RU2527333C1 - Skin regeneration and anti-hyperkeratosis ointment with vitamin a - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention concerns an ointment composition for reducing hyperkeratosis, softening, stimulating skin regeneration, containing retinol palmitate, α-tocopherol as a stabilising agent, as well as emulsion wax, Vaseline oil, glycerol, ethanol and water.

EFFECT: higher efficacy and stability.

2 dwg, 4 tbl, 4 ex

Description

The invention relates to pharmacy and relates to the creation of an ointment composition for topical application containing retinoid retinol palmitate, which has pharmacological effects in relation to the proliferation and differentiation of keratinocytes, intended to soften the skin and enhance its regeneration, as well as for use in the complex treatment of skin diseases.

Biologically active forms of vitamin A are natural regulators of morphogenetic processes in the epidermis [1]. In dermatological practice, it is often necessary to act on the pathogenetic links of skin diseases by modifying the proliferation and differentiation of the cellular elements of the epidermis and dermis. In recent decades, synthetic analogues of vitamin A, retinoids, one of which is retinol palmitate (RP), are widely used for this purpose [2].

It was found that RP through gene expression dose-dependently enhances, and with increasing doses of vitamin A, it inhibits keratinocyte proliferation. Its inhibitory effect on the terminal differentiation of skin epithelial cells is known, which contributes to the rejuvenation of their population in the epidermis. RP also activates the synthesis of glycosaminoglycans in the connective tissue layer of the skin, stimulates the immune processes.

The well-known drug Videstim ^® , which is an ointment for cutaneous use, containing 0.5% RP on an emulsion basis, stabilizers and antioxidants [3]. Its pharmacological activity in the form of effects on regenerative processes in the skin has been proven in animal experiments [4] and confirmed in clinical practice [5, 6, 7]. The drug is effective in the treatment of eczema, dermatitis, cheilitis, surface cracks and abrasions of the skin, skin diseases associated with impaired keratinization, it is used to activate reparative processes in various dermatoses after glucocorticosteroid therapy. It is approved for use by nursing mothers to repair nipple cracks [8].

In the patent literature there are reports of soft dosage forms for cutaneous use containing RP. So, patent RU 2115409 protects a cosmetic product for skin care of the face and body, which includes RP (vitamin A), tocopherol acetate (vitamin E), structure-forming agents, plasticizing additives, preservatives, perfume [9]. The ointment composition described in patent RU 2146921 consists of RP, ascorbyl palmitate, tocopherol acetate, ergocalciferol and a water-emulsion base [10]. The named compositions are multivitamin; vitamins that are their constituents as active substances, and especially retinoid - RP, are susceptible to oxidation, however, in the list of excipients used in the compositions, there are no stabilizers with antioxidant properties.

The closest in purpose, composition and technical nature of the claimed invention is the patent RU 2036640, which describes the composition of the ointment composition with RP stabilized with a mixture of antioxidants and containing emulsifier No. 1 [11]. It is known that to prevent the oxidation of retinoids, including RP, antioxidants are usually used - butylhydroxytoluene (BOT) and butylhydroxyanisole (BOA) [12, 13]. These compounds are used in pharmacy and the food industry, but it has been established that they also have some undesirable effects, for example, potential carcinogenic properties, the ability to increase cholesterol [14, 15], cause diseases of the gastrointestinal tract, liver, allergic reactions [16] to irritate the skin, eyes and mucous membranes [17]. The emulsifier No. 1, which is part of the composition, is a hard-to-touch solid mass in the form of tiles weighing 10-15 kg; working with it requires the introduction of the “Grinding” stage in the production process, which involves production losses and the use of expensive equipment.

Thus, in order to ensure the quality and improve the safety profile of drugs, the development of modern non-toxic drugs for external use is relevant.

An object of the present invention is to provide an ointment that softens and regenerates the skin, prevents excessive keratinization and has an improved safety profile.

In accordance with the invention, an ointment composition for external use is described that stimulates regeneration processes in the skin and prevents excessive keratinization and dryness of the skin, containing palmitate as the active substance retinol, and α-tocopherol, emulsion wax, paraffin oil, glycerin, as auxiliary substances ethyl and water in the following ratio of components, wt.%:

Retinol palmitate 0.3-0.7 α-tocopherol 0.15-0.25 Emulsion Wax 5.0-15.0 Vaseline oil 5.0-15.0 Glycerol 5.0-15.0 Ethanol 95% 5.0-15.0 Distilled water up to 100.0

α-tocopherol (a synthetic analogue of natural α-tocopherol) is a non-toxic compound; As a stabilizer, it is widely used in the pharmaceutical and food industries. The use of α-tocopherol as an auxiliary substance in order to prevent retinoid oxidation in drugs allows avoiding the use of components such as BOT and BOA while maintaining high pharmacological and consumer properties of the drug.

Emulsion wax, unlike emulsifier No. 1, is a homogeneous mass in the form of flakes, it is easily weighed, mixed with liquid paraffin, it melts quickly and evenly, and there are no losses with its use. Emulsion wax obtained by fusion of synthetic primary fatty alcohols with potassium salts of phosphoric acid esters, due to the presence of phosphorus groups in the molecules of higher fatty acids, is close in structure to the lecithin and cephalin that make up the skin fat. As a result, it has an effective emollient effect on the skin, prevents the loss of moisture, and does not leave a feeling of greasy [18]. The pH of the emulsion obtained using emulsion wax is close to the natural value of this indicator in healthy skin.

Experiment 1

In the claimed composition of the ointment composition, α-tocopherol was introduced to stabilize the retinoid, and therefore, at the first stage of laboratory studies, the stability of RP was studied using model mixtures as an example.

Objective: to study the stability of the substance of RP stabilized by α-tocopherol.

The object of the study was model mixtures - the substance of RP in liquid paraffin without antioxidant (1) - control - and a similar combination, characterized by the presence of α-tocopherol in it (2). The initial concentration of RP in model mixtures was 1%, and the concentration of α-tocopherol was 0.05%. Samples were laid on “accelerated aging” in wide-necked glass jars with free access of air at elevated temperatures (40 ° C).

Method: spectrophotometry with respect to a solution of a standard sample.

The results of the analysis of the quantitative content of RP in model mixtures stored at 40 ° C are presented in table 1.

Table 1 Quantitative determination of palmitate retinol in model mixtures stored at 40 ° C No. Shelf life, days The quantitative content of retinol palmitate in model mixtures,% without α-tocopherol (1) with α-tocopherol (2) one one 0.99 1.01 2 7 0.98 0.95 3 22 0.98 0.99

four 29th 0.79 0.98 5 36 0.49 0.95 6 42 0.14 0.90 7 83 - 0.15

From these data it follows that the RP content in the samples of both model mixtures remained almost at the same level until the 22nd day of observation. Subsequently, the concentration of the substance in the control sample, i.e. in the model mixture without antioxidant (1) began to decline. The analysis carried out in the following days, recorded an avalanche-like decrease in the concentration of retinoid in the control samples (Fig. 1). In the model mixture with antioxidant (2), the retinoid concentration remained at the initial level until the 36th day of observation, and only later was its decrease observed (see Table 1, Fig. 1).

The obtained result shows that the presence in the model mixture of even a small amount of α-tocopherol (0.05%) almost doubles the initial stability of RP, which indicates that α-tocopherol has a pronounced antioxidant effect under the studied conditions and, therefore, , about the prospects of its introduction into the composition of drugs in order to stabilize retinoids.

Experiment 2

Purpose: to establish an effective concentration of α-tocopherol, which can inhibit the oxidation of RP for a long time.

The object of the study was model mixtures - the substance of RP in liquid paraffin without antioxidant (1) and similar combinations (2-7), characterized in that α-tocopherol was added to them in various concentrations (Table 2). The initial concentration of retinoid in model mixtures was 1%, α-tocopherol - 0.02-0.25%. The samples were stored in glass jars with a wide neck with free access to air under more severe conditions of “accelerated aging” (50 ° C) than in the 1st experiment.

Method: spectrophotometry with respect to a standard sample.

table 2 The composition of model mixtures with retinol palmitate stabilized by α-tocopherol Model Mix No. Vaseline oil, % Retinol palmitate,% α-tocopherol,% one 99.00 1,0 0 2 98.98 1,0 0.02 3 98.95 1,0 0.05 four 98.89 1,0 0.11 5 98.87 1,0 0.13 6 98.81 1,0 0.19 7 98.75 1,0 0.25

The results of quantitative determination of RP in model mixtures after 53 days of storage at a temperature of 50 ° C are presented in Fig. 2.

The diagram shows that different amounts of α-tocopherol in model mixtures have an unequal effect on the stability of RP. The addition of an antioxidant in the concentration range from 0.02 to 0.05% during storage for 53 days at 50 ° C under conditions of air access was ineffective. In an amount of 0.11%, α-tocopherol stabilized the retinoid, but not to the desired degree. The highest stability indices of RP under the studied conditions were observed at concentrations of α-tocopherol in model mixtures from 0.13 to 0.25% inclusive. Those. the more antioxidant in the mixture, the stronger (until a certain concentration is reached) its property is shown to prevent the oxidation / destruction of the pharmaceutical substance (RP)

Thus, experimental studies of the stability of RP during its storage under accelerated aging conditions in the composition of model mixtures containing α-tocopherol demonstrated the effectiveness of the chosen approach to the stabilization of the retinoid, i.e. replacing a mixture of phenolic antioxidants (BOT and BOA) in the composition of the drug with a synthetic analogue of natural vitamin E, and allowed us to go on to study the stability of RP in the composition of the ointment of the claimed composition.

Experiment 3

Purpose: to establish the duration of stability of RP as a pharmaceutical substance in the composition of ointment compositions containing α-tocopherol.

The object of the study was samples of ointment compositions differing in the content of RP and α-tocopherol.

Method: high performance liquid chromatography.

Ointment Technology

1. The required amount of water is placed in the reactor 1 and heated to 75-80 ° C.

2. In parallel, the necessary quantities of liquid paraffin and emulsion wax are placed in the reactor 2. The mixture is heated to a temperature of 75-80 C, melting the components.

3. Estimated amounts of RP and α-tocopherol are weighed into the molten mixture in reactor 2. The mixture is thoroughly mixed using an immersion homogenizer.

4. The head of the homogenizer is lowered into the reactor 1 (see p. 1), it is turned on (8-10 thousand rpm), and with active stirring of the mixture, the melt of the medicinal and auxiliary substances of the ointment from the reactor 2 is slowly added in a thin stream.

5. After 2-5 minutes [depending on the volume of the reactor used (0.5-3.0 L)], after mixing all the components of the preparation, the ointment is homogenized.

6. After 2-5 minutes, a mixture of ethanol (ethyl alcohol) and glycerol (glycerol) is added to the reactor, after which the ointment is further homogenized for 2 minutes. Due to the fact that the ointment contains thermolabile components (RP and α-tocopherol), the destruction of which is enhanced at high temperatures, it is forcibly cooled.

7. After reducing the temperature of the ointment to 35-40 ° C, it is transferred to the packaging section in tubes.

8. The ointment is Packed in aluminum tubes, marked with labels and stored at a temperature of 2 to 8 ° C.

Examples of the preparation of specific compositions

Example 4

1. In reactor 1 with an effective load of 100 kg of ointment, 65.3 liters of purified water are measured, the engine of the frame mixer is turned on, and the water is heated to a temperature of 75-80 ° C.

2. 8 kg of emulsion wax and 6 kg of liquid paraffin are weighed into reactor 2, the engine of the frame mixer is turned on, and, heating the mixture to a temperature of 75-80 ° C, it is melted.

3. After the fat components are melted, 0.5 kg of RP and 0.2 kg of α-tocopherol are weighed into reactor 2 and mixed thoroughly.

4. The combination of the components of the ointment in the reactor 1 and reactor 2 is carried out with active stirring using a flow-type rotary pulsation apparatus integrated in the reactor system.

5. The mixing of the contents of the two reactors is continued for 20 minutes until a homogeneous emulsion is obtained, into which a mixture of 10 kg of ethyl alcohol and 10 kg of glycerol is gradually added.

6. The resulting composition is finally homogenized for 15 minutes, cooled to a temperature of 30-35 ° C and Packed in aluminum tubes.

Similarly (according to the same scheme), other ointments were obtained (examples 1, 2, 3, 5 in tables 3 and 6, 7 in table 4).

results

At the first stage, the antioxidant activity of different concentrations of α-tocopherol was studied using ointment compositions, the RP content of which was 0.5%, i.e. average of the declared values. The ointment composition without stabilizer served as a control (Table 3).

The study showed that in the control samples (example 1) and when using a 0.1% concentration of α-tocopherol (example 2), the RP content in ointment compositions did not withstand the required shelf life (2 years). An increase in the antioxidant concentration to 0.15% (example 3) and higher (examples 4, 5) allowed us to achieve the desired effect: the RP content in these experimental ointment compositions corresponded to what was desired for a period corresponding to 3 years of storage under the conditions specified in the draft ND for such ointments (2-8 ° C).

Table 3 The concentration of palmitate retinol in ointment compositions stabilized with α-tocopherol when determining the shelf life by the method of “accelerated aging” at a temperature of 40 ° C The experimental storage period, days Shelf life, years The content of retinol palmitate in ointments,% Example 1 Example 2 Example 3 Example 4 Example 5 without α-tocopherol 0.1% α-tocopherol 0.15% α-tocopherol 0.2% α-tocopherol 0.25% α-tocopherol After manufacturing 0.51 0.51 0.50 0.50 0.52 46 one 0.49 0.52 0.50 0.51 0.50 69 1,5 0.48 0.51 0.51 0.50 0.51 92 2 0.45 0.48 0.50 0.51 0.52 138 3 0.40 0.45 0.49 0.51 0.50

Note: ND quality indicators from 0.45% to 0.55%.

At the second stage, the antioxidant activity of the minimum of optimally effective concentrations of α-tocopherol (0.15%) established for the ointment with a 0.5% RP content was studied using ointment compositions, the RP content of which was 0.3%, 0 , 5% and 0.7%, which reflects the entire range of the declared concentrations of retinoid (table 4).

Table 4 The concentration of palmitate retinol in ointment compositions with 0.3%, 0.5% and 0.7% palmitate retinol stabilized with 0.15% α-tocopherol when determining their shelf life by the method of “accelerated aging” at a temperature of 40 ° C The experimental storage period, days Shelf life, years The content of retinol palmitate in ointments,% Example 6 Example 3 Example 7 0.3% RP 0.5% RP 0.7% RP After manufacturing 0.31 0.52 0.71 46 one 0.31 0.52 0.71 69 1,5 0.30 0.51 0.70 92 2 0.31 0.51 0.68 115 2,5 0.30 0.51 0.67

138 3 0.31 0.50 0.67 Note: ND quality indicators are from 0.27% to 0.33%, from 0.45% to 0.55% and from 0.63 to 0.77%, respectively.

The study showed that the minimum concentration of α-tocopherol that is optimally effective for an ointment with 0.5% RP shows the desired stabilizing effect with respect to ointment compositions containing RP within the stated concentration range and ensures their stability during the storage period provided for in the draft ND .

Literature

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2. Guzev KS, Nozdrin V.I. New domestic medicines with retinoids - M .: FNPP "Retinoids", 2003. - 112 p.

3. Almanac "Retinoids". - M .: FNPP "Retinoids", 2000. - Issue 8. - C.3-10.

4. Nozdrin V.I., Yatskovsky A.N., Guzev K.S. and others. An experimental study of the specific pharmacological activity of the ointment Videstim // Almanac "Retinoids". - M .: FNPP "Retinoids", 2000. - Issue 8. - S.11-16.

5. Ivanov O.L., Samgin M.A., Panichkina G.S. The study of the effectiveness and tolerability of the drug Videstim (ointment with retinol palmitate 0.5%) // Almanac "Retinoids". - M .: FNPP "Retinoids", 2000. - Issue 8. - S. 38-41.

6. Kubanova A.A., Fedorov S.M., Timoshin G.G. Clinical study of Weidestim ointment (ointment with retinol palmitate 0.5%) // Almanac "Retinoids". - M .: FNPP "Retinoids", 2000. - Issue 8. - S. 42-44.

7. Mother of Pearl Yu.N. Clinical study of Videstim ointment containing 0.5% palmitate retinol // Retinoids Almanac. - M .: FNPP "Retinoids", 2000. - Issue 8. - S. 46-48.

8. Albanova V.I., Palchik E.A. The use of ointment Videstim ^® during breastfeeding // Almanac "Retinoids". - M .: FNPP "Retinoids", 2006. - Issue 23. - S. 41-43.

9. Patent RU 2115409. - Publ. 07/20/1998.

10. Patent RU 2146921. - Publ. 03/27/2000.

11. Patent RU 2036640. - Publ. 06/10/1995.

12. Arkhapchev Yu.P. Method for determination of butyloxyanisole and butyloxytoluene in ointment with retinol palmitate by HPLC method // Pharmaceutical science in solving issues of drug supply. M., 1998. - Scientific works. - T. XXXVII. - S.86-89.

13. Guzev K.S. Theoretical background and experimental study of dosage forms containing 13-cis-retinoic acid and retinol palmitate: Abstract. dis. Doct. pharmacist, sciences. - M., 1997 .-- 50 p.

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18. Wojciechowska A.L., Wolfenzon I.I. Chemistry is for you. Cosmetics today. - M .: Chemistry, 1988 .-- P.141.

Claims (1)

A topical ointment composition that reduces epidermis keratinization, softens the skin and stimulates regenerative processes in it, based on a retinoid containing retinol palmitate, α-tocopherol, emulsion wax, liquid paraffin, glycerin, ethanol and water in the following ratio of components, wt.% :
Retinol palmitate 0.3-0.7 α-tocopherol 0.15-0.25 Emulsion Wax 5.0-15.0 Vaseline oil 5.0-15.0 Glycerol 5.0-15.0 Ethanol 95% 5.0-15.0 Distilled water up to 100.0

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