RU2362577C2 - Extract of common licorice, possessing antituberculous activity - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: extract of common licorice, possessing antituberculous activity, is received by extraction of herb or roots of common licorice Glycyrrhiza glabra 40% by ethyl alcohol at a parity 1:5 and an extract conditioning in a dark place at a room temperature within 10 days with the subsequent filtering and autoclave treatment. Thus the extract from an underground part contains 20-30% of a glycyrrhizin and salts of Ca and K of glycyrrhizic acid, 10-20% glycyrrhetinic acid, 40-50% of flavonoids (liquiritin, flavin, flavonols, flavones), 10-15% of tannins, lectin proteins and carbohydrates and an extract from a herb contains 20-25% of triterpene saponin, 30-45% of flavonols (quercetin, tempferol), 25-40% of flavonoids (halkanes, aurones), 10-15% of C-glycosides, coumarins and lectin proteins. Extract application of common licorice as an agent possessing antituberculous activity and a way of reception of a common licorice extract under item 1, consisting that land or underground parts of common licorice Glycyrrhiza glabra are extracted using 40% ethyl alcohol at a parity 1:5, the extract is further maintained in a dark place at a room temperature within 10 days is offered also, filtered and autoclaved under the pressure of 0.3-0.5 atm. within 15-30 minutes.

EFFECT: agent on the basis of a common licorice extract can be an addition to complex antituberculous therapy.

3 cl, 7 ex, 7 dwg, 1 tbl

Description

The invention relates to medicine, namely to herbal medicine, and is a herbal medicine and can be used as a prophylactic anti-tuberculosis action in the form of biological additives.

Phthisiology is experiencing difficulties associated with the peculiarities of the course of tuberculosis. This is expressed by a sharp increase in the prevalence of infection, a high proportion of active and chronic destructive processes, and massive bacterial excretion. All this leads to insufficient effectiveness of specific therapy, due to the increase in pathogen resistance to traditional anti-TB drugs (Vasiliev A.V., Grishko A.N. // Tuberculosis and the city: problems of prevention, diagnosis and treatment. - St. Petersburg, 1996. - С .9-16).

There are anti-tuberculosis herbal compositions containing Ledum flowers, plantain leaf, thyme leaf, nettle leaf, valerian root, blackcurrant leaf, calendula flowers and dandelion root with a certain ratio of components that are used against the background of antibiotic therapy (Patent No. 96121489 RU, 1996 ) The patent provides a multicomponent composition from plants, each component of which can inhibit the activity of others and affect the activity of individual components, which is a disadvantage of this composition.

Known extract of fir paws used for the treatment of patients with infiltrative pulmonary tuberculosis (Patent No. 2050855 RU, 1992), including oral administration; plant extract contributes to the disappearance of side effects arising from the introduction of tuberculostatics, stimulates cellular immunity.

The disadvantages of this tool is its weak specificity. The majority of local and organismic antimicrobial agents include antiseptics of chemical origin, which are xenobiotics for the body and cause additional stress on its metabolizing and eliminating systems, and cause the development of adverse reactions, especially in children and patients with chronic diseases.

The objective of the present invention is the isolation of plant substances from the root and other organs (inflorescences, leaves, shoots) of the plant Glycyrrhiza glabra to create a natural herbal remedy with significant anti-tuberculosis action due to higher concentrations of biologically active plant substances and not causing side effects when ingested .

The task is achieved in an original way of processing extracts that increase the content of the following biologically active substances in plant preparations: a) triterpene saponin glycyrrhizin, as well as Ca and K salts of glycyrrhizic acid in the extract of the root Glycyrrhiza glabra (up to 20-30%); glycyrrhetinic acid (up to 10-20%); flavonoids - liquiquirithin, flavin, flavonols, flavones, yellow glycoside (up to 40-50%); glucuronic acid, tannins (up to 10-15%); - b) Glycyrrhiza glabra - triterpene saponin (up to 20-25%), flavonols - quercetin, tempferol (up to 30-45%) as a part of options for the extract of the aerial part (shoots, leaves, inflorescences); flavonoid glycosides - chalkans, aurons (up to 5-40%); C-glycosides, coumarins and other substances (up to 10-15%).

A distinctive feature of the proposed products is that the authors are the first to suppress Mc. tuberculosis, active in animals and humans, causing pulmonary tuberculosis, isolated biologically active substances and prepared a drug with anti-tuberculosis activity from various organs of the plant Glycyrrhiza glabra.

According to biochemical results and literature data (D. Muravyova, Pharmacognosy), the following biologically active substances are distinguished in water-alcohol extracts (40% alcohol) of the proposed plant preparations: in the extracts of the root of Glycyrrhiza glabra, triterpene saponin glycyrrhizin, as well as Ca and K salts glycyrrhizic acid with a high percentage, glycirretic acid aglycone (sapogenin triterpene structure), yellow glycoside liquiquirithin (flavin), flavonols, their aglyconic and glycosidic compounds, chalcones, flavans, flavos noides, tannins. In the extracts of the ground part of Glycyrrhiza glabra, in addition to the previous flavonoids, there are quercetin, isoquercetin, tempferol, chalcans, aurons, and other substances.

Increasing the therapeutic effectiveness of these drugs makes it possible to recommend them for implementation in laboratories of the health system as components of anti-tuberculosis and antimicrobial phytopreparations.

The results of scientific studies showed a complete or almost complete suppression of the metabolism of mycobacteria under the influence of herbal preparations from licorice, containing these active substances.

In the experiments, the effect of extractable preparations in various concentrations of active substances on the viability of the sensitive strain of Mycobacterium tuberculosis (H ₃₇ RV) isolated from patients was studied. The standard methods of multiple dilutions in Shkolnikova’s liquid transparent medium with 0.2 ml of H ₃₇ RV culture diluted to 10 ^-8 and absolute concentrations on a dense Levenshtein-Jensen nutrient medium were used. Water-alcohol extracts of plants of sandy cumin (Helichrysum arenarium L.), yarrow (Achillea micrantha MB) as a comparative example, as well as extractable root preparations with rhizome and aerial organs of the stem, leaves, licorice inflorescences (Glycyrrhiza glabra) participated in corresponding doses to the dry weight of active substances in a liquid medium: 2.5 × 10 ^-4 mg / ml; 1.25 x 10 ^-4 mg / ml; 0.625 × 10 ^-4 mg / ml; 0.313 × 10 ^-4 mg / ml; 0.156 x 10 ^-4 mg / ml; 0.078 × 10 ^-4 mg / ml. Before use, the extracts were autoclaved under cotton plugs to comply with antiseptics and the complete removal of alcohol residues.

Table No. 1 presents the results of a study of the anti-tuberculosis activity of water-alcohol extracts from licorice.

The following are descriptions of the results of a study of the anti-tuberculosis activity of extractable herbal preparations, placed in table No. 1.

Example No. 1. When diluting licorice root extract at a dose of 2.5 × 10 ^-4 mg / ml of active substances, Mycobacterium tuberculosis growth was completely suppressed.

When diluting licorice root extract at a dose of 1.25 × 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was completely suppressed.

When diluting the extract of licorice root naked at a dose of 0.625 × 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was completely suppressed.

When diluting the extract of licorice root naked at a dose of 0.313 × 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was completely suppressed.

When diluting licorice root extract at a dose of 0.156 × 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was completely suppressed.

When diluting the extract of licorice root naked at a dose of 0.078 × 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was completely suppressed (Fig. 2a).

Example No. 2. When diluting the extract of licorice stalk naked at a dose of 2.5 × 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was completely suppressed.

When diluting the extract of the licorice stalk naked at a dose of 1.25 × 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was completely suppressed.

When diluting the extract of the licorice stalk naked at a dose of 0.625 × 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was completely suppressed.

When diluting the extract of licorice stalk naked at a dose of 0.313 × 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was completely suppressed.

When diluting the extract of the licorice stalk naked at a dose of 0.078 × 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was completely suppressed.

When diluting the extract of the licorice stalk naked at a dose of 0.156 × 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was partially suppressed.

Example No. 3. When diluting the extract of inflorescences of licorice naked at a dose of 2.5 × 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was completely suppressed.

When diluting the extract of inflorescences of licorice naked at a dose of 1.25 × 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was completely suppressed.

When diluting the extract of inflorescences of licorice naked at a dose of 0.625 × 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was completely suppressed.

When diluting the extract of inflorescences of licorice naked at a dose of 0.313 × 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was completely suppressed.

When diluting the extract of inflorescences of licorice naked at a dose of 0.156 × 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was partially suppressed.

When diluting the extract of inflorescences of licorice naked at a dose of 0.078 × 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was partially suppressed (Fig.2b).

Example No. 4. When diluting the extract of licorice leaf naked at a dose of 2.5 × 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was completely suppressed.

When diluting the licorice leaf extract at a dose of 1.25 × 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was completely suppressed.

When diluting the extract of licorice leaves at a dose of 0.625 × 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was completely suppressed.

When diluting the extract of licorice leaves naked in a dose of 0.313 × 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was completely suppressed.

When diluting the extract of licorice leaves naked at a dose of 0.156 × 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was partially suppressed.

When diluting the extract of licorice leaves naked at a dose of 0.078 × 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was partially suppressed (Fig. 2c).

Example No. 5

When breeding an extract of inflorescences of yarrow finely flowered in a dose

0.625 × 10 ^-4 mg / ml of active substances The growth of Mycobacterium tuberculosis was completely suppressed.

Upon dilution of the extract of inflorescences of the yarrow finely flowered at a dose of 1.25 × 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was partially suppressed.

Upon dilution of the extract of inflorescences of yarrow finely flowered at a dose of 0.313 × 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was partially suppressed.

When diluting the extract of yarrow inflorescences with a dose of 0.156 × 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was partially suppressed.

When diluting the extract of inflorescences of yarrow with small flowers at a dose of 0.078 × 10 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was partially suppressed (Fig.

Example No. 6. When diluting the parmelia tallium extract at a dose of 2.5 × 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was completely suppressed.

When diluting the parmelia tallium extract at a dose of 0.625 × 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was partially suppressed.

When diluting the parmelia tallium extract at a dose of 1.25 × 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was partially suppressed.

When diluting the parmelia tallium extract at a dose of 0.313 × 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was partially suppressed.

When diluting the parmelia tallium extract at a dose of 0.156 × 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was partially suppressed.

When diluting the parmelia tallium extract at a dose of 0.078 × 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was partially suppressed (Fig. 2e).

Example No. 7. When diluting the extract of inflorescences of sandy cmin in a dose of 2.5 × 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was completely suppressed.

When diluting an extract of inflorescences of sandy cmin, at a dose of 1.25 × 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was partially suppressed.

When diluting the extract of inflorescences of sandy cmin, at a dose of 0.625 × 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was completely suppressed.

When diluting the extract of inflorescences of sandy cmin, at a dose of 0.313 × 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was partially suppressed.

When diluting the extract of inflorescences of sandy cmin in a dose of 0.156 × 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was partially suppressed.

When diluting the extract of inflorescences of sandy cmin, at a dose of 0.078 × 10 ^-4 mg / ml of active substances, the growth of Mycobacterium tuberculosis was partially suppressed (Fig.2e).

Thus, studies have shown that the highest inhibitory effect was observed in the extract from licorice root, then extracts of the stem, inflorescences and licorice leaves of naked Glycyrrhiza glabra (options) compared with extracts of plants taken for comparison (lichen - wandering Parmelia Parmelia vagans, yarrow small-flowered - Achillea micrantha M.V., sand cumin - Helichrysum arenarium L.).

The activity of herbal preparations from three plants Glycyrrhiza glabra - the claimed preparation from a mixture of root extract and other parts of licorice (options), Helichrysum arenarium, Achillea micrantha (comparative preparations) against Mycobacterium tuberculosis (H37RV) was further studied in the method of diffusion into a nutrient medium, on which mycobacterium tuberculosis was seeded (Fig. 1). Controls in this method for comparing activity were taken on discs saturated with known antibiotics: chloramphenicol, furagin, penicillin. As a result, the extracts placed in the wells of the infected nutrient medium at a dose of 0.625 × 10 ^-4 mg / ml showed anti-tuberculosis activity in this method at the level of the most active antibiotic. Chloramphenicol formed the diameter of the zone of growth inhibition of the microorganism - 32 mm furagin - 23.5 mm; penicillin - 4.5 mm; Achillea micrantha extracts - 21.5 mm; Glycyrrhiza glabra - 32.5 mm; Helichrysum arenarium - 25 mm).

The results of this method are reflected in figure 1.

Figure 2 presents photographs of the results of suppressing the formation of colonies of mycobacterium tuberculosis under the influence of an extractable preparation of the root and other parts of the licorice plant in comparison with extracts of other plants placed in table No. 1 and described here.

The proposed drugs - Glycyrrhiza glabra extract (options) have pronounced anti-tuberculosis activity and can serve as ready-made drugs for use in complex anti-tuberculosis therapy, as well as a prophylactic and as dietary supplements for a long course of the disease and for a better effect of patients' recovery.

Claims (3)

1. Naked licorice extract with anti-tuberculosis activity, characterized in that it is obtained by extraction of the ground or underground parts of licorice Glycyrrhiza glabra with 40% ethyl alcohol at a ratio of 1: 5 and keeping the extract in a dark place at room temperature for 10 days followed by filtration and autoclaving, while the extract from the underground part contains 20-30% of glycyrrhizin and Ca and K salts of glycyrrhizic acid, 10-20% of glycyrrhetinic acid, 40-50% of flavonoids (liququirithin, flavin, flavonols, flavo s), 10-15% of tannins, lectin proteins and carbohydrates and the extract from the ground contains 20-25% of triterpene saponin, 30-45% of flavonols (quercetin, tempferol), 25-40% of flavonoids (chalkans, aurons), 10 -15% C-glycosides, coumarins and lectin proteins. 2. The use of licorice extract according to claim 1 as a means of having anti-tuberculosis activity. 3. The method of obtaining licorice extract according to claim 1, characterized in that the ground or underground parts of licorice Glycyrrhiza glabra are extracted with 40% ethyl alcohol at a ratio of 1: 5, then the extract is kept in a dark place at room temperature for 10 days , filtered and autoclaved under a pressure of 0.3-0.5 atm for 15-30 minutes

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