proposed, including sampling of real objects containing Ceftr in patients with covid, sample preparation and measurement of the potential difference (EMF) of a reference electrode and an indicator electrode with a membrane based on an electrode active component (EAC) in the form of an ion associate of ceftriaxone and octadecylamine (ODA). ). The ionometric determination of Ceftr is carried out according to a calibration graph built on reference solutions in the pH range of 7-8, while the calibration graph is built on the measured values of the electrode potential from the concentrations of Ceftr in reference solutions; and when used as a sample of whole blood, the protein is preliminarily precipitated according to GOST and the formed elements are removed. The above method allows you to determine the content of Ceftr within 1 min, while the use of expensive instruments, organic solvents is eliminated, there is no multi-stage process, the time and detection error are reduced, and the accuracy of the determination is increased.

The problem is solved by the fact that the method of quantitative determination of cephalosporin antibiotic in biological media is carried out by sampling the biological medium containing ceftriaxone, its sample preparation, including the removal of solid elements with subsequent precipitation and removal of proteins, measuring the equilibrium potential (EMF) and determining the concentration of the antibiotic according to the calibration curve (Fig. 1), built on a reference medium, which is used as a biological medium without ceftriaxime, which has undergone a similar sample preparation, followed by the introduction of a solution of the antibiotic to be determined in various concentrations into the prepared sample, while the calibration graph is built according to the measured values of the potential of ceftriaxone-selective electrode relative to the reference electrode, depending on the content of ceftriaxone in the test solution. To remove solid elements from a sample of a biological medium without an antibiotic content and with an antibiotic content, the sample is preliminarily centrifuged for 10-20 minutes at 2000-3500 rpm, and the precipitation of proteins is carried out with zinc sulfate in a sodium hydroxide medium, the removal of proteins is carried out by centrifugation for 10- 20 min at 2000-3500 rpm. Oral fluid and blood plasma or whole blood can be used as a biological medium, while in the process of sample preparation solid food residues are removed from the oral fluid, and formed elements are removed from whole blood.

The proposed method is as follows: first, a solution of ceftriaxone with a concentration of 0.1 M is prepared by dissolving the calculated amount in distilled water, then solutions of lower concentrations of 1⋅10 ^-2 are prepared by successive dilution; 1⋅10 ^-3 ; 1⋅10 ^-4 ; 1⋅10 ^-5 M. Next, various amounts of the drug are placed in a glass with a capacity of 25 ml and a biological medium is added up to 2-3 ml, for example, mixed saliva (oral fluid - RRP) or blood serum of a practically healthy person (not taking for 7 -10 days of ceftriaxone). The volume of the test solution is given by the volume of a 25 ml volumetric flask, in which the components are mixed. Then, samples of covid patients treated with ceftrioxone are prepared, centrifuged and proteins are precipitated under similar conditions, the equilibrium potential is measured relative to the bioassay without antibiotic and according to the calibration graph. In FIG. 1 shows a calibration curve for determining the content of ceftriaxone with the content of Ceftr 10 and 50 mmol/l in the membrane. According to FIG. 1 calculate the content of ceftriaxone in the test medium.

Examples of specific implementation of the method

Example 1

To carry out the express method for determining ceftriaxone in the mixed saliva of patients with covid-19, samples of mixed saliva were taken from a patient with covid-19 by taking oral fluid into dry polyethylene test tubes. The sample was taken 1–2 hours after the meal; the oral cavity was rinsed with water before collection. The IRR sample was centrifuged for 15 minutes at 3500 rpm. Then 1 ml of NaOH (c=0.12 mol/l) and 4 ml of ZnSO ₄ (c=5.4 g/l) were added to the sample and heated in a water bath. After protein precipitation, the supernatant was taken and centrifuged again for 15 minutes at 3500 rpm.

The concentration of ceftriaxone in the mixed saliva was determined by the calibration curve method. To prepare a series of aqueous solutions of ceftriaxone, a weighed portion of powder 1.4439 g was dissolved in a volumetric flask with a capacity of 25 ml and brought to the mark with distilled water (the concentration of the initial solution was 1⋅10 ^-1 M, diluted by an order of magnitude, solutions of the required concentrations were obtained). 2.5 ml of the initial solution of Ceftr was taken into a volumetric flask with a capacity of 25 ml, a solution with a concentration of 1⋅10 ^-2 M was obtained, etc.

The minimum detectable content of the antibiotic was 0.05 µg/ml.

Potentiometric studies were carried out using an 8-channel computerized system for collecting potentiometric data based on a PC, Ecotest-120, and a KM-8 switch (NPP ECONIKS, Moscow, Russia); A Wirowka MPW-6 centrifuge was used to separate the protein components from the mixed saliva. The results of the determination of ceftriaxone in the mixed saliva of patient M. are shown in table 1.

Table 1 shows the dependence of the concentration of ceftriaxone in the mixed saliva of patient M. on the time of sampling. It has been shown that the maximum concentration of Ceftr in the GRP is reached by 18-19 hours after taking 20 mg of the drug at 8 am, then the concentration decreases to the initial values. After the evening intake of 20 mg Ceftr, the concentration of the drug in the FRP increases again.

Taking into account the complexity of the analyzed objects and the analyte itself, the reliability of the results obtained during the implementation of the method was evaluated by the "introduced-found" method. The determination error did not exceed 4%.

The data obtained indicate the possibility of ionometric determination of ceftriaxone in the oral fluid of patients with covid during pharmacokinetic studies.

Example 2

For the ionometric determination of ceftriaxone in the blood serum of a patient with covid, the method was tested on the blood serum of a healthy person with ceftriaxone added. Blood (4-5 ml) taken from the cubital vein was kept for 30 minutes without a stabilizer at room temperature, then centrifuged to separate the formed elements. The precipitation of proteins, measurements of EMF, construction of calibration graphs were carried out according to the technologies presented in example 1. The results of the potentiometric behavior of ceftriaxime in blood serum were characterized by parameters similar to Example 1. The correctness of the results of determining ceftriaxone was controlled using the additive method according to the formula:

The results of the determination of ceftriaxone in the blood flame of a patient with covid M. by the “introduced found” method are shown in Table 2.

The technical result obtained from the application of the proposed method

The technical result of the proposed method is to reduce the time for determining ceftrioxime, increase the detection interval for ceftriaxone and optimize the metrological characteristics of the method (increase in accuracy, decrease in the error in determining the results) (Table 1).

In addition, one of the advantages of the proposed method is the possibility of using mixed saliva as a biological medium, which, in comparison with a blood test, is characterized by painless sampling, simplicity, convenience, no risk of infection, the impossibility of injury to the skin and vascular walls, and the adequacy of the concentration of the substance. pharmacotherapeutic effect in the oral cavity.

Thus, the proposed method expands the functionality of the express determination of ceftriaxone in biological fluids by expanding the range of used objects of the cephalosporin antibiotic. The method is characterized by high expressivity, the ability to determine the active concentration of the antibiotic in a wide concentration range, simplicity, availability and low cost.

The range of detectable concentrations of 0.05-55.4 µg/ml makes it possible to determine Ceftr in the mixed saliva and blood of patients with infectious diseases, for example, in patients with covid. Comparative characteristics of the chromatographic and ionometric methods for the determination of ceftriaxone are given in table 3. Thus, the method is characterized by high speed, low cost and a wide range of determined contents.

The data obtained indicate the possibility of rapid determination of ceftriaxone in blood plasma using a ceftriaxone-selective electrode. Unlike other cephalosporins, ceftriaxone has a long half-life (7-8 hours), which is why daily monitoring is recommended when using this drug. A day later, the concentration of the antibiotic in the blood plasma reaches within 10 µg/ml (Table 2).

Claims (1)

An express method for determining ceftriaxone in mixed saliva and blood plasma, including precipitation, removal of proteins and formed elements, construction and determination of antibiotic concentrations according to the calibration graph of EMF, mV, characterized in that 2 ml of the biological fluid is placed in a 25 ml container, the pH is adjusted to 7-8, the ceftriaxone-selective electrode with a membrane based on the electrode-active component in the form of an ion associate of ceftriaxone and octadecylamine, and the reference electrode are lowered into the solution, and the content of ceftriaxone in the test medium is determined within one minute.

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