FR2518992A1 - 1-Amino-omega-aryloxy substd. ethane and propane derivs. - with calcium antagonising activity e.g. for treating angina - Google Patents

Abstract

Amines of formula (I) and their acid addn. salts are new (R is H, halo, methyl, hydroxy, 1-4C alkoxy or benzyloxy, n is 1 or 2, m is 2 or 3. A is COCH2CH2, CHOH.CH2CH2, CH2CH2CH2, CHOH.C(CH3)2CH2 or CO.C(CH3)2.CH2 with Ar attached to the left-hand side. R1, R2 is H, 1-4C alkyl, H, 5-6C cycloalkyl or H, 4-8C cycloalkylalkyl (except where A is CO.C(CH3)2 CH2 or CHOH.C(CH3)2.CH2); or is di(1-4C) alkyl, or together with N completes pyrrolidino, piperidino, hexamethyleneimino or morpholino. Ar is gp. (b) or (c), R3 is halo, nitro or methyl. R4 is 1-4C alkoxy, p is 0-2, q is 0-4, (p+q not over 4) but when A is COCH2CH2 or CHOH.CH2CH2, p and q cannot both be zero). Also new are the intermediates (III) and (V) (R'1, R'2 is di(1-4C) alkyl or completes a heterocyclic ring). (I) have calcium antagonising activity so are useful as antiangina, antiarrhythmic, antihypertensive and vasodilating agents. In mice, intravenous LD50 values were up to about 40 mg/kg and the usual oral dose is up to 500 mg taken 1-5 times a day.

Description

 The present invention relates to novel aromatic derivatives carrying an aminoalkoxy chain and their pharmaceutically acceptable salts, as well as the process for the preparation of these derivatives and salts and their therapeutic application.

dans laquelle - R représente un atome d'hydrogène ; un ou deux atomes d'halogène ; ou un ou
deux groupes méthyle, hydroxyle, alkyloxy de 1 à 4 atomes de carbone ou
benzyloxy - R et R2 représentent chacun un groupe alkyle comportant de 1 à 4 atomes de
carbone, ou forment conjointement avec l'atome d'azote auquel ils sont liés
un groupe hétérocyclique choisi parmi les suivants : pyrrolidino, pipéridino,
morpholino - m prend la valeur 2 ou 3 - R3 représente un groupe alkyloxy comportant de 1 à 4 atomes de carbone ; - n prend la valeur 1, 2 ou 3 ; et - A représente un enchaînement propyl-one-1
123 (-C0-CH2-CH2-) ou hydroxy-1 propyle

le groupe aromatique portant la chaîne aminoalcoxy étant fixé
en position 1 de ces enchaînements.More specifically, the novel derivatives according to the invention correspond to the general formula

in which - R represents a hydrogen atom; one or two halogen atoms; or one or
two methyl, hydroxyl, alkyloxy groups of 1 to 4 carbon atoms or
benzyloxy - R and R2 each represent an alkyl group having from 1 to 4 carbon atoms
carbon, or together with the nitrogen atom to which they are bound
a heterocyclic group chosen from the following: pyrrolidino, piperidino,
morpholino - m is 2 or 3 - R3 is an alkyloxy group having 1 to 4 carbon atoms; n is 1, 2 or 3; and - A represents a sequence propyl-one-1
123 (-C0-CH2-CH2-) or 1-hydroxypropyl

the aromatic group carrying the aminoalkoxy chain being fixed
in position 1 of these sequences.

 The pharmaceutically acceptable salts of the derivatives of formula (I) are, for their part, constituted by the addition salts of mineral acid, such as hydrochloric acid, or of organic acid, such as oxalic acid, of said derivatives. of formula (I).

dans laquelle R, R1, R2, R3, m et n ont les mêmes significations que dans la formule (I).The present invention also relates to the process for preparing these derivatives and their salts. More precisely
The derivatives of formula (I) for which A represents the propyl-one-1 chain are obtained by reduction, preferably by nickel
from Raney and in a hydroalcoholic medium, compounds of formula

in which R, R 1, R 2, R 3, m and n have the same meanings as in formula (I).

B / The derivatives of formula (I) for which A represents the 1-hydroxypropyl chain, are obtained
- or by reduction of the compounds of formula (II), by the complex
sodium borohydride - pyridine, especially in an alcoholic medium and
in the presence of preferably concentrated soda, the latter being in
at least stoichiometric quantity when R in formula (II) represents
contains a hydroxyl group, and in quantity at least two times stoichi
metric when R represents two hydroxyl groups.

or by reduction with sodium borohydride alone, preferably
alcoholic medium of the derivatives of formula (I) for which A represents
the propyl-one-1 chain and whose preparation is point Al
above.

dans laquelle R3, n, m et

ont les mêmes significations que dans la formule (II) et R' a les memes significations que R dans (II), sans toutefois pouvoir représenter un ou deux groupes hydroxyle.C / The derivatives of formula (I) for which A represents the 1-hydroxy-propyl group and R has the same meanings as above, but can not however represent one or two hydroxyl groups, are also obtained by reduction with borohydride. excess sodium of compounds of formula

in which R3, n, m and

have the same meanings as in formula (II) and R 'has the same meanings as R in (II), without being able to represent one or two hydroxyl groups.

 When R 'in the formula (IIa) represents one or two benzyloxy groups, this reduction is optionally followed by a catalytic debenzylation preferably with palladium on carbon, for example at 10%, which also makes it possible to obtain the derivatives of formula (I) for which A represents the 1-hydroxypropyl chain and R represents one or two hydroxyl groups.

formule (II), respectivement avec ies aiaenyaes aromatiques ae Iormuie

dans laquelle R a les mêmes significations que dans la formule (II). The compounds of formula (II) and those of formula (IIa) are obtained by condensation of the compounds of formula in which R n, m and

formula (II), respectively with the aromatic aiaenyaes

in which R has the same meanings as in formula (II).

 The condensation may be carried out either in ethanol, in the presence of sodium ethoxide, or in methanol in the presence of sodium methoxide, or in the alcohol in the presence of aqueous sodium hydroxide when R in the formula (IV), represents one or two hydrococyl groups.

dans laquelle m et

ont les mêmes significations que dans la formule (III), respectivement avec les acetopnenones de formule

dans laquelle n et R3 ont les mêmes significations que dans la formule (III).The compounds (III) are, for their part, obtained by condensation of the derivatives of formula

in which m and

have the same meanings as in formula (III), respectively with the acetopnenones of formula

in which n and R3 have the same meanings as in formula (III).

This condensation is preferably carried out in an aprotic organic solvent, such as acetone, acetonitrile or DMF, in the presence of potassium carbonate.

 D / The salts of the derivatives of formula (I) are obtained in a conventional manner and for example by the action of an inorganic or organic acid in solution in a suitable solvent on said derivatives of formula (I) also in solution in a suitable solvent .

 The following preparations are given as non-limiting examples to illustrate the invention.

Example 1: 3,6-dimethoxy (2-piperidinoethoxy) oxalate acetophenone (III)
Code number: 45
A suspension of 78.5 g of 3,6-dimethoxy-2-hydroxy-acetophenone (VI), 110.5 g of piperidinoethyl chloride hydrochloride (V) and 165.6 g of carbonate is refluxed for 24 hours. of potassium in 620 ml of acetonitrile. Then the mixture is filtered, the filtrate is evaporated, the residue is taken up in methylene chloride, washed with 1 N aqueous sodium hydroxide solution, then with water, dried over sodium sulfate, filtered and the filtrate evaporated. The residue is dissolved in acetone, an acetonic solution of oxalic acid is added and the precipitate obtained is filtered off. The expected product is thus obtained with a yield of 52% and whose characteristics are listed in Table I below.

 By the same method, but from the corresponding reagents, the compounds of formula (III) appearing in Table I and of code numbers 46 to 54 are obtained.

TABLE I

<SEP> Weight <SEP> Item <SEP> ANALYSIS <SEP> ELEMENTARY
<tb> Number <SEP> Formula
<tb><SEP> of <SEP>#<SEP> m <SEP> (R3) n <SEP> mole- <SEP> of <SEP> or <SEP> SPECTRUM <SEP> NMR
<Tb>

<SEP> gross
<tb><SEP> Code <SEP> cular <SEP> merge
<tb><SEP> (C)
<tb><SEP>%<SEP> C <SEP> H <SEP> N
<tb><SEP> 45 <SEP>#<SEP> 2 <SEP> 3,6-diOCH3 <SEP> C19H27NO8 <SEP> 397.41 <SEP> 155 <SEP> Cal. <SEP> 57.42 <SEP> 6.85 <SEP> 3.52
<tb><SEP> Tr. <SEP> 56.45 <SEP> 6.32 <SEP> 3.53
<tb><SEP><SEP> Spectrum of <SEP> NMR. <SEP> (CDCl3) <SEP>#<SEP> pom = 6.5, <SEP> d <SEP> and
<tb><SEP> 6.9, <SEP> d <SEP> (J = 9Hz) <SEP> (2 <SEP> H <SEP> aromatic <SEP> in <SEP> 4 <SEP> and
<tb><SEP> 46 <SEP>"<SEP> 3 <SEP> 3,6-DiOCH3 <SEP> C18H27NO4 <SEP> 321.40 <SEP> Oil <SEP> 5) <SEP>: <SEP> 4 , 05, <SEP> t <SEP>(-O-CH-2);<SEP> 3.75 <SEP> and <SEP> 3.85, <SE> s
<tb><SEP> (2CH-3O) <SEP>;<SEP> 2.5 <SEP> s <SEP> (CH-3CO) <SEP>;<SEP> 2.4 <SEP> m
<tb><SEP>(#)<SEP>;<SEP> 1.6, <SEP> m <SEP> (4CH-2).
<Tb>

<SEP> NMR <SEP> (CDCl3) <SEP>#<SEP> ppm = 6.55, <SEP> d <SEP> and <SEP> 6.9, <SEP> d
<tb><SEP> (J = 9Hz) <SEP> (2 <SEP> H <SEP> aromatic <SEP> in <SEP> 4 <SEP> and <SEP>5);
<tb><SEP> 47 <SEP>#<SEP> 2 <SEP>"<SEP> C16H23NO4 <SEP> 293.35 <SEP>"<SEP> 4.08, <SEP> t <SEP> (OCH2) <SEP>;<SEP> 3.78 <SEP> and <SEP> 3.85 <SEP> s <SEP>(2CH3O);
<tb><SEP> 2.9, t <SEP>(#)<SEP>;<SEP> 2.6, <SEP> m <SEP>(#)<SEP>;
<tb><SEP> 2.5, s <SEP> 9CH2CO) <SEP>;<SEP> 1.9, <SEP> m <SEP>(#)
<tb><SEP> HMN <SEP> (CDCl3) <SEP>#<SEP> ppm = 6.6 <SEP> and <SEP> 6.9, d <SEP> (J = 9Hz)
<tb><SEP> (2 <SEP> H <SEP> aromatic <SEP> in <SEP> 4 <SEP> and <SEP> 5) <SEP>;<SEP> 4.10, <SEP> t
<tb><SEP> 48 <SEP>#<SEP> 2 <SEP>"<SEP> C16H25NO4 <SEP> 295.37 <SEP>"<SEP> (O-CH-2) <SEP>;<SEP> 3.75 <SEP> and <SEP> 3.82, <SEP> s <SEP>(2CH-30);
<tb><SEP> 2.9 <SEP> t <SEP> (CH-2-N) <SEP>;<SEP> 2.65 <SE> g
<tb><SEP>(#)<SEP>;<SEP> 2.5 <SEP> A <SEP>(CH3CO);<SEP> 1.05 <SEP> t <SEP> (2CH-3)
<tb> FTABLEAU I (continued)

<SEP> Weight <SEP> Item <SEP> ANALYSIS <SEP> ELEMENTARY
<tb> Number <SEP> Formula
<tb><SEP> of <SEP>#<SEP> m <SEP> (R3) n <SEP> mole- <SEP> of <SEP> or <SEP> SPECTRUM <SEP> NMR
<Tb>

<SEP> gross
<tb><SEP> Code <SEP> oulaire <SEP> merge
<tb><SEP> (C)
<tb><SEP> NMR <SEP> (CDCl3) <SEP>#<SEP> ppm = 6.55 <SEP> and <SEP> 6.9, d <SEP> (J = 9Hz)
<tb><SEP> (2 <SEP> H <SEP> aromatic <SEP> in <SEP> 4 <SEP> and <SEP>5);<SEP> 4.10, <SEP> t <SEP>(OCH2);
<tb><SEP> 49 <SEP>#<SEP> 2 <SEP> 2,6-diOCH3 <SEP> C16H23NO5 <SEP> 309.21 <SEP> Oil <SEP> 3.78 <SEP> and <SEP> 3.8, <SEP> s <SEP> (2CH-30) <SEP>;<SEP> 3,7, <SEP> m
<tb><SEP>(#)<SEP>;<SEP> 2.7, <SEP> T <SEP>(#);<SEP> 2.5, <SEP> s
<tb><SEP>(CH-3CO);<SEP> 2.6 <SEP> m <SEP>(#)
<tb><SEP> NMR <SEP> (CDCl3) <SEP>#SEP> ppm = 6, <SEP> 10, <SEP> s <SEP> (2 <SEP> H <SEP>)
<SEP> ques <SEP>);<SEP> 4.1, <SEP> t <SEP> (-OCH-2) <SEP>;<SEP> 3.76 <SEP> and <SEP> 3.80, <SEP> S
<tb><SEP> 50 <SEP>#<SEP> 2 <SEP> 4,6-DiOCH3 <SEP> C17H25NO4 <SEP> 307.38 <SEP>"<SEP> (20CH-3) <SEP>;<MS> 2.45 <SEP> s <SEP> (-COCH-3) <SEP>;<SEP> 2.7, <SEP> t
<tb><SEP> (CH-2-N) <SEP>;<SEP> 2,4 <SEP> and <SEP> 1,5 <SEP> m <SEP>(#)
<tb><SEP> NMR <SEP> (CDCl3) <SEP>#<SEP> ppm = 6.9 <SEP> to <SEP> 7.2, M <SEP> (3 <SEP> H <SEP> aro
<SEP> topics) <SEP>;<SEP> 4,12, <SEP> t <SEP> (OCH-2) <SEP>;<SEP> 3.85, <SE> S
<tb><SEP> 51 <SEP>#<SEP>"<SEP> 3-OCH3 <SEP> C16H23NO3 <SEP> 277.35 <SEP>"<SEP> (OCH-3) <SEP>;<SEP> 2.8, <SEP> t <SEP>(#)<SEP>;<SEP> 2,6, <SEP> q
<tb><SEP>(#)<SEP>;<SEQ> 2.63, <SEP> s <SEP>(CH-3CO);<SEP> 1.0, <SEP> t <SEP> (2CH-3)
<tb><SEP> NMR <SEP> (CDCl) <SEP> s <SEP> ppm = 7.28, <SEP> t <SEP> (H <SEP> Aromatic
<tb><SEP> in <SEP> 4) <SEP>;<SEP> 6.6, <SEP> d <SEP> (2 <SEP> H <SEP> aromati
<SEP> 52 <SEP>#<SEP>"<SEP> 6-OCH3 <SEP> C16H23NO3 <SEP> 277.35 <SEP>"<SEP> ques <SEP> in <SEP> 3 <SEP> and <SEP > 5) <SEP>;<SEQ> 4,12, <SEP> t <SEP> (CH-2O) <SEP>;<SEP> 3.82
<tb><SEP> s <SEP> (CH-30) <SEP>;<SEP> 2.72 <SEP> t <SEP>(#)<SEP>;<SEP> 2.5 <SEP> S
<tb><SEP> (CH-3CO).
<Tb>

TABLE (I) (continued)

<SEP> Weight <SEP> Item <SEP> ANALYSIS <SEP> ELEMENTARY
<tb> Number <SEP> Formula
<tb><SEP> of <SEP>#<SEP> m <SEP> (R3) n <SEP> mole- <SEP> of <SEP> or <SEP> SPECTRUM <SEP> NMR
<Tb>

<SEP> gross
<tb><SEP> Code <SEP> cular <SEP> merge
<tb><SEP> (C)
<tb><SEP> NMR <SEP> (CDCl3) <SEP>#<SEP> ppm = 6.58 <SEP> and <SEP> 6.9, <SEP> d <SEP> (2 <SEP> H)
<tb><SEP> aromatic <SEP> in <SEP> 4 <SEP> and <SEP>5);<SEP> 4.12, t <SEP> (OCH-2) <SEP>;
<tb><SEP> 53 <SEP>#<SEP> 2 <SEP> 3,6-diOCH3 <SEP> C14N21NO4 <SEP> 267,32 <SEP> Oil <SEP> 3,75 <SEP> and <SEP> 3.8f2, s <SEP> (2CH-30) <SEP>;<SEP> 2.65, <SE> t
<tb><SEP> (CH-2-N) <SEP>;<SEP> 2.5, <SEP> s <SEP> (CM3CO) <SEP>;<SEP> 2.32, <SEP> s
<tb><SEP>(#)
<tb><SEP> NMR <SEP> (CDCl30 <SEP>#<SEP> ppm = <SEP> 6.3 <SEP> s <SEP> (H <SEP> Aromatic
<tb><SEP> in <SEP>5);<SEP> 4.18, <SEP> t (OCH-2) <SEP>;<SEP> 3.78 <SEP>, <SEP> 3.80 <SEP> and <SEP> 3.9,
<tb><SEP> 54 <SEP>#<SEP>"<SEP> 3,4,6-triOCH3 <SEP> C17H27NO5 <SEP> 325.39 <SEP>"<SEP> s <SEP> (3CH-3 ); <SEP> 2.9 <SEP> t <SEP>(#)<SEP>;<SEP> 2.6 <SEP> Q
<tb><SEP>(#)<SEP>;<SEP> 1.05, <SEP> t <SEP>(#)
<Tb>
Example 2: (4-chloro-phenyl) -3,6-dimethoxy-2-piperidinoethoxy-2-phenyl-1-phenyl
propene-2 one-1 (II)
umero of code: 25
A mixture of 15.4 g of 3,6-dimethoxy (piperidinoethoxy) -2-acetophenone (III) obtained in the preceding example and 7.1 g of parachlorobenzaldehyde (IV) is allowed to stir at ambient temperature for 4 hours. 0.5 g of sodium in 150 ml of methanol. Then it is diluted with water, extracted with ethyl acetate, washed with water, the organic phase is evaporated and the residue is chromatographed on a silica column. Elution with pure chloroform and then with the chloroform mixture ( 98%) - methanol (2%), there is obtained 10.2 g (yield = 48%) of the expected product (oily) whose characteristics are listed in Table II below.

 By the same method, but from the corresponding reagents, the compounds of code numbers 24, 26 to 28, 43 and 44 appearing in Table II are obtained.

TABLE II

<SEP> Weight <SEP> Item <SEP> ANALYSIS <SEP> ELEMENTARY
<tb> Number <SEP> Formula
<tb><SEP> of <SEP>#<SEP> R <SEP> m <SEP> (R3) n <SEP> mol- <SEP> of <SEP> SPECTRUM <SEP> NMR
<Tb>

<SEP> gross
<tb><SEP> Code <SEP> cular <SEP> merge <SEP> SPECTER <SEP> IR
<Tb>

<SEP> (C)
<tb><SEP> NMR <SEP> (CDCl3) <SEP>#<SEP> ppm = 6.5 <SEP> to <SEP> 7.6 <SEP> (7 <SEP> H <SEP> aroma
<SEP> ticks <SEP> and <SEP> CH = CH) <SEP>;<SEP> 4.05 <SEP> t <SEP> (OCH-2) <SEP>;<SEP> 3,7
<tb><SEP> 24 <SEP>#<SEP> H <SEP> 2 <SEP> 3,6-diOCH3 <SEP> C24H29NO4 <SEP> 395.48 <SEP> Oil <SEP> and <SEP> 3, 85 <SEP> s <SEP> (2CH-30) <SEP>;<SEP> 2.6 <SEP> t <SEP> (CH2-N) <SEP>;
<tb><SEP> 2,4 <SEP> and <SEP> 1,5 <SEP> m <SEP>(#)
<tb><SEP> NMR <SEP> (CDCl3) <SEP>#<SEP> ppm = 7.45, <SEP> s <SEP> (4 <SEP> protons)
<tb><SEP> 25 <SEP>"<SEP> 4-Cl <SEP>"<SEP>"<SEP> C24H28ClNO4 <SEP> 429.93 <SEP>"<SEP> aromatic <SEP>: <SEP>#)<SEP>;<SEP> of <SEP> 6.60 <SEP> to
<tb><SEP> 7.60, <SE> m <SEP> (4 <SEP> protons <SEP>: <SEP> 2 <SEP> aromatic <SEP> and
<tb><SEP> -CH = CH-) <SEP>;<SEP> 4.33, <SEP> t <SEP> (O-CH-2) <SEP>;<SEP> 3.78 <SEP> s
<tb><SEP> and <SEP> 3.90, <SEP> s <SEP> (2OCH-3) <SEP>;<SEP> 2.90, <SEP> m
<tb><SEP>(#)<SEP>;<SEP> 1.70 <SEP> m <SEP>(#)
<tb><SEP> IR <SEP>: <SEP> tapes <SEP> -CO-CH = CH- <SEP> to <SEP> 1650 <SEP> and
<tb><SEP> 1630 <SEP> cm-1
<tb><SEP> NMR <SEP> (CDCl3) <SEP>#<SEP> ppm = 6.5 <SEP> to <SEP> 7.6, <SEP> m <SEP> (6 <SEP> H <SEP> aro
<SEP> MATERIALS <SEP> and <SEP> CH = CH) <SEP> 4.05 <SEP> t <SEP> (OCH-2) <SEP>;
<tb><SEP> 26 <SEP>"<SEP> 4-F <SEP>"<SEP>"<SEP> C24H28FNO4 <SEP> 413.47 <SEP>"<SEP> 3.65 <SEP> and <SEP> 3.78 <SEP> s <SEP> (2CH3O) <SEP>;<SEP> 2.55, <SEP> t
<tb><SEP> (CH2-N) <SEP>;<SEP> 2.35 <SEP> and <SEP> 1.4, <SEP> m <SEP>(#)
<tb> TABLE II

<SEP> Weight <SEP> Item <SEP> ANALYSIS <SEP> ELEMENTARY
<tb> Number <SEP> Formula
<tb><SEP> of <SEP>#<SEP> R <SEP> m <SEP> (R3) n <SEP> mol- <SEP> of <SEP> SPECTRUM <SEP> NMR
<Tb>

<SEP> gross
<tb><SEP> Code <SEP> cular <SEP> merge <SEP> SPECTER <SEP> IR
<Tb>

<SEP> (C)
<tb><SEP> NMR <SEP> (CDCl3) <SEP>#<SEP> ppm = 6.5 <SEP> to <SEP> 7.5 <SEP> m <SEP> (6 <SEP> H <SEP > aro
<SEP> matters <SEP> and <SEP> CH = CH) <SEP>;<SEP> 4.1, t <SEP> (OCH2) <SEP>;
<tb><SEP> 27 <SEP>#<SEP> 4-CH3 <SEP> 2 <SEP> 3,6-diOCH3 <SEP> C25H31NO4 <SEP> 410.51 <SEP> Oil <SEP> 3.7 <SEP> and <SEP> 3.82 <SEP> s <SEP> (2CH3O)) <SEP>;<SEP> 2.6, <SE> t
<tb><SEP> (CH2-N) <SEP>;<SEP> 2.38 <SEP> and <SEP> 1.5 <SEP> m <SEP>(#)
<tb><SEP> NMR <SEP> (CDCl3) <SEP>#<SEP> ppm = 6.5 <SEP> to <SEP> 7.6, m <SEP> (6 <SEP> H <SEP> aro
<SEP> matters <SEP> and <SEP> CH = CH); <SEP> 4.1, t <SEP> (OCH2), 3.7,
<tb><SEP> 28 <SEP>"<SEP> 4-OCH3 <SEP> 2 <SEP>"<SEP> C25H31NO5 <SEP> 425.51 <SEP>"<SEP> 3.78 <SEP> and <MS> 3.82 <SEP> s <SEP> (3CH3O) <SEP>;<SEP> 2.6, <SEP> t
<tb><SEP> (CH2-N) <SEP>;<SEP> 2.4 <SEP> and <SEP> 1.4, <SEP> m <SEP>(#)
<tb><SEP> C24H34ClNO5 <SEP>% <SEP> C <SEP> H <SEP> N
<tb><SEP> 29 <SEP>"<SEP> 2-OH <SEP> 2 <SEP>"<SEP> + <SEP> 4% <SEP> H2O <SEP> 470.81 <SEP> 88
<tb><SEP> hydrochloride <SEP> Cal. <SEP> 61.22 <SEP> 7.73 <SEP> 2.98
<tb><SEP> Tr. <SEP> 61.50 <SEP> 7.93 <SEP> 2.97
<tb><SEP> + <SEP> 4 <SEP>% <SEP> H2O <SEP> NMR <SEP> (CDCl3) <SEP>#<SEP> ppm = 7.45 <SEP> s <SEP> (OH ); <SEP> 6.5 <SEP> a
<tb><SEP> 7.4, <SEP> m <SEP> (6H <SEP> Aromatic <SEP> and <SEP> CH = CH) <SEP>;
<tb><SEP> 30 <SEP>#<SEP> 3-OH <SEP>"<SEP>"<SEP> C24H29NO5 <SEP> 411.48 <SEP> Oil <SEP> 4.1, t <SEP> (OCH2) <SEP>;<SEP> 3.65 <SEP> and <SEP> 3.8, <SEP> s <SEP>(2CH3O);
<tb><SEP> 2.7, t <SEP> (CH2-N) <SEP>, <SEP> 2.5 <SEP> and <SEP> 1.5, <SEP> m <SEP>(#)
<tb> TABLE II (continued0

<SEP> Weight <SEP> Item <SEP> ANALYSIS <SEP> ELEMENTARY
<tb> Number <SEP> Formula
<tb><SEP> of <SEP>#<SEP> R <SEP> m <SEP> (R3) n <SEP> mol- <SEP> of <SEP> SPECTRUM <SEP> NMR
<Tb>

<SEP> gross
<tb><SEP> Code <SEP> cular <SEP> merge <SEP> SPECTER <SEP> IR
<Tb>

<SEP> (C)
<tb><SEP> NMR <SEP> (CDCl3) <SEP>#<SEP> ppm = 6.5 <SEP> to <SEP> 7.4 <SEP> m <SEP> (6 <SEP> pro
<SEP> aromatic <SEP> tones <SEP> and <SEP> -CH = CH-) <SEP>;<SEP> 4.20, <SEP> t
<tb><SEP> 31 <SEP>#<SEP> 4-OH <SEP> 2 <SEP> 3,6-diOCH3 <SEP> C24H29NO5 <SEP> 411.48 <SEP> 93 <SEP> (-OCH2) <SEP>;<SEP> 3.72 <SEP> and <SEP> 3.82, <SEP> s <SEP> (2-OCH3) <SEP>;
<tb><SEP> 2,6 <SEP> and <SEP> 1,55 <SEP> m <SEP>(#)
<tb><SEP> NMR <SEP> (CDCl3) <SEP>#<SEP> ppm = 6.6 <SEP> to <SEP> 7.6, <SEP> m <SEP> (OH, 6H)
<tb><SEP> aromatic <SEP> and <SEP> CH = CH) <SEP>;<SEP> 4.1 <SEP> and <SEP>(OCH2);
<tb><SEP> 32 <SEP>"<SEP>"<SEP> 3 <SEP> 3,6-DiOCH3 <SEP> C25H31NO5 <SEP> 425.51 <SEP> Oil <SEP> 3.7 <SEP> and <SEP> 3.9, <SEP> s <SEP>(2CH3O);<SEP> 3, <SEP> m <SEP>(#)<SEP>;
<tb><SEP> 2, m <SEP> (CH2 <SEP> and <SEP>#)
<tb><SEP> NMR <SEP> (CDCl3) <SEP>#<SEP> ppm = 6.4 <SEP> to <SEP> 7.2 <SEP> m <SEP> (OH, <SEP> 6 <SEP> H)
<tb><SEP> aromatic <SEP> and <SEP> CH = CH); <SEP> 4.05 <SEP> t <SEP>(OCH2);
<tb><SEP> 33 <SEP>#<SEP>"<SEP> 2 <SEP>"<SEP> C25H27NO5 <SEP> 397.45 <SEP>"<SEP> 3.6 <SEP> and <SEP> 3.8 <SEP> s <SEP> (2CH3O) <SEP>;<SEP> 2.9, <SEP> t <SEP>(CH2-N);
<tb><SEP> 2.6 <SEP> and <SEP> 1.7, <SEP> m <SEP>(#)
<tb><SEP> NMR <SEP> (CDCl3) <SEP>#<SEP> ppm = 9.3 <SEP> s <SEP>(OH);<SEP> 6.5 <SEP> to <SEP> 7.4 <SEP> m
<tb><SEP> (6 <SEP> H <SEP> aromatic <SEP> and <SEP> CH = CH); <SEP> 4.1, t <SEP>(OCH2);
<tb><SEP> 34 <SEP>#<SEP>"<SEP>"<SEP>"<SEP> C23H29NO5 <SEP> 399.47 <SEP>"<SEP> 3.7 <SEP> and <SEP> 3.82, <SEP> s <SEP> (2CH3O) <SEP>;<SEP> 2.95 <SEP> t
<tb><SEP> (CH2-N) <SEP>;<SEQ> 2.65 <SEP> q <SEP> and <SEP> 1.0, t <SEP>(#)
<tb> TABLE II (continued)

<SEP> Weight <SEP> Item <SEP> ANALYSIS <SEP> ELEMENTARY
<tb> Number <SEP> Formula
<tb><SEP> of <SEP>#<SEP> R <SEP> m <SEP> (R3) n <SEP> mol- <SEP> of <SEP> SPECTRUM <SEP> NMR
<Tb>

<SEP> gross
<tb><SEP> Code <SEP> cular <SEP> merge <SEP> SPECTER <SEP> IR
<Tb>

<SEP> (C)
<tb><SEP> NMR <SEP> (CDCl3) <SEP>#<SEP> ppm = <SEP> 6.6 <SEP> to <SEP> 7.4, <SEP> m <SEP> (OH, <SEP> 6H)
<tb><SEP> aromatic <SEP> and <SEP> CH = CH); <SEP> 4.1, t <SEP> (OCH2) <SEP>;
<tb><SEP> 35 <SEP>#<SEP> 4-OH <SEP> 2 <SEP> 3,6-diOCH3 <SEP> C23H27NO6 <SEP> 413.45 <SEP> Oil <SEP> 3.7 <SEP> and <SEP> 3.85, <SEP> s <SEP>(2CH3O);<SEP> 3.75, m <SEP> and <SEP> 2.6, m
<tb><SEP>(#)
<tb><SEP>%<SEP> C <SEP> H <SEP> N
<tb><SEP> 36 <SEP>#<SEP>"<SEP>"<SEP> 3,4,6-triOCH3 <SEP> C25H32ClNO6 <SEP> 477.97 <SEP> 214
<tb><SEP> Cal. <SEP> 62.82 <SEP> 6.75 <SEP> 2.93
<tb><SEP> (hydrochloride) <SEP> Tr. <SEP> 62.92 <SEP> 6.94 <SEP> 2.92
<tb><SEP>%<SEP> C <SEP> H <SEP> N
<tb><SEP> 37 <SEP>"<SEP>"<SEP>"<SEP> 4,5,6-triOCH3 <SEP> C25H32ClNO6 <SEP> 477.97 <SEP> 235
<tb><SEP> Cal. <SEP> 62.82 <SEP> 6.75 <SEP> 2.93
<tb><SEP> Tr. <SEP> 60.45 <SEP> 6.66 <SEQ> 2.97
<tb><SEP> NMR <SEP> (CDCl3) <SEP>#<SEP> ppm = 6.4 <SEP> to <SEP> 7.4 <SEP> m <SEP> (OH, <SEP> 7 <SEP> H)
<tb><SEP> aromatic <SEP> and <SEP> CH = CH); <SEP> 4.1, t <SEP>(OCH2);
<tb><SEP> 38 <SEP>#<SEP>"<SEP>"<SEP> 6-OCH3 <SEP> C23H27NO4 <SEP> 381.45 <SEP> - <SEP> 3.78 <SE> s <SEP> (CH3O) <SEP>;<SEP> 2.88, <SEP> t <SEP> (CH2-N) <SEP>;<SEP> 2.5
<tb><SEP> and <SEP> 1,4, <SEP> m <SEP>(#)
<tb> TABLE II (continued)

<SEP> Weight <SEP> Item <SEP> ANALYSIS <SEP> ELEMENTARY
<tb> Number <SEP> Formula
<tb><SEP> of <SEP>#<SEP> R <SEP> m <SEP> (R3) n <SEP> mol- <SEP> of <SEP> SPECTRUM <SEP> NMR
<Tb>

<SEP> gross
<tb><SEP> Code <SEP> cular <SEP> merge <SEP> SPECTER <SEP> IR
<Tb>

<SEP> (C)
<tb><SEP> NMR <SEP> (CDCl3) <SEP>#<SEP> ppm = 6.4 <SEP> to <SEP> 7.4, <SEP> m <SEP> (4 <SEP> H <SEP> aro
<SEP> matters <SEP> and <SEP> CH = CH) <SEP>;<SEP> 6.2, s <SEP>(OH);<SEP> 6, <SEP> 12,
<tb><SEP> 39 <SEP>#<SEP> 4-OH <SEP> 2 <SEP> 4,6-diOCH3 <SEP> C24H29NO5 <SEP> 411.48 <SEP> Oil <SEP> s <SEP> (2 <SEP> H <SEP> aromatics <SEP> in <SEP> 3 <SEP> and <SEP> 5) <SEP>;<SEP> 4.1, <SEP> t
<tb><SEP> (OCH2) <SEP>;<SEP> 3.7 <SEP> and <SEP> 3.8 <SEP> s <SEP> (2CH3O) <SEP>;<SEP> 2.7 <SEP> t
<tb><SEP> (CH2-N) <SEP>;<SEP> 2.5, <SEP> m <SEP> and <SEP> 1.4, m <SEP>(#)
<tb><SEP> NMR <SEP> (CDCl3) <SEP>#<SEP> ppm = 6.5 <SEP> to <SEP> 7.6 <SEP> m <SEP> (OH, <SEP> 6 <SEP> H
<tb><SEP> aromatic <SEP> and <SEP> CH = CH) <SEP>;<SEQ> 4.08, t <SEP>(OCH2);
<tb><SEP> 40 <SEP>#<SEP>"<SEP>"<SEP> 3,6-diOCH3 <SEP> C21H25NO5 <SEP> 371.42 <SEP> 163 <SEP> 3.65 <SEP> and <SEP> 3.8, a <SEP> (20CH3) <SEP>;<SEP> 2.7, t
<tb><SEP>(#)<SEP>;<SEP> 2.30 <SEP> s <SEP>(#)
<tb><SEP> NMR <SEP> (CDCl3) <SEP>#<SEP> ppm = 6.6 <SEP> to <SEP> 7.4 <SEP> m <SEP> (OH, <SEP> 4 <SEP> H
<tb><SEP> aromatic <SEP> and <SEP> CH = CH); <SEP> 6.3 <SEP> s <SEP> (H <SEP> aromati
<SEP> 41 <SEP>#<SEP>"<SEP>"<SEP> 3,4,6-triOCH3 <SEP> C24H31NO6 <SEP> 429.50 <SEP> 143 <SEP> ques <SEP> in <SEP >5);<SEP> 4.1, t <SEP> (OCH2) <SEP>;<SEP> 3,7,3,8 <SEP> and <SEP> 3,9
<tb><SEP> s <SEP> (3CH3O) <SEP>;<SEP> 2.9, <SEP> t <SEP>(#)<SEP>;<SEP> 2.62 <SE> q <SEP> and
<tb><SEP> 1.0, <SEP> t <SEP>(#)
<tb><SEP> NMR <SEP> (CDCl3) <SEP>#<SEP> ppm = 6.7 <SEP> to <SEP> 7.5 <SEP> m <SEP> (OH <SEP> and <SEP > 7H
<tb><SEP> aromatic <SEP> and <SEP> CH = CH) <SEP>;<SEP> 4.2, <SEP> t <SEP> (OCH) <SEP>;
<tb><SEP> 42 <SEP>"<SEP>"<SEP>"<SEP> 3-OCH3 <SEP> C23H27NO4 <SEP> 365.45 <SEP> Oil <SEP> 3.82, <SEP> s <SEP> (OCH3) <SEP>;<SEP> 2.9. <SEP> t <SEP> (CH2-N) <SEP>;<SEP> 2.62,
<tb><SEP> q <SEP>(#)<SEP>;<SEP> 1,1, <SEP> t <SEP> (2CH3)
<tb> TABLE II

<SEP> Weight <SEP> Item <SEP> ANALYSIS <SEP> ELEMENTARY
<tb> Number <SEP> Formula
<tb><SEP> of <SEP>#<SEP> R <SEP> m <SEP> (R3) n <SEP> mol- <SEP> of <SEP> SPECTRUM <SEP> NMR
<Tb>

<SEP> gross
<tb><SEP> Code <SEP> cular <SEP> merge <SEP> SPECTER <SEP> IR
<Tb>

<SEP> (C)
<tb><SEP>%<SEP> C <SEP> H <SEP> N
<tb><SEP> 43 <SEP>#<SEP>#<SEP> 2 <SEP> 4,6-diOCH3 <SEP> C31H25NO5 <SEP> 501.60 <SEP> 130 <SEP> Cal. <SEP> 74.22 <SEP> 7.03 <SEP> 2.79
<tb><SEP> Tr. <SEP> 73.74 <SEP> 7.14 <SEP> 2.85
<tb><SEP> NMR <SEP> (CDCl3) <SEP>#<SEP> ppm = 6.5 <SEP> to <SEP> 7.4 <SEP> (15 <SEP> H <SEP> aro
<SEP> matters <SEP> and <SEP> CH = CH) <SEP>;<SEP> 5.08 <SEP> and <SEP> 5.1 <SEP> s
<sep>SEP> 44 <SEP>"<SEP> 3,4-di <SEP>"<SEP> 3,6-diOCH3 <SEP> C38H42NO6 <SEP> 607.672 <SEP> Oil <SEP> (2CH2O) <SEP>;<SEP> 4.1, t <SEP> (OCH2) <SEP>;<SEP> 3.65 <SEP> and <SEP> 3.78, <SEP> s
<tb><SEP>#<SEP>(2OCH3);<SEP> 2.6 <SEP> t <SEP> (CH2-N) <SEP>;<SEP> 2.4 <SEP> and <SEP> 1.5, <SEP> m
<tb><SEP>(#)
<Tb>
Example 3: (4-hydroxy-phenyl) -3 [3,6-dimethoxy-2- (piperidinoethoxy) -phenyl)
propene-2 one-1 (II)
Code number: 31
To a solution of 12 g of 3,6-dimethoxy (piperidinoethoxy) -2-acetophenone (III) obtained in Example 1 and 4.8 g of parahydroxybenzaldehyde (IV) in 60 ml of water, a solution is slowly added. 16.8 g of sodium hydroxide pellets in 18 ml of water. Then allowed to stir for 5 hours at room temperature, neutralized with 4 N hydrochloric acid, extracted with chloroform, washed with water, dried over sodium sulfate, filtered and the solvent evaporated. The expected product is obtained in crystalline form and with a yield of 47%.

 The characteristics of this product are listed in Table II.

 By the same method, but from the corresponding reagents, the compounds of formula (II) and code numbers: 29, 30 and 32 to 42 appearing in Table II are obtained.

Example 4: (4-Hydroxyphenyl) -3- (3,6-dimethoxy) hydrochloride (piperidino)
ethoxy) -2 phenyl] -1 propanone-1 (I)
Code number: 2
A solution of 14 g of compound of formula (II) of code number 31 obtained in the previous example and 3.65 g of potassium hydroxide pellets in a mixture of 250 L of water and 250 ml of ethanol in the presence of Raney nickel.

Then filtered, acidified with hydrochloric acid, concentrated, evaporated solvents, the residue in boiling alcohol and filtered hot.

The filtrate is evaporated and the residue is chromatographed on a silica column.

Elution with a mixture of methylene chloride (80%) and methanol (19%) concentrated ammonia (1%) gives 11.3 g (yield = 79%) of the expected product, the characteristics of which are listed in Table III below. .

 By the same method, but from the corresponding reagents, there is obtained the compound (I) of code number 1 shown in Table III.

Example 5: (4-hydroxy-phenyl) -3 [3,6-dimethoxy-2- (piperidinoethoxy) phenyl] -1-phenyl]
propanol (I)
Code number 10
A solution of 10 g of compound (II) of code number 31 obtained in Example 3, 4.6 g of sodium borohydride and 9.5 g of pyridine is refluxed under a nitrogen atmosphere. and 2.5 g of sodium hydroxide in 80 ml of ethanol. Then diluted with water, acidified with concentrated hydrochloric acid, neutralized with sodium bicarbonate, extracted with chloroform and dried over sodium sulfate. Then filtered, evaporated the filtrate, crystallizes the residue in petroleum ether and washed several times with ethyl ether. This gives 3.8 g (yield = 33%) of the expected product whose characteristics are listed in Table III.

 By the same method, but from the corresponding reagents, the compounds of formula (I) appearing in Table III and of code numbers 3 to 9 and 11 to 23 are obtained.

Example 6: (4-hydroxy-phenyl) -3 [3,6-dimethoxy-2- (piperidinoethoxy) phenyl] phenyl]
propanol (I)
Code number: 10
To a solution of 16 g of 3- (4-hydroxyphenyl) -3- (3,6-dimethoxy-2- (piperidinoethoxy) phenyl] -propanone-1 (1) (code number 2, base form), in 100 ml of methanol, a large excess of sodium borohydride (1 g) is slowly added in small portions. Then it is heated for 30 minutes at 500 ° C., the solvent is evaporated, the residue is taken up in water, neutralized with 1N hydrochloric acid, extracted with methylene chloride, dried over sodium sulphate, filtered and the solvent evaporated. . A product identical to that obtained in Example 5 is thus obtained with a yield of 85%.

 By the same method, but from the corresponding reagents, the compounds of formula (I) and of code numbers 3 to 9 and 11 to 23 appearing in Table III are obtained.

TABLE III

<SEP> Weight <SEP> Item <SEP> ANALYSIS <SEP> ELEMENTARY
<tb> No.
<Tb>

<SEP> A <SEP> R <SEP> m <SEP> (R3) n <SEP>#<SEP> Formula <SEP> gross <SEP> mol- <SEP> of <SEP> Form <SEP> OR <SEP> SPECTRUM <SEP> NMR
<Tb>

Code <SEP> cular <SEP> merge
<tb><SEP> (C)
<tb><SEP>%<SEP> C <SEP> H <SEP> N
<tb><SEP> NMR <SEP> (CDCl3) <SEP>#<SEP> ppm = 6.82 <SEP> m <SEP> and <SEP> 6, <SEP> 10, <SEP> s
<tb><SEP> (6H <SEP> aromatics0 <SEP>;<SEQ> 4.1, t <SEP> (OCH2) <SEP>;<SEQ> 3.72
<tb><SEP> 1 <SEP> -CD-CH2-CH2 <SEP> 4-OH <SEP> 2 <SEP>#<SEP> 4, o-diOCH3 <SEP> C24H31NO5 <SEP> 413.49 <SEP > 88 <SEP> and <SEP> 3.8 <SEP> s <SEP>(2CH3O);<SEP> 2.4 <SEP> to <SEP> 3, m <SEP> (10 <SEP> H:
<tb><SEP> COCH2CH2 <SEP> and <SEP>#<SEP>);<SEP> 1.5, m
<tb><SEP> (CH2CH2CH2)
<tb><SEP> Cal. <SEP> 64.06 <SEP> 7.17 <SEP> 3.11
<tb><SEP> 2 <SEP> -CD-CH2-CH2- <SEP>"<SEP>"<SEP>"<SEP> 3,6-diOCH3 <SEP> C24H32ClNO5 <SEP> 449.96 <SEP> 181 <SEP> HCl
<tb><SEP> Tr. <SEP> 63.93 <SEP> 7.09 <SEP> 3.08
<tb><SEP> Cal. <SEP> 72.15 <SEP> 8.33 <SEP> 3.51
<tb><SEP> 3 <SEP> -CH-CH2-CH2 <SEP> H <SEP>"<SEP>"<SEP>"<SEP> C24H33NO4 <SEP> 399.51 <SEP> 79 <SEP> Base
<tb><SEP> Tr. <SEP> 72.04 <SEP> 8.51 <SEP> 8.45
<tb><SEP> OH <SEP> Cal. <SEP> 69.04 <SEP> 7.73 <SEP> 3.36
<tb><SEP> 4 <SEP>"<SEP> 4-F <SEP>"<SEP>"<SEP>"<SEP> C24H32FNO4 <SEP> 417,50 <SEP> Oil <SEP>"
<tb><SEP> Tr. <SEP> 68.49 <SEP> 7.56 <SEP> 3.15
<tb> TABLE III (continued)

<SEP> Weight <SEP> Item <SEP> ANALYSIS <SEP> ELEMENTARY
<tb> No.
<Tb>

<SEP> A <SEP> R <SEP> m <SEP>#<SEP> (R3) n <SEP> Formula <SEP> gross <SEP> mol- <SEP> of <SEP> Form <SEP> OR <SEP> SPECTRUM <SEP> NMR
<Tb>

Code <SEP> cular <SEP> merge
<tb><SEP> (C) <SEP>% <SEP> C <SEP> H <SEP> N
<tb><SEP> Cal. <SEP> 66.42 <SEP> 7.43 <SEP> 3.23
<tb><SEP> 5 <SEP> -CH-CH2-CH2- <SEP> 4-Cl <SEP> 2 <SEP>#<SEP> 3,6-dIOCH3 <SEP> C24H32CHNO4 <SEP> 433.96 <SEP> Oil <SEP> Base
<tb><SEP> OH <SEP> Tr. <SEP> 65.80 <SEP> 7.95 <SEP> 3.34
<tb><SEP> Cal. <SEP> 72.61 <SEP> 8.53 <SEP> 3.39
<tb><SEP> 6 <SEP>"<SEP> 4-CH3 <SEP>"<SEP>"<SEP>"<SEP> C25H35NO4 <SEP> 413.54 <SEP>"<SEP>"
<tb><SEP> Tr. <SEP> 72.31 <SEP> 8.58 <SEP> 3.27
<tb><SEP> Cal. <SEP> 69.90 <SEP> 8.21 <SEP> 3.26
<tb><SEP> 7 <SEP>"<SEP> 4-CH3O <SEP>"<SEP>"<SEP>"<SEP> C25H35NO5 <SEP> 429.54 <SEP>"<SEP>"
<tb><SEP> Tr. <SEP> 69.25 <SEP> 8.33 <SEP> 3.14
<tb><SEP> HCl <SEP> + <SEP> Cal. <SEP> 61.22 <SEP> 7.73 <SEP> 2.48
<tb><SEP> 8 <SEP>"<SEP> 2-OH <SEP>"<SEP>"<SEP>"<SEP> C24H34ClNO4 <SEP> 470.81 <SEP> 88 <SEP> 4 <SEP> % <SEP> H2O
<tb><SEP> + <SEP> 4 <SEP>% <SEP> H2O
<tb><SEP> Tr. <SEP> 61.50 <SEP> 7.93 <SEP> 2.97
<tb> TABLE III (continued)

<SEP> Weight <SEP> Item <SEP> ANALYSIS <SEP> ELEMENTARY
<tb> No.
<Tb>

<SEP> A <SEP> R <SEP> m <SEP>#<SEP> (R3) n <SEP> Formula <SEP> gross <SEP> mol- <SEP> of <SEP> Form <SEP> OR <SEP> SPECTRUM <SEP> NMR
<Tb>

Code <SEP> cular <SEP> merge
<tb><SEP> (C) <SEP>% <SEP> C <SEP> H <SEP> N
<tb><SEP> Cal. <SEP> 69.31 <SEP> 8.01 <SE> 3.37
<sep> 9 <SEP> -CH-CH2-CH2- <SEP> 3-OH <SEP> 2 <SEP>#<SEP> 3,6-diOCH3 <SEP> C24H33NO5 <SEP> 415.52 <SEP> 128 <SEP> Base
<tb><SEP> OH <SEP> Tr. <SEP> 69.25 <SEP> 8.02 <SEP> 3.19
<tb><SEP> Cal. <SEP> 69.31 <SEP> 8.02 <SEP> 3.37
<tb><SEP> 10 <SEP>"<SEP> 4-OH <SEP>"<SEP>"<SEP>"<SEP> C24H33NO5 <SEP> 415.52 <SEP> 142 <SEP>"
<tb><SEP> Tr. <SEP> 69.29 <SEP> 8.01 <SEP> 3.21
<tb><SEP> Cal. <SEP> 69.90 <SEP> 8.21 <SEP> 3.26
<tb><SEP> 11 <SEP>"<SEP>"<SEP> 3 <SEP>"<SEP>"<SEP> C25H35NO5 <SEP> 429.54 <SEP> 118 <SEP>"
<tb><SEP> Tr. <SEP> 69.95 <SEP> 8.35 <SEP> 3.30
<tb><SEP> Cal. <SEP> 68.46 <SEP> 8.24 <SEP> 3.47
<tb><SEP> 12 <SEP>"<SEP>"<SEP> 2 <SEP>#<SEP>"<SEP> C23H33NO5 <SEP> 403.50 <SEP> 90 <SEP>"
<tb><SEP> Tr. <SEP> 68.28 <SEP> 8.39 <SEP> 3.46
<tb> TABLE III (continued0

<SEP> Weight <SEP> Item <SEP> ANALYSIS <SEP> ELEMENTARY
<tb> No.
<Tb>

<SEP> A <SEP> R <SEP> m <SEP>#<SEP> (R3) n <SEP> Formula <SEP> gross <SEP> mol- <SEP> of <SEP> Form <SEP> OR <SEP> SPECTRUM <SEP> NMR
<Tb>

Code <SEP> cular <SEP> merge
<tb><SEP> (C) <SEP>% <SEP> C <SEP> H <SEP> N
<tb><SEP> Cal. <SEP> 68.80 <SEP> 7.78 <SEP> 3.49
<tb><SEP> 13 <SEP> -CH-CH2-CH2- <SEP> 4-CH <SEP> 2 <SEP>#<SEP> 3,6-diOCH3 <SEP> C23H31NO5 <SEP> 401.49 <SEP> 159 <SEP> Base
<tb><SEP> Tr. <SEP> 68.14 <SEP> 7.84 <SEP> 3.52
<tb><SEP> 3/4
<tb><SEP> C25H35NO6 <SEP> Cal. <SEP> 62.03 <SEP> 7.17 <SEP> 2.73
<tb><SEP> 14 <SEP>"<SEP>"<SEP>"<SEP>#<SEP> 3,4,5,6- <SEP> 513,06 <SEP> 175 <SEP> oxalate
<tb><SEP> triOCH3 <SEP> + <SEP> 3/4 <SEP> HOOC-COOH
<tb><SEP> Tr. <SEP> 61.89 <SEP> 7.32 <SEP> 2.73
<tb><SEP> Cal. <SEP> 67.39 <SEP> 7.92 <SEP> 3.14
<tb><SEP> 15 <SEP>"<SEP>"<SEP>"<SEP>"<SEP> 4,5,6- <SEP> C25H36NO6 <SEP> 445.54 <SEP> 177 <SEP> Base
<tb><SEP> triOCH3
<tb><SEP> Tr. <SEP> 67.16 <SEP> 8.08 <SEP> 2.89
<tb><SEP> 0.5 <SEP> oxa
<SEP> C24H32NO6 <SEP> late <SEP> Cal <SEP> 66.17 <SEP> 8.00 <SEP> 3.22
<tb><SEP> 16 <SEP>"<SEP>"<SEP>"<SEP>"<SEP> 6-OH <SEP> 435.56 <SEP> 148 <SEP> + <SEP> 1.2 <SEP>%
<tb><SEP> + <SEP> 1,2 <SEP> 5 <SEP> H2O <SEP> H2O
<tb><SEP> Tr. <SEP> 66.32 <SEP> 7.62 <SEP> 3.17
<tb> TABLE III (continued)

<SEP> Weight <SEP> Item <SEP> ANALYSIS <SEP> ELEMENTARY
<tb> No.
<Tb>

<SEP> A <SEP> R <SEP> m <SEP>#<SEP> (R3) n <SEP> Formula <SEP> gross <SEP> mol- <SEP> of <SEP> Form <SEP> OR <SEP> SPECTRUM <SEP> NMR
<Tb>

Code <SEP> cular <SEP> merge
<tb><SEP> (C) <SEP>% <SEP> C <SEP> H <SEP> N
<tb><SEP> Cal. <SEP> 66.17 <SEP> 7.48 <SEP> 3.36
<sep> 17 <SEP> -CH-CH2-CH2- <SEP> 4-OH <SEP> 2 <SEP>#<SEP> 3,6-diOCH3 <SEP> C23H31NO6 <SEP> 417.49 <SEP> 107 <SEP> Base
<tb><SEP> OH
<tb><SEP> Tr. <SEP> 65.88 <SEP> 7.70 <SEP> 3.47
<tb><SEP> C21H29N96 <SEP> Base <SEP> + <SEP> Cal. <SEP> 66.43 <SEP> 7.83 <SEP> 3.69
<tb><SEP> 18 <SEP>"<SEP>"<SEP>"<SEP>#<SEP>"<SEP> 379.70 <SEP> 105 <SEP> 1.1 <SEP>%
<tb><SEP> + <SEP> 1,1 <SEP>%
<tb><SEP> H2O
<tb><SEP> Tr. <SEP> 66.03 <SEP> 7.98 <SEP> 3.86
<tb><SEP> Cal. <SEP> 66.49 <SEP> 8.14 <SEP> 3.23
<tb><SEP> 19 <SEP>"<SEP>"<SEP>"<SEP>#<SEP> 3,4,6- <SEP> C24H35NO6 <SEP> 433.53 <SEP> 112 <SEP> Base
<tb><SEP> triOCH3
<tb><SEP> Tr. <SEP> 66.40 <SEP> 8.48 <SEP> 2.93
<tb><SEP> C25H33NO8 <SEP> Oxalate <SEP> Cal <SEP> 62.07 <SEP> 7.07 <SEP> 2.90
<tb><SEP> 20 <SEP>"<SEP>"<SEP>"<SEP>"<SEP> 3-OCH3 <SEP> 483.75 <SEP> 103 <SEP> + <SEP> 1.7 <SEP>%
<tb><SEP> + <SEP> 1.7 <SEP>% <SEP> H2O <SEP> H2O
<tb><SEP> Tr. <SEP> 62,24 <SEP> 7,14 <SEP> 3,04
<tb> TABLE III (continued)

<SEP> Weight <SEP> Item <SEP> ANALYSIS <SEP> ELEMENTARY
<tb> No.
<Tb>

<SEP> A <SEP> R <SEP> m <SEP>#<SEP> (R3) n <SEP> Formula <SEP> gross <SEP> mol- <SEP> of <SEP> Form <SEP> OR <SEP> SPECTRUM <SEP> NMR
<Tb>

Code <SEP> cular <SEP> merge
<tb><SEP> (C) <SEP>% <SEP> C <SEP> H <SEP> N
<tb><SEP> NMR <SEP> (CDCl3) <SEP>#<SEP> ppm = 6.8 <SEP> to <SEP> 7.5, m <SEP> 9 <SEP> H)
<tb><SEP> Oxalate <SEP> aromatics) <SEP>;<SEP> 6.25, s <SEP> (2 <SEP> H <SEP> aroti
<SEP> 21 <SEP> -CH-CH2-CH2- <SEP>#<SEP> 2 <SEP>#<SEP> 4,6-diOCH3 <SEP> C31H39NO5 <SEP> 505.63 <SEP> Oil <SEP > + <SEP> 1.7 <SEP>% <SEP> ques <SEP> in <SEP> 3 <SEP> and <SEP>5);<SEP> 5.05 <SEP> s <SEP> (COH2- #);
<tb><SEP> H2O <SEP> 5.1, m <SEP>(CH-O);<SEP> 4.1m <SEP> (OH <SEP> and <SEP> OCH2)
<tb><SEP> OH <SEP> 3.8 <SEP> s <SEP> (2CH3O) <SEP>;<SEP> 2 <SEP> to <SEP> 2,3 <SEP> M <SEP> (10 <SEP> H
<tb><SEP> -CH2-CH2 <SEP> and <SEP>#)<SEP>;<SEP> 1.4 <SEP> A <SEP> 1.8
<tb><SEP> m <SEP>(#)
<tb><SEP> NMR <SEP> (CDCl3) <SEP>#<SEP> ppm = 7.2 <SEP> to <SEP> 7.6, <SEP> M <SEP> (10 <SEP> H)
<tb><SEP> benzyl) <SEP>;<SEP> 6.6 <SEP> to <SEP> 6.9 <SEP> m <SEP> (5 <SEP> H <SEP> aro
<SEP> topics) <SEP>;<SEP> 5.1, s <SEP> (30CH2M) <SEP>;<SEP> 5 <SEP> to
<tb><SEP> 5.3, <SEP> m <SEP> (CH <SEP> and <SEP> CH-O) <SEP>;<SEP> 4, <SEP> and <SEP> 3,4 <SEP> m
<tb><SEP> OH <SEP> (OCH2) <SEP>;<SEP> 3.7 <SEP> and <SEP> 3.78, <SEP> s <SEP>(2OH3O);
<sep>SEP> 22-SEP-CH 2 CH 2 -CH 2 SEP 3,4-di-SEP-SEP-3,6-diOCH 3 -MSP-C 38 H 45 NO 6 SEP 611, <SEP><SEP> Base <SEP> 2.2 <SEP> to <SEP> 2.6 <SEP> m <SEP> and <SEP> 1.4 <SEP> To <SEP> 1.8, <SEP> m
<tb><SEP>#<SEP> (CH2CH2 <SEP> and <SEP>#)
<tb><SEP> C24H34ClNO6 <SEP> HCl <SEP> + <SEP> Cal. <SEP> 58.63 <SEP> 7.61 <SEP> 2.85
<tb><SEP> 23 <SEP>"<SEP> 3,4-DiOH <SEP>"<SEP>"<SEP>"<SEP> 491.57 <SEP> 140 <SEP> 4.8 <SEP> %
<tb><SEP> + <SEP> 4,8 <SEP>% <SEP> H2O <SEP> H2O
<tb><SEP> Tr. <SEP> 58.66 <SEP> 7.42 <SEQ> 2.67
<Tb>
EXAMPLE 7 Parabenzyloxyphenyl-3 - [(2-piperidino-ethoxy) -2-dimethoxy-4,6
phenyl-1-hydroxy-1 propane (I)
Code number: 21
A suspension of 0.5 g of 3-parabenzyloxyphenyl-3- (2-piperidino-ethoxy) -2-dimethoxy-phenyl-1-propen-2-one-1 (IIa) is refluxed for 90 minutes (code number 43). and 0.2 g of sodium borohydride in 10 1 of ethanol and 1 to 2 drops of concentrated sodium hydroxide. Then it is diluted with water, extracted with ethyl acetate, washed with water, dried over sodium sulphate, filtered and the filtrate is evaporated. This gives 0.4 g (yield = 80%) of the expected product (oily) whose characteristics are listed in Table III.

 By the same method, but from the corresponding reagents, the compounds of formula (I) of code numbers 3 to 7 and 22 appearing in Table III are obtained.

Example 8: (3,4-Dihydroxy) -3-phenyl-3- (2-piperidinoethoxy) hydrochloride
3,6-dimethoxyphenyl] -1-hydroxy-propane (I)
Code number: 23
A suspension of 13 g of compound (I) of code number 22 and 1.3 g of palladium on carbon is hydrogenolyzed in an autoclave at a pressure of 4 bar at a temperature of 300 ° C. for 7 hours. at 10% in 300 ml of ethanol and 1 to 2 drops of 5N hydrochloric ethanol. Then the mixture is filtered, the residue is taken up in chloroform, washed with a dilute solution of ammonia, and then with water, dried over sodium sulphate, filtered, the filtrate is evaporated and the residue is crystallized from petroleum ether. The precipitate obtained is dissolved in ethanol, hydrochloric ethanol is added, the solvent is evaporated and the residue is crystallized. ether. 2.3 g (yield = 22%) of the expected product are obtained whose characteristics are listed in Table III.

 By the same process ,. but from the corresponding reagents, the compounds of formula (I) of code number 8 to 20 appearing in Table III are obtained.

 The compounds of formula (I) and their salts have been studied in experimental animals and have shown pharmacological activities and in particular an inhibitory activity of trans-membrane transfer of calcium.

 These activities were particularly highlighted by the depolarization test of the isolated coronary arteries of dogs, carried out according to the following protocol.

 Dogs of both sexes weighing 12 to 25 kg are anesthetized with pentobarbital sodium (30 mg / kg / v) and the interventricular branch of the left coronary artery is removed. Fragments are cut in the proximal portion (1.5 cm in length and 2 mm in diameter) and distal (0.5 to 1 cm in length and in diameter 0.5 mm) and are kept in a Tyrode bath at 370 C balanced by a constant flow of a mixture of 95% oxygen and 5% carbon dioxide. They are connected to an isotonic myograph at a tension of 1.5 g for the fragment from the proximal portion (proximal fragment) and 0.2 g for the fragment from the distal portion (distal fragment). One hour after obtaining from equilibrium, the survival medium is replaced by a hyperpotassium medium (35 mM / 1) and the smooth muscles contract. The addition of the derivatives of formula (I) or of their salts then causes a relaxation of these muscles.

Some results obtained with the derivatives of formula (I) and their salts in the abovementioned test are summarized as examples in Table IV below, which also lists the acute toxicity of the compounds tested and which is estimated in mice. according to the method of MILLER and
TAINTER (Proc.Soc.Expl., Biol.Med. (1944), 57, 261)
TABLE IV

<SEP> Dose <SEP> of <SEP> derived <SEP> tested <SEP> causing <SEP> a
<tb> Number <SEP> DL <SEP><SEP> Mouse <SEP> decrease <SEP> of <SEP> 50 <SEP>% <SEP> of <SEP> the <SEP> contraction
<tb><SEP> of <SEP> induced <SEP> by <SEP> the <SEP> medium <SEP> hyperpotassium
<tb><SEP> (mg / kg / iv)
<tb><SEP> Code <SEP> [IC <SEP> 50 <SEP> (Moles)]
<tb><SEP> fragment <SEP> proximal <SEP> fragment <SEP> distal
<tb><SEP> 2 <SEP> 14 <SEP> 6,4.10-6 <SEP> 1,3,10-6
<tb><SEP> 5 <SEP> 33 <SEP> 1,6.10-6 <SEP> 5,4,10-7
<tb><SEP> 10 <SEP> 20 <SEP> 2,1.10-7 <SEP> 1,9,10-7
<tb><SEP> 12 <SEP> 23 <SEP> 9.10-8 <SEP> 1
<tb><SEP> 14 <SEP> 33 <SEP> 2,910-7 <SEP> 2,4,10-7
<Tb>
The difference between the toxic doses and the active doses allows the therapeutic use of the derivatives of formula (I) and their salts, inter alia for the treatment of disorders related to a disruption of intra and extra cellular movements of calcium, and in particular disorders of the cardiovascular system, particularly as antiangorous, antiarrhythmic, antihypertensive and vasodilator.

 The present invention also relates to pharmaceutical compositions containing at least one derivative of formula (I) or a salt thereof, in combination with a pharmaceutically acceptable carrier.

 These compositions will for example be administered orally in the form of tablets, dragees or capsules containing up to 500 mg of active ingredient (1 to 5 per day) and in the form of drops dosed up to 10 k (20 drops, 3 times). per day), rectally in the form of suppositories containing up to 30C mg of active ingredient (1 to 2 per day) or in the form of injectable ampoules containing up to 300 mg of active ingredient (1 to 2 per day) ).

Claims (16)

claims  1. Novel aminoalkoxy aromatic derivatives having the general formula

 in which - R represents a hydrogen atom; one or two halogen atoms; or one or  two methyl, hydroxyl, alkyloxy groups of 1 to 4 carbon atoms or  benzyloxy R 1 and R 2 each represent an alkyl group having from 1 to 4 carbon atoms  carbon, or together with the nitrogen atom to which they are bound  a heterocyclic group chosen from the following: pyrrolidino, piperidino,  morpholino - m is 2 or 3 R3 is alkyloxy having 1 to 4 carbon atoms - n is 1, 2 or 3; and - A rePreSente a sequence propyl-one-1  123 (-CO-CH2-CH2-) or 1-hydroxypropyl

 the aromatic group bearing the aminoalkoxy chain being attached in position 1 of these sequences, as well as their pharmaceutically acceptable mineral or organic acid addition salts.  2. Derivatives and salts according to claim 1 characterized in that A represents the sequence propyl-1-one (-CO-CH2-CH2-)  3. Derivatives and salts according to claim 2, characterized in that the set [R,

 takes one of the following values [4-OH, 4,6-diOCH3, [4-OH, 3,6-diOCH3, 2,

 4. Derivatives and salts according to claim 1, characterized in that A represents the 1-hydroxypropyl chain

  5. Derivatives and salts according to claim 4, characterized in that the set [R, (R3) n m,

 takes one of the following values

 (4-F, 3,6-diOCH3, 2,

 in which R, R 1, R 3, n and m have the same meanings as in claim 1, and then optionally salify the compounds obtained by adding a mineral or organic acid.

 6. Process for the preparation of the derivatives of formula (I) and of their salts, for which A represents the sequence propyl-one-1 (-CO-CH 2 -CH 2 -), characterized in that it consists in reducing by hydrogenation catalytic compounds of formula  7. Process according to claim 6, characterized in that the reduction is carried out by Raney nickel in a hydroalcoholic medium.  8. Process for the preparation of the derivatives of formula (I) and of their salts, for which A represents the 1-hydroxypropyl linkage

 characterized in that it consists in reducing the compounds of formula (II), defined in claim 6, by the sodium borohydride-pyridine complex in the presence of sodium hydroxide, the latter being in at least a stoichiometric amount when R, in the formula (II) represents a hydroxyl group and in an amount at least twice stoichiometric when R represents two hydroxyl groups, then optionally salifying the compounds obtained by adding a mineral or organic acid.  9. Process according to claim 8, characterized in that the sodium hydroxide is used in concentrated form and in that the reduction is carried out in an alcoholic medium.  10. Process for the preparation of the derivatives of formula (I) and of their salts, for which A represents the 1-hydroxypropyl chain

 characterized in that it consists in reducing the compounds of formula (I) for which A represents the sequence propyl-one-1 (-CO-CH 2 -CH 2 -) by sodium borohydride, preferably in an alcoholic medium, then optionally salifying the compounds obtained, by adding a mineral or organic acid.  11. Process for the preparation of the derivatives of formula (I) and of their salts, for which A represents the 1-hydroxypropyl chain

 and R represents the hydrogen atom, one or two halogen atoms, or one or two methyl, alkyloxy groups of 1 to 4 carbon atoms or benzyloxy, characterized in that it consists in reducing by an excess of sodium borohydride, the compounds of the formula

 in which Rt, R2, m, n and R3 have the same meaning as in formula (I) defined in claim 1, R 'having the same meanings as R in claim 1, but without being able to represent one or two hydroxyl groups, and optionally to salify the compounds obtained, by adding a mineral or organic acid.  12. Process for the preparation of the compounds of formula (I) and of their salts, for which A represents the hydroxylpropyl chain

 and R represents one or two hydroxyl groups, characterized in that it consists of hydrogenolysing the corresponding compounds of formula (I) for which R represents one or two benzyloxy groups.  13. The method of claim 12, characterized in that the hydrogenolysis is carried out in the presence of palladium on charcoal.  .14. As medicaments, especially against conditions due to physiological disorders of calcium, the derivatives and salts of claims 1 to 5.  15. Pharmaceutical composition, characterized in that it comprises at least one derivative or salt according to claims 1 to 5, in combination with a pharmaceutically acceptable carrier.  16. As intermediates necessary for the synthesis of the compounds of formula (I), the compounds of formula (II) defined in claim 6, as well as compounds of formula

 wherein R1, R2, R3, n and m have the same meanings as in claim 1.