Hexahydropyrimidines. IV.1 Synthesis ... - ACS Publications

reduction. 20. 400. 0.267. 36. 100 .067. 38. 40 .027. 36. 20 .013. 36. 10 .007. 29. 5 .0033. 11. 2.5 .0017. 4. 1. 312 .208. 6. 2. 156 . 104. 4. 4. 100...
0 downloads 0 Views 374KB Size
SOTES

,January, 19G4 TABLE I1

Compound

20

1 2 4

5 6

S 10 11 15

16 17 18 22

Triparanol

a

Calculated dose, mg./kg./day

115

IV. Synthesis of 2- [4(N,N-Bis(2-chloroethyl)amino)aryl]-1,3-bis-

Hexahydropyrimidines. Response,a Concentration. % i n diet

400 100 40 20 10 5 2 3 312 156 100 10 100 .io0 230 500 100 100 312 100

-_ 43

219 10 100 10 500 250 100 100 10

0.267 ,067 ,027 ,013 ,007 ,0033 ,0017 208 104 . 067 ,007 . 067 ,333 ,167 ,333 ,067 ,067 ,208 ,067 ,050 ,146 ,007 ,067 ,007 ,333 ,167 ,067 ,067 ,007

% reduction

36 38 36 36 29 11

(aralky1)hexahydropyrimidines as Antitumor Agents2 JOHN H. BILLMAN AND

48 31 65 22 30 34 0 6

57 0 46

5 0

17 49

49 27

%reduction = 100

limited. At the end of treatment (1 or 2 weeks) the mice were bled by heart puncture, the bloods were centrifuged, and the plasma separated. Cholesterol determination was done on the plasma for each mouse. Experimental3 Preparation of Carbinols. Sodamide (Method A).-Sodamide was added portionwise to an excess of 7-picoline stirred and cooled in ice-water. This mixture frequently became very dark as the picolyl sodium formed. The appropriate ketone dissolved in additional ?-picoline was added very rapidly and the resulting mixture was stirred overnight. This mixture was then poured into a large excess of water and allowed to crystallize. After filtering, the products could then be recrystallized from a suitable solvent. General Grignard Procedure (Method B).-To the Grignard solution prepared from 0.2 g.-atom of magnesium and 0.2 mole of p-chlorobenzyl chloride in 100 ml. of ether was slowlv added a suspension of 0.19 mole of the pyridyl ketone in 300 ml. of ether with stirring. The mixture was then heated to reflux for 4 hr. with continued stirring. The reartion mixture was then decomposed by the addition of an equivalent of ammonium chloride in saturated aqueous solution. The salts were filtered and washed with more ether which was then concentrated to a n oil by distilling the ether. The residual oil was distilled an uacuo and the product rwrystallized from a suitable solvent.

Acknowledgment.-We are indebted to Dr. John Schmidt and Don Martin for the pharmacological screening and to E. F. Shelberg and his staff for analytical data. We wish to thank Dr. James Short of the Organic Chemistry Department for help and suggestions. (3) ?,felting points were taken on a Hoover capillary melting point app a r a t u s n i t h the thermometer calibrated against melting point standards.

L.

hIEISENHEIMER3

Department of Chemistry, Indiana University, Blooniington, Indiana

4 6

4 27 0 36

JOHN

Received September 12, 1963

In a recent publication, the synthesis of a number of 1,2,3,-substituted hexaliydropyrimidines as potential antitumor agents was reported.’ It was suggested that these compounds I may be thought of as potential aldehydes, since they can hydrolyze under mild acid conditions to liberate the free aldehyde 11.

n

ArCH2NyKCHzAr

H’,

H20

A

Ar‘CHO

I1

-H20

+

CH I

Ar ’ I

ArCHZNH(CHz)3NHCHzAr

I11

The available test data for those hexahydropyrimjdines indicated no significant activity when screened in the carcinoma 755, sarcoma 180, and leukemia 1210 systems. However, the 2-substituted l13-bis(p-methoxybenzy1)hexahydropyrimidines prepared from benzaldehyde, 2,4-dichlorobenza1dehydeland o-ethoxybenzaldehyde displayed reproducible activity in a tissue culture screen. These results suggest that possibly a more potent cytotoxic aldehyde is necessary for in vivo antitumor activity. To this end, hexahydropyrimidines have been prepared from benzaldehyde nitrogen mustard IT’ and o-tolualdehyde nitrogen mustard Y. CHO

(yH3 CHO

N(CH2CH,C1)2 V

Due to the potential alkylating action of the nitrogen mustard grouping, the derivatives of these aldehydes might show selective antitumor activity if they are released preferentially a t the tumor site, unless, of course, the nitrogen mustard grouping is capable of more rapid alkylation from the hexahydropyrimidine transport molecule. The hexahydropyrimidines reported in Table I were synthesized by condensing the aldehydes IT.’or 1 nith secondary 1,3-diamines of the general structure I11 in a refluxing solution of ethanol or acetonitrile. The latter solvent was found to be much preferred in two of the syntheses. The diamines I11 mere prepared by reduction of the corresponding di-Schiff base VI. (1) J H 13illman a n d J L lleisenheimer part 111 J Ired Chem , 6 682 (1963) (2) This in5estigation u a s supported b y a Public Health S e n i c e Fellow ship (GF-13.650) from the Dir ision of General Medical Sclences, National Institutes of Health, Public Health S e n i c e (3) National Institutes of Health Fellow, 1961-1963 Taken from the P h D thesis of J. L. ?,I., Indiana University, 1963.

I

VI

a, Ar b, Ar c, Ar ti, Ar

= = =

=

.2rCH?SH(CH2)1SHCFI..2r I1 I p-rnethosyphenyl p-chlorophenyl 2,bdichlorophenyl 3,4-dichlorophenyl

-1low-pressure hydrogenation of compound I'Ia using platinum oxide catalyst furnished X,X'-bis(p-methoxyhenzyl)-l ,&diaminopropane IIIa. The other diamines were obtained by reduction of the corresporiding diSchiff base with sodium b ~ r o h y d r i d e . ~The di-Schiff bases were prepared by treating the appropriate aromatic aldehyde with 1,3-diaminopropane in a molar ratio of 2 : l . For example, compound VIh was ohtained from p-chlorohenzaldehyde and 1,: