DE1493083C - - Google Patents

Description

Q ₇ H ₃₁ CO-N

30th

in which R ₁ and R _{2 have} the above meaning, characterized in that linoleic acid is reacted in a manner known per se according to Patent 1,468,952 in the presence of an aqueous agent, preferably dicyclohexylcarbodiimide, or a functional derivative of linoleic acid with a corresponding amine.

3. The method according to claim 2, characterized in that one linoleic acid chloride in the presence a basic condensing agent reacts with the amine.

4. The method according to claim 2, characterized in that there is a lower alkyl ester of Reacts linoleic acid directly or in the presence of an alkali metal alcoholate with the amine.

The main patent 1,468,952 describes linoleic acid amides and a process for the production of linoleic acid amides the general formula

Q ₇ H ₁₁ CON

60

in which R _{1 is} the isopropyl, allyl, cyclopentyl, methylcyclohexyl or methyl or 2,4,6-trimethylphenyl _{radical and R 2 is} hydrogen, R ₁ and R _{2 are} each an isobutyl, phenyl or allyl radical or together with the Nitrogen atom denotes the pyrrolidyl or hexamethyleneimine group, R ₁ denotes the phenyl or cyclohexyl group and R ₂ denotes the methyl group and R ₁ denotes the phenyl or 3-methylphenyl group and R ₂ denotes the ethyl group dehydrating agent, preferably dicyclohexylcarbodiimide, or a functional derivative of linoleic acid with a corresponding amine.

Linoleic acid chloride is preferably used in this process in the presence or absence of one inorganic or organic alkaline condensing agent or linoleic acid in the presence of a dehydrating By means of such as dicyclohexylcarbodiimide, with the amine.

The present invention aims to improve or further development of the process according to the main patent.

The invention also relates to new linoleic acid amides produced by this process.

Atherosclerosis is one of the problems associated with diseases that have not yet been satisfactorily resolved Adult. Albeit the cause of arteriosclerosis despite the discussions in the professional world so far could not be elucidated, it is widely recognized that one of the most essential histopathological see Evidence for arteriosclerosis is a deposition of lipoids in the blood vessels. Therefore Researches were directed to the disturbed lipoid metabolism. Special attention was aimed from the beginning on the exceptionally high blood cholesterol level.

A number of experimental and clinical facts have been reported to establish the relationship between atherosclerosis and high blood cholesterol levels. The development of Means for reducing the high blood cholesterol level is therefore for prevention or prevention of atherosclerosis extremely important.

Work has already been carried out intensively on the development of such agents which lower the cholesterol level and quite a few compounds have been clinically proven, but none of these agents have been satisfactory. Some work pretty well but inevitably lead to harmful side effects that are not neglected can be; the others are insufficient in effectiveness because they are administration in excessively large doses.

The only group of compounds which are now in practical use for this purpose include those which are unsaturated Fatty acids, especially linoleic acid. The reason for using linoleic acid is theirs Harmless to the human body. However, their effectiveness is not so high and besides uncertain and indefinite. Therefore, extremely high doses administration is necessary, if at least a certain lowering of the cholesterol level should be achieved.

The invention has set itself the task of providing a process for the production of further agents for lowering to develop the cholesterol level, which the known agents in terms of their effectiveness, to reduce the elevated cholesterol level in the blood are superior and have no noticeable toxicity show.

Knowing in detail the disadvantages of the means of reduction proposed and used so far the cholesterol blood level and with the aim of remedying this, in-depth investigations have been carried out performed with a variety of compounds; it was found that certain N-sub-

Substituted linoleic acid amides meet the requirements placed on the funds.

According to the biological tests, these acid amides surpass linoleic acid in terms of effectiveness decrease the level of cholesterol in the blood. Furthermore, the acid amides are effective not as uncertain and indefinite as linoleic acid. They can be treated with linoleic acid in their harmlessness compare, even when given continuously over long periods of time, and in their steady and constant effectiveness during continuous administration. Such specific biological properties of the acid amides prepared according to the invention have not yet been described.

The N-substituted linoleic acid amides obtained by the process according to the invention have the general formula

20th

C ₁₇ H ₃₁ CO-N

CH ₃ (CH ₂ ) ₄ CH = CH - CH ₂

CH = CH - (CH ₂ ) ₇ - COOH

drive the low-temperature recrystallization, the distillation, the urea method or the salt recrystallization be won.

Linoleic acid halides are known and their methods of preparation are in various references described, including the thionyl chloride method and the phosgene method. After these Process the acid chloride, the acid bromide, or the acid iodide are produced; of these is this Acid chloride is most important for the process according to the invention.

As a functional derivative of linoleic acid, compounds of the following formula can be used:

C ₁₇ H ₃₁ COA

wherein A is methoxy, ethoxy, n-propoxy, iso-propoxy, n-butoxy, iso-butoxy or tert-butoxy means.

The amines of the general formula to be used in the process according to the invention

wherein a) R _{1 is} a phenyl monosubstituted by chlorine or bromine, a phenyl disubstituted by chlorine and the methyl group, a 3-trifluoromethylphenyl, a 4-methoxyphenyl, a cyclohexyl optionally substituted by a hydroxyl or methoxy group, a 4 Ethoxycyclohexyl, a benzyl radical optionally substituted in the 2,3,4 or α-position by a methyl group or in the 2-position by a hydroxyl or methoxy group, or an α-alkyl (C ₂ -C ₄ ) benzyl radical, R _{2 is} a hydrogen atom or b) R ₁ and R _{2 are} each a benzyl radical.

These compounds can be prepared by the process according to the invention by reacting linoleic acid in a manner known per se according to Patent 1,468,952 in the presence of a dehydrating agent, preferably dicyclohexylcarbodiimide, or a functional derivative of linoleic acid with a corresponding amine. The substituents R ₁ and R _{2 of} the amine have the meanings already given above for the linoleic acid amides.

Intensive and extensive studies of biological activities have shown that these compounds the concentration of cholesterol in the blood in test animals such as mice, rats, rabbits, Dogs and donkeys significantly reduce this even with continuous administration over several Months no toxicity occurs at all.

The linoic acid used in the process according to the invention can be of any origin. Usually it is obtained from various natural fatty oils, especially vegetable oils Linoleic acid, consisting essentially of octadeca-9,12-dienoic acid of the formula

60

is the preferred material for the process of the invention, although the other isomers are also Octadecadienecarboxylic acids can be present. For example, relatively pure linoleic acid can be used from safflower oil by cleaning according to the Ver-HN

have substituents which have the meanings already given. In the case of the monosubstituted phenyl radical, the substituent R ₁ can carry the chlorine or bromine atom in the o-, m- or p-position; the same applies to the cyclohexyl radical substituted by a hydroxyl or methoxy group.

The following processes can be used to prepare the linoleic acid amides according to the invention will.

For example, you can

1. Linoleic acid directly with an amine of the formula

HN

(wherein R ₁ and R ₂ are as defined above) in the presence or absence of. dehydrating agents, such as disubstituted carbodiimide compounds, ρ - toluenesulfonic acid or p-toluenesulfonyl chloride, react in an aqueous organic solvent (Organic Synthesis, Vol. 20, 1940, p. 66),

2. convert the linoleic acid into the acid chloride (Organic Synthesis, Vol. 37, 1957, p. 66) and that Acid chloride with at least an equimolar amount of the amine in the presence of a basic one To implement condensing agent, '

3. the linoleic acid ester directly with the amine in the presence or absence of a solvent and · reacting a condensation agent (this method, the so-called »aminolysis«, is easiest (Journal of Organic Chemistry, Vol. 8, 1943, p. 473),

4. a mixed acid anhydride of linoleic acid of the formula

C ₁₇ H ₃₁ CC)

RCO

wherein R is an alkyl or alkoxy radical, with the amine in the presence of a basic Kon- ' let the densification agent react. (Journal of the American Chemical Society, Vol. 71, 1949, P. 2215).

The procedure mentioned under 1 using dicyclohexylcarbodiimide is very advantageous, because the desired product can be easily obtained by filtering and separating without any special Preparations can be isolated, the urea again after appropriate work-up can be used. Instead of dicyclohexylcarbodiimide, diisopropylcarbodiimide, Diphenylcarbodiimide and all other dialkyl, dicycloalkyl or di-substituted phenylcarbodiimides can be used. The reaction takes place by combining the separately in an organic solvent dissolved linoleic acid or the di-substituted carbodiimide at room temperature in a molar ratio of 1: 1 and stirring the mixture as necessary, mixing taking place with cooling can. After standing for 3 to 24 hours at room temperature, the resulting urea becomes Filtered off and the desired product came out of the fiI isolated.

The procedure described under 2 can also be carried out in a solvent such as water, organic Solvents or in the amine used as the starting material are carried out, each Temperature up to about the boiling point of the solvent used, advantageously below Inert gas such as nitrogen or helium is used.

The aminolysis method described under 3 can be carried out with alkali metal alcoholates as basic catalysts. However, the reaction can also be carried out without using a catalyst. Any inert organic solvent can be used as the solvent, e.g. B. an alcohol, an aromatic or an aliphatic hydrocarbon. In this procedure, the starting mixture is left to stand at a temperature from room temperature to about 400 ^° C. for a period of 3 hours to one month, the desired product being obtained in a favorable yield. By using inert gases such as helium or nitrogen, undesired oxidation and discoloration can be avoided. The reaction time can be shortened further by increasing the temperature above the boiling point of the reaction mixture in an autoclave or by removing the alcohol generated from the reaction system during the reaction. This method offers a particular simplification when the reaction is carried out in the absence of a solvent.

Example 1

10 g of linoleic acid, 5 g of o-methoxycyclohexylamine and 9 g of dicyclohexylcarbodiimide were mixed in 20 ml of benzene and the mixture was left to stand overnight at room temperature. The excess dicyclohexylcarbodiimide was decomposed with acetic acid and the resulting reaction mixture was filtered. The filtrate was washed successively with a 5% aqueous hydrochloric acid solution, a 5% aqueous sodium carbonate solution and water, dried over anhydrous sodium sulfate and then concentrated. The N - ο - methoxycyclohexyllinoleic acid amide (11 g) was obtained by distillation at 190 to 195 ° C. and 0.1 mm Hg, nV ^s 1.5090.

Elemental analysis:

Calculated ... C 76.67, H 11.58, N 3.58%;
found .... C 76.98, H 11.60, N 3.62%.

The same procedure as in Example 1 was repeated except that various other amines were used and solvents are used. The following table shows the results obtained and those used Amines and solvents. In the table, DCCD means dicyclohexylcarbodiimide, DFCD means diphenylcarbodiimide, DBCD dibenzylcarbodiimide and DICD diisopropylcarbodiimide. In the same table means b calculated and g found.

Amine OCH ₃ Solution
medium table A. C.
b G H
b G N
b G Dehydration
ization
medium at
game NH ₂ - <f ~~ V- OC ₂ H ₅ benzene Bp. ⁰ C / mm Hg "D ° C 76.67 76.77 11.58 11.78 3.58 3.79 DCCD 2 CH ₃ 190 to 195 / 0.1 25th
1.4848 NH ₂ CH - \ / benzene 76.90 76.82 11.68 11.77 3.45 3.55 DCCD 3 NH 192 to 195 / 0.1 24
1.4851 - Tetra
hydrofuran 81.40 80.89 10.77 10.69 3.65 3.94 DCCD 4th CCl ₄ 200 to '205 / 0.05 21.5
1.4901 83.60 83.87 9.87 9.97 3.05 3.23 DFCD 5 208 to 213 / 0.03 24
1.5155

continuation

at
game Amine Solution
medium Bp ° C / mm Hg n _D ° C C.
b %
G H
b %
G N
b %
G Dehydration
ization
medium 6th NH ₂ CH ₂ - / ^
CH ₃ Ethylene
dichloride 188 to 193 / 0.02 27
1.4982 81.40 81.42 10.77 11.05 3.65 3.68 DCCD CH ₃ 7th NH ₂ CH ₂ ^ J> benzene 204 to 209 / 0.06 27
1.5027 81.40 81.57 10.77 10.81 3.65 3.69 DBCD 8th NH ₂ - CH ₂ - </ ~ \ _{- CH 3} benzene 203 to 206 / 0.06 27
1.4953 81.40 81.62 10.77 10.99 3.65 3.68 DCCD 'OCH ₃ - 9 NH ₂ -CH ₂ - \ ^ y ether 190 to 203 / 0.03 27
1.4952 78.14 78.04 10.34 10.23 3.51 3.38 DCCD . OH 10 NH ₂ CH ₂ ^ Q " ether 205 to 211 / 0.02 30th
1.4860 77.87 77.72 10.2 10.21 3.63 3.76 DCCD 11th NH ₂ -Q ether 200 to 203 / 0.03 29
1.4833 73.71 74.51 8.85 8.39 3.44 3.50 DCCD I.
CF ₃

Example 12

A mixture of 10 g of linoleic acid, 14 g of cyclohexylamine, 0.2 g of p-toluenesulfonic acid and 30 ml of toluene was refluxed for 8 hours using a water separator. After the completion of the reaction, the toluene solution was washed with a 5% aqueous hydrochloric acid solution, a 10% aqueous sodium carbonate solution and with water, and then dried. The toluene was removed and the product was distilled. 10 g of N-cyclohexallinoleic acid amide were obtained. 180-181 ° C / 0.02 mm Hg, n ² f 1.4890.

Elemental analysis:

Calculated ... C 79.71, H 11.99, N 3.87%;
found .... C 79.42, H 12.08, N 3.80%.

Example 13

A mixture of 10 g of linoleic acid and 5 g of α-methylbenzylamine was heated to 200 ° C. in an autoclave for 6 hours. The reaction mixture was distilled at 203 to 209 ° C./0.09 mm Hg, 10 g of α-methylbenzyllinoleic acid amide were obtained. nf 1.4930.

Analysis:

Found ... C 81.56, H 10.91, N 3.78%;
calculated ... C 81.40, H 10.77, N 3.65%.

Example 14

A solution of 15 g of linoleic acid chloride in 20 ml of ether was added dropwise at 0 to 5 ° C. to a mixture of 7 g of 4-methoxycyclohexylamine, 4 g of trimethylamine and 50 ml of ether. After the addition was complete, the mixture was stirred at room temperature for 2 hours and then refluxed for 4 hours. Then it was treated in the same manner as in Example 1. 16.2 g of N-4-methoxycyclohexyllinoleic acid amide were obtained (boiling point 188 to 192 ° C./0.03 mm Hg, n% ^{4 1.4850).}

Elemental analysis:

Calculated ... C76.67, H 11.58, N 3.38%;
found .... C 76.91, H 11.79, N 3.90%.

In the same manner as in the previous examples, various amides were prepared using various amines, solvents and bases as shown in the following table, which also shows the results obtained. The following abbreviations are used in the table:
MIBK = methyl isobutyl ketone,
THF = tetrahydrofuran,
TMA = trimethylamine,
TEA = triethylaniline,
DEA = diethylaniline,

DMA = dimethylaniline,
A = the same amine that is also used as an

gangsamin was used.

309 612/139

ίο

Table B.

at
game Amine CH ₃ Solution
medium base Formed amide Kp.
° C / mm
Ed ⁰ C
“D C.
b G H
b G N
b G OCH ₃ NH ₂ CH ₂ ^) OCH ₃ 15th CH ₃ benzene A. -CONH - <^> 194-200 /
0.04 30th
1.5088 76.67 76.75 11.58 11.66 3.58 3.72 OCH ₃ NH ₁ CH ₁ ^ OCH ₃ 16 NH ₂ ^ Q) acetone X ₂ CO ₃ -C0NH <3> · 194-198 /
0.03 31
1.5070 76.67 76.81 11.58 11.71 3.58 3.81 17th NH ₂ -C ^^ - OQ, H _S OCH ₃ MIBK K ₂ CO ₃ -CONH - <> - OC ₂ H ₅ 192-195 / 30th 76 98 77.05 11.68 11.72 3.45 3 72 OH NH ₂ CH ₂ Q OH 0.05 1.4848 18th ether TFA 190-199 /
0.03 30th
1.4860 76.34 76.49 11.58 11.68 3.71 3.81 OH NH ₂ CH ₂ / ^)
OH OH 19th nh (ch ₂ <O) ₂ toluene Pyridine -CONH ^). 188-197 /
0.04 30th
1.4860 76.34 76.52 11.48 11.70 3.71 3.75 20th NH ₂ <^ THF Pyridine -conhOoh 190-202 /
0.04 30th
1.4863 76.34 76.55 11.48 11.58 3.71 3.79 21 CH ₃ CF ₃ MIBK Ca (OH) ₂ -CONHCH <ζ ~ \
CH ₃ 200-204 /
0.07 30th
1.4921 81.40 81.73 10.77 11.01 3.65 3.67 CH ₃ 22nd toluene DEA -C ONHCH ₂ \ ~ / 192-201 /
0.03 30th
1.4960 81.40 81.65 10.77 10.98 3.65 3.82 CH ₃ 23 THF NaOH -CONHCH ₂ / ~ S 200-203 /
0.07 27
1.502 81.40 81.64 10.77 10.69 3.65 3.84 24 acetone K ₂ CO ₃ - CONHCH ₂ \ ~ / CH ₃ 203-206 /
0.05 30th
1.4945 81.40 81.59 10.77 10.95 3.65 3.79 25th Benzenes DMA -CONHCH ₂ <ζ ~ \ 192-198 /
0.02 30th
1.4943 78.14 78.37 10.34 10.63 3.51 3.72 OCH ₃ 26th MIBK Na ₂ CO ₃ -CONHCH ₂ - / "^.
OH 201-211 /
0.03 32
1.4851 77.87 78.00 10.20 10.44 3.63 3.88 27 acetone A. \ ² X = // 2 207-213 /
- 0.03 31
1.5150 83.60 83.88 9.87 10.05 3.05 3.09 , 28 Pyridine Pyridine -CONH <f>
No 199-202 /
0.03 32.5
1.4840 73.71 74.51 8.85 8.25 3.44 3.59 CF ₃

Ester G Amine ^ y- Nh ₂ table B ' H' Kataly
sator C ₁₇ Amide
H ₃₁ CO- OH at
game QH ₅ 10 OH
I. f ° C 38 - .-NH -O OCH ₃ 29 140 OQH ₅ CH ₃ 10 OH 35 - -NH -ς> 30th 140 Γ ~ -
OH
OH
I. CH ₃ 10 36 - -NH 31 CH ₃ 10 HO- - <Q> -NH ₂ 145 37 - -NH O 32 t-bu 10 CH ₃ O- - <^> NH ₂ 140 3 KOtBu -NH O 33 CH ₃ 10 QH ₅ O- OCH ₃ 140 38 - - -NH O 34 <Q> -NH ₂ 140 CH ₃ 10 35 - -NH <y Cl 35 150 Γ
OCH ₃ CH ₃ 10 HN ₂ - Γ
Cl 40 - -NH 36 Cl
I. 140 Γ '
Cl. <> Cl
I ' CH ₃ 10 HN ₂ - <> _C1 40 - -NH -Δ 37 CH ₃ 10 NH ₂ - H ₃ C Cl 140 40 - -NH -ο Br 38 NH ₂ - 140 H _} C Cl CH ₃ 10 40 - -NH -O 39 . NH ₂ - 140 CH ₃ CH ₃ 10 40 - -NH 40 NH ₂ - 140 Cl CH ₃ 10 NH ₂ - 40 - ■ -NH 41 CH ₃ 10 140 40 - ■ -NH 42 -O 140 CF ₃ CH ₃ G I.
Cl 5 O* -O 5 I.
CF ₃ 5 5 5 5 5 10 10 1Ö 10 10 10 10

Ester G NH ₂ Arnin CH ₃ continuation G f ° C H Kataly
sator Arnid
C ₁₇ H ₃₁ CO- at
game CH ₃ 10 NH ₂ CH ₂ -ö 5 140 40 - -NH- 43 CH ₃ 10 / CH ₂
NH -O -OCH ₃ 5 140 40 - -NHCH ₂ - 44 CH ₃ 10 NH ₂ CH O CH ₃ 5 140 40 - / CH ₂ -
—N
\: h ₂ - 45 CH ₃ 10 CH; 5 140 40 - —NH-CH- 46 1 O CH ₃ NH ₂ -CH ₂ OCH ₃ CH ₃ 10 5 140 40 - -NHCH ₂ - 47 OH NH ₂ CH ₂ CH ₃ 10 NH ₂ CH ₂ 5 140 40 - -NHCH ₂ - 48 CH ₃ 10 5 140 40 - -NHCH ₂ - 49 NH ₂ CH ₂ -CH ₃ CH ₃ 10 5 140 40 - -NHCH ₂ - 50 NH ₂ CH ₂ CH ₃ 10 5 140 40 - -NHCH ₂ - 51 O O
O O CH ₃ CH ₃ O OCH, OCH ₃ OH
Γ

The physical data of the compounds listed in Table B 'are as follows:

Table B ".

Bp ° C / mm Hg or m.p. ° c C. b % G Elemental analysis b % G N% b G example "d 79.71 79.68 H 11.99 12.23 3.87 4.01 199 to 203 / 0.03 30th
1.4850- 76.34 76.57 11.48 11.73 3.71 4.00 29 188 to 192 / 0.01 30th
1.4863 76.34 76.02 11.48 12.00 3.71 4.13 30th 190 to 193 / 0.06 ' 30th
1.4871 76.34 76.48 11.48 11.54 3.71 4.09 31 191 to 194 / 0.05 31
1.4869 76.67 76.78 11.58 12.03 3.58 4.01 32 185 to 190 / 0.05 ' 30.5
1.4849 33

ΙΙΓΊΙΙ-ΊΙ

(Continuation)

Bp ° C / mm Hg or m.p. ⁰ C C% b G Elemental analysis % G N% b G example 76.98 76.81 H 11.79 3.45 3.67 193 to 196 / 0.1 30.5 b. 34 1.4847 76.67 76.48 11.68 11.98 3.58 3.89 200 to 204 / 0.08 31 35 1.5081 73.94 74.12 11.58 9.38 3.59 3.59 185 / 0.09 30.5 36 1.4990 73.94 74.41 9.24 9.45 3.59 3.88 185 to 190 / 0.03 27 37 1.4980 73.94 74.09 9.24 9.48 3.59 3.77 185 to 190 / 0.04. 23 38 1.5010 74.35 74.78 9.24 9.83 .3.47 3.68 185 to 195 / 0.02 27 39 1.4965 74.35 74.81 9.42 9.33 3.47 3.61 180 to 185 / 0.02 25th 40 1.4927 66.36 66.21 9.42 8.32 3.23 3.90 220 / 0.03 24 ■
1.5250
24
1.4859 73.71 74.42 8.46 3.44 3.53 41 200 to 201 / 0.04. 26th 77.92 77.81 8.29 10.45 3.64 3.81 ': '42 Mp. 55 to 57 ■ 1.4900 81.24 81.44 8.85 10.67 3.79 3.89 43 190 to 192 / 0.1 25th 10.13 44 1.5155 83.60 83.87 10.64 9.97 3.05 3.23 208 to 218 / 0.03 27 45 1.4929 81.40 81.87 9.87 11.00 3.65 3.72 203 to 207 / 0.15 27 46 1.4982 81.40 81.42 10.77 10.50 3.65 3.68 188 to 200 / 0.04 27 47 1.5026 81.40 81.28 10.77 11.28 3.65: 3.60 204 to 216 / 0.07 27 - 48 1.4949 81.40 81.62 10.77 10.51 3.65 3.74 203 to 207 / 0.06 27 49. 1.4952 78.14 78.04 10.77 10.23 .3.53. 3.38 190 to 200 / 0.03 30th 50 1.4860. 77.87 78.72 10.14 10.21 3.63 3.76 205 to 211 / 0.02. 51 10.20

Example 52

A mixture of 10 g of ethyl linolate, 10 g of dibenzylamine and an ethanolic solution of 1.0 g of sodium was heated to 70 to 85 ° C. for about 2 hours. Then the same amount of water was added and the mixture was extracted with ether. The essential part was washed with a 5% aqueous solution of hydrochloric acid and then with water, and then dried over anhydrous sodium sulfate. 13 g of Ν, Ν-dibenzyllinoleic acid amide, boiling point 203 to 207 ° C. / 0.04 mm Hg, nl ° 1.5150 were obtained.

Elemental analysis:

Calculated ... C 83.60, H 9.87, N 3.05%;
found .... C 83.71, H 10.03, N 3.22%.

Example 53

A mixture of 10 g of methyl linolate, 5 g of α-methylbenzylamine and a methanolic solution of 1.2 g of sodium was heated to 70 ° C. in a vacuum of 100 mm Hg for 2 hours, with removal of the methanol. 12 g of Na-methylbenzyllinoleic acid amide, boiling point 200 to 203 ° C./0.07 mm Hg, nf 1.4919 were obtained. .

Elemental analysis:

Calculated ... C 81.40, H 10.77, N 3.65%;
found .... C 81.77, H 10.94, N 3.66%.

Example 54

A mixture of 10 g of methyl linolate, 5 g of 2-methoxybenzylamine, 3.7 g of sodium methylate and 100 ml of toluene was reacted to remove the methanol in about 2 hours. 10 g of N-2-methoxybenzyllinoleic acid amide, boiling point 195 to 201 ° C./0.03 mm Hg, ni ^{5 1.4978 were obtained.}

Elemental analysis:

Calculated ... C 78.14, H 10.34, N 3.51%;
found .... C 78.03, H 10.20, N 3.79%.

Different amines were made in the same way

309012/139

which are compiled in the following table:

Table C.

at
game Linoleic acid
ester Amine used
NH ₂ - Formed amide
C ₁₇ H ₃₁ CONH- C.
b G H
b G N
b G Kp.
° C / mm Hg 32 57 ethyl
methyl
methyl CH ₃
—CH ₂ ~ y ~ \
_ _CHz ^ 2ycH ₃
OH
- CH ₂ ^ ~ \ CH ₃
—CH ₂ - ^ ~ J)
-CH ₂ - ^^ - CH ₃
OH 81.40 81.31 10.77 10.89 3.65 3.91 200 to 207 / 0.05
203 to 206 / 0.05
205 to 209 / 0.03 1.5019
32 81.40 81.22 10.77 10.92 3.65 3.78 1.4940
30th
1.4859 77.87 77.69 10.20 10.41 3.63 3.81

. . Washed with water and then dried. So-

Example then it was concentrated under reduced pressure

A mixture of 10 g of methyl linolate, 10 g of cyclo- trated and then distilled. One received. 7 g

hexylamine and a solution of 0.2 g of sodium in N-cyclohexyl-linoleic acid amide, b.p. 190 to 192 ° C /

60 ml of methyl alcohol was allowed 144 hours at room ₂₅ 0.03 mm Hg, n | ⁵ 1.4865.

stand temperature. Then the mixture was marked with _. ,

Water was added, and the oily layer was analyzed with ether.

extracted. The ethereal solution was calculated at a ... C 79.71, H 11.99, N 3.87%;

5% aqueous hydrochloric acid solution and then found with C 79.94, H 12.08, N 3.90%.

Table D.

at
game Ester G NH ₂ - Amine G catalyst solvent Temp.
⁰ C time
(Hours.) Formed amide
C ₁₇ H ₃₁ CO- Cl
\\ Cl
I. 59 CH ₃ 10 NH ₂ ö 10 KOtBu benzene 22nd 100 -NH- CH ₃ NH ₂ CH ₃ Ö 60 CH ₃ 10 NH ₂ 10 After ₃ Toluene- 22nd 100 -NH- 61 CH ₃ 10 NH ₂ - O 5 0 toluene 60 120 -NH- 62 C ₂ H ₅ 10 O 5 KOtBu t-butanol 30th 120 -NH- 63 CH ₃ 10 <y 10 After ₃ Methanol 30th 100 -NH- > - 'OCH ₃ -Cl ^ OH -OCH ₃ ^ OCH ₃ -OH -OCH ₃

The physical values of the compounds listed in Table D are given in Table D 'below listed:

Bp ° C / mm Hg or m.p. ° ^c
"ß Table D ' %
G H
b %
G N
b G Out
prey example 188 / 0.05
190 to 195 / 0.03 23
1.4992
23
1.4940 C.
b "74.50
74.91 9.24 "
9.42 9.81
10.65 3.59.
3.47 • j co
3.48 4.8
4.6 ■ 59
60 "73.94
74.35

(Continuation)

example Bp ° C / mm Hg or m.p. ⁰ C C.
b %
G H
b %
G N
b %
G Out
prey 61 m. p. 56 to 58 77.92 77.61 10.13 10.31 3.64 3.49 6.0 62 190 to 191 / 0.06 23
1.4880 76.34. 76.51 11.48 11.09 3.71 3.49 6.1 63 190 to 192 / 0.05 22nd
1.4861 76.67 76.09 11.58 11.39 3.58 3.62 4.9

Example 64

A mixture of 10 g of methyl linolate and 5 g of cyclohexylamine was left in an autoclave for 5 hours heated to 210 ° C.: 12 g of N-cyclohexyllinoleic acid amide are obtained (Bp 200 to 208 ° C / 0.05 mm Hg).

Elemental analysis:

Calculated ... C 79.71, H 11.99, N 3.87%;
found .... C 79.90, H 12.03, N 3.84%.

Example 65

A mixture of 10 g conjugated methyl linolate and 5 g of cyclohexylamine was heated to 200 ° C. in an autoclave for 5 hours. One received 12.1 g of N-cyclohexyllinoleic acid amide (boiling point 200 to 209 ° C / 0.04 mmHg).

Elemental analysis:

Calculated ... C 79.71, H 11.99, N 3.87%;
found .... C 79.88, H 12.05, N 3.61%.

The UV and IR absorption indicates the presence of conjugated double bonds.

Example 66

A mixture of 10 g of methyl linolate and 5 g of o-methylbenzylamine was heated to 210 ° C. for _{7 hours under N 2 in an autoclave.} 11.5 g were obtained No-Methylbenzyllinolsäureamid (bp. 192 to 21O ⁰ C / 0.06 mm Hg, 1.4982 nV).

Elemental analysis:

Calculated ... C 81.40, H 10.77, N 3.65%; found .... C 81.61, H 10.94, N 3.60%. ;

Example 67 ^r

A mixture of 10 g of conjugated methyl linolate and 5 g of p-methoxycyclohexylamine was heated to 150 ° C. _{in N 2 for 40 hours.} 12 g of Np-methoxycyclohexyllinoleic acid amide (boiling point 195 to 203 ° C./0.05 mmHg) were obtained.

Elemental analysis:

Calculated ... C 76.67, H 11.58, N 3.58%; found .... C 76.81, H 11.31, N 3.24%.

In the same way, the following connection was made: *

example

Amide

Fp.
⁰ C C%

H%

N%

trans-N-cyclohexyllinoleic acid amide

51 to 52 79.71

80.00

11.99

12.27

3.87

3.85

Example 69

To a solution of 14 g of linoleic acid and 5.5 g of triethylamine in 100 ml of tetrahydrofuran was at 5.9 g of ethyl chloroacetate were added to a temperature of -10 to -5 ° C. with stirring. Then the The reaction mixture was stirred at -5 ° C. for a further 20 minutes. 7.7 g of 2-methyl-6-chloroaniline were then added added to the solution at -5 ° C. with stirring. Stirring was continued during the Temperature was gradually increased to room temperature. Then the temperature gradually increased increased further, and the solution was stirred at 40 ° C for 20 minutes. .

After the solution was cooled, the tetrahydrofuran was distilled off under reduced pressure.

The residue was taken up in ether, one after the other with cold dilute hydrochloric acid, with a cold aqueous solution of sodium carbonate and washed with water and then over anhydrous Dried sodium carbonate. After distilling off the ether and distilling the residue under reduced pressure The pressure was 12.9 g. (Yield 64%) 2-chloro-6-methylphenyllinoleic acid amide (bp. 210 to 215 ° C / 0.02 mm Hg, ni? 1.5147).

Elemental Analysis (C ₂₅ H ₃₈ ONCl): Calculated ... C 74.35, H 9.42, N 3.47, Cl 8.80%; found .... C 74.57, H 9.61, N 3.42, Cl 8.67%.

In the same way, the following compounds were made.

21

Table E.

22nd

example

Amide C ₁₇ H _{31 CONH-}

Bp ° C / mm Hg

⁰ C c% b G H% b G N b "D 74.35 74.51 9.42 9.67 3.47 31 1.4910 66.36 66.71 8.29 8.42 3.23 26th 1.5249 74.35 74.67 9.42 9.68 3.47 25th

CH,

CH,

184 to 190 / 0.03

200 to 208 / 0.03

180 to 185

^25th

Analysis:

Example 73

N- (α-ethylbenzyl) linolamide ' ^J Calculated ... C81.55, H 10.90, N 3.52%; A mixture of 10 g linoleic acid and 7 g α-ethyl found ... C 81.45, H 11.00, N 3.50%.

6 hours at 150 ⁰ C benzylamine was heated. It preserved the effectiveness of the present invention

13.4 g of N- (a-ethylbenzyl) linoleic acid amide were derived from linoleic acid amide compounds from the following-

Bp. 180 to 190 ° C / 0.04mm Hg obtained, nl ° 1.5024. 30 can be seen in the table.

Table F. > Cholesterol-'
1%
administered K
78 connection > 74 to No control) 47 Linoleic acid > 71 C ₁₇ H ₃₁ CONH ^ ζ ~ I.
Cl 52 C ₁₇ H ₃₁ CONH - <^ 20th C ₁₇ H ₃₁ CONHCH ₂ - / ^ VcH ₃ C ₁₇ H ₃₁ CONH - / ~ > ■■. 46 C ₁₇ H ₃₁ CONH - \ \
Cl C ₁₇ H ₃₁ CONH - ^ f 50 Cl C ₁₇ H ₃₁ CONH ~ / ~ Blood level values
0.2%
administered /
H ₃ C ) 0
101 to 104 55 101 77 58 67 61 63

continuation

connection Cholesterol-!
1%
administered Slut mirror values
0.2%
administered C ₁₇ H ₃₁ CONH ^ (~ \ 79 94 I.
OH Q ₇ H ₃₁ CONH - <^^ OH 64 82 OCH ₃ Q ₇ H ₃₁ CONH - <^ _ y> 60 90 Q ₇ H ₃₁ CONH - <^ ~ ^ OC ₂ H ₅ 52 (0.4%) 80 Q ₇ H ₃₁ CONH - <^> 56 (0.8%) -75 I.
OCH ₃ Q ₇ H ₃₁ CONH- / ~ Λ 72 85 . I.
CF ₃ Q ₇ H ₃₁ CONH - ^< \ ~~ V ~? ^r 79 86 Q ₇ H ₃₁ CONfCH ₂ - / ~~ V) 67 Q ₇ H ₃₁ CONH ~ ^ ~ \ 67 Cl Q ₇ H ₃₁ CONH - ^ ~ V- Cl 46 CH ₃ Cl Q ₇ H ₃₁ CONH - \ ~ y 35 44 CH ₃ Q ₇ H ₃₁ CONH- ^ "V- CH ₃ 42 Cl Q ₇ H ₃₁ CONH - CH ~ ^ \ ~ y 39 78 CH ₃
t Q ₇ H ₃₁ CONH-CH ₂ - / "V-CH ₃ 55

continuation

connection Cholesterol j
1%
administered Blood level values
0.2%
administered Q ₇ H ₃₁ CONH-CH ₂ - 56 Q ₇ H ₃₁ CONH-CH ₂ - 64 Q ₇ H ₃₁ CONH-CH ₂ - 70 trans-Q ₇ H ₃₁ CONH - 60 conj. Q ₇ H ₃₁ CONH - 69 conj. Q ₇ H ₃₁ CONH - 39 80 Q ₇ H ₃₁ CONH-CH ₂ - 71 Q ₇ H ₃₁ CO-NH-CH- 39 CH ₃ Q ₇ H ₃₁ CO-NH-CH- 40 C ₂ H ₅ C ₁₇ H ₃₁ CO-NH-CH- 39 ISO-C ₃ H ₇ Q ₇ H ₃₁ CO-NH-C 41 :H- o ■■■ Ί
CH ₃ Q Γ
CH ₃ O I,
OCH ₃ O O ο. Q I.
OH O O O O

The effectiveness was tested on mice, which on a special, with cholesterol and bile acids fortified diet were put on. The blood cholesterol level of the mice was 3 to 4 times that normal value has been increased. The linoleic acid amide compound became good in amounts of 1 or 0.2% mixed into the special diet and administered orally continuously for 8 to 12 days. Then the Quantitative total cholesterol level in the blood serum of the animals. The cholesterol blood level indices were derived from the values calculated by taking the value that was found in the animals of the control group, i.e. those of no remedy was given, was set equal to 100.

Another significant effectiveness of the N-substituted linoleic acid amide compounds prepared according to the invention is to prevent the build-up of cholesterol and fat in the liver that is involved Enters animals placed on a cholesterol diet. It appears that the linoleic acid amide compounds increase the decreased lipid metabolism function of the liver. This effectiveness is also beneficial because because lipid metabolism is mainly based on the functioning of the liver. In the case of linoleic acid, a such effectiveness never observed.

The extremely low toxicities of the N-substituted linoleic acid amide compounds prepared according to the invention result from the following values

before, which summarizes the acute toxicity of a compound prepared according to the invention for mice is.

. Table G.

medium CH ₃ /
\ LD ₅₀ -We
by mouth rte (g / kg)
intra-
peritoneal \
CH ₃ Q ₇ H ₃₁ CONHCH O > 50 1.0 A. C ₁₇ H ₃₁ CONH - ' Y > 50 9.0 I.
CH ₃ C ₁₇ H ₃₁ CONH -I > 50 10.5 Linoleic acid ... · .... > 50 <10 ■ '

As can be seen from the above values, there were no deaths and no marked toxic Symptoms observed even at very high doses (by oral route) such as 0.5 g per 10 g, i.e. H. 50 g / kg Body weight. Even with daily administration of N-cyclohexyllinoleic acid amide in concentrations of 1, 0.5 or 0.2% in the 3-week diet in mice did not show any pronounced toxic symptoms and no deaths were observed. The appetite was normal and the digestive function was unchanged. The internal organs showed no noticeable change during the dissection. The same result performed experiments with N-2-methylphenyllinoleic acid amide on rats.

The cholesterol lowering agents which are obtained by the method according to the invention, can be administered orally, usually 0.1 to 20 g per day, preferably 0.5 to 5 g per day and administration can continue for 1 to 5 months, usually about 3 months. The cholesterol lowering agents can be given in any convenient form which is oral Administration is common. So they can be enclosed in capsules or in liquid form, as tablets or be given in powder form. When preparing the means in these different forms can a suitable solid carrier can be mixed or impregnated with the active compound, or the active Compound can be in a liquid carrier such as edible oil, preferably an oil containing linoleic acid, be included. It is also possible to use a mixture of two or more of the invention obtained N-substituted linoleic acid amides, and further these compounds can also used in a mixture with linoleic acid.

Comparative experiments

A. Investigation of the cholesterol-lowering effect of the linoleic acid amides according to the invention upon administration of these compounds in rats

Male Wistar rats weighing between 100 and 120 g were used to carry out the experiments. They received semi-synthetic feed containing 1 percent by weight cholesterol every day. After 2 weeks, the cholesterol level in blood samples taken from the test animals was determined according to the method of RG Herrmann, Proceedings of the Society for Experimental Biology and Medicine, Vol. 94, 1957, p. 503.
The animals examined were divided into two groups, and during the following 8 weeks the animals were given the above-mentioned cholesterol feed and also various of the compounds according to the invention in the amounts shown in Table H below. After the end of the test, the cholesterol level in the serum and the cholesterol content in the liver and the lipid content in the liver were determined. The results obtained are summarized in Table H below.

Table H.

Cholesterol-lowering effects of various doses of linoleic acid amides when administered orally to rats

within 8 weeks

Investigated connection 'Dose of the
examined
connection Quantity
the animals Choleste
in the Serur mirrors
η (mg%) cholesterol
salary in
the liver Lipid content
in the liver cholesterol before the after (mg / 100 g (g / 100 g feed (%) treatment treatment Liver) Control attempt 10 359 357 4035 10 24 C ₁₇ H ₃₁ CONH - CH -Y ~ \ 0.2 11th 368 184 740 4.79 0.1 10 360, . 206 110Ö 5.19 CH ₃ . 0.05 11th 357 331 1597 6.05 Ci ₇ H ₁₁ COOH 02 11th 360 364 4237 1200 Control experiment λ . 12th 344 '362 3329 11.77

continuation

Investigated connection Dose of
examined
connection
by doing Quantity
the animals Choleste
in the Serur mirrors
η (rag%) cholesterol
salary in
the liver Lipid content
in the liver
(g / 100 g
Liver) Cholesterol-
feed (%) before the
treatment after
treatment (mg / 100 g
Liver) 7.81
8.35
9.12 C ₁₇ H ₃₁ CONHCH ₂ - ^ ~ ^
OCH ₃ 0.2
0.1
0.05 11
11
11 345
345
350 OO Ul U)
VO VO O 601
798
1200 ■ 10.69
13.33 " C ₁₇ Ho ₁ COOH 0.2
0.1 8th
8th 349
355 306
362 3800
4200 10.24 10 362 360 4022 4.11
5.65
8.72 Control attempt 0.2
0.1
0.05 OO OO VO 360
355
355 141
158
172 729
800
1100 C ₁₇ H ₃₁ CONH - <(~ \ ~ OC ₂ H ₅ 5.13
6.06
8.01 Cl
f 0.02
0.1.
0.05 10
10
10 351
360
360 105
112
131 600
711
829 6.08 C ₁₇ H ₃₁ CONH ^ (~ ^>
CH ₃ 0.2 10 351 331 4129 12.06 C ₁₇ Ho ₁ COOH 0.1 10 351 352 4400

B. Investigation of the cholesterol-lowering effect of the compounds according to the invention upon administration these compounds on chickens

7 day old Hyland chickens were used to carry out the experiments. They were 7 days fed for a long time with commercial feed, the 1 percent by weight cholesterol and various of the invention Compounds in the amounts given in Table I below.

After the end of the test, the

Chickens killed, and following the procedure of R. G. H e r r m a η η, Proceedings of the Society for Experimental Biology and Medicine, Vol. 94, 1957, p. 503, the cholesterol levels in serum and in the liver and the lipid content in the liver is determined. The results obtained are in Table I below compiled.

Table I.

Cholesterol-lowering effects of various doses of linoleic acid amides given orally for 7 days

of chicken

Investigated connection

Dose of
examined
connection

by doing
Cholesterol-

feed (%)

Quantity

Cholesterol levels
in the serum

Cholesterol content
in the liver

Lipid content in the liver

Control attempt

C ₁₇ H ^ CO - NH - CH

/ 3-sitosterol.

0.2
1.0

5.0

100

(4826 ± 42.8)
mg%

78.3
54.9

41.0 ^:

100

(1.88 ± 0.15)
g / 100 g liver

71.9
45.9

22.0

100

(6.41 ± 0.24) g / 100 g liver

90.2 84.3

65.9

The serum cholesterol level, the liver cholesterol level and the liver lipid level are related to the comparison value 100.

C. Investigation of the antiatherogenic and anticholesterolemic effects of the compounds according to the invention in the administration of these compounds

on rabbits

Male white rabbits weighing 2 to 3 kg were placed in individual cages and with 50 g of commercial rabbit food and 20 g of cholesterol food, 60 percent by weight from the im Commercially available feed, 8 percent by weight cholesterol and 32 percent by weight hydrogenated Coconut oil, fed daily for 1 week. The test animals were divided into two groups and received various der for the following 9 weeks in addition to the cholesterol diet Compounds according to the invention in the amounts given in Table I below.

After the end of the experiment, blood was drawn from the heart of the animals under ether anesthesia removed, then the animals were sacrificed. The cholesterol content in the serum and in the liver and the lipid content in the liver was determined by the method of R. G. Herrmann, Proceedings of the Society for Experimental Biology and Medicine, Vol. 94, 1957, p. 503. The heart and aorta were carefully cut out, opened lengthways and fixed in 10% formalin and then stained with Sudan IV. These samples were rated on a scale from 0 to 4 (cf. D. K r i t c h e ν s k y et al, - Journal of Atherosclerosis Research, Vol. 1, 1961, p. 211).

The results obtained in these experiments are summarized in Table K below.

Table K

Antiatherogenic and anticholesterolemic effects of different doses of linoleic acid amides in 9-week-olds

oral administration to rabbits

Investigated connection

Dose in mg per animal per day number
the animals

Cholesterol levels

in the serum

(mg%) cholesterol content

in the liver
(g / 100 g liver)

, Degree of atherosclerosis

(Scale from 0 to 4)

Lipid content

in the liver

(g / 100 g liver)

Control attempt

C ₁₇ H ₃₁ CONHCH- ^
CH ₃

jS-Sitosterirt

Control attempt.

400 200 100.

800

C ₁₇ H ₃₁ CONHCH ₂

C ₁₇ H ₃₁ CONH

C ₁₇ H ₃₁ CONH

/ 3-sitosterol ...

0C, H

2 ** 5

400 400

400 800

6 6 6

5 6

5 6 1650

80
285
480

1220
2240

1210
920

1065
1570

1.76

0.32
0.73
0.64

2.45
1.77

1.05
1.32

Q, 89
2.12

1.28

0.04 0.72 1.07

1.98 1.26

0.84

Ul

0.90 1.88

6.03

4.29 4.68 4.60

7.87 6.41

5.51 5.18

4.90 6.99

D. Clinical investigation of N- (a-methylbenzyl) linoleic acid amide

6o

Clinical trials have been carried out with N- (a-methylbenzyl) linoleic acid amide, hereinafter referred to as AC-223 carried out to demonstrate the cholesterol-lowering effects of this compound upon its administration Show patient. The following results were obtained:.

Nine patients with hypercholesterolemia were given 2.25 g of AC-223 daily for several weeks, and the effect of this drug on serum cholesterol was determined.

Of the nine patients examined, three had hypertension and another three suffered from diabetes mellitus and the rest had arteriosclerosis, myocarin infarction and myxodema, respectively. The AC-223 was in the form of capsules, each 250 mg

309612/139

contained. The patients took three capsules with each meal. Before starting treatment the serum cholesterol level was determined twice with at least a one-week interval, and the mean was taken as the initial comparative value.

The blood samples were always taken from fasting patients, the treatment for the main diseases was held constant during the administration of AC-223. Regarding the food there was no special indication. The diabetes patients were constantly monitored, but without to be in the hospital.

As can be seen from the following Table L, the mean value for the cholesterol in the serum was the nine patients before treatment 282.2 mg / dl. 2 weeks after starting AC-223 administration the mean value of cholesterol in the serum had decreased to 249.0 mg / dl, and the percentage decrease was 11.7%. Four weeks after treatment, the mean was 224.6 mg / dL, and the percentage Decrease was 20.4%. After 4 weeks of administration, no case was found, other than none Decreased serum cholesterol.

The serum triglyceride was determined in five patients at the same time. However, it did not become measurable Effect on serum triglyceride content observed when AC-223 was administered.

In four hypertensive patients, administration of AC-223 did not reduce blood pressure achieved. Neither was there any change in normal blood pressure in other patients. In all cases, no adverse side effects at all were found.

Table L
Investigation of the effect of N- (a-methylbenzyl) linoleic acid amide on the cholesterol level in serum

A! Dead- gender Main disease before Cholesterol content in the treatment Through 2 weeks serum 4 weeks acceptance old
of the Pa 2 weeks right away cut . after that after that in% tient before before mg / dl mg / dl after treatment mg / dl 9 arteriosclerosis mg / dl mg / dl 305 311 acceptance 252 (-17.4) 41 310 300 342 271 in % 239 • (-30.1) 9 " Diabetes mellitus 348 336 275 198 180 (-34.5) 54 C? Hypertension 290 259 294 254 (+ 2.0) 59 9 Diabetes mellitus 294 293 281 (-20.8) 258 (-11.9) 39 9 Myxodema 293 232 226 (-28.0) 208 (-10.3) 51 C? Hypertension 246 218 248 238 (-13.6) 224 (-9.7) 40 <? Myocardial infarction 252 244 282 240 (-4.1) 226 (-19.9) 56 9 Hypertension 280 284 269 222 (-2.6) 210 (-21.9) 40 C? Diabetes mellitus 266 272 282.2 249.0 (-4.0) 224.6 (-20.4) 45 · average (-14.9) (-17.5) (-11.7)

Claims (2)

Patent claims:
1. Linoleic acid amides of the general formula Q ₇ H ₃₁ CO-N IO wherein a) R _{1 is} a phenyl monosubstituted by chlorine or bromine, a phenyl disubstituted by chlorine and the methyl group, a 3-trifluoromethylphenyl, a 4-methoxyphenyl, a cyclohexyl optionally substituted by a hydroxyl or methoxy group, a 4 Ethoxycyclohexyl, an α-position optionally in 2,3,4- or through a hydroxyl or methoxy group through a methyl group or a 2-position substituted benzyl radical or an α-alkyl- (C ₂ -C ₄ ) -benzyl radical, R _{2 represents} a hydrogen atom or b) R ₁ and R ₂ each represent a benzyl radical. 2. Process for the preparation of linoleic acid amides of the general formula.