Title of Invention	N-ACYLIC AMINOACID DERIVATIVES, FOR THE PRODUCTION AND PHARMACEUTICAL COMPOSITIONS THEREOF
Abstract	The present invention relates to N-acyl derivatives of amino acids and pharmaceutically acceptable salts thereof or pharmaceutically acceptable salts thereof, to novel processes for preparing the same, to use thereof as anti-allergic, anti-anaphylactic, anti-inflammatory and hypolipidemic agents as well as to a pharmaceutical composition comprising the indicated compounds in an efficient amount and to a method for treating allergic and inflammatory diseases and lipid metabolism disorders: bronchial asthma, allergic rhinitis, pollinoses, seasonal and year-round rhinitis, allergic pneumonitis, atopic dermatitis, psoriasis, urticaria, allergic (including anaphylactic) reactions to insect stings and medicaments, cold allergy, allergic conjunctivitis, atherosclerosis, obesity, ischemic heart and cerebral disease, myocardial infarction and stroke.

Title of Invention

N-ACYLIC AMINOACID DERIVATIVES, FOR THE PRODUCTION AND PHARMACEUTICAL COMPOSITIONS THEREOF

Abstract

The present invention relates to N-acyl derivatives of amino acids and pharmaceutically acceptable salts thereof or pharmaceutically acceptable salts thereof, to novel processes for preparing the same, to use thereof as anti-allergic, anti-anaphylactic, anti-inflammatory and hypolipidemic agents as well as to a pharmaceutical composition comprising the indicated compounds in an efficient amount and to a method for treating allergic and inflammatory diseases and lipid metabolism disorders: bronchial asthma, allergic rhinitis, pollinoses, seasonal and year-round rhinitis, allergic pneumonitis, atopic dermatitis, psoriasis, urticaria, allergic (including anaphylactic) reactions to insect stings and medicaments, cold allergy, allergic conjunctivitis, atherosclerosis, obesity, ischemic heart and cerebral disease, myocardial infarction and stroke.

Full Text	2420-300760. N-acyl derivatives of amino acids, a process for preparation thereof, a pharmaceutical composition and use thereof as antiallergic, anti-inflammatory and hypolipidemic agents Description The present invention relates to the field of bioorganic chemistry and concerns N-acyl derivatives of amino acids and pharmaceutically acceptable salts thereof, novel processes for synthesis of said compounds as well as pharmaceutical compositions based on them and use thereof in medicine as anti-allergic, anti-inflammatory and hypolipidemic agents. Prior art Allergic diseases and lipid metabolism disorders are known to be highly prevalent at the present time because of a poor environmental situation, change in the structure of nutrition and life style of population. Therefore, the problem of developing medicaments for combating these pathologies as well as inflammatory processes accompanying allergy, remains to be actual. H1-histamine receptor blockers are the most spread group of anti-allergic drugs.. At the present time, two generations of anti-histamine drugs are distinguished [Mashkovsky M.D. Lekarstvennye sredstva (Medicaments)/ Moscow, the Novaya Volna publishers, 2005, p.285]. Anti-histamine drugs of the first generation pass through blood-brain barrier and are capable of inducing H1-receptor blockade of the central nervous system cells that causes their adverse sedative effect. High blood concentration of these drugs are required to achieve a pronounced anti-histamine action that requires prescription thereof at high doses. A rather frequent development of tachyphylaxy, effect on the CNS manifested by disordered coordination, dizziness, feeling of flabbiness, lowered ability of concentrating attention are negative characteristics of these drugs. In spite of the aforesaid, anti-histamine agents of the first generation are still used especially in the situations when a very fast treatment effect is needed, for example in anaphylaxis. Dimedrol (diphenhydramine), suprastine (chloropyramine), tavegil (clemastine) and phencarol (chyphenadine) belong to the first generation anti-histamine drugs. Anti-histamine drugs of the second generation have attained a wide use in allergological practice since they have no adverse effects inherent to the first generation drugs. In particular, the second generation drugs do not pass through the blood-brain barrier, they do not exert sedative and hypnotic effects. These drugs are characterized by a fast and long-lasting anti- histamine action. Claritine (Loratadine), Zirtec (Cetirisine), Kestine (Ebastine) belong to the second generation anti-histamine drugs. However, the conducted clinical trials have revealed side effects of these drugs caused by interaction thereof with other medicaments or by interruption of its metabolism induced by P450 cytochrome. Thus, potentially sedative (Cetirisine, Loratadine) and potentially cardiotoxic (Terphenadine, Asthemisol (Ebastine) effects 2 have been detected in the second generation anti-histamine agents. In some cases, for example in bronchial asthma, glucocorticoids exerting a potent anti- allergic action are used. However, use thereof is accompanied by systemic manifestations such as Itsenko-Cushing syndrome, hypertension, hyperkalemia, osteoporosis etc. [Mashkovsky M.D. Lekarstvennye sredstva (Medicaments)/ Moscow, 1993, Vol.1, p.365]. The pathochemical stage of allergic response development, which to a significant extent is determined by the activation degree of the first order allergy target cells (basophils and mast cells), plays a special role in the development of allergic diseases. Capability of accumulating and releasing biologically active compounds, first of all histamine, under the effect of a stimulus (allergen) is an important feature thereof. In IgE- and/or IgG-mediated response to antigen, just these cells determine degree of manifestation of immediate allergy clinical picture [Parker Ch.V./ Mediators: Release and Functions.// In: Immunology. Edited by W. Pole. Moscow, the Mir publishers. 1989. vol.3, pp.170-247; Chakravarty N.K.// In: The mast cell: Its role in health and disease, ed. J. Pepys. 1979. p.38-46]. There is a group of drugs (sodium cromoglycate (cromoglycic acid disodium salt), ketotyphen, oxatomide) useful in bronchial asthma and bronchospastic conditions the action of which is based on the capability of inhibiting mast cell degranulation and hampering release from them of mediator substances promoting the development of bronchial spasms, allergy and inflammation (bradykinin, histamine). Mucosal irritation, headache, laryngeal edema, cough, suffocation may be observed as side effects [Mashkovsky M.D. Lekarstvennye sredstva (Medicaments)/ Moscow, the Novaya Volna publishers, 2005, p.297]. Ischemic heart disease that is the first most frequent cause of lethality of adult population world-wide is known to be the most frequent manifestation of atherosclerosis. Lipid metabolism disorder manifested by elevated blood plasma cholesterol level including low density lipoprotein cholesterol (LDLC) and very low density lipoprotein cholesterol (VLDLC) which are called "atherogenic" lipoproteins with simultaneous decrease in the amount of "anti-atherogenic" lipoproteins is recognized as one of the leading disorders in the instant disease. Change in plasma lipid content and ratio was shown to reflect modification thereof in membranous structures of parenchymal organs. Composition of cellular membranes, for example macrosomal, is directly depends on the diet given to experimental animals [Wade A., Harred W. // Feder. Proct. 1976, vol. 55. pp. 2475-2479]. Administration of cholesterol to animals induces cholesterol accumulation in cellular membranes decreasing fluidity thereof that in turn, results in functional state modification of enzymes [Buters J.T.M., Zysset T., Reichen J.//Biochem. Pharmacol. 1993. vol. 46. Iss 6. pp. 983-991]. Hypolipidemic agents lowering blood level of cholesterol and triglycerids may be used 3 for treating and preventing diseases associated with lipid metabolism disorders. The latter are characterized by elevated level of triglycerides, total cholesterol (TC), low density and very low density lipoprotein cholesterol (LDLC and VLDLC) and by lowered level of high density lipoprotein cholesterol in such diseases as atherosclerosis, obesity, ischemic heart and cerebral disease, myocardial infarction, stroke and which serve as a risk factor of manifested diabetes and thrombus formation. Clinical use of so called statines, cholesterol biosynthesis inhibitors, for example zokor (simvastatine) is known. Drugs of the given group at doses 80 mg daily are sufficiently effective mainly with regard to lowering total cholesterol level, but these drugs being poorly available and representing chemical compounds which are xenogenic for the body. Furthermore, use thereof can be accompanied by the side effects such as change in hepatic function with elevated blood transaminase levels and dyspepsia [Mashkovsky M.D. Medicaments./ Meditsina publishers. Moscow. 1993. vol.1, p.463]. In view of the foregoing, a search for novel efficient anti-allergic and hypolipidemic agents with alternative mechanisms of action which are capable of manifesting activity at low concentrations and devoid of side effects is actual. With this regard, compounds comprising residues of substances of natural origin are of a special interest as for them, a lower toxicity and a lower occurrence of side effects may be predicted. In the International application publication WO 99/01103 anti-allergic and hypolipidemic action of N-acyl derivatives of biogenic amines, for example γ-glutamyl histamine and the closest analog thereof glutaryl histamine is disclosed; these compounds are the closest ones by structure and action to the claimed compounds. In the article of Krzhechkovskaya V.V., Zheltukhina G.A., Nebolsin V.E. et al. Study of anti-anaphylactic activity and mechanisms of action of γ-L-glutamyl histamine. // Pathogenez (Pathogenesis). 2003. Vol.1 No 2, pp.60-64 γ- glutamyl histamine was shown to possess a frank anti-anaphylactic activity when different animal species and administration rates are used. The results obtained show that in mast cells of animals a significant lowering histamine level and antigen-stimulated secretion thereof occurs under the effect of γ-glutamyl histamine. Decrease in bronchial spasm value more than by 50% as compared to the control was shown in the test of glutaryl histamine effect on manifestation degree of antigen-induced bronchial spasm. The instant effect was manifested in both oral and intratracheal route of administration at a low dose of 50 µg/kg. Glutaryl histamine is capable of lowering manifestations of passive cutaneous anaphylaxis. In WO 99/01103 administration to animals of glutaryl histamine at doses 50 and 500 µg/kg was shown to significantly lower intensity of delayed type hypersensitivity. Furthermore, glutaryl histamine at doses 50 and 500 µg/kg also possessed some anti-cholesterolemic activity lowering total cholesterol by 5 to 7% as 4 compared to animals with atherogenic loading. Drawback of glutaryl histamine is a comparatively high cost and a poor availability of the starting material for preparation thereof i.e. histamine. Furthermore, the indicated substance is insufficiently effective in the tests mentioned above. In order to expand arsenal of technical means and to create a more efficient and available anti-allergic, anti-inflammatory and hypolipidemic agent, the inventors have revealed certain specific N-acyl derivatives of amino acids of general formula I disclosed in the International application publication WO 99/01103 but particularly not described, not prepared and not characterized therein except for glutaryl-L-histidine methyl ester (XII). Thus, the compounds of the instant invention are covered by general formula I of the International application indicated above. However, in the indicated publication neither particular structural formulas of the given compounds nor any physical-chemical characteristics are presented, as well as processes for preparation thereof are not disclosed. The compounds of the instant invention fall under general structural formula of the compounds disclosed in the International application publication WO 03/072124 possessing the inducing cellular differentiation activity. However, in the given publication, a process for synthesis thereof is not disclosed, and any physical-chemical constants are not presented. One of the compounds, glutaryl histidine, is mentioned only in the form of His C- terminal methyl ester [Glt-His(OMe) (XII)] in the US 3,963,691 as an inermediate used in the synthesis of the peptide Glt-His-Trp-Ser-Tyr-Gly-Leu-Arg-Pro-Gly-poly-Lys. Furthermore, in the International application publication WO 99/01103, synthesis of glutaryl-L-histidine methyl ester (XII) is disclosed and physical-chemical characteristics are presented: data of 1H-NMR, mass spectrometry, HPLC. In the International application publication WO 93/04690, the compound succinyl histidine is mentioned. In this publication, addition of free imidasole or succinyl histidine is indicated to accelerate the reaction between carnosine and dihydroxyacetone. Synthesis of succinyl histidine and physical-chemical constants are not presented. Structural formula of succinyl pryptophane is mentioned in the US application 2005079515. In the indicated publication, neither synthesis of succinyl tryptophane nor physical- chemical constants are not presented. In the journal "Byuleten' experimental'noy biologii i meditsiny", 1998, vol.125, No 5, pp.544-547, dipotassium salt of N-succinyl-d,l-tryptophane possessing anti-arrhythmic and anti- fibrillation activity is disclosed, which provides antiishemic and antihypoxic action and stabilizes hemodynamic parameters in acute myocardial ischemia. In Justus liebigs annalen der chemie, 1966, Band 691. P. 159-164, racemic succinyl tryptophane is disclosed. In Tetrahedron, 2005, v.61, No4, P.919-926, physical-chemical characteristics of succinyl-L-tryptophane and succinyl-D-tryptophane are presented. Any information about biological activity thereof is lacking. In the article Joseph R.Votano et al. Inhibition of deoxyhemoglobin S polymerization by biaromatic peptides found to associate with the hemoglobin molecule at a preferred site. Biochemistry, 1977, v. 16, No25, pp.5484-5491 succinyl-L-tryptophane is mentioned and capability thereof to bind to deoxyhemoglobin is studied. In the article Dongmei H., Chao W., Ming Z., Shiqi P. Synthesis and analgesic activity of N,N'-dicarbonyltryptamines. Prep. Biochem. & Biotechnol., 2000, V.30(3), P.231-240, synthesis of Nα-succinyl-L-tryptophane methyl ester (XI) is disclosed originating from tryptophane methyl ester and succinic anhydride in the presence of dimethylamine pyridine with subsequent chromatographic purification of the target product. Nα-succinyl-L-tryptophane methyl ester is characterized by physical-chemical data: 1H-NMR-, IR-spectroscopy, mass spectrometry, melting point and elemental analysis data. Gluteryl-L-tryptophane methyl ester (XIII) is mentioned in the article Raimondi S., Monti D., Pagnoni U.M., Riva S. Glutaryl acylases: One-reaction enzymes or versatile enantioselective biocatalysts? Adv. Synth. Catal. 2003. V.345(6-7). P.783-789, wherein only typical synthesis technique is presented and only 1H-NMR data are presented out of physical- chemical constants. The compound (XIII) was synthesized as a substrate for glutaryl acylase. Preparation of Nα-glutaryl-L-histamine is disclosed in the International application publication WO 99/01103 which process is N-acylation of biogenic amine with glutaric anhydride in the medium of unhydrous N,N-dimethyl formamide. Furthermore, in the publication of Gershkovich A.A., Kibirev V.K.//Chemical synthesis of peptides./Kiev, Nαukova Dumka publishers, 1992, p.360 a process for acylation of amino acids in aqueous-organic, strongly alkaline medium is disclosed. In the publication of Sorm F., Pravda Z. Proteins and amino acids. X. Synthesis of two peptide analogsV/Chemicke Listy pro Vedu a Prumysl. 1951. V.45. P.423-425, a synthesis process of succinyl tyrosine ethyl ester in a mixture of water and ethyl acetate at 1:1 ratio is disclosed originating from tyrosine ethyl ester chlorohydrate and glutaric anhydride in the presence of NaHCO3 for maintaining a weakly alkaline pH. Free histidine acylation with .carboxylic acid anhydrides is not disclosed in the literature. Object of the instant invention is providing novel effective N-acyl derivatives of amino acids and pharmaceutically acceptable salts thereof possessing anti-allergic, anti-inflammatory and hypolipidemic action at low doses and not showing side effects, pharmaceutical 6 compositions based on them, use thereof as more effective anti-allergic, anti-inflammatory and hypolipidemic agents, as well as novel processes of synthesis of N-acyl derivatives of amino acids. The inventors have developed a simple and efficient process of synthesis of compounds of general formula I consisting in that glutaric or succinic anhydride in the form of a solid is added to an aqueous solution of an amino acid in the absence of inorganic and organic base with obtaining the target product with a sufficiently high yield of 55 to 60%. The inventors have developed one more synthesis process of compounds of general formula I including N-acyl derivatives of histidine and tryptophane which process is the reaction in a biphasic system consisting of an aqueous histidine solution or tryptophane salt and an acylating agent solution in a suitable organic solvent in using the acylating agent excess. Summary of the invention The instant invention relates to novel N-acyl derivatives of amino acids of general and pharmaceutically acceptable salts thereof possessing anti-allergic, anti-inflammatory and hypolipidemic action. The instant invention also relates to a process for preparing N-acyl derivatives of amino acids of formula I and salts thereof comprising addition of glutaric or succinic anhydride in the form of a solid to an aqueous amino acid solution of general formula I: 7 and optionally converting the target product into a salt thereof. The instant invention further relates to a process for preparing N-acyl derivatives of amino acids and salts thereof which process comprises reacting in a biphasic system of glutaric or succinic anhydride with an aqueous solution of the amino acid of general formula and optionally converting the target product into a salt thereof. The instant invention relates also to use of compounds of general formula I and pharmaceutically acceptable salts thereof as anti-allergic, anti-inflammatory and hypolipidemic agents. Further, the instant invention relates to pharmaceutical compositions and an agent possessing anti-allergic, anti-anaphylactic, anti-inflammatory and hypolipidemic action comprising an effective amount of the compound of formula I or a pharmaceutically acceptable salt thereof as well as if needed a pharmaceutically acceptable carrier. One more object of the invention is a method for treating allergic diseases including bronchial asthma, allergic rhinitis, pollinoses, seasonal rhinitis, round-year rhinitis, atopic dermatitis, psoriasis, urticaria, allergic (including anaphylactic( reactions to insect stings and medicaments, cold allergy, allergic conjunctivitis, chronic obstructive pulmonary diseases, namely chronic obstructive bronchitis, emphysema, obliterating bronchitis, mucoviscedosis, as well as diseases related to lipid metabolism disorders: atherosclerosis, obesity, ischemic heart and cerebral disease, myocardial infarction, stroke, which method comprises administering to a subject an effective amount of the compound of general formula I or a pharmaceutically acceptable salt thereof. Detailed disclosure of the invention Preferable compounds of general formula 1 are presented in Table 1. Synthesis of compounds of general formula I can be accomplished by two processes. The first process consists in a gradual adding to an aqueous solution of an amino acid of general formula glutaric or succinic anhydride in the form of a solid with subsequent isolation of the target product using ion exchange chromatography, preferably by passing reaction mixture through a column with cationite and subsequent crystallization from aqueous solution. The crystals of the target product obtained are washed with a suitable solvent, preferably methanol. The main advantage of the claimed process consists in the absence of alkali in the amino acid aqueous solution that prevents from inactivation of dicarboxylic acid anhydride resulting from hydrolysis. Furthermore, imidazol residue in the amino acid molecule can effect acidic-basic autocatalysis of acylation reaction of the amino group of amino acid. Rather high yields (55- 60%) in using the claimed process are achieved in particular due to a gradual adding dicsarboxylic acid anhydride taken in the excess, and to vigorous stirring reaction mass. Compounds of general formula I can be also prepared using an alternative process in a biphasic system which process comprises adding glutaric or succinic anhydride in a water immiscible solvent to .an aqueous solution of the amino acid of general formula: The instant process allows to use the excess of an acylating agent, achieve the complete acylation of a-amino group of the amino acid and yield of the target product of about 70%. In order to maintain required pH, instead of an inorganic alkali, the organic base pyridine is used which does not hydrolyze anhydride and in addition is known to be catalyst of acylation. Using pyridine allows for avoiding contamination of the final product by inorganic salts which together with the reaction product remain in aqueous layer. The used approaches allow for simplifying separation of the target product from non-reacted anhydride and respective amino acid and isolating the target product by a simple crystallization. 10 Preferable water immiscible organic solvents are butanol, ethylacetate and chloroform. Preferable solvents useful for crystallizing the target product are water-alcohol mixtures, in particular, water-ethanol. N-acyl derivatives of amino acid esters of invention (VI-XIII) can be prepared by the action of respective internal anhydrides of dicarboxylic acids on amino-free histidine or tryptophane esters in an organic or water-organic medium. Preferable is preparing the compounds VI-XIII in a biphasic system using water immiscible organic solvents butanol, ethylacetate and chloroform. Compounds of general formula I can also be prepared in the form of pharmaceutically acceptable salts by reacting for example with sodium hydroxide, potassium hydroxide, magnesium carbonate, lithium hydroxide, calcium carbonate using routine processes widely disclosed in the literature. Compounds of general formula I have anti-allergic, anti-inflammatory and hypolipidemic activity and they can be used fro treating allergic, anaphylactic diseases including those accompanied by inflammation, as well as lipid metabolism disorders. In particular, compounds of the present invention may be used for treating the following allergic diseases: bronchial asthma, allergic rhinitis, pollinoses, seasonal rhinitis, round-year rhinitis, atopic dermatitis, psoriasis, urticaria, allergic (including anaphylactic) reactions to insect stings and medicaments, cold allergy, allergic conjunctivitis, chronic obstructive pulmonary diseases, namely chronic obstructive bronchitis, emphysema, obliterating bronchitis, mucoviscedosis, as well as diseases related to lipid metabolism disorders such as: atherosclerosis, obesity, ischemic heart and cerebral disease, myocardial infarction and stroke. Compounds of the present invention are administered in an effective amount which provides for a desirable therapeutic result. For treating allergic diseases including bronchial asthma, allergic rhinitis, pollinoses, seasonal rhinitis, round-year rhinitis, atopic dermatitis, psoriasis, urticaria, allergic (including anaphylactic) reactions to insect stings and medicaments, cold allergy, allergic conjunctivitis, chronic obstructive pulmonary diseases, namely chronic obstructive bronchitis, emphysema, obliterating bronchitis, mucoviscedosis, as well as diseases related to lipid metabolism disorders such as: atherosclerosis, obesity, ischemic heart and cerebral disease, myocardial infarction and stroke, compounds of general formula I may be administered perorally, topically, parenterally, nasally, by inhalation or rectally in unit dosage forms comprising non-toxic pharmaceutically acceptable carriers. As used in the instant disclosure, the term "parenteral administration" means subcutaneous, intravenous, intramuscular or intraperitoneal injections or infusions. Compounds of the present invention can be administered to a patient at doses from 0.01 11 to 10 mg/kg body weight daily, preferably at doses from 0.05 .to 5 mg/kg once or more times daily. At the same time, it should be noted that a particular dose for each particular patient will depend on many factors including activity of a given compound used, age, body weight, sex, general health condition and nutrition regimen of the patient, time and route of administering a medicament, elimination rate thereof from the body, a particular combination of medicaments used as well as on severity of disease to be treated in the given individual. Pharmaceutical composition of the instant invention comprise the compound of general formula I in an amount effective to achieve a desired result and can be administered in unit dosage forms (for example in a solid, semisolid or liquid forms) comprising compounds of the instant invention as an active ingredient in admixture with a carrier or excipinent suitable for intramuscular, intravenous, peroral, sublingual, inhalation, intranasal and intrathecal administration. Active ingredient can be included into a composition together with conventionally used non-toxic pharmaceutically acceptable carriers suitable for manufacturing solutions, tablets, pellets, capsules, dragee, suppositories, emulsions, suspensions, ointments, gels and any other dosage forms. As excipients, different substances such as saccharides for example glucose, lactose or sucrose mannitol or sorbitol, cellulose derivatives and/or calcium phosphate for example tricalcium phosphate or acidic calcium phosphate may be used, and as a binding component, such materials as starch paste, for example corn, wheat, rise, potato starch, gelatine, tragacant, methylcellulose, hydroxypropyl methylcellulose, sodium carboxymethylcellulose and/or polyvinylpyrrolidone. If needed, disintegrants such as the above mentioned starches and carboxymethyl starch, cross-linked polyvinylpyrrolidone, agar or alginic acid or a salt thereof such as sodium alginate can be used. Optional additives such as agents controlling fluidity and lubricants such as silica, talc, stearic acid and salts thereof such as magnesium stearate or calcium stearate and/or propyleneglycol can be used. A core is usually coated by a layer which is resistant to the action of gastric juice. For this, concentrated solutions of saccharides can be used which solutions may optionally comprise gum Arabic, talc, polyvinyl pyrrolidone, polyethylene glycol and/or titanium dioxide, and suitable organic solvents or mixtures thereof. As additives, stabilizers, thickeners, colorants and flavours can be also used. As an ointment base, carbohydrate ointment bases such as white and yellow vaseline (Vaselinum album, Vaselinum flavum), Vaseline oil (Oleum Vaselini), white and liquid ointment (Unguentum album, Unguentum flavum) can be used, and as additives for imparting a 12 more compact consistence, hard paraffin and wax, absorbtive ointment bases such as hydrophilic vaseline (Vaselinum hydrophylicum), lanoline (Lanolinum), coldcream (Unguentum leniens); oitment bases washable with water such as hydrophilic ointment (Unguentum hydrophylum); water soluble ointment bases, such as polyethylene glycol ointment (Unguentum Glycolis Polyaethyleni), bentonite bases and others can be used. As a base for gels, methylcellulose, carboxymethylcellulose sodium salt. oxypropylcellulose, polyethylene glycol or polyethylene oxide and carbopol can be used. As a base for suppositories, water insoluble bases such as cocoa butter; water soluble or water miscible bases such as gelatin-glycerol or polyethylene oxide and combined (soap- glycerol) can be used. In preparing a unit dosage form, an amount of an active ingredient used in a combination with a carrier may vary depending on a recipient subjected to therapy, a particular administration route of a medicament. Thus, in using compounds of the instant invention in the form of solutions for injections, content of an active ingredient therein is 0.01 to 5%. As diluents, 0.9% sodium chloride solution, distilled water, novocaine solution for injections, Ringer solution, glucose solution and specific additives for dissolution can be used. In administering compounds of the instant invention into the body in the form of tablets and suppositories, their amount is from 5.0 to 500.0 mg per an unit dosage form. Dosage forms of the instant invention are manufactures according to the standard techniques such as for example processes of mixing, granulation, forming dragee, dissolution and freeze-drying. It should be noted that compounds of the instant invention show biological activity at doses that are by two-three folds lower than those of the known drugs used for comparison, in a practically similar efficacy, and for them, no adverse side effect have been detected, and contraindication for their use have not been found. At the same time, in examining toxicity of compounds according to the instant invention at a dose 3,000 mg/kg orally, death of experimental animals has not been recorded. Detailed description of the compounds according to the present invention, preparation thereof and the study of pharmacological activity is presented in the following examples intended for illustration of preferable embodiments of the invention and not limiting the scope thereof. Synthesis examples of N-acyl derivatives of general formula I Individuality of the prepared compounds has been checked using TLC method on the plates "Kieselgel 60 F254" "Merck" (Germany) in the systems: methanol (1), chloroform- 13 methanol-ammonia (4:3:1) (2). Chromatograms were developed by a chlorotolidine reagent, ninhydrine, iodine by luminescence in UV light. Optic rotation angles were measured on the polarometer "Perkin Elmer 341" (Sweden). 1H-NMR was recorded on the apparatus "AMX-400 Bruker" (Germany). Melting point was determined on the apparatus "Boetius" (Germany). Analytical HPLC was carried out on the apparatus "System Gold" ("Beckman", USA), elution rate 0.25 ml/min; detection at 214 nm under the following conditions: column Ultrasphere ODS "Beckman", 2x250 mm, 5 pm, elution with 0.1% TFA, elution rate 0.25 ml/min (1); eluting rate 1 ml/min, detection at 220 nm; column Luna-5 "Phenomenex", C18, 250x4.6 mm, elution 25% acetonitryl in 0.05 M phosphate buffer (pH 3.0) (2). Example 1 Nα-glutaryl-L-histidine (IV) Technique A To solution of 103.4 g (0.67 mmol) histidine in 400 ml water 83.7 g (0.73 mol) glutaric anhydride were added. Suspension was stirred for 1 hour, the formed solution was boiled down to the volume 150 ml, left in a refrigerator for 16 hours. Precipitate was filtered off, washed with 150 ml ethanol and dried. Purification was carried out by ion exchange chromatography on the resin Purolight in H+ form eluting with water. Fractions comprising the target product were combined, boiled down until precipitation begun and left for 16 hours at 4°C. Precipitate was filtered off, washed with 200 ml methanol and dried to a constant weight. Yield 98.8 g (55%). Rf 0.55 (1), 0.37 (2). Tmp=222-224oC. [α]D20+15.95° (C 0.53, water). [M+H]+ 270.1. 1H-NMR spectrum (D2O), δ, m.d.: 1.60-1.80 (m, 2H, β-CH2-Glt), 2.10-2.25 (m, 4H, α,γ-CH2-Glt), 2.90- 3.25 (m, 2H, β-CH2-His), 4.40-4.50 (m, 1H, α-CH-His), 7.15 (s, 1H, CH-4-Im), 8.50 (s, 1H, CH- 2-Im). Found, %: C 49.18; H 5.91; N 15.42. C11H15N3O5. Calculated, %: C 49.07; H 5.62; N 15.61. Technique B To suspension of 0.3 g (1.93 mmol) histidine in 5 ml water under vigorous stirring 0.44 g (3.86 mmol) glutaric anhydride dissolved in 2.5 ml ethylacetate is added. The suspension was stirred for 2 hours, pH was adjusted to 7 with pyridine and stirred for another 1 hour. Ethylacetate and aqueous layers were separated. Aqueous layer was twice washed with ester, ester layer was discharged. Water was removed in vacuo, precipitate was dissolved in a minimum amount of water and ethanol was added prior to beginning sedimentation of a white precipitate, left at +4°C for 20 hours. Precipitate was filtered off, dried in vacuo. Yield 0.36 g (70%). Rf 0.56 (1), 0.35 (2). Tmp=219-221°C. [α]D20=+15.71° (C 0.56, water). [M+H]+ 270.1. 14 1H-NMR spectrum (D2O), δ, m.d.: 1.40-1.55 (m, 2H, β-CH2-Glt), 1.90-2.0 (m, 4H, α, γ-CH2- Glt), 2.7-3.0 (m, 2H, β-CH2-His), 4.20-4.30 (m, 1H, α-CH-His), 6.95 (s, 1H, 4-CH-Im), 8.30 (s, 1H, 2-CH-Im). HPLC under the conditions: (1) - individual peak, retention time 14.55 min. Found, %: C 49.07; H 5.65; N 15.65. C11H15N3O5. Calculated, %: C 49.07; H 5.62; N 15.61. Example 2 Nα~suctinyl-L-histidine (V) Synthesis was carried out in accordance with the technique A presented for compound IV. Yield 0.08 g (57%). Rf 0.44(1), 0.25(2). Tm.p=179-181°C. [α]D20=+30.71° (C 0.56, water). [M]+ 255.2. 1H-NMR spectrum (D2O), δ, m.d.: 2.15-2.30 (m, 4H, (CH2)2-Suc), 2.75-2.95 (m, 2H, β- CH2-His), 4.25 (br.s, 1H, a-CH-His), 6.95 (s, 1H, 4-CH-Jm), 8.25 (s, 1H, 2-CH-Jm). Found, %: C 47.09; H 5.04; N 16.40. C10H13N3O5. Calculated, %: C 47.06; H 5.13; N 16.46 Synthesis was carried out according to the technique B carried out for compound IV. Yield 0.101(67%). Rf 0.45(1), 0.27(2). Tm.p=178-180°C. [α]D20=+30.8° (C 0.57, water). HPLC under the conditions (1) - individual peak, retention time 7.54 MHH. Found %: C 47.15; H 5.2; N 16.50. C10H13N3O5. Calculated %: C 47.06; H 5.13; N 16.46. Example 3 Nα-Glutaryl tryptophane (III) To suspension of 1.0 g (4.9 mmol) tryptophane in 7 ml water 1 N NαOH solution (4.9 mmol) was added drop-wise. To the prepared solution, solution of 0.56 g (4.9 mmol) glutaric aldehyde in 3 ml ethylacetate were added. Reaction mixture was stirred for 3 hours at room temperature under argon in darkness and left for 16 hours at +4°C. Solvent was removed from the reaction mixture in vacua. The oily residue obtained was dissolved in 30 ml water while stirring, cooled down to 0°C, and 1 N HC1 was added to adjust pH to 4. The product was extracted with ethylacetate (3x25 ml). The combined ethylacetate extract was cooled down to 0°C, washed with water (4 x 25 ml) to ajust pH to 7, washed with 5% HC1 (5 ml) and washed 15 with water (4 x 25 ml) adjust pH to 7.0, dried over anhydrous Na2SO4 for 1 hour. Residue of Na2SO4 was filtered off, washed with ethylacetate, the solvent was removed in vacuo. Grayish solid precipitate was obtained which was dried in vacuo. Yield 1.0 g (70%). Rf 0.54(1). Tm.p=150-152°C. [α]D20=+8.20° (C 0.5, methanol). 1H-NMR spectrum (CD3OD), δ, m.d.: 1.75-1.84 (m, 2H, β-CH2-Glt), 2.15-2.30 (m, 4H, α,γ-CH2-Glt), 3.30-3.40 (m, 2H, β-CH2-Trp), 3.80-3.90 (m, 1H, α-CH-Trp), 6.97 (t, J=7 Hz, 1H, CH-6-Ind), 7.06 (t, J=7 Hz, 1H, CH-7-lnd), 7.15 (d, J=7 Hz, 1H, CH-2-Ind), 7.33 (d, J=7 Hz, 1H, CH-5-Ind), 7.55 (d, J=7 Hz, 1H, CH-8-Ind). HPLC under the conditions: (2) - individual peal, retention time 6.77 minutes. Found, %: C 60.07; H 5.65; N 8.75. C16H18N2O5 Calculated, %: C 60.37; H 5.7; N 8.8. Example 4 N°- Succinyl-L-tryptophane (II) Synthesis was carried out in accordance with the technique presented for the compound III. Yield 100.5 mg (67%). Rf 0.63(1). [α]D20=+21.05° (C 0.6, water). 1H-NMR spectrum (DMSO-d6), δ, m.d.: 2.33-2.41 (d, 4H, α,β-CH2-Suc), 2.93-3.01 (d, 1H, β-CH2-Trp), 3.10-3.16 (m, 1H, β-CH2-Trp), 4.39-4.47 (m, 1H, a-CH-Trp), 6.93-7.06 (m, 2H, CH-6,7-Ind), 7.11 (d, J=2.2 Hz, 1H, CH-2-Ind), 7.30-7.32 (m, 1H, CH-5-Ind), 7.44-7.47 (m, 1H, CH-8-Ind). [M]+ 304.3. HPLC under the conditions: (2) - individual peal, retention time 6.35 minutes. Found, %: C 59.07; H 5.65; N 9.35. C15H16N2O5 Calculated, %: C 59.21; H 5.3; N 9.21. Example 5 Nα-glutaryl-L-histidine monosodium salt (IV) To a solution of 1.0 g (3.7 mmol) of Nα-glutaryl-L-histidine in 15 ml water, a solution of 0.15 g (3.7 mmol) NαOH in 20 ml water was added while stirring and cooling down to +5°C. The solution was stirred for 30 min, the solvent was removed in vacuo. To an oily residue, benzene was added in portions, the solvent was removed in vacuo. A solid residue was dried over granulated alkali. Yield 1.07 g (99.7%). 16 Tm.p =208-210°C. [α]D20=+16.27° (C 0.58, water). Found, %: C 45.25; H 5.51; N 14.52. C11H15N3O5Na. Calculated, %: C 45.21; H 5.17; N 14.38. Example 6 Nα-succinyl-L-histidine monosodium salt (V) Synthesis was carried out in accordance with the technique presented for Nα-glutaryl-L- histidine monosodium salt (IV) (Example 5). Yield 1.06 g (97.0%). [α]D20=+40.21° (C 0.48, water). Found, %: C 43.25; H 4.51; N 15.52. C10H13N3O5Na. Calculated, %: C 43.17; H 4.71; N 15.10. Example 7 Nα-succinyl-L-tryptophane monosodium salt (II) Synthesis was carried out in accordance with the technique presented for Nα-glutaryl-L- histidine monosodium salt (IV) (Example 5). Yield 0.21 g (98.0%). Tm.p=147-150°C. [α]D20=+22.02° (C 0.39, water). Found, %: C 55.25; H 4.51; N 8.32. C15H16N2O5Na. Calculated, %: C 55.05; H 4.93; N 8.56. HPLC under the conditions: (2) - individual peal, retention time 6.56 minutes. Example 8 Nα-glutaryl-L-tryptophane monosodium salt (III) Synthesis was carried out in accordance with the technique presented for Nα-glutaryl-L- histidine monosodium salt (IV) (Example 5). Yield 0.11 g(99.0%). Tm.p=128-130°C. [α]D20=+22.06° (C 0.34, methanol). Found, %: C 56.15; H 5.21; N 8.22. C16H18N2O5Na. Calculated, %: C 56.30; H 5.32; N 8.21. HPLC under the conditions: (2) - individual peal, retention time 6.96 minutes. Example 9 Nα-glutaryl-L-histidine monosodium salt (IV) To a solution of 1.0 g (3.7 mmol) Nα-glutaryl-L-histidine in 15 ml water a solution of 0.3 17 g (7.44 mmol) NaOH in 15 ml water was added while stirring and cooling down to +5°C. The solution was stirred for 30 min, the solvent was removed in vacuo. To an oily residue, benzene was added in portions, the solvent was removed in vacuo. A solid residue was dried over granulated alkali. Yield 1.15 g (99.0%). [α]D20=+l 1.92° (C 0.57, water). Found, %: C 41.25; H 4.51; N 13.52. C11H15N3O5Na2. Calculated, %: C 41.91; H 4.80; N 13.3. Example 10 Nα-succinyl-L-histidine disodium salt (V) Synthesis was carried out in accordance with the technique presented for Nα-glutaryl-L- histidine disodium salt (IV) (Example 9). Yield 1.16 g (99.0%). Tm.p=124-128°C. [α]D20=+20.06° (C 0.67, water). Found, %: C 39.55; H 4.31; N 13.52. C10H13N3O5Na2. Calculated, %: C 39.88; H 4.35; N 13.95. Example 11 Nα-succinyl-L-tryptophane disodium salt (II) Synthesis was carried out in accordance with the technique presented for Nα-glutaryl-L- histidine disodium salt (IV) (Example 9). Yield 0.56 g (97.7%). Found, %: C 51.35; H 4.31; N 8.22. C15H16N2O5Na2. Calculated, %: C 51.43; H 4.60; N 8.0. Example 12 Nα-glutaryl-L-tryptophane disodium salt (III) Synthesis was carried out in accordance with the technique presented for Nα-glutaryl-L- histidine disodium salt (IV) (Example 9). Yield 0.56 g (98.5%). Found, %: C 52.55; H 4.71; N 7.52. C16H18N2O5Na2. Calculated, %: C 52.75; H 4.98; N 7.69. Example 13 Nα-succinyl-L-histidine methyl ester To a solution of 1.0 g (4.13 mmol) histidine methyl ester in 5 ml of N,N- dimethylformamide 5 ml water and a solution of 0.41 g (4.13 mmol) succinic anhydrife in 2.5 ml 18 ethylacetate were added in vigorous stirring. The mixture was stirred for 2 hours at room temperature. Ethylacetate and water layer were separated. Water layer was washed twice with ester, ester layer was discarded. Water was removed in vacuo, a residue was triturated with 10 ml hexane. A residue was filtered off and dried in vacuo. Yield 0.70 g (67%). Rf 0.38(1). Tm.p=171-173°C. 1H-NMR spectrum (DMSO-d6), δ, m.d.: 2.26-2.37 (m, 4H, α,β-CH2-Suc), 2.70 (s, 3H, - O-CH3), 2.76-2.87 (m, 2H, β-CH2-His), 4.33-4.45 (m, 1H, α-CH2-His), 6.78 (s, 1H, 4-CH-Im), 7.93 (s, 1H, 2-CH-Im), 8.25 (d, J=7Hz, NH-amide.). [α]D20=+l 1.92° (C 0.57, water). According to similar typical techniques, the novel compounds of general formula I presented in Table 2 were also prepared. Table 2 Structure and characteristics of compounds of general formula I 19 Tests for biological activity Example 14 Effect of compounds of general formula I on immediate type allergic reactions (in vitro test of ovalbumin (OA)-induced blood basophil degranulation of immunized guinea pig) Leukocytes from guinea pig blood were isolated according to the Freemel's method [Immunologicheskiye Metody under edition of G. Frimel/Moscow., "Meditsina" publishers, 1987, p.222 in the inventor's modification]. Guinea pigs of both sexes weighing from 600 to 800 g were used to conduct the test. The animals were once immunized with a mixture of 10 µg ovalbumin and 100 mg aluminum hydroxide per one animal according to Andersson [Anderson P. Antigen-induced bronchial anaphylaxis in actively sensitized guinea-pigs.//Allergy. 1980. Vol. 35. P.63-71]. Under ester anesthesia, 15 ml blood were drawn from guinea pig heart. Double precipitation of cells using EDTA and a citrate-containing precipitating liquid was used to isolate basophils in the leukocyte suspension. Blood was mixed with 5% EDTA-Na2 2H2O ("Sigma") solution at 9:1 ratio and in 30 minutes it was subjected to mild centrifugation (for 12 minutes at 80 g). Supernatant was collected and centrifuged for 15 minutes at 500 g. To the remaining cells, a citrate-containing precipitating liquid (3) was added at 20 proportion 3:10 (it was thermostated at 37°C for 30 minutes). A supernatant fraction enriched by leukocytes was centrifuged for 7 minutes at 100 g. To leukocyte precipitate, 0.85% NaCl solution was added and cellular concentration was brought to 30x103/µl.. Protocol of the in vitro basophil degranulation test [Spravochnil po klinicheskim laboratornym metodam issledovaniya (A reference book on clinical-laboratory examination methods)/Edited by E.A. Cost/Moscow, "Meditsina" publishers, 1975, p. 130]. For the test, a centrifuge tube (3 tubes per each sample) was filled with 300 ul cellular suspension, then salt solution of a tested compound (or a salt solution in the control of spontaneous and maximum degranulation) was added and pre-incubated at 37°C for 15 minutes, then into each tube 300 µl 1% OA solution was added (in the control of spontaneous degranulation a salt solution in the same amount was added) and once more pre-incubated at 37°C for 10 minutes. Functional leukocyte concentration was 104/µl. Samples (100 µl) were taken off from each tube into separate tubes to assess a complete basophil degranulation, and to the remained cells, a cooled salt solution was added (5 ml into each tube) to arrest degranulation reaction, then the tubes were centrifuged for 7 min at 100 g, and from precipitate, preparations for microscopy were prepared. The preparations were fixed and stained according to the method of Seder et al. [Seder R.A. et al. Mouse splenic and bone marrow cell populations that express high - affinity Fes receptors and produce interleukin-4 are highly enriched in basophils.// Proc.Natl.Acad.USA, 1991, V.88, P.2835-2839]. In order to detect a specific basophil granulation, the dye 0.5% alcyanic blue (pH 1.0) was used, nuclei were additionally stained with safranin (0.1% solution in 1% acetic acid). The preparations were used to assess a total degranulation inhibition. Atotal degranulation inhibition (DI) (%) was calculated according to the formula: max - % of degranulated basophils at the maximum degranulation (OA) spontaneous - % of degranulated basophils in spontaneous degranulation (control) experimental - % of degranulated basophils following exposure to the tested compound. Assessment of a complete basophil degranulation Samples selected following basophil degranulation test (100 µl each) were poured into tubes with the dye (0.5% alcyane blue, pH 1.0) at ratio 1:1. Staining was carried out at room temperature for not less than 50 min. Stained basophils were calculated using the Fooks- Rosenthal chamber. Inhibition of a complete basophil degranulation (ICD) was calculated according to the formula: ICD(%)=1 -[(M m (c) - M m (exper.)] / [M m (c) - M m (OA)] x 100, wherein 21 M m (c) - mean (by three samples) basophil number in the spontaneous basophil degranulation test; M±m (OA) - mean (by three samples) basophil number in the maximum antigen-induced basophil degranulation test; M±m (exper.) - mean (by three samples) basophil number in the basophil degranulation test following incubation with the tested compound. Table 3 In vitro inhibition of OA-induced basophil degranulation of guinea pig blood as effected by compounds of general formula I Order No of test Groups Complete degranulation inhibition (CDI), (%) Number of completely degranulated basophils, (%) 1. Control 1 (spontaneous degranulation) 100 0 2. Ovalbumin 1% (max degranulation) 0 35.2±0.8 3. Compound IV (10-3M) 99.2±11.2 2.6±2.6* 4. Compound IV (10-4M) 99.5+12.0 2.9±1.6* 5. Compound IV (10-5M) 113.5+2.7 0 6. Compound IV (10-6M) 90.0±1.8 3.9±0.6 7. Compound IV (10-7M) 76.7±1.5 9.1+0.8 8. Glutaryl histamine (10-3M) 9.3±5.5 31.6±6.33 9. Glutaryl histamine (10-4M) 24.1±1.1 25.3±3.38 10. Glutaryl histamine (10-5M) 0 29.8±6.73 11. Control 2 100 0 22 12. Ovalbumin 1% (max degranulation) 0 38.9+8.43 13. Compound V (10-3M) 10.6±7.6 35.3±7.29 14. Compound V (10-4M) 18.9+11.8 31.2+6.8 15. Compound V (10-5M) 44.0+11.27 24.6+10.38 16. Hydrocortisone (10-3M) 71.0+1.6 10.0±0.7 17. Hydrocortisone (10-4M) 48.0±0.8 17.3+0.9 18. Hydrocortisone (10-5M) 40.0±0.6 20.0+1.3 (* - P The data of Table 3 show that as compared to glutaryl histamine, the compound (IV) exerts a pronounced anti-anaphylactic action manifested by a practically 100% degranulation inhibition in the test of a complete OA-induced degranulation of blood basophils collected in immunized guinea pigs (in vitro anaphylaxis reaction in a calcium free medium). A significant anti-anaphylactic effect of compound IV is also manifested by decrease in the number of degranulated cells, especially pronounced at concentration 10-5 M (absence of degranulated cells). Example 15 Study of the effect of compounds of general formula I on systemic anaphylaxis in vivo A bronchial spasm model in conscious guinea pigs actively sensitized by exposure to aerosol ovalbumin as an antigen was used [Kovaleva V.L. "Metodicheskiye ukazaniya po izucheniyu bronkholiticheskikh I protivovospalitel'nykh sredstv.// Rukovodstvo po experimental'nomy (doklinicheskomu) izucheniyu novykh pharmacologicheskikh veshchestv, Moscow. 2000. pp.242-250]. Guinea pigs were sensitized by ovalbumin according to the method of Andersson [Anderson P. Antigen-induced bronchial anaphylaxis in actively sensitized guinea-pigs.//Allergy. 1980. Vol. 35. P. 63-71] and in 1-2 months following sensitization, bronchial spasm was induced by aerosol administration of albumin booster dose (3 mg/kg in 1 ml normal saline). In test groups, guinea pigs were for three days administered with tested compounds at 23 doses 10 µg/kg, 50 µg/kg, and 150 µg/kg, using a probe. In the other group of experiments, the tested compounds at dose 50 µg/kg (in 1 ml normal saline) were administered nasally (using a nebulizer) also once daily for three days. The control group was administered with normal saline. One hour post the last administration of substances, ovalbumin was administered by inhalation using a nebulizer, and intensity and duration (in seconds) of bronchial spasm reaction in animals was assessed. Table 4 Inhibition of systemic anaphylactic reaction of guinea pigs in administering by inhalation of compound IV at dose 50 µg/kg Groups Duration of acute phase, seconds Duration of sub-acute phase, seconds Control 1 (normal saline) 180±6 650±34 Compound IV 50 µg/kg 0 400±25 Table 5 Inhibition of systemic anaphylactic reaction of guinea pigs in intragastric administering compound IV at doses 10 and 150 µg/kg (M±m) Groups Duration of acute phase, seconds Total reaction time, seconds Control 2 (normal saline) 296.7+104.6 628.3±80.6 Compound IV 10 µg/kg 68.0±54.7* 428.0±75.0 Compound IV 150 µg/kg 72.0±42.1* 337.0±78.5* * - P Experimental results presented in Tables 4 and 5 show that compound IV in intragastric administration at doses 10 and 150 µg/kg and at dose 50 µg/kg by inhalation exhibited anti- anaphylactic activity. Administering the substance at dose 50 µg/kg by inhalation blocked the development of the acute phase of bronchoconstrictory reaction which by inducing suffocation, is a cause of animals' death. In intragastric administration of compound IV at doses 10 and 150 µg/kg, a significant protective effect with regard to antigen-induced bronchial spasm was detected. Thus, compound IV exhibits a significant protective effect with regard to systemic 24 anaphylactic reaction in vivo. Example 16 Anti-allergic action of compounds of general formula I on the model of allergic rhinitis in guinea pigs The model of allergic rhinitis in guinea pigs was used. Guinea pigs were immunized according to the certain scheme for 1.5-2 months (Hutson P.A., Church M.K. et al. 1988): the animals were first immunized by intraperitoneal administration of ovalbumin at dose 10 mg/kg at 7-day interval (twice), then ovalbumin solution was inhaled to the guinea pigs using the Pari nebulizer at increasing concentration beginning from 0.1% and reaching 1% at 4-day intervals between inhalations. The last ovalbumin dose was administered into the nasal passages using a micropipette. 24 hours post the last ovalbumin administration nasal washing was collected (through a system of special tubes) and changes in nasal mucosa was assessed using a complex of histological and cytological methods. The compounds tested (0.1% solution) were daily administered in the form of inhalations using nebulizing device for 6 days; at day 6 of administration, antigen (OA) challenge was performed. Nαsal wash-off was obtained 24 hours post challenge. Table 6 The effect of compound IV on cytosis (absolute number of cells in 1 µl) in a nasal wash-off It follows form Tables 5-7 that under the conditions of modeling allergic rhinitis, compound IV significantly suppresses eosinophilic inflammation. This is supported by lowering down to the norm absolute and relative number of eosinophils, as well as by a significant lowering cytosis in nasal wash-off. Example 17 Anti-allergic activity of compounds of general formula I in the model of allergic pneumonitis in guinea pigs The model of allergic pneumonitis in guinea pigs was used. Immunization of the animals was similar to that described in Example 7. 24 hours post the last ovalbumin administration broncho-alveolar wash-off was collected (through a cannula inserted into the trachea), and changes in bronchial mucosa was assessed using a complex of histological and cytological methods. The compounds tested (0.1% solution) were daily administered in the form of inhalations using a nebulizing device for 6 days; at day 6 of administration, antigen (OA) challenge was performed. Table 10 The effect of compound IV on absolute number of cellular subpopulations in broncho-alveolar wash-off of guinea pigs (in 1 µl) * - difference from the intact control; ° - difference from the model (,°-P It follows from the data of Tables 9 and 10 that compound IV under the conditions of allergic pneumonitis model significantly inhibits inflammatory process that is manifested by decrease in cytosis, lowering the level of the key inflammatory cells eosinophils, by a sharp lowering neutrophil level as well as by decrease in lymphocyte number. 27 Example 18 Study of anti-inflammatory action of compounds of general formula I on the model of pneumonitis induced in rats by sephadex The model of sephadex-induced (6-day) pneumonitis in rats Male Wistar rats weighing 270-300 g were used in the tests. Inflammation in the lungs was induced by a single inhalation of sephadex A-25 (hydrophilic powder with particle sizes from 20 to 80 µm) at dose 5 mg/kg using a dosing device which is a laboratory analog of the inhaler "Cyclohaler" (the Scientific-Research Institute for Pulmonology of the RF). A technique of inhalation administering sephadex and pharmacological substances Sephadex A-25 at dose 5 mg per 1 kg body weight was administered to rats under ester anesthesia using an original dosing device for inhalation administering dry powders. Following administration of Sephadex A-25, Wistar rats rapidly recovered form anesthesia, and no peculiarities in their behavior and respiration character were noted. The substances in the form of a dry powder were administered by inhalation at dose 500 µg/kg 1 hour post Sephadex administration, then for 5 days in succession once daily at one and the same morning hours. The control was represented by two groups: a group of intact animals, anda group of rats administered once with Sephadex by inhalation. The results of therapeutic action of pharmacological substances on pneumonitis development were assessed using morphological and morphometric parameters (volume density and alveolitis) 6 days post aerosol Sephadex administration. Methods used in the study Histological method Histological examinations of the lungs stained by hematoxyline and eosine. Morphometric methods 4-5 urn thick histological lung slices were prepared wherein neutrophil number was calculated as well as volume density of alveolitis and emphysema was assessed using the Avtandilov's mesh [Avtandilov G.G., Vvedeniye v kolichestvennuyu pathologicheskuyu morphologiyu.// Moscow. "Meditsina" publishers. 1980. p. 203]. Morphometric examination of pulmonary lymphoid tissue was also carried out. To this end, micro preparations of the lungs were fixed according to the method of Beinenstock et al [Bienenstock J., Johnson N., Perey D.Y.E. Bronchial lymphoid tissue 1. Morphologic characteristics//Lab. Invest. 1973. v.28 p.693- 698.] The lungs with trachea were removed from the thoracic cavity, and the micro preparation was placed into 2% water acetic acid solution. 18-24 hours later, the trachea, the main and lobular bronchi were dissected, and morphometric assessment of volume density of the lymphoid 28 tissue associated with the bronchi was carried out using the point calculation method under a magnifying glass (magnification x7). Volume density of alveolitis and emphysema was determined using the point calculation method. Cytological methods Broncho-alveolar wash-off was obtained in rats and guinea pigs under hexenal anesthesia by double washing the lungs through the trachea with 10 ml normal saline. Viability of cells was determined in the test with tryptane blue. Absolute number of cells in 1 ml (cytosis) was determined in the broncho-alveolar wash-off liquid (BAW) using the Goryaev's chamber. In the smears of the BAW liquid precipitate obtained using centrifugation at 200 g for 10 minutes and then stained according to Romanovsky-Gimza, endopulmonary cytogram was calculated (in percent) [Avtsyn A.P., Lukomskij G.I., Romanova L.K. et al. Endopul'monal'naya cytogramma.// Sov. Med. 1982. No 7. pp.8-14]. The study results were processed using variation statistics method and the Student's t-test Table 11 Broncho-alveolar wash-off cytosis parameters of Wistar rats following aerosol exposure to Sephadex A-25 and treatment with pharmacological agents (M±m) Cytosis Absolute number of cells in 1 ul BAW Histological examination of the lungs Compound IV induced a distinct anti-inflammatory action: prevalence of alveolitis was significantly lower as compared to the model group of animals; emphysema was not practically detected; infiltration of interalveolar septa with neutrophils was not noted. By cytosis level and number of neutrophils in the BAW, inflammatory process was also significantly less pronounced that in animals administered with Sephadex for 5 days. Thus, all complex of the experimental models used suggests a significant anti-allergic, anti-anaphylactic and anti-inflammatory activity of compounds of general formula I manifested in both in vitro tests and in modeling allergic and inflammatory pathology in vivo. Example 19 The study of hypolipidemic action of compounds of general formula I on the model of hypercholesterolemia in rats The study was carried out on male Wistar rats weighing 200±20 g. Hyperlipidemia was induced by oral administration of cholesterol loading, oily cholesterol suspension: olive oil (Acorsa, Spain) - 5 ml/kg weigh of animals; cholesterol (Sigma, USA) - 1 g/kg weight; sodium cholate (Sigma, USA) - 100 mg/ kg weight. As a reference preparation, the preparation from the group of statines "Mevacor" (Lovastatine) manufactured by the firm Merck Sharp & Dohn was used at dose 40 mg/kg. Cholesterol suspension was administered daily in the morning for 10 days. The compounds tested (at dose 500 µg/kg) and the reference preparation (at dose 40 mg/kg) were administered to the animals togester with cholesterol suspension for 10 days. All the animals received a standard briquetted forage. The animals were divided into the following groups: "Control" - intact animals (n=6); "Cholesterol" - rats that orally received cholesterol loading (n=10); " Lovastatine" - rats that orally received cholesterol loading and Lovastatine (n=10); "Compound IV" - rats that orally received cholesterol loading and the tested compound IV(n=10). Blood was sampled at days 5, 8 and 10 of the experiment. Statistical processing of the hypolipidemic action data of the tested substances was carried out with regard to the "Cholesterol" group (Table 13). Table 13 Cholesterol and triglyceride level in blood serum and liver of rats orally administered for 10 days with olive oil, cholesterol and compound IV concurrently with cholesterol loading -p -p *-p Administering compound IV at dose 500 µg/kg resulted in a significant lowering serum total cholesterol by 19.5%, hepatic cholesterol by 22.7%, LDL cholesterol by 29.8% and hepatic triglycerides by 19%. The compound glutaryl histamine, by lowering total cholesterol level only by 9%, exerted effect only on LDL and VLDL (low and very; low density lipoproteins) that is shown in the publication of the International application WO 99/01103, and it is apparently less efficient than compound IV in a similar, biological experiment. The study results of the other claimed compounds are presented below. Experimental groups included: 1) "Cholesterol" -rats orally administered with oily cholesterol suspension for 10 days; 2) "Compound IV" -rats orally administered with oily cholesterol suspension and the tested compound IV; 31 3) "Compound IV - INa" - rats orally administered with oily cholesterol suspension and the tested mono-sodium salt of compound IV; 4) "Compound IV - 2Na" - rats orally administered with oily cholesterol suspension and the tested di-sodium salt of compound IV; 5) "Compound V - INa" -rats orally administered with oily cholesterol suspension and the tested mono-sodium salt of the compound V; 6) "Compound III - INa" -rats orally administered with oily cholesterol suspension and the tested mono-sodium salt of the compound III; 7) "Compound II - INa" -rats orally administered with oily cholesterol suspension and the tested mono-sodium salt of the compound II; 8) "Sim" - rats orally administered with oily cholesterol suspension and Simvastatine; 9) control - intact rats before beginning the test. At day 10 of the test blood samples were taken following decapitation of the animals. The animals fasted for 12 hours prior to decapitation. Blood serum total cholesterol, triglycerides and high density lipoprotein cholesterol (HDLC) were measured. Low and very low density lipoprotein cholesterol was calculated by the difference between total cholesterol and HDL cholesterol. Blood serum total cholesterol and triglycerides were determined using the enzymatic methods. Cholesterol level in high density lipoproteins (α-LP) was determined using the precipitation method of LDL and VLDL with phosphotungstic acid and magnesium ions. Statistical processing Data in the tables are presented as a mean value ± standard error. Significance of differences between the groups "cholesterol" and "preparation..." was assessed by the two- sampled Student's t-test. Error probability (p) is indicated in the table graphs. The data on the effect of the compounds on blood serum cholesterol and triglyceride levels of rats that received cholesterol loading are presented in Tables 14 to 21. 10-day administering oily cholesterol suspension to rats resulted in a significant 2,3-fold rise in serum cholesterol level and in 1.9-fold rise in triglyceride levels. In the development of induced hyperlipidemia, HDL cholesterol lowered by 15%. 5-fold rise in LDL+VLDL cholesterol was observed. 2.3-fold rise in LDL+VLDL triglycerides was observed. Table 15 Blood serum cholesterol and triglyceride levels (nig/100 ml) in rats at day 5 of the experiment 33 35 Administering a mono-sodium salt of compound III to the animals significantly lowered total cholesterol (CH) by 29% and cholesterol of the VLDL+LDL fractions by 40%, but it did 37 not change the level of CH of serum anti-atherogenic HDL and total triglycerides. The results obtained suggest that mono- and di-sodium salts were superior over compound IV by action dynamics on serum total cholesterol and LDL+VLDL cholesterol and other parameters of lipid metabolism. Whereas by day 10 of the experiment, a significant and comparable lowering the mentioned parameters occurred under the effect of all the compounds mentioned above and the reference preparation "Zokor" (Simvastatine), salt of compound IV begun action at earlier terms of the experiment (by days 5 and 8). The both sodium salts of compound IV elevated HDL already by day 5 of the experiment, whereas compound IV elevated this parameter only by day 8. The reference preparation Simvastatine did not effect HDL cholesterol. Furthermore, disodium salt of compound IV lowered serum total triglyceride levels at days 5 and 10 of the experiment. A distinguishing feature of the compound V mono-sodium salt was the ability thereof to lower serum total triglyceride levels, whereas lowering total cholesterol and VLDP cholesterol levels and rise in HDL level were lower than in the compound III and compound IV mono- sodium salts. Thus, as compared to the activity of the compounds disclosed in the publication of International application WO 99/01103, and the compounds proposed in the instant invention, salts of the compounds II, III, IV and V possess enhanced hypolipidemic activity including the capability of lowering serum triglyceride, total cholesterol levels including LDL cholesterol level and elevating HDL cholesterol. Example 19 Study of hypolipidemic effect of compounds of general formula I on the model of "endogenous" hypercholesterolemia in guinea pigs The study was carried out on male guinea pigs (Aguti line) weighing 304±25 g. The experiment lasted 31 days. The control group included 6 guinea pigs (intact animals). The compounds studied were administered from day 1 of the experiment (from day 1 of administering fat loading). The animals of experimental groups received orally for 31 days a compound studied and fat loading. The compound studied at doses indicated below was administered in the form of an aqueous solution (0.5 ml per an animal); fat loading (a mixture of porcine fat and preliminary heated corn oil at 4:1 ratio by volume, at the rate of 5 ml/kg weight 0.5 h post administering the substance studied. Experimental groups: 1) "control" - intact animals; 2) "fat"- animals that received fat loading only; 38 3) "compound IV" - animals that received fat loading + compound IV at dose 500 fig/kg body weight; 4) "compound V" - animals that received fat loading + compound V at dose 500 µg/kg body weight. The data on blood serum cholesterol and triglyceride levels in guinea pigs that received fat loading and the compounds studied, are presented in Tables 22 to 25. 39 Table 24 Total cholesterol level in lipoprotein fractions at day 31 of blood serum guinea pigs that received fat loading and the compounds studied The studied compounds IV and V significantly lowered total cholesterol level by 33.9 and 37.8% respectively only by day 31 of the experiment At the same time, they significantly lowered LDL cholesterol by 37.7 and 38%. Fig. 1. Change in serum total cholesterol level as effected by fat loading and different doses (50-1,500 µg/kg) of compound IV. Thin vertical lines indicate standard deviation from the mean value. Advantage of the claimed compounds, in particular compound IV, is a broad range of acting doses that provides for broadness of therapeutic effect thereof. Thus, for example, compound IV was practically similarly effective in lowering total cholesterol level during 20 days at interval of doses from 50 to 1,500 µg/kg differing 30-fold. Thus, the claimed compounds corresponding to general formula I possess a significant hypolipidemic activity considerably improving the lipid metabolism parameters in blood serum and in the liver. Example 20 Study of anti-inflammatory action of compounds of general formula I on the model of carrageenan rat paw edema The experiments were performed on white outbred male rats weighing 250 g. A total amount of animals per an experiment was 12. The model of carrageenan-induced edema according to the method of Winter et al. was used (Winter et al. Studies of the mediators of the acute inflammatory response induced in rats in different sites by carrageenan and turpentine.//J.Phamacol. 1971. V.I04. P. 15-29). 0.1 ml 1% carrageenan solution (SERVA) was subplantarly injected into the right rat paw. The animals were placed into individual chambers. Gel (1%) comprising a substance tested was applied on the paw three times: immediately following carrageenan administration, ate 1 and 2 hours post 41 administration. 4 hours post administration of carrageenan, paw volumes were measured using a plethysmograph (Ugo Basile) Therapeutic effect of the gel was assessed by inhibition degree of inflammatory reaction in comparison with the intact left paw of the given animal and rat paw reaction of the control (untreated) group. Inflammatory reaction inhibition expressed in percent, was calculated according to the formula: The tested compounds VI and XIII in the form of 1% gel caused inhibition of edema by 44% and 40%, respectively, and the reference preparation diclofenac (1% gel) inhibited edema by 62%. Examples of dosage forms Example 21 A. Tablets The tablets are prepared using the ingredients presented below: Compound corresponding to general formula I or a pharmaceutically acceptable salt thereof 1-150 mg Potato starch 20-50 mg Magnesium stearate 3 mg Aerosyl 1 mg Lactose up to 300 mg The components are mixed and compressed to form tablets weighing 300 mg each. B. Suppositories Example of a suppository composition: Compound corresponding to general formula I or a pharmaceutically acceptable salt thereof 1-100 mg Cocoa butter An amount required to prepare a suppository If needed, preparing rectal, vaginal and urethral suppositories with respective excipients is possible. C. Ointments Example of ointment composition: Compound corresponding to general formula I or a pharmaceutically acceptable salt thereof 1-500 mg 42 Vaseline 10 g Ointments are prepared according to the generally known technology. D. Gels Example of a gel composition: Compound corresponding to general formula I or a pharmaceutically acceptable salt thereof 1 -500 mg Carbopol 200 mg Benzyl alcohol 20 mg Ethyl alcohol 300 mg water Up to 10 g E. Dry powder for inhalations Example of a powder composition: Compound corresponding to general formula I or a pharmaceutically acceptable salt thereof 20-200 mg lactose Up to 1 g The powder is filled into a special device (container) or into a gelatin capsule. F. Nαsal spray Example of a spray composition: Compound corresponding to general formula I or a pharmaceutically acceptable salt thereof 1.5 -15 0 mg Purified water Up to 15 ml G. Eye drops Composition example of eye drops: Compound corresponding to general formula I or a pharmaceutically acceptable salt thereof 0.5-50 mg preservative 10 mg Purified water Up to 5 ml H. Solution for injections Composition example of a solution for injections: Compound corresponding to general formula I or a pharmaceutically acceptable salt thereof 0.2-20 mg Water for injections 2 mg R2=H, -CH3, -C2H5 and pharmaceutically acceptable salts thereof, with proviso that the compound of general formula I is not succinyl-L-tryptophane, succinyl-D-tryptophane and succinyl-D,L-tryptophane and a dipotassium salt thereof, Nα- succinyl-L-tryptophane methyl ester, Nα-glutaryl-L-histidine methyl ester, Nα-glutaryl-L- tryptophane methyl ester. 2. The compound according to claim 1, wherein pharmaceutically acceptable salt is mono- or disodium salt. 3. A process for preparing N-acyl derivatives of amino acids of general formula I wherein n is 2 or 3; and or pharmaceutically acceptable salts thereof, comprising addition of glutaric or succinic acid anhydride as a solid to aqueous solution of an amino acid of general formula: 44 and optionally converting the target product into a salt thereof. 5. A pharmaceutical composition possessing anti-allergic, anti-anaphylactic, anti- inflammatory and hypolipidemic activity comprising N-acyl derivatives of amino acids of general formula I or pharmaceutically acceptable salts thereof for manufacturing a medicament possessing anti-allergic, anti-anaphylactic, anti-inflammatory and hypolipidemic activity. 7. Use of N-acyl derivatives of amino acids according to claim 6 for manufacturing a medicament for lowering antigen-dependent histamine secretion, basophil degranulation as well as for controlling the level of eosinophils, neutrophils and lymphocytes. 8. Use of N-acyl derivatives of amino acids according to claim 6 for manufacturing a medicament for ameliorating the symptoms of bronchial asthma, allergic rhinitis, pollinoses, season and year-round rhinitis, allergic pneumonitis, atopic dermatitis, psoriasis, urticaria, allergic (including anaphylactic) reactions to insect stings and medicaments, cold allergy, allergic conjunctivitis. 9. Use of N-acyl derivatives of amino acids of general formula I or pharmaceutically acceptable salts thereof, with proviso that the compound of general formula I is not a dipotassium salt of succinyl-D,L-tryptophane, for manufacturing a medicament for ameliorating the symptoms of atherosclerosis, obesity, ischemic heart and cerebral disease, myocardial infarction and stroke. 10. A medicament possessing anti-allergic, anti-anaphylactic, anti-inflammatory and hypolipidemic activity comprising N-acyl derivatives of amino acids of general formula I or pharmaceutically acceptable salts thereof. 11. A method for treating allergic, anaphylactic diseases including diseases accompanied by inflammation, hyperlipidemia, hypercholesterolemia, comprising administration to a mammal of an effective amount of the compound of general formula I wherein n is 2 or 3; and R1 represents 12. A method according to claim 11 for treating bronchial asthma, allergic rhinitis, pollinoses, season and year-round rhinitis, allergic pneumonitis, atopic dermatitis, psoriasis, urticaria, allergic (including anaphylactic) reactions to insect stings and medicaments, cold allergy, allergic conjunctivitis. 13. A method for treating atherosclerosis, obesity, ischemic heart and cerebral disease, myocardial infarction, stroke, comprising administration to a mammal of an effective amount of the compound of general formula I or a pharmaceutically acceptable salt thereof, with proviso that the compound of general formula I is not a dipotassium salt of succinyl-D,L-tryptophane. The present invention relates to N-acyl derivatives of amino acids and pharmaceutically acceptable salts thereof or pharmaceutically acceptable salts thereof, to novel processes for preparing the same, to use thereof as anti-allergic, anti-anaphylactic, anti-inflammatory and hypolipidemic agents as well as to a pharmaceutical composition comprising the indicated compounds in an efficient amount and to a method for treating allergic and inflammatory diseases and lipid metabolism disorders: bronchial asthma, allergic rhinitis, pollinoses, seasonal and year-round rhinitis, allergic pneumonitis, atopic dermatitis, psoriasis, urticaria, allergic (including anaphylactic) reactions to insect stings and medicaments, cold allergy, allergic conjunctivitis, atherosclerosis, obesity, ischemic heart and cerebral disease, myocardial infarction and stroke.

Full Text

2420-300760.
N-acyl derivatives of amino acids, a process for preparation thereof, a pharmaceutical
composition and use thereof as antiallergic, anti-inflammatory and hypolipidemic agents
Description
The present invention relates to the field of bioorganic chemistry and concerns N-acyl
derivatives of amino acids and pharmaceutically acceptable salts thereof, novel processes for
synthesis of said compounds as well as pharmaceutical compositions based on them and use
thereof in medicine as anti-allergic, anti-inflammatory and hypolipidemic agents.
Prior art
Allergic diseases and lipid metabolism disorders are known to be highly prevalent at the
present time because of a poor environmental situation, change in the structure of nutrition and
life style of population. Therefore, the problem of developing medicaments for combating these
pathologies as well as inflammatory processes accompanying allergy, remains to be actual.
H1-histamine receptor blockers are the most spread group of anti-allergic drugs.. At the
present time, two generations of anti-histamine drugs are distinguished [Mashkovsky M.D.
Lekarstvennye sredstva (Medicaments)/ Moscow, the Novaya Volna publishers, 2005, p.285].
Anti-histamine drugs of the first generation pass through blood-brain barrier and are
capable of inducing H1-receptor blockade of the central nervous system cells that causes their
adverse sedative effect. High blood concentration of these drugs are required to achieve a
pronounced anti-histamine action that requires prescription thereof at high doses. A rather
frequent development of tachyphylaxy, effect on the CNS manifested by disordered
coordination, dizziness, feeling of flabbiness, lowered ability of concentrating attention are
negative characteristics of these drugs. In spite of the aforesaid, anti-histamine agents of the first
generation are still used especially in the situations when a very fast treatment effect is needed,
for example in anaphylaxis. Dimedrol (diphenhydramine), suprastine (chloropyramine), tavegil
(clemastine) and phencarol (chyphenadine) belong to the first generation anti-histamine drugs.
Anti-histamine drugs of the second generation have attained a wide use in allergological
practice since they have no adverse effects inherent to the first generation drugs. In particular,
the second generation drugs do not pass through the blood-brain barrier, they do not exert
sedative and hypnotic effects. These drugs are characterized by a fast and long-lasting anti-
histamine action. Claritine (Loratadine), Zirtec (Cetirisine), Kestine (Ebastine) belong to the
second generation anti-histamine drugs. However, the conducted clinical trials have revealed
side effects of these drugs caused by interaction thereof with other medicaments or by
interruption of its metabolism induced by P450 cytochrome. Thus, potentially sedative
(Cetirisine, Loratadine) and potentially cardiotoxic (Terphenadine, Asthemisol (Ebastine) effects

2
have been detected in the second generation anti-histamine agents.
In some cases, for example in bronchial asthma, glucocorticoids exerting a potent anti-
allergic action are used. However, use thereof is accompanied by systemic manifestations such
as Itsenko-Cushing syndrome, hypertension, hyperkalemia, osteoporosis etc. [Mashkovsky M.D.
Lekarstvennye sredstva (Medicaments)/ Moscow, 1993, Vol.1, p.365].
The pathochemical stage of allergic response development, which to a significant extent
is determined by the activation degree of the first order allergy target cells (basophils and mast
cells), plays a special role in the development of allergic diseases. Capability of accumulating
and releasing biologically active compounds, first of all histamine, under the effect of a stimulus
(allergen) is an important feature thereof. In IgE- and/or IgG-mediated response to antigen, just
these cells determine degree of manifestation of immediate allergy clinical picture [Parker
Ch.V./ Mediators: Release and Functions.// In: Immunology. Edited by W. Pole. Moscow, the
Mir publishers. 1989. vol.3, pp.170-247; Chakravarty N.K.// In: The mast cell: Its role in health
and disease, ed. J. Pepys. 1979. p.38-46].
There is a group of drugs (sodium cromoglycate (cromoglycic acid disodium salt),
ketotyphen, oxatomide) useful in bronchial asthma and bronchospastic conditions the action of
which is based on the capability of inhibiting mast cell degranulation and hampering release
from them of mediator substances promoting the development of bronchial spasms, allergy and
inflammation (bradykinin, histamine). Mucosal irritation, headache, laryngeal edema, cough,
suffocation may be observed as side effects [Mashkovsky M.D. Lekarstvennye sredstva
(Medicaments)/ Moscow, the Novaya Volna publishers, 2005, p.297].
Ischemic heart disease that is the first most frequent cause of lethality of adult population
world-wide is known to be the most frequent manifestation of atherosclerosis. Lipid metabolism
disorder manifested by elevated blood plasma cholesterol level including low density lipoprotein
cholesterol (LDLC) and very low density lipoprotein cholesterol (VLDLC) which are called
"atherogenic" lipoproteins with simultaneous decrease in the amount of "anti-atherogenic"
lipoproteins is recognized as one of the leading disorders in the instant disease.
Change in plasma lipid content and ratio was shown to reflect modification thereof in
membranous structures of parenchymal organs. Composition of cellular membranes, for example
macrosomal, is directly depends on the diet given to experimental animals [Wade A., Harred W.
// Feder. Proct. 1976, vol. 55. pp. 2475-2479]. Administration of cholesterol to animals induces
cholesterol accumulation in cellular membranes decreasing fluidity thereof that in turn, results in
functional state modification of enzymes [Buters J.T.M., Zysset T., Reichen J.//Biochem.
Pharmacol. 1993. vol. 46. Iss 6. pp. 983-991].
Hypolipidemic agents lowering blood level of cholesterol and triglycerids may be used

3
for treating and preventing diseases associated with lipid metabolism disorders. The latter are
characterized by elevated level of triglycerides, total cholesterol (TC), low density and very low
density lipoprotein cholesterol (LDLC and VLDLC) and by lowered level of high density
lipoprotein cholesterol in such diseases as atherosclerosis, obesity, ischemic heart and cerebral
disease, myocardial infarction, stroke and which serve as a risk factor of manifested diabetes and
thrombus formation.
Clinical use of so called statines, cholesterol biosynthesis inhibitors, for example zokor
(simvastatine) is known. Drugs of the given group at doses 80 mg daily are sufficiently effective
mainly with regard to lowering total cholesterol level, but these drugs being poorly available and
representing chemical compounds which are xenogenic for the body. Furthermore, use thereof
can be accompanied by the side effects such as change in hepatic function with elevated blood
transaminase levels and dyspepsia [Mashkovsky M.D. Medicaments./ Meditsina publishers.
Moscow. 1993. vol.1, p.463].
In view of the foregoing, a search for novel efficient anti-allergic and hypolipidemic
agents with alternative mechanisms of action which are capable of manifesting activity at low
concentrations and devoid of side effects is actual. With this regard, compounds comprising
residues of substances of natural origin are of a special interest as for them, a lower toxicity and
a lower occurrence of side effects may be predicted.
In the International application publication WO 99/01103 anti-allergic and hypolipidemic
action of N-acyl derivatives of biogenic amines, for example γ-glutamyl histamine and the
closest analog thereof glutaryl histamine is disclosed; these compounds are the closest ones by
structure and action to the claimed compounds. In the article of Krzhechkovskaya V.V.,
Zheltukhina G.A., Nebolsin V.E. et al. Study of anti-anaphylactic activity and mechanisms of
action of γ-L-glutamyl histamine. // Pathogenez (Pathogenesis). 2003. Vol.1 No 2, pp.60-64 γ-
glutamyl histamine was shown to possess a frank anti-anaphylactic activity when different
animal species and administration rates are used. The results obtained show that in mast cells of
animals a significant lowering histamine level and antigen-stimulated secretion thereof occurs
under the effect of γ-glutamyl histamine. Decrease in bronchial spasm value more than by 50%
as compared to the control was shown in the test of glutaryl histamine effect on manifestation
degree of antigen-induced bronchial spasm. The instant effect was manifested in both oral and
intratracheal route of administration at a low dose of 50 µg/kg. Glutaryl histamine is capable of
lowering manifestations of passive cutaneous anaphylaxis. In WO 99/01103 administration to
animals of glutaryl histamine at doses 50 and 500 µg/kg was shown to significantly lower
intensity of delayed type hypersensitivity. Furthermore, glutaryl histamine at doses 50 and 500
µg/kg also possessed some anti-cholesterolemic activity lowering total cholesterol by 5 to 7% as

4
compared to animals with atherogenic loading.
Drawback of glutaryl histamine is a comparatively high cost and a poor availability of the
starting material for preparation thereof i.e. histamine. Furthermore, the indicated substance is
insufficiently effective in the tests mentioned above.
In order to expand arsenal of technical means and to create a more efficient and available
anti-allergic, anti-inflammatory and hypolipidemic agent, the inventors have revealed certain
specific N-acyl derivatives of amino acids of general formula I disclosed in the International
application publication WO 99/01103 but particularly not described, not prepared and not
characterized therein except for glutaryl-L-histidine methyl ester (XII).
Thus, the compounds of the instant invention are covered by general formula I of the
International application indicated above. However, in the indicated publication neither
particular structural formulas of the given compounds nor any physical-chemical characteristics
are presented, as well as processes for preparation thereof are not disclosed. The compounds of
the instant invention fall under general structural formula of the compounds disclosed in the
International application publication WO 03/072124 possessing the inducing cellular
differentiation activity. However, in the given publication, a process for synthesis thereof is not
disclosed, and any physical-chemical constants are not presented.
One of the compounds, glutaryl histidine, is mentioned only in the form of His C-
terminal methyl ester [Glt-His(OMe) (XII)] in the US 3,963,691 as an inermediate used in the
synthesis of the peptide Glt-His-Trp-Ser-Tyr-Gly-Leu-Arg-Pro-Gly-poly-Lys. Furthermore, in
the International application publication WO 99/01103, synthesis of glutaryl-L-histidine methyl
ester (XII) is disclosed and physical-chemical characteristics are presented: data of 1H-NMR,
mass spectrometry, HPLC.
In the International application publication WO 93/04690, the compound succinyl
histidine is mentioned. In this publication, addition of free imidasole or succinyl histidine is
indicated to accelerate the reaction between carnosine and dihydroxyacetone. Synthesis of
succinyl histidine and physical-chemical constants are not presented.
Structural formula of succinyl pryptophane is mentioned in the US application
2005079515. In the indicated publication, neither synthesis of succinyl tryptophane nor physical-
chemical constants are not presented.
In the journal "Byuleten' experimental'noy biologii i meditsiny", 1998, vol.125, No 5,
pp.544-547, dipotassium salt of N-succinyl-d,l-tryptophane possessing anti-arrhythmic and anti-
fibrillation activity is disclosed, which provides antiishemic and antihypoxic action and stabilizes
hemodynamic parameters in acute myocardial ischemia.
In Justus liebigs annalen der chemie, 1966, Band 691. P. 159-164, racemic succinyl

tryptophane is disclosed.
In Tetrahedron, 2005, v.61, No4, P.919-926, physical-chemical characteristics of
succinyl-L-tryptophane and succinyl-D-tryptophane are presented. Any information about
biological activity thereof is lacking.
In the article Joseph R.Votano et al. Inhibition of deoxyhemoglobin S polymerization by
biaromatic peptides found to associate with the hemoglobin molecule at a preferred site.
Biochemistry, 1977, v. 16, No25, pp.5484-5491 succinyl-L-tryptophane is mentioned and
capability thereof to bind to deoxyhemoglobin is studied.
In the article Dongmei H., Chao W., Ming Z., Shiqi P. Synthesis and analgesic activity of
N,N'-dicarbonyltryptamines. Prep. Biochem. & Biotechnol., 2000, V.30(3), P.231-240, synthesis
of Nα-succinyl-L-tryptophane methyl ester (XI) is disclosed originating from tryptophane methyl
ester and succinic anhydride in the presence of dimethylamine pyridine with subsequent
chromatographic purification of the target product. Nα-succinyl-L-tryptophane methyl ester is
characterized by physical-chemical data: 1H-NMR-, IR-spectroscopy, mass spectrometry,
melting point and elemental analysis data.
Gluteryl-L-tryptophane methyl ester (XIII) is mentioned in the article Raimondi S.,
Monti D., Pagnoni U.M., Riva S. Glutaryl acylases: One-reaction enzymes or versatile
enantioselective biocatalysts? Adv. Synth. Catal. 2003. V.345(6-7). P.783-789, wherein only
typical synthesis technique is presented and only 1H-NMR data are presented out of physical-
chemical constants. The compound (XIII) was synthesized as a substrate for glutaryl acylase.
Preparation of Nα-glutaryl-L-histamine is disclosed in the International application
publication WO 99/01103 which process is N-acylation of biogenic amine with glutaric
anhydride in the medium of unhydrous N,N-dimethyl formamide. Furthermore, in the
publication of Gershkovich A.A., Kibirev V.K.//Chemical synthesis of peptides./Kiev, Nαukova
Dumka publishers, 1992, p.360 a process for acylation of amino acids in aqueous-organic,
strongly alkaline medium is disclosed.
In the publication of Sorm F., Pravda Z. Proteins and amino acids. X. Synthesis of two
peptide analogsV/Chemicke Listy pro Vedu a Prumysl. 1951. V.45. P.423-425, a synthesis
process of succinyl tyrosine ethyl ester in a mixture of water and ethyl acetate at 1:1 ratio is
disclosed originating from tyrosine ethyl ester chlorohydrate and glutaric anhydride in the
presence of NaHCO3 for maintaining a weakly alkaline pH.
Free histidine acylation with .carboxylic acid anhydrides is not disclosed in the literature.
Object of the instant invention is providing novel effective N-acyl derivatives of amino
acids and pharmaceutically acceptable salts thereof possessing anti-allergic, anti-inflammatory
and hypolipidemic action at low doses and not showing side effects, pharmaceutical

6
compositions based on them, use thereof as more effective anti-allergic, anti-inflammatory and
hypolipidemic agents, as well as novel processes of synthesis of N-acyl derivatives of amino
acids.
The inventors have developed a simple and efficient process of synthesis of compounds
of general formula I consisting in that glutaric or succinic anhydride in the form of a solid is
added to an aqueous solution of an amino acid in the absence of inorganic and organic base with
obtaining the target product with a sufficiently high yield of 55 to 60%.
The inventors have developed one more synthesis process of compounds of general
formula I including N-acyl derivatives of histidine and tryptophane which process is the reaction
in a biphasic system consisting of an aqueous histidine solution or tryptophane salt and an
acylating agent solution in a suitable organic solvent in using the acylating agent excess.
Summary of the invention
The instant invention relates to novel N-acyl derivatives of amino acids of general

and pharmaceutically acceptable salts thereof possessing anti-allergic, anti-inflammatory
and hypolipidemic action.
The instant invention also relates to a process for preparing N-acyl derivatives of amino
acids of formula I and salts thereof comprising addition of glutaric or succinic anhydride in the
form of a solid to an aqueous amino acid solution of general formula I:

7
and optionally converting the target product into a salt thereof.
The instant invention further relates to a process for preparing N-acyl derivatives of
amino acids and salts thereof which process comprises reacting in a biphasic system of glutaric
or succinic anhydride with an aqueous solution of the amino acid of general formula

and optionally converting the target product into a salt thereof.
The instant invention relates also to use of compounds of general formula I and
pharmaceutically acceptable salts thereof as anti-allergic, anti-inflammatory and hypolipidemic
agents.
Further, the instant invention relates to pharmaceutical compositions and an agent
possessing anti-allergic, anti-anaphylactic, anti-inflammatory and hypolipidemic action
comprising an effective amount of the compound of formula I or a pharmaceutically acceptable
salt thereof as well as if needed a pharmaceutically acceptable carrier.
One more object of the invention is a method for treating allergic diseases including
bronchial asthma, allergic rhinitis, pollinoses, seasonal rhinitis, round-year rhinitis, atopic
dermatitis, psoriasis, urticaria, allergic (including anaphylactic( reactions to insect stings and
medicaments, cold allergy, allergic conjunctivitis, chronic obstructive pulmonary diseases,
namely chronic obstructive bronchitis, emphysema, obliterating bronchitis, mucoviscedosis, as
well as diseases related to lipid metabolism disorders: atherosclerosis, obesity, ischemic heart
and cerebral disease, myocardial infarction, stroke, which method comprises administering to a
subject an effective amount of the compound of general formula I or a pharmaceutically
acceptable salt thereof.
Detailed disclosure of the invention
Preferable compounds of general formula 1 are presented in Table 1.

Synthesis of compounds of general formula I can be accomplished by two processes. The
first process consists in a gradual adding to an aqueous solution of an amino acid of general
formula

glutaric or succinic anhydride in the form of a solid with subsequent isolation of the
target product using ion exchange chromatography, preferably by passing reaction mixture
through a column with cationite and subsequent crystallization from aqueous solution. The
crystals of the target product obtained are washed with a suitable solvent, preferably methanol.
The main advantage of the claimed process consists in the absence of alkali in the amino acid
aqueous solution that prevents from inactivation of dicarboxylic acid anhydride resulting from
hydrolysis. Furthermore, imidazol residue in the amino acid molecule can effect acidic-basic
autocatalysis of acylation reaction of the amino group of amino acid. Rather high yields (55-
60%) in using the claimed process are achieved in particular due to a gradual adding
dicsarboxylic acid anhydride taken in the excess, and to vigorous stirring reaction mass.
Compounds of general formula I can be also prepared using an alternative process in a
biphasic system which process comprises adding glutaric or succinic anhydride in a water
immiscible solvent to .an aqueous solution of the amino acid of general formula:

The instant process allows to use the excess of an acylating agent, achieve the complete
acylation of a-amino group of the amino acid and yield of the target product of about 70%. In
order to maintain required pH, instead of an inorganic alkali, the organic base pyridine is used
which does not hydrolyze anhydride and in addition is known to be catalyst of acylation. Using
pyridine allows for avoiding contamination of the final product by inorganic salts which together
with the reaction product remain in aqueous layer. The used approaches allow for simplifying
separation of the target product from non-reacted anhydride and respective amino acid and
isolating the target product by a simple crystallization.

10
Preferable water immiscible organic solvents are butanol, ethylacetate and chloroform.
Preferable solvents useful for crystallizing the target product are water-alcohol mixtures,
in particular, water-ethanol.
N-acyl derivatives of amino acid esters of invention (VI-XIII) can be prepared by the
action of respective internal anhydrides of dicarboxylic acids on amino-free histidine or
tryptophane esters in an organic or water-organic medium. Preferable is preparing the
compounds VI-XIII in a biphasic system using water immiscible organic solvents butanol,
ethylacetate and chloroform.
Compounds of general formula I can also be prepared in the form of pharmaceutically
acceptable salts by reacting for example with sodium hydroxide, potassium hydroxide,
magnesium carbonate, lithium hydroxide, calcium carbonate using routine processes widely
disclosed in the literature.
Compounds of general formula I have anti-allergic, anti-inflammatory and hypolipidemic
activity and they can be used fro treating allergic, anaphylactic diseases including those
accompanied by inflammation, as well as lipid metabolism disorders.
In particular, compounds of the present invention may be used for treating the following
allergic diseases: bronchial asthma, allergic rhinitis, pollinoses, seasonal rhinitis, round-year
rhinitis, atopic dermatitis, psoriasis, urticaria, allergic (including anaphylactic) reactions to insect
stings and medicaments, cold allergy, allergic conjunctivitis, chronic obstructive pulmonary
diseases, namely chronic obstructive bronchitis, emphysema, obliterating bronchitis,
mucoviscedosis, as well as diseases related to lipid metabolism disorders such as:
atherosclerosis, obesity, ischemic heart and cerebral disease, myocardial infarction and stroke.
Compounds of the present invention are administered in an effective amount which
provides for a desirable therapeutic result.
For treating allergic diseases including bronchial asthma, allergic rhinitis, pollinoses,
seasonal rhinitis, round-year rhinitis, atopic dermatitis, psoriasis, urticaria, allergic (including
anaphylactic) reactions to insect stings and medicaments, cold allergy, allergic conjunctivitis,
chronic obstructive pulmonary diseases, namely chronic obstructive bronchitis, emphysema,
obliterating bronchitis, mucoviscedosis, as well as diseases related to lipid metabolism disorders
such as: atherosclerosis, obesity, ischemic heart and cerebral disease, myocardial infarction and
stroke, compounds of general formula I may be administered perorally, topically, parenterally,
nasally, by inhalation or rectally in unit dosage forms comprising non-toxic pharmaceutically
acceptable carriers. As used in the instant disclosure, the term "parenteral administration" means
subcutaneous, intravenous, intramuscular or intraperitoneal injections or infusions.
Compounds of the present invention can be administered to a patient at doses from 0.01

11
to 10 mg/kg body weight daily, preferably at doses from 0.05 .to 5 mg/kg once or more times
daily.
At the same time, it should be noted that a particular dose for each particular patient will
depend on many factors including activity of a given compound used, age, body weight, sex,
general health condition and nutrition regimen of the patient, time and route of administering a
medicament, elimination rate thereof from the body, a particular combination of medicaments
used as well as on severity of disease to be treated in the given individual.
Pharmaceutical composition of the instant invention comprise the compound of general
formula I in an amount effective to achieve a desired result and can be administered in unit
dosage forms (for example in a solid, semisolid or liquid forms) comprising compounds of the
instant invention as an active ingredient in admixture with a carrier or excipinent suitable for
intramuscular, intravenous, peroral, sublingual, inhalation, intranasal and intrathecal
administration. Active ingredient can be included into a composition together with
conventionally used non-toxic pharmaceutically acceptable carriers suitable for manufacturing
solutions, tablets, pellets, capsules, dragee, suppositories, emulsions, suspensions, ointments,
gels and any other dosage forms.
As excipients, different substances such as saccharides for example glucose, lactose or
sucrose mannitol or sorbitol, cellulose derivatives and/or calcium phosphate for example
tricalcium phosphate or acidic calcium phosphate may be used, and as a binding component,
such materials as starch paste, for example corn, wheat, rise, potato starch, gelatine, tragacant,
methylcellulose, hydroxypropyl methylcellulose, sodium carboxymethylcellulose and/or
polyvinylpyrrolidone. If needed, disintegrants such as the above mentioned starches and
carboxymethyl starch, cross-linked polyvinylpyrrolidone, agar or alginic acid or a salt thereof
such as sodium alginate can be used.
Optional additives such as agents controlling fluidity and lubricants such as silica, talc,
stearic acid and salts thereof such as magnesium stearate or calcium stearate and/or
propyleneglycol can be used.
A core is usually coated by a layer which is resistant to the action of gastric juice. For
this, concentrated solutions of saccharides can be used which solutions may optionally comprise
gum Arabic, talc, polyvinyl pyrrolidone, polyethylene glycol and/or titanium dioxide, and
suitable organic solvents or mixtures thereof.
As additives, stabilizers, thickeners, colorants and flavours can be also used.
As an ointment base, carbohydrate ointment bases such as white and yellow vaseline
(Vaselinum album, Vaselinum flavum), Vaseline oil (Oleum Vaselini), white and liquid
ointment (Unguentum album, Unguentum flavum) can be used, and as additives for imparting a

12
more compact consistence, hard paraffin and wax, absorbtive ointment bases such as hydrophilic
vaseline (Vaselinum hydrophylicum), lanoline (Lanolinum), coldcream (Unguentum leniens);
oitment bases washable with water such as hydrophilic ointment (Unguentum hydrophylum);
water soluble ointment bases, such as polyethylene glycol ointment (Unguentum Glycolis
Polyaethyleni), bentonite bases and others can be used.
As a base for gels, methylcellulose, carboxymethylcellulose sodium salt.
oxypropylcellulose, polyethylene glycol or polyethylene oxide and carbopol can be used.
As a base for suppositories, water insoluble bases such as cocoa butter; water soluble or
water miscible bases such as gelatin-glycerol or polyethylene oxide and combined (soap-
glycerol) can be used.
In preparing a unit dosage form, an amount of an active ingredient used in a combination
with a carrier may vary depending on a recipient subjected to therapy, a particular administration
route of a medicament.
Thus, in using compounds of the instant invention in the form of solutions for injections,
content of an active ingredient therein is 0.01 to 5%. As diluents, 0.9% sodium chloride solution,
distilled water, novocaine solution for injections, Ringer solution, glucose solution and specific
additives for dissolution can be used. In administering compounds of the instant invention into
the body in the form of tablets and suppositories, their amount is from 5.0 to 500.0 mg per an
unit dosage form.
Dosage forms of the instant invention are manufactures according to the standard
techniques such as for example processes of mixing, granulation, forming dragee, dissolution
and freeze-drying.
It should be noted that compounds of the instant invention show biological activity at
doses that are by two-three folds lower than those of the known drugs used for comparison, in a
practically similar efficacy, and for them, no adverse side effect have been detected, and
contraindication for their use have not been found. At the same time, in examining toxicity of
compounds according to the instant invention at a dose 3,000 mg/kg orally, death of
experimental animals has not been recorded.
Detailed description of the compounds according to the present invention, preparation
thereof and the study of pharmacological activity is presented in the following examples
intended for illustration of preferable embodiments of the invention and not limiting the scope
thereof.
Synthesis examples of N-acyl derivatives of general formula I
Individuality of the prepared compounds has been checked using TLC method on the
plates "Kieselgel 60 F254" "Merck" (Germany) in the systems: methanol (1), chloroform-

13
methanol-ammonia (4:3:1) (2).
Chromatograms were developed by a chlorotolidine reagent, ninhydrine, iodine by
luminescence in UV light.
Optic rotation angles were measured on the polarometer "Perkin Elmer 341" (Sweden).
1H-NMR was recorded on the apparatus "AMX-400 Bruker" (Germany).
Melting point was determined on the apparatus "Boetius" (Germany).
Analytical HPLC was carried out on the apparatus "System Gold" ("Beckman", USA),
elution rate 0.25 ml/min; detection at 214 nm under the following conditions: column
Ultrasphere ODS "Beckman", 2x250 mm, 5 pm, elution with 0.1% TFA, elution rate 0.25
ml/min (1); eluting rate 1 ml/min, detection at 220 nm; column Luna-5 "Phenomenex", C18,
250x4.6 mm, elution 25% acetonitryl in 0.05 M phosphate buffer (pH 3.0) (2).
Example 1
Nα-glutaryl-L-histidine (IV)
Technique A
To solution of 103.4 g (0.67 mmol) histidine in 400 ml water 83.7 g (0.73 mol) glutaric
anhydride were added. Suspension was stirred for 1 hour, the formed solution was boiled down
to the volume 150 ml, left in a refrigerator for 16 hours. Precipitate was filtered off, washed with
150 ml ethanol and dried. Purification was carried out by ion exchange chromatography on the
resin Purolight in H+ form eluting with water. Fractions comprising the target product were
combined, boiled down until precipitation begun and left for 16 hours at 4°C. Precipitate was
filtered off, washed with 200 ml methanol and dried to a constant weight. Yield 98.8 g (55%). Rf
0.55 (1), 0.37 (2). Tmp=222-224oC. [α]D20+15.95° (C 0.53, water). [M+H]+ 270.1. 1H-NMR
spectrum (D2O), δ, m.d.: 1.60-1.80 (m, 2H, β-CH2-Glt), 2.10-2.25 (m, 4H, α,γ-CH2-Glt), 2.90-
3.25 (m, 2H, β-CH2-His), 4.40-4.50 (m, 1H, α-CH-His), 7.15 (s, 1H, CH-4-Im), 8.50 (s, 1H, CH-
2-Im). Found, %: C 49.18; H 5.91; N 15.42. C11H15N3O5. Calculated, %: C 49.07; H 5.62; N
15.61.
Technique B
To suspension of 0.3 g (1.93 mmol) histidine in 5 ml water under vigorous stirring 0.44 g
(3.86 mmol) glutaric anhydride dissolved in 2.5 ml ethylacetate is added. The suspension was
stirred for 2 hours, pH was adjusted to 7 with pyridine and stirred for another 1 hour.
Ethylacetate and aqueous layers were separated. Aqueous layer was twice washed with ester,
ester layer was discharged. Water was removed in vacuo, precipitate was dissolved in a
minimum amount of water and ethanol was added prior to beginning sedimentation of a white
precipitate, left at +4°C for 20 hours. Precipitate was filtered off, dried in vacuo. Yield 0.36 g
(70%). Rf 0.56 (1), 0.35 (2). Tmp=219-221°C. [α]D20=+15.71° (C 0.56, water). [M+H]+ 270.1.

14
1H-NMR spectrum (D2O), δ, m.d.: 1.40-1.55 (m, 2H, β-CH2-Glt), 1.90-2.0 (m, 4H, α, γ-CH2-
Glt), 2.7-3.0 (m, 2H, β-CH2-His), 4.20-4.30 (m, 1H, α-CH-His), 6.95 (s, 1H, 4-CH-Im), 8.30 (s,
1H, 2-CH-Im). HPLC under the conditions: (1) - individual peak, retention time 14.55 min.
Found, %: C 49.07; H 5.65; N 15.65. C11H15N3O5. Calculated, %: C 49.07; H 5.62; N 15.61.
Example 2
Nα~suctinyl-L-histidine (V)
Synthesis was carried out in accordance with the technique A presented for compound
IV.
Yield 0.08 g (57%).
Rf 0.44(1), 0.25(2).
Tm.p=179-181°C.
[α]D20=+30.71° (C 0.56, water).
[M]+ 255.2.
1H-NMR spectrum (D2O), δ, m.d.: 2.15-2.30 (m, 4H, (CH2)2-Suc), 2.75-2.95 (m, 2H, β-
CH2-His), 4.25 (br.s, 1H, a-CH-His), 6.95 (s, 1H, 4-CH-Jm), 8.25 (s, 1H, 2-CH-Jm).
Found, %: C 47.09; H 5.04; N 16.40. C10H13N3O5. Calculated, %: C 47.06; H 5.13; N
16.46
Synthesis was carried out according to the technique B carried out for compound IV.
Yield 0.101(67%).
Rf 0.45(1), 0.27(2).
Tm.p=178-180°C.
[α]D20=+30.8° (C 0.57, water).
HPLC under the conditions (1) - individual peak, retention time 7.54 MHH.
Found %: C 47.15; H 5.2; N 16.50. C10H13N3O5. Calculated %: C 47.06; H 5.13; N 16.46.
Example 3
Nα-Glutaryl tryptophane (III)
To suspension of 1.0 g (4.9 mmol) tryptophane in 7 ml water 1 N NαOH solution (4.9
mmol) was added drop-wise. To the prepared solution, solution of 0.56 g (4.9 mmol) glutaric
aldehyde in 3 ml ethylacetate were added. Reaction mixture was stirred for 3 hours at room
temperature under argon in darkness and left for 16 hours at +4°C. Solvent was removed from
the reaction mixture in vacua. The oily residue obtained was dissolved in 30 ml water while
stirring, cooled down to 0°C, and 1 N HC1 was added to adjust pH to 4. The product was
extracted with ethylacetate (3x25 ml). The combined ethylacetate extract was cooled down to
0°C, washed with water (4 x 25 ml) to ajust pH to 7, washed with 5% HC1 (5 ml) and washed

15
with water (4 x 25 ml) adjust pH to 7.0, dried over anhydrous Na2SO4 for 1 hour. Residue of
Na2SO4 was filtered off, washed with ethylacetate, the solvent was removed in vacuo. Grayish
solid precipitate was obtained which was dried in vacuo.
Yield 1.0 g (70%).
Rf 0.54(1).
Tm.p=150-152°C.
[α]D20=+8.20° (C 0.5, methanol).
1H-NMR spectrum (CD3OD), δ, m.d.: 1.75-1.84 (m, 2H, β-CH2-Glt), 2.15-2.30 (m, 4H,
α,γ-CH2-Glt), 3.30-3.40 (m, 2H, β-CH2-Trp), 3.80-3.90 (m, 1H, α-CH-Trp), 6.97 (t, J=7 Hz, 1H,
CH-6-Ind), 7.06 (t, J=7 Hz, 1H, CH-7-lnd), 7.15 (d, J=7 Hz, 1H, CH-2-Ind), 7.33 (d, J=7 Hz, 1H,
CH-5-Ind), 7.55 (d, J=7 Hz, 1H, CH-8-Ind).
HPLC under the conditions: (2) - individual peal, retention time 6.77 minutes.
Found, %: C 60.07; H 5.65; N 8.75. C16H18N2O5 Calculated, %: C 60.37; H 5.7; N 8.8.
Example 4
N°- Succinyl-L-tryptophane (II)
Synthesis was carried out in accordance with the technique presented for the compound
III.
Yield 100.5 mg (67%).
Rf 0.63(1).
[α]D20=+21.05° (C 0.6, water).
1H-NMR spectrum (DMSO-d6), δ, m.d.: 2.33-2.41 (d, 4H, α,β-CH2-Suc), 2.93-3.01 (d,
1H, β-CH2-Trp), 3.10-3.16 (m, 1H, β-CH2-Trp), 4.39-4.47 (m, 1H, a-CH-Trp), 6.93-7.06 (m,
2H, CH-6,7-Ind), 7.11 (d, J=2.2 Hz, 1H, CH-2-Ind), 7.30-7.32 (m, 1H, CH-5-Ind), 7.44-7.47 (m,
1H, CH-8-Ind). [M]+ 304.3.
HPLC under the conditions: (2) - individual peal, retention time 6.35 minutes.
Found, %: C 59.07; H 5.65; N 9.35. C15H16N2O5 Calculated, %: C 59.21; H 5.3; N 9.21.
Example 5
Nα-glutaryl-L-histidine monosodium salt (IV)
To a solution of 1.0 g (3.7 mmol) of Nα-glutaryl-L-histidine in 15 ml water, a solution of
0.15 g (3.7 mmol) NαOH in 20 ml water was added while stirring and cooling down to +5°C.
The solution was stirred for 30 min, the solvent was removed in vacuo. To an oily residue,
benzene was added in portions, the solvent was removed in vacuo. A solid residue was dried
over granulated alkali.
Yield 1.07 g (99.7%).

16
Tm.p =208-210°C.
[α]D20=+16.27° (C 0.58, water).
Found, %: C 45.25; H 5.51; N 14.52. C11H15N3O5Na. Calculated, %: C 45.21; H 5.17; N
14.38.
Example 6
Nα-succinyl-L-histidine monosodium salt (V)
Synthesis was carried out in accordance with the technique presented for Nα-glutaryl-L-
histidine monosodium salt (IV) (Example 5).
Yield 1.06 g (97.0%).
[α]D20=+40.21° (C 0.48, water).
Found, %: C 43.25; H 4.51; N 15.52. C10H13N3O5Na. Calculated, %: C 43.17; H 4.71; N
15.10.
Example 7
Nα-succinyl-L-tryptophane monosodium salt (II)
Synthesis was carried out in accordance with the technique presented for Nα-glutaryl-L-
histidine monosodium salt (IV) (Example 5).
Yield 0.21 g (98.0%).
Tm.p=147-150°C.
[α]D20=+22.02° (C 0.39, water).
Found, %: C 55.25; H 4.51; N 8.32. C15H16N2O5Na. Calculated, %: C 55.05; H 4.93; N
8.56.
HPLC under the conditions: (2) - individual peal, retention time 6.56 minutes.
Example 8
Nα-glutaryl-L-tryptophane monosodium salt (III)
Synthesis was carried out in accordance with the technique presented for Nα-glutaryl-L-
histidine monosodium salt (IV) (Example 5).
Yield 0.11 g(99.0%).
Tm.p=128-130°C.
[α]D20=+22.06° (C 0.34, methanol).
Found, %: C 56.15; H 5.21; N 8.22. C16H18N2O5Na. Calculated, %: C 56.30; H 5.32; N
8.21.
HPLC under the conditions: (2) - individual peal, retention time 6.96 minutes.
Example 9
Nα-glutaryl-L-histidine monosodium salt (IV)
To a solution of 1.0 g (3.7 mmol) Nα-glutaryl-L-histidine in 15 ml water a solution of 0.3

17
g (7.44 mmol) NaOH in 15 ml water was added while stirring and cooling down to +5°C. The
solution was stirred for 30 min, the solvent was removed in vacuo. To an oily residue, benzene
was added in portions, the solvent was removed in vacuo. A solid residue was dried over
granulated alkali.
Yield 1.15 g (99.0%).
[α]D20=+l 1.92° (C 0.57, water).
Found, %: C 41.25; H 4.51; N 13.52. C11H15N3O5Na2. Calculated, %: C 41.91; H 4.80; N
13.3.
Example 10
Nα-succinyl-L-histidine disodium salt (V)
Synthesis was carried out in accordance with the technique presented for Nα-glutaryl-L-
histidine disodium salt (IV) (Example 9).
Yield 1.16 g (99.0%).
Tm.p=124-128°C.
[α]D20=+20.06° (C 0.67, water).
Found, %: C 39.55; H 4.31; N 13.52. C10H13N3O5Na2. Calculated, %: C 39.88; H 4.35; N
13.95.
Example 11
Nα-succinyl-L-tryptophane disodium salt (II)
Synthesis was carried out in accordance with the technique presented for Nα-glutaryl-L-
histidine disodium salt (IV) (Example 9).
Yield 0.56 g (97.7%).
Found, %: C 51.35; H 4.31; N 8.22. C15H16N2O5Na2. Calculated, %: C 51.43; H 4.60; N
8.0.
Example 12
Nα-glutaryl-L-tryptophane disodium salt (III)
Synthesis was carried out in accordance with the technique presented for Nα-glutaryl-L-
histidine disodium salt (IV) (Example 9).
Yield 0.56 g (98.5%).
Found, %: C 52.55; H 4.71; N 7.52. C16H18N2O5Na2. Calculated, %: C 52.75; H 4.98; N
7.69.
Example 13
Nα-succinyl-L-histidine methyl ester
To a solution of 1.0 g (4.13 mmol) histidine methyl ester in 5 ml of N,N-
dimethylformamide 5 ml water and a solution of 0.41 g (4.13 mmol) succinic anhydrife in 2.5 ml

18
ethylacetate were added in vigorous stirring. The mixture was stirred for 2 hours at room
temperature. Ethylacetate and water layer were separated. Water layer was washed twice with
ester, ester layer was discarded. Water was removed in vacuo, a residue was triturated with 10 ml
hexane. A residue was filtered off and dried in vacuo.
Yield 0.70 g (67%).
Rf 0.38(1).
Tm.p=171-173°C.
1H-NMR spectrum (DMSO-d6), δ, m.d.: 2.26-2.37 (m, 4H, α,β-CH2-Suc), 2.70 (s, 3H, -
O-CH3), 2.76-2.87 (m, 2H, β-CH2-His), 4.33-4.45 (m, 1H, α-CH2-His), 6.78 (s, 1H, 4-CH-Im),
7.93 (s, 1H, 2-CH-Im), 8.25 (d, J=7Hz, NH-amide.). [α]D20=+l 1.92° (C 0.57, water).
According to similar typical techniques, the novel compounds of general formula I
presented in Table 2 were also prepared.
Table 2
Structure and characteristics of compounds of general formula I

19
Tests for biological activity
Example 14
Effect of compounds of general formula I on immediate type allergic reactions (in vitro test
of ovalbumin (OA)-induced blood basophil degranulation of immunized guinea pig)
Leukocytes from guinea pig blood were isolated according to the Freemel's method
[Immunologicheskiye Metody under edition of G. Frimel/Moscow., "Meditsina" publishers,
1987, p.222 in the inventor's modification].
Guinea pigs of both sexes weighing from 600 to 800 g were used to conduct the test. The
animals were once immunized with a mixture of 10 µg ovalbumin and 100 mg aluminum
hydroxide per one animal according to Andersson [Anderson P. Antigen-induced bronchial
anaphylaxis in actively sensitized guinea-pigs.//Allergy. 1980. Vol. 35. P.63-71].
Under ester anesthesia, 15 ml blood were drawn from guinea pig heart. Double
precipitation of cells using EDTA and a citrate-containing precipitating liquid was used to isolate
basophils in the leukocyte suspension.
Blood was mixed with 5% EDTA-Na2 2H2O ("Sigma") solution at 9:1 ratio and in 30
minutes it was subjected to mild centrifugation (for 12 minutes at 80 g). Supernatant was
collected and centrifuged for 15 minutes at 500 g.
To the remaining cells, a citrate-containing precipitating liquid (3) was added at

20
proportion 3:10 (it was thermostated at 37°C for 30 minutes). A supernatant fraction enriched by
leukocytes was centrifuged for 7 minutes at 100 g. To leukocyte precipitate, 0.85% NaCl
solution was added and cellular concentration was brought to 30x103/µl..
Protocol of the in vitro basophil degranulation test [Spravochnil po klinicheskim
laboratornym metodam issledovaniya (A reference book on clinical-laboratory examination
methods)/Edited by E.A. Cost/Moscow, "Meditsina" publishers, 1975, p. 130].
For the test, a centrifuge tube (3 tubes per each sample) was filled with 300 ul cellular
suspension, then salt solution of a tested compound (or a salt solution in the control of
spontaneous and maximum degranulation) was added and pre-incubated at 37°C for 15 minutes,
then into each tube 300 µl 1% OA solution was added (in the control of spontaneous
degranulation a salt solution in the same amount was added) and once more pre-incubated at
37°C for 10 minutes. Functional leukocyte concentration was 104/µl. Samples (100 µl) were
taken off from each tube into separate tubes to assess a complete basophil degranulation, and to
the remained cells, a cooled salt solution was added (5 ml into each tube) to arrest degranulation
reaction, then the tubes were centrifuged for 7 min at 100 g, and from precipitate, preparations
for microscopy were prepared. The preparations were fixed and stained according to the method
of Seder et al. [Seder R.A. et al. Mouse splenic and bone marrow cell populations that express
high - affinity Fes receptors and produce interleukin-4 are highly enriched in basophils.//
Proc.Natl.Acad.USA, 1991, V.88, P.2835-2839].
In order to detect a specific basophil granulation, the dye 0.5% alcyanic blue (pH 1.0)
was used, nuclei were additionally stained with safranin (0.1% solution in 1% acetic acid). The
preparations were used to assess a total degranulation inhibition.
Atotal degranulation inhibition (DI) (%) was calculated according to the formula:

max - % of degranulated basophils at the maximum degranulation (OA)
spontaneous - % of degranulated basophils in spontaneous degranulation (control)
experimental - % of degranulated basophils following exposure to the tested compound.
Assessment of a complete basophil degranulation
Samples selected following basophil degranulation test (100 µl each) were poured into
tubes with the dye (0.5% alcyane blue, pH 1.0) at ratio 1:1. Staining was carried out at room
temperature for not less than 50 min. Stained basophils were calculated using the Fooks-
Rosenthal chamber. Inhibition of a complete basophil degranulation (ICD) was calculated
according to the formula:
ICD(%)=1 -[(M m (c) - M m (exper.)] / [M m (c) - M m (OA)] x 100, wherein

21
M m (c) - mean (by three samples) basophil number in the spontaneous basophil
degranulation test;
M±m (OA) - mean (by three samples) basophil number in the maximum antigen-induced
basophil degranulation test;
M±m (exper.) - mean (by three samples) basophil number in the basophil degranulation
test following incubation with the tested compound.
Table 3
In vitro inhibition of OA-induced basophil degranulation of guinea pig blood as effected by
compounds of general formula I

Order No
of test Groups Complete
degranulation
inhibition (CDI),
(%) Number of completely
degranulated basophils,
(%)
1. Control 1 (spontaneous
degranulation) 100 0
2. Ovalbumin 1% (max
degranulation) 0 35.2±0.8
3. Compound IV
(10-3M) 99.2±11.2 2.6±2.6*
4. Compound IV
(10-4M) 99.5+12.0 2.9±1.6*
5. Compound IV
(10-5M) 113.5+2.7 0
6. Compound IV
(10-6M) 90.0±1.8 3.9±0.6
7. Compound IV
(10-7M) 76.7±1.5 9.1+0.8
8. Glutaryl histamine
(10-3M) 9.3±5.5 31.6±6.33
9. Glutaryl histamine
(10-4M) 24.1±1.1 25.3±3.38
10. Glutaryl histamine
(10-5M) 0 29.8±6.73
11. Control 2 100 0

22

12. Ovalbumin 1% (max
degranulation) 0 38.9+8.43
13. Compound V
(10-3M) 10.6±7.6 35.3±7.29
14. Compound V
(10-4M) 18.9+11.8 31.2+6.8
15. Compound V
(10-5M) 44.0+11.27 24.6+10.38
16. Hydrocortisone
(10-3M) 71.0+1.6 10.0±0.7
17. Hydrocortisone
(10-4M) 48.0±0.8 17.3+0.9
18. Hydrocortisone
(10-5M) 40.0±0.6 20.0+1.3
(* - P The data of Table 3 show that as compared to glutaryl histamine, the compound (IV)
exerts a pronounced anti-anaphylactic action manifested by a practically 100% degranulation
inhibition in the test of a complete OA-induced degranulation of blood basophils collected in
immunized guinea pigs (in vitro anaphylaxis reaction in a calcium free medium). A significant
anti-anaphylactic effect of compound IV is also manifested by decrease in the number of
degranulated cells, especially pronounced at concentration 10-5 M (absence of degranulated
cells).
Example 15
Study of the effect of compounds of general formula I on systemic anaphylaxis in vivo
A bronchial spasm model in conscious guinea pigs actively sensitized by exposure to
aerosol ovalbumin as an antigen was used [Kovaleva V.L. "Metodicheskiye ukazaniya po
izucheniyu bronkholiticheskikh I protivovospalitel'nykh sredstv.// Rukovodstvo po
experimental'nomy (doklinicheskomu) izucheniyu novykh pharmacologicheskikh veshchestv,
Moscow. 2000. pp.242-250].
Guinea pigs were sensitized by ovalbumin according to the method of Andersson
[Anderson P. Antigen-induced bronchial anaphylaxis in actively sensitized guinea-pigs.//Allergy.
1980. Vol. 35. P. 63-71] and in 1-2 months following sensitization, bronchial spasm was
induced by aerosol administration of albumin booster dose (3 mg/kg in 1 ml normal saline).
In test groups, guinea pigs were for three days administered with tested compounds at

23
doses 10 µg/kg, 50 µg/kg, and 150 µg/kg, using a probe. In the other group of experiments, the
tested compounds at dose 50 µg/kg (in 1 ml normal saline) were administered nasally (using a
nebulizer) also once daily for three days. The control group was administered with normal saline.
One hour post the last administration of substances, ovalbumin was administered by inhalation
using a nebulizer, and intensity and duration (in seconds) of bronchial spasm reaction in animals
was assessed.
Table 4
Inhibition of systemic anaphylactic reaction of guinea pigs in administering by inhalation of
compound IV at dose 50 µg/kg

Groups Duration of acute phase,
seconds Duration of sub-acute
phase, seconds
Control 1 (normal saline) 180±6 650±34
Compound IV
50 µg/kg 0 400±25
Table 5
Inhibition of systemic anaphylactic reaction of guinea pigs in intragastric administering
compound IV at doses 10 and 150 µg/kg (M±m)

Groups Duration of acute phase,
seconds Total reaction time, seconds
Control 2 (normal saline) 296.7+104.6 628.3±80.6
Compound IV
10 µg/kg 68.0±54.7* 428.0±75.0
Compound IV
150 µg/kg 72.0±42.1* 337.0±78.5*
* - P Experimental results presented in Tables 4 and 5 show that compound IV in intragastric
administration at doses 10 and 150 µg/kg and at dose 50 µg/kg by inhalation exhibited anti-
anaphylactic activity. Administering the substance at dose 50 µg/kg by inhalation blocked the
development of the acute phase of bronchoconstrictory reaction which by inducing suffocation,
is a cause of animals' death. In intragastric administration of compound IV at doses 10 and 150
µg/kg, a significant protective effect with regard to antigen-induced bronchial spasm was
detected.
Thus, compound IV exhibits a significant protective effect with regard to systemic

24
anaphylactic reaction in vivo.
Example 16
Anti-allergic action of compounds of general formula I on the model of allergic rhinitis in
guinea pigs
The model of allergic rhinitis in guinea pigs was used.
Guinea pigs were immunized according to the certain scheme for 1.5-2 months (Hutson
P.A., Church M.K. et al. 1988): the animals were first immunized by intraperitoneal
administration of ovalbumin at dose 10 mg/kg at 7-day interval (twice), then ovalbumin solution
was inhaled to the guinea pigs using the Pari nebulizer at increasing concentration beginning
from 0.1% and reaching 1% at 4-day intervals between inhalations. The last ovalbumin dose was
administered into the nasal passages using a micropipette. 24 hours post the last ovalbumin
administration nasal washing was collected (through a system of special tubes) and changes in
nasal mucosa was assessed using a complex of histological and cytological methods. The
compounds tested (0.1% solution) were daily administered in the form of inhalations using
nebulizing device for 6 days; at day 6 of administration, antigen (OA) challenge was performed.
Nαsal wash-off was obtained 24 hours post challenge.
Table 6
The effect of compound IV on cytosis (absolute number of cells in 1 µl) in a nasal wash-off

It follows form Tables 5-7 that under the conditions of modeling allergic rhinitis,
compound IV significantly suppresses eosinophilic inflammation. This is supported by lowering
down to the norm absolute and relative number of eosinophils, as well as by a significant
lowering cytosis in nasal wash-off.
Example 17
Anti-allergic activity of compounds of general formula I in the model of allergic
pneumonitis in guinea pigs
The model of allergic pneumonitis in guinea pigs was used.
Immunization of the animals was similar to that described in Example 7.
24 hours post the last ovalbumin administration broncho-alveolar wash-off was collected
(through a cannula inserted into the trachea), and changes in bronchial mucosa was assessed
using a complex of histological and cytological methods.
The compounds tested (0.1% solution) were daily administered in the form of inhalations
using a nebulizing device for 6 days; at day 6 of administration, antigen (OA) challenge was
performed.

Table 10
The effect of compound IV on absolute number of cellular subpopulations in broncho-alveolar
wash-off of guinea pigs (in 1 µl)

* - difference from the intact control; ° - difference from the model
(*,°-P It follows from the data of Tables 9 and 10 that compound IV under the conditions of
allergic pneumonitis model significantly inhibits inflammatory process that is manifested by
decrease in cytosis, lowering the level of the key inflammatory cells eosinophils, by a sharp
lowering neutrophil level as well as by decrease in lymphocyte number.

27
Example 18
Study of anti-inflammatory action of compounds of general formula I on the model of
pneumonitis induced in rats by sephadex
The model of sephadex-induced (6-day) pneumonitis in rats
Male Wistar rats weighing 270-300 g were used in the tests.
Inflammation in the lungs was induced by a single inhalation of sephadex A-25
(hydrophilic powder with particle sizes from 20 to 80 µm) at dose 5 mg/kg using a dosing device
which is a laboratory analog of the inhaler "Cyclohaler" (the Scientific-Research Institute for
Pulmonology of the RF).
A technique of inhalation administering sephadex and pharmacological substances
Sephadex A-25 at dose 5 mg per 1 kg body weight was administered to rats under ester
anesthesia using an original dosing device for inhalation administering dry powders. Following
administration of Sephadex A-25, Wistar rats rapidly recovered form anesthesia, and no
peculiarities in their behavior and respiration character were noted. The substances in the form of
a dry powder were administered by inhalation at dose 500 µg/kg 1 hour post Sephadex
administration, then for 5 days in succession once daily at one and the same morning hours. The
control was represented by two groups: a group of intact animals, anda group of rats
administered once with Sephadex by inhalation.
The results of therapeutic action of pharmacological substances on pneumonitis
development were assessed using morphological and morphometric parameters (volume density
and alveolitis) 6 days post aerosol Sephadex administration.
Methods used in the study
Histological method
Histological examinations of the lungs stained by hematoxyline and eosine.
Morphometric methods
4-5 urn thick histological lung slices were prepared wherein neutrophil number was
calculated as well as volume density of alveolitis and emphysema was assessed using the
Avtandilov's mesh [Avtandilov G.G., Vvedeniye v kolichestvennuyu pathologicheskuyu
morphologiyu.// Moscow. "Meditsina" publishers. 1980. p. 203]. Morphometric examination of
pulmonary lymphoid tissue was also carried out. To this end, micro preparations of the lungs
were fixed according to the method of Beinenstock et al [Bienenstock J., Johnson N., Perey
D.Y.E. Bronchial lymphoid tissue 1. Morphologic characteristics//Lab. Invest. 1973. v.28 p.693-
698.] The lungs with trachea were removed from the thoracic cavity, and the micro preparation
was placed into 2% water acetic acid solution. 18-24 hours later, the trachea, the main and
lobular bronchi were dissected, and morphometric assessment of volume density of the lymphoid

28
tissue associated with the bronchi was carried out using the point calculation method under a
magnifying glass (magnification x7). Volume density of alveolitis and emphysema was
determined using the point calculation method.
Cytological methods
Broncho-alveolar wash-off was obtained in rats and guinea pigs under hexenal anesthesia
by double washing the lungs through the trachea with 10 ml normal saline. Viability of cells was
determined in the test with tryptane blue. Absolute number of cells in 1 ml (cytosis) was
determined in the broncho-alveolar wash-off liquid (BAW) using the Goryaev's chamber. In the
smears of the BAW liquid precipitate obtained using centrifugation at 200 g for 10 minutes and
then stained according to Romanovsky-Gimza, endopulmonary cytogram was calculated (in
percent) [Avtsyn A.P., Lukomskij G.I., Romanova L.K. et al. Endopul'monal'naya
cytogramma.// Sov. Med. 1982. No 7. pp.8-14].
The study results were processed using variation statistics method and the Student's t-test
Table 11
Broncho-alveolar wash-off cytosis parameters of Wistar rats following aerosol exposure to
Sephadex A-25 and treatment with pharmacological agents (M±m)
Cytosis
Absolute number of cells in 1 ul BAW

Histological examination of the lungs
Compound IV induced a distinct anti-inflammatory action: prevalence of alveolitis was
significantly lower as compared to the model group of animals; emphysema was not practically
detected; infiltration of interalveolar septa with neutrophils was not noted. By cytosis level and
number of neutrophils in the BAW, inflammatory process was also significantly less pronounced
that in animals administered with Sephadex for 5 days.
Thus, all complex of the experimental models used suggests a significant anti-allergic,
anti-anaphylactic and anti-inflammatory activity of compounds of general formula I manifested
in both in vitro tests and in modeling allergic and inflammatory pathology in vivo.
Example 19
The study of hypolipidemic action of compounds of general formula I on the model of
hypercholesterolemia in rats
The study was carried out on male Wistar rats weighing 200±20 g. Hyperlipidemia was
induced by oral administration of cholesterol loading, oily cholesterol suspension:
olive oil (Acorsa, Spain) - 5 ml/kg weigh of animals;
cholesterol (Sigma, USA) - 1 g/kg weight;
sodium cholate (Sigma, USA) - 100 mg/ kg weight.
As a reference preparation, the preparation from the group of statines "Mevacor"
(Lovastatine) manufactured by the firm Merck Sharp & Dohn was used at dose 40 mg/kg.
Cholesterol suspension was administered daily in the morning for 10 days. The compounds
tested (at dose 500 µg/kg) and the reference preparation (at dose 40 mg/kg) were administered to
the animals togester with cholesterol suspension for 10 days. All the animals received a standard
briquetted forage.
The animals were divided into the following groups:
"Control" - intact animals (n=6);
"Cholesterol" - rats that orally received cholesterol loading (n=10);
" Lovastatine" - rats that orally received cholesterol loading and Lovastatine (n=10);
"Compound IV" - rats that orally received cholesterol loading and the tested compound
IV(n=10).
Blood was sampled at days 5, 8 and 10 of the experiment.
Statistical processing of the hypolipidemic action data of the tested substances was

carried out with regard to the "Cholesterol" group (Table 13).
Table 13
Cholesterol and triglyceride level in blood serum and liver of rats orally administered for 10
days with olive oil, cholesterol and compound IV concurrently with cholesterol loading

*-p **-p ***-p Administering compound IV at dose 500 µg/kg resulted in a significant lowering serum
total cholesterol by 19.5%, hepatic cholesterol by 22.7%, LDL cholesterol by 29.8% and hepatic
triglycerides by 19%. The compound glutaryl histamine, by lowering total cholesterol level only
by 9%, exerted effect only on LDL and VLDL (low and very; low density lipoproteins) that is
shown in the publication of the International application WO 99/01103, and it is apparently less
efficient than compound IV in a similar, biological experiment.
The study results of the other claimed compounds are presented below.
Experimental groups included:
1) "Cholesterol" -rats orally administered with oily cholesterol suspension for 10 days;
2) "Compound IV" -rats orally administered with oily cholesterol suspension and the
tested compound IV;

31
3) "Compound IV - INa" - rats orally administered with oily cholesterol suspension and
the tested mono-sodium salt of compound IV;
4) "Compound IV - 2Na" - rats orally administered with oily cholesterol suspension and
the tested di-sodium salt of compound IV;
5) "Compound V - INa" -rats orally administered with oily cholesterol suspension and
the tested mono-sodium salt of the compound V;
6) "Compound III - INa" -rats orally administered with oily cholesterol suspension and
the tested mono-sodium salt of the compound III;
7) "Compound II - INa" -rats orally administered with oily cholesterol suspension and
the tested mono-sodium salt of the compound II;
8) "Sim" - rats orally administered with oily cholesterol suspension and Simvastatine;
9) control - intact rats before beginning the test.
At day 10 of the test blood samples were taken following decapitation of the animals.
The animals fasted for 12 hours prior to decapitation.
Blood serum total cholesterol, triglycerides and high density lipoprotein cholesterol
(HDLC) were measured. Low and very low density lipoprotein cholesterol was calculated by the
difference between total cholesterol and HDL cholesterol.
Blood serum total cholesterol and triglycerides were determined using the enzymatic
methods.
Cholesterol level in high density lipoproteins (α-LP) was determined using the
precipitation method of LDL and VLDL with phosphotungstic acid and magnesium ions.
Statistical processing
Data in the tables are presented as a mean value ± standard error. Significance of
differences between the groups "cholesterol" and "preparation..." was assessed by the two-
sampled Student's t-test. Error probability (p) is indicated in the table graphs.
The data on the effect of the compounds on blood serum cholesterol and triglyceride
levels of rats that received cholesterol loading are presented in Tables 14 to 21.

10-day administering oily cholesterol suspension to rats resulted in a significant 2,3-fold
rise in serum cholesterol level and in 1.9-fold rise in triglyceride levels. In the development of
induced hyperlipidemia, HDL cholesterol lowered by 15%. 5-fold rise in LDL+VLDL
cholesterol was observed. 2.3-fold rise in LDL+VLDL triglycerides was observed.
Table 15
Blood serum cholesterol and triglyceride levels (nig/100 ml) in rats at day 5 of the experiment

33

35

Administering a mono-sodium salt of compound III to the animals significantly lowered
total cholesterol (CH) by 29% and cholesterol of the VLDL+LDL fractions by 40%, but it did

37
not change the level of CH of serum anti-atherogenic HDL and total triglycerides.
The results obtained suggest that mono- and di-sodium salts were superior over
compound IV by action dynamics on serum total cholesterol and LDL+VLDL cholesterol and
other parameters of lipid metabolism. Whereas by day 10 of the experiment, a significant and
comparable lowering the mentioned parameters occurred under the effect of all the compounds
mentioned above and the reference preparation "Zokor" (Simvastatine), salt of compound IV
begun action at earlier terms of the experiment (by days 5 and 8). The both sodium salts of
compound IV elevated HDL already by day 5 of the experiment, whereas compound IV elevated
this parameter only by day 8. The reference preparation Simvastatine did not effect HDL
cholesterol. Furthermore, disodium salt of compound IV lowered serum total triglyceride levels
at days 5 and 10 of the experiment.
A distinguishing feature of the compound V mono-sodium salt was the ability thereof to
lower serum total triglyceride levels, whereas lowering total cholesterol and VLDP cholesterol
levels and rise in HDL level were lower than in the compound III and compound IV mono-
sodium salts.
Thus, as compared to the activity of the compounds disclosed in the publication of
International application WO 99/01103, and the compounds proposed in the instant invention,
salts of the compounds II, III, IV and V possess enhanced hypolipidemic activity including the
capability of lowering serum triglyceride, total cholesterol levels including LDL cholesterol level
and elevating HDL cholesterol.
Example 19
Study of hypolipidemic effect of compounds of general formula I on the model of
"endogenous" hypercholesterolemia in guinea pigs
The study was carried out on male guinea pigs (Aguti line) weighing 304±25 g. The
experiment lasted 31 days. The control group included 6 guinea pigs (intact animals). The
compounds studied were administered from day 1 of the experiment (from day 1 of
administering fat loading).
The animals of experimental groups received orally for 31 days a compound studied and
fat loading. The compound studied at doses indicated below was administered in the form of an
aqueous solution (0.5 ml per an animal); fat loading (a mixture of porcine fat and preliminary
heated corn oil at 4:1 ratio by volume, at the rate of 5 ml/kg weight 0.5 h post administering the
substance studied.
Experimental groups:
1) "control" - intact animals;
2) "fat"- animals that received fat loading only;

38
3) "compound IV" - animals that received fat loading + compound IV at dose 500 fig/kg
body weight;
4) "compound V" - animals that received fat loading + compound V at dose 500 µg/kg
body weight.
The data on blood serum cholesterol and triglyceride levels in guinea pigs that received
fat loading and the compounds studied, are presented in Tables 22 to 25.

39
Table 24
Total cholesterol level in lipoprotein fractions at day 31 of blood serum guinea pigs that
received fat loading and the compounds studied

The studied compounds IV and V significantly lowered total cholesterol level by 33.9
and 37.8% respectively only by day 31 of the experiment At the same time, they significantly
lowered LDL cholesterol by 37.7 and 38%.

Fig. 1. Change in serum total cholesterol level as effected by fat loading and different
doses (50-1,500 µg/kg) of compound IV. Thin vertical lines indicate standard deviation from the
mean value.
Advantage of the claimed compounds, in particular compound IV, is a broad range of
acting doses that provides for broadness of therapeutic effect thereof. Thus, for example,
compound IV was practically similarly effective in lowering total cholesterol level during 20
days at interval of doses from 50 to 1,500 µg/kg differing 30-fold.
Thus, the claimed compounds corresponding to general formula I possess a significant
hypolipidemic activity considerably improving the lipid metabolism parameters in blood serum
and in the liver.
Example 20
Study of anti-inflammatory action of compounds of general formula I on the model of
carrageenan rat paw edema
The experiments were performed on white outbred male rats weighing 250 g. A total
amount of animals per an experiment was 12.
The model of carrageenan-induced edema according to the method of Winter et al. was
used (Winter et al. Studies of the mediators of the acute inflammatory response induced in rats in
different sites by carrageenan and turpentine.//J.Phamacol. 1971. V.I04. P. 15-29). 0.1 ml 1%
carrageenan solution (SERVA) was subplantarly injected into the right rat paw. The animals
were placed into individual chambers. Gel (1%) comprising a substance tested was applied on
the paw three times: immediately following carrageenan administration, ate 1 and 2 hours post

41
administration. 4 hours post administration of carrageenan, paw volumes were measured using a
plethysmograph (Ugo Basile) Therapeutic effect of the gel was assessed by inhibition degree of
inflammatory reaction in comparison with the intact left paw of the given animal and rat paw
reaction of the control (untreated) group. Inflammatory reaction inhibition expressed in percent,
was calculated according to the formula:

The tested compounds VI and XIII in the form of 1% gel caused inhibition of edema by
44% and 40%, respectively, and the reference preparation diclofenac (1% gel) inhibited edema
by 62%.
Examples of dosage forms
Example 21
A. Tablets
The tablets are prepared using the ingredients presented below:
Compound corresponding to general formula I or a
pharmaceutically acceptable salt thereof 1-150 mg
Potato starch 20-50 mg
Magnesium stearate 3 mg
Aerosyl 1 mg
Lactose up to 300 mg
The components are mixed and compressed to form tablets weighing 300 mg each.
B. Suppositories
Example of a suppository composition:
Compound corresponding to general formula I or a
pharmaceutically acceptable salt thereof 1-100 mg
Cocoa butter An amount required to prepare a
suppository
If needed, preparing rectal, vaginal and urethral suppositories with respective excipients
is possible.
C. Ointments
Example of ointment composition:
Compound corresponding to general formula I or a
pharmaceutically acceptable salt thereof 1-500 mg

42
Vaseline 10 g
Ointments are prepared according to the generally known technology.
D. Gels
Example of a gel composition:
Compound corresponding to general formula I or a
pharmaceutically acceptable salt thereof 1 -500 mg
Carbopol 200 mg
Benzyl alcohol 20 mg
Ethyl alcohol 300 mg
water Up to 10 g
E. Dry powder for inhalations
Example of a powder composition:
Compound corresponding to general formula I or a
pharmaceutically acceptable salt thereof 20-200 mg
lactose Up to 1 g
The powder is filled into a special device (container) or into a gelatin capsule.
F. Nαsal spray
Example of a spray composition:
Compound corresponding to general formula I or a
pharmaceutically acceptable salt thereof 1.5 -15 0 mg
Purified water Up to 15 ml
G. Eye drops
Composition example of eye drops:
Compound corresponding to general formula I or a
pharmaceutically acceptable salt thereof 0.5-50 mg
preservative 10 mg
Purified water Up to 5 ml
H. Solution for injections
Composition example of a solution for injections:
Compound corresponding to general formula I or a
pharmaceutically acceptable salt thereof 0.2-20 mg
Water for injections 2 mg

R2=H, -CH3, -C2H5
and pharmaceutically acceptable salts thereof,
with proviso that the compound of general formula I is not succinyl-L-tryptophane,
succinyl-D-tryptophane and succinyl-D,L-tryptophane and a dipotassium salt thereof, Nα-
succinyl-L-tryptophane methyl ester, Nα-glutaryl-L-histidine methyl ester, Nα-glutaryl-L-
tryptophane methyl ester.
2. The compound according to claim 1, wherein pharmaceutically acceptable salt is
mono- or disodium salt.
3. A process for preparing N-acyl derivatives of amino acids of general formula I

wherein n is 2 or 3; and

or pharmaceutically acceptable salts thereof, comprising addition of glutaric or succinic
acid anhydride as a solid to aqueous solution of an amino acid of general formula:

44

and optionally converting the target product into a salt thereof.
5. A pharmaceutical composition possessing anti-allergic, anti-anaphylactic, anti-
inflammatory and hypolipidemic activity comprising N-acyl derivatives of amino acids of
general formula I

or pharmaceutically acceptable salts thereof for manufacturing a medicament possessing
anti-allergic, anti-anaphylactic, anti-inflammatory and hypolipidemic activity.
7. Use of N-acyl derivatives of amino acids according to claim 6 for manufacturing a
medicament for lowering antigen-dependent histamine secretion, basophil degranulation as well
as for controlling the level of eosinophils, neutrophils and lymphocytes.
8. Use of N-acyl derivatives of amino acids according to claim 6 for manufacturing a
medicament for ameliorating the symptoms of bronchial asthma, allergic rhinitis, pollinoses,
season and year-round rhinitis, allergic pneumonitis, atopic dermatitis, psoriasis, urticaria,
allergic (including anaphylactic) reactions to insect stings and medicaments, cold allergy,
allergic conjunctivitis.
9. Use of N-acyl derivatives of amino acids of general formula I

or pharmaceutically acceptable salts thereof, with proviso that the compound of general
formula I is not a dipotassium salt of succinyl-D,L-tryptophane, for manufacturing a medicament
for ameliorating the symptoms of atherosclerosis, obesity, ischemic heart and cerebral disease,
myocardial infarction and stroke.
10. A medicament possessing anti-allergic, anti-anaphylactic, anti-inflammatory and
hypolipidemic activity comprising N-acyl derivatives of amino acids of general formula I

or pharmaceutically acceptable salts thereof.
11. A method for treating allergic, anaphylactic diseases including diseases accompanied
by inflammation, hyperlipidemia, hypercholesterolemia, comprising administration to a mammal
of an effective amount of the compound of general formula I

wherein n is 2 or 3; and
R1 represents

12. A method according to claim 11 for treating bronchial asthma, allergic rhinitis,
pollinoses, season and year-round rhinitis, allergic pneumonitis, atopic dermatitis, psoriasis,
urticaria, allergic (including anaphylactic) reactions to insect stings and medicaments, cold
allergy, allergic conjunctivitis.
13. A method for treating atherosclerosis, obesity, ischemic heart and cerebral disease,
myocardial infarction, stroke, comprising administration to a mammal of an effective amount of
the compound of general formula I

or a pharmaceutically acceptable salt thereof, with proviso that the compound of general
formula I is not a dipotassium salt of succinyl-D,L-tryptophane.

The present invention relates to N-acyl derivatives of amino acids and pharmaceutically
acceptable salts thereof or pharmaceutically acceptable salts thereof, to novel processes for preparing the same, to use thereof as anti-allergic, anti-anaphylactic, anti-inflammatory and hypolipidemic agents as well as to a pharmaceutical composition comprising the indicated compounds in an efficient
amount and to a method for treating allergic and inflammatory diseases and lipid metabolism
disorders: bronchial asthma, allergic rhinitis, pollinoses, seasonal and year-round rhinitis,
allergic pneumonitis, atopic dermatitis, psoriasis, urticaria, allergic (including anaphylactic) reactions to insect stings and medicaments, cold allergy, allergic conjunctivitis, atherosclerosis, obesity, ischemic heart and cerebral disease, myocardial infarction and stroke.

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Patent Number

264601

Indian Patent Application Number

82/KOLNP/2008

PG Journal Number

03/2015

Publication Date

16-Jan-2015

Grant Date

08-Jan-2015

Date of Filing

04-Jan-2008

Name of Patentee

OTKRYTOE AKTSIONERNOE OBSCHESTVO "OTECHESTVENNYE LEKARSTVA"

Applicant Address

UL. GILYAROVSKOGO, D. 4, STR. 5 129090 MOSCOW

Inventors:

#	Inventor's Name	Inventor's Address
1	NEBOLSIN VALDIMIR EVGENIEVICH	SEVERNOE CHERTANOVO 4-403-249, MOSCOW 113648
2	ZHELTUKHINA GALINA ALEXANDROVNA	UL. ISKRY 13-1-292, MOSCOW 129344
3	KOVALEVA VIOLETTA LEONIDOVNA	UL. NOVOPESCHANAYA 3-82, MOSCOW 125057
4	KROMOVA TATYANA ALEXANDROVNA	UL. BILIBINA 17-60, KALUGA 248010

PCT International Classification Number

C07D 233/64

PCT International Application Number

PCT/RU2006/000311

PCT International Filing date

2006-06-15

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	2005118635	2005-06-15	Russia